HTML 특수문자 리스트 (√ √ √ π ø ｍ²ｍ³ ｍ⁴, ¹ ² ³ ⁴, ₁₂₃₄, ㄷ ＋ － × ÷ ± ≤ ≥ ℃ ▶ ㅊ √ax2 + bx + c

시작시간 = [2025-04-03 10:26:30.0207]
req=[org.apache.catalina.connector.RequestFacade@8025ec7]
res=[org.apache.catalina.connector.ResponseFacade@539c5eec]
conn=[com.mysql.jdbc.JDBC4Connection@1840a51d]
cdAry[0] = []
cdAry[1] = [TABLE 1.1) String uAry[][]
query[0] = Select sid, SYMBOL, UNIT, DESCR, kid From S_DATA Where kid=8 and sid=0

sid	SYMBOL	UNIT	DESCR	kid
0	PUnit	kg/cm²	0 | kg/cm² | 입력 압력단위 (Pressue Input Unit) = kg/cm² |	8

]
cdAry[2] = [TABLE 2.1) String bAry[][] = S_RESULT
query[1] = Select sid, DESCR, UNIT, SYMBOL, T1,T2,T3,T4,T5,T6,T7,T8,T9,T10,REMARK From S_RESULT Where kid=8 and sid<100 Order By sid

sid	DESCR	UNIT	SYMBOL	T1	T2	T3	T4	T5	T6	T7	T8	T9	T10	REMARK
0	Nominal Capacity [공칭용량]	m³	V_nom	2572.440	3053.630	3053.630	3053.630	8181.230	696.910	2500.490	2006.970	904.780	381.700
1	Storage Capacity [저장용량]	m³	V_sto	2421.910	2752.170	2752.170	2752.170	8143.010	538.330	2241.580	1950.430	876.950	370.320
2	Vapor Space Capacity	m³	V_hil	150.530	301.460	301.460	301.460	38.220	158.580	258.910	56.540	27.830	11.380
3	Storage Capacity Ratio	%	R_Sto	94.150	90.130	90.130	90.130	99.530	77.250	89.650	97.180	96.920	97.020
4	Vapor Space Ratio	%	R_vapor	5.850	9.870	9.870	9.870	0.470	22.750	10.350	2.820	3.080	2.980
10	A. WEIGHT SUMMARY
11	SHELL PLATE	Ton	Ws	317.351	319.336	318.935	318.935	1268.664	121.299	153.848	205.811	37.638	16.996
12	UPPER COLUMN (PLATE)	Ton	Wuc	6.958	13.819	13.819	13.819	32.372	1.900	6.905	6.648	2.643	1.711
13	LOWER COLUMN (PIPE)	Ton	Wc	14.901	22.934	22.934	22.934	56.334	4.503	13.933	20.978	4.079	3.273
14	CROSS BRACE (PIPE)	Ton	Wb	12.004	15.547	15.547	15.547	38.771	2.853	11.396	16.625	2.830	2.169
15	ROOF PLATFORM & STAIRWAY	Ton	Wr	13.411	20.641	20.641	20.641	50.701	4.053	12.540	18.880	3.671	2.946
16	WATER SPRAY AND ATTACHMENT	Ton	Wsp	11.921	18.347	18.347	18.347	45.067	3.602	11.146	16.782	3.263	2.618
17	MANHOLE & NOZZLE	Ton	Wn	12.200	16.300	16.300	16.300	19.500	8.100	12.200	12.200	8.100	8.100
18	INTERNAL LADDER & ATTACHMENT	Ton	Wi	9.626	12.861	12.861	12.861	15.386	6.391	9.626	9.626	6.391	6.391
19	ANCHOR BOLT/NUT	Ton	Wa	3.180	3.180	3.180	3.180	4.452	1.908	3.180	3.180	2.544	1.908
20	COLUMN FIRE PROOFING	Ton	Win	30.200	40.300	40.300	40.300	70.500	20.100	30.200	30.200	20.100	20.100
21	BLANK 1	Ton	W_1
22	BLANK 2	Ton	W_2
23	BLANK 3	Ton	W_3
24	BLANK 4	Ton	W_4
25	BLANK 5	Ton	W_5
26	Lower-Column O.D	mm	Dcol	609.600	914.400	914.400	914.400	1066.800	406.400	609.600	609.600	406.400	406.400
27	Lower-Column Thickness	mm	Tcol	12.700	14.000	14.000	14.000	16.000	12.700	12.700	12.700	12.700	12.700
28	Cross-Brace O.D	mm	Dbrace	273.100	273.100	273.100	273.100	323.500	168.300	273.100	219.100	168.300	168.300
29	Cross-Brace Thickness	mm	Tbrace	9.300	12.700	12.700	12.700	15.600	7.100	9.300	12.700	7.100	7.100
30	■ EMPTY WEIGHT (1 Unit)	Ton	We	431.750	483.270	482.860	482.860	1601.750	174.710	264.970	340.930	91.260	66.210	We = W(1)+ .. +W(10)
31	B. LOADING DATA
32	CONTENTS WEIGHT (at Operating)	Ton	Wc	1302.990	1786.160	1720.110	1640.290	4885.810	288.540	1448.060	1212.190	438.480	185.160	Wc = Vsto * S.G
33	HYDROSTATIC TEST WATER WEIGHT	Ton	Wt	2572.440	3053.630	3053.630	3053.630	8181.230	696.910	2500.490	2006.970	904.780	381.700	Wt = Vnom * 1.0
34	1) VERTICAL LOAD
35	EMPTY WEIGHT	Ton	We	431.750	483.270	482.860	482.860	1601.750	174.710	264.970	340.930	91.260	66.210	We = W(1)+ .. +W(10)
36	OPERATING WEIGHT	Ton	Wo	1734.740	2269.430	2202.970	2123.150	6487.560	463.250	1713.030	1553.120	529.740	251.370	Wo = We + Wc
37	HYDROSTATIC TEST WEIGHT	Ton	Wh	3004.190	3536.900	3536.490	3536.490	9782.980	871.620	2765.460	2347.900	996.040	447.910	Wh = We + Wt
38	2) HORIZONTAL LOAD
39	SEISMIC FACTOR (CS=0.25 Fix)		CS	0.250	0.250	0.250	0.250	0.250	0.250	0.250	0.250	0.250	0.250
40	SEISMIC LOAD (Base Shear) Vs = CS x Wo	Ton	Vs	433.690	567.360	550.740	530.790	1621.890	115.810	428.260	388.280	132.440	62.840	Vs = CS x Wo
41	WIND LOAD (Base Shear)	Ton	Vw

]
cdAry[3] = [TABLE 3.1) String cAry[][] = S_DETAIL, cAry.length = [36] cAry[0].length = [12]
query[2] = Select sid, SYMBOL, T1,T2,T3,T4,T5,T6,T7,T8,T9,T10 From S_DETAIL Where kid=8 and sid<100 Order By sid

sid	SYMBOL	T1	T2	T3	T4	T5	T6	T7	T8	T9	T10
1	TNO	T-3201(4)	T-3205(3)	T-3208(3)	T-3213(3)	TKK	알제리	롯데 G1	말레이시아	SN2388	SN2345
2	CODE	DIV. 2	DIV. 2	DIV. 2	DIV. 2	DIV. 2	DIV. 1	DIV. 1	DIV. 1	DIV. 1	DIV. 1
3	CONTENT	Propylene	Butadiene	Crude C4	HP Petrochemical	Mixed C4	LPG	C4	1.3 BUTADIENE	LNG FUEL	LNG FUEL
4	SG	0.538	0.649	0.625	0.596	0.6	0.536	0.646	0.6215	0.5	0.5
5	MATL	SA537-CL2	SA537-CL2	SA537-CL2	SA537-CL2	SA516-65	SA537-CL2	SA516-70	SA516-70	SA553-TYPE1	SA553-TYPE1
6	DTEMP	70	70	70	70	87	100	80	68	40	40
7	Sd	230.00	230.00	230.00	230.00	148.49	158.00	138.00	138.00	187.00	187.00
8	Di	17000	18000	18000	18000	25000	11000	16840	15650	12000	9000
9	CA	3.2	3.2	3.2	3.2	3.0	1.5	1.5	3.0	1	1
10	HT	12000	12000	12000	12000	15500	9000	11420	15350	7000	7000
11	HHLL	14500	14500	14500	14500	24000	7600	13480	14080	10740	8070
12	HLL	14100	14100	14100	14100	24000	7600	13480	12520	10740	8070
13	LLL	2300	2300	2300	2300	1000	1000	1000	2000	2000	2000
14	LLLL	2000	2000	2000	2000	1000	1000	1000	1000	1000	1000
15	Pi	21.6	18.0	18.0	18.0	17.9	21.9239	6.0	6.0	5.076147	5.076147
16	Pe	1.033227	1.033227	1.033227	1.033227	1.05	1.05	0.517	1.033227	0.45	0.45
17	MDMT	-15	-15	-15	-15	-10	-46	-15	-19	-19	-19
18	E	1.0	1.0	1.0	1.0	1	1	1	1	1	1
19	TQTY	4.0	4.0	4.0	4.0	1	1	10	1	1	1
20	CQTY	10	10	10	10	14	6	10	10	8	6
21	SQTY	8	9	9	9	10	5	8	8	7	5
22	CACB	3.0 / 3.0	3.0 / 3.0	3.0 / 3.0	3.0 / 3.0	3.0 / 3.0	1.5 / 1.5	1.5 / 1.5	1.5 / 1.5	1.5 / 1.5	1.5 / 1.5
23	L	64.0	64.0	64.0	64.0	64	64	64	25.4	25.2	25.2
24	tdReq	43.87	39.63	39.56	39.48	83.10	39.68	22.07	22.13	9.84	7.47
25	twReq	34.53	30.89	30.89	30.89	75.78	21.40	16.74	15.37	4.36	3.14
26	tmReq	31.55	28.26	28.26	28.26	69.48	21.40	16.74	15.37	4.36	3.14
27	teReq	15.33	18.36	18.39	18.42	16.58	7.76	17.68	33.05	9.52	5.8
28	tTops	43.5	39.0	39.0	39.0	78.5	40.5	20.5	34.0	10.5	8.5
29	tMids	44.5	40.5	40.0	40.0	83.5	40.5	22.5	34.0	11.0	8.5
30	tBtms	45.0	40.5	40.5	40.5	84.0	40.5	23.0	34.0	11.0	8.5
31	tUsed	45.0	40.5	40.5	40.5	84.0	40.5	23.0	34.0	11.0	8.5
32	MSG	OK	OK	OK	OK	두께64mm초과Sd 확인필요!	OK	OK	OK	OK	OK
33	tdCyo	84.73	76.21	76.07	75.91	163.72	78.39	42.74	41.36	18.7	13.96
34	ttCyt	72.41	65.09	65.09	65.09	155.02	44.46	35.05	33.8	9.72	7.29
35	tCyli	85.5	77.0	77.0	77.0	164.5	79.5	43.5	42.5	19.5	15.0

]
cdAry[4] = [[cAry, dAry] TANK STRENGTH CALCULATION SHEET, uid= [0], units= [kg/cm²]

1	1	TANK NO. (Max. 40 Char.)	TNO =		T-3201(4) 0	T-3205(3) 0	T-3208(3) 0	T-3213(3) 0	TKK 0	알제리 0	롯데 G1 0	말레이시아 0	SN2388 0	SN2345 0
2	2	VESSEL DESIGN CODE (ASME SEC. VIII, Div. 1,2)	CODE =		DIV. 2 2	DIV. 2 2	DIV. 2 2	DIV. 2 2	DIV. 2 2	DIV. 1 1	DIV. 1 1	DIV. 1 1	DIV. 1 1	DIV. 1 1
3	3	STORAGE LIQUID NAME	CONTENT =		Propylene 0	Butadiene 0	Crude C4 0	HP Petrochemical 0	Mixed C4 0	LPG 0	C4 0	1.3 BUTADIENE 0	LNG FUEL 0	LNG FUEL 0
4	4	DESIGN SPECIFIC GRAVITY	SG =		0.538 0.538	0.649 0.649	0.625 0.625	0.596 0.596	0.6 0.6	0.536 0.536	0.646 0.646	0.6215 0.6215	0.5 0.5	0.5 0.5
5	5	MATERIAL OF SHELL PLATE	MATL =		SA537-CL2 0	SA537-CL2 0	SA537-CL2 0	SA537-CL2 0	SA516-65 0	SA537-CL2 0	SA516-70 0	SA516-70 0	SA553-TYPE1 0	SA553-TYPE1 0
6	6	DESIGN TEMPERATURE (Max.)	DTEMP =	℃	70 70	70 70	70 70	70 70	87 87	100 100	80 80	68 68	40 40	40 40
7	7	ALLOWABLE STRESS at Deisin(Operating)	Sd =	MPa	230.00 230	230.00 230	230.00 230	230.00 230	148.49 148.49	158.00 158	138.00 138	138.00 138	187.00 187	187.00 187
8	8	TANK INSIDE DIAMETER	Di =	mm	17000 17000	18000 18000	18000 18000	18000 18000	25000 25000	11000 11000	16840 16840	15650 15650	12000 12000	9000 9000
9	9	CORROSION ALLOWANCE (SHELL)	CA =	mm	3.2 3.2	3.2 3.2	3.2 3.2	3.2 3.2	3.0 3	1.5 1.5	1.5 1.5	3.0 3	1 1	1 1
10	10	TANK EQUATOR LEVEL (FROM GROUND)	HT =	mm	12000 12000	12000 12000	12000 12000	12000 12000	15500 15500	9000 9000	11420 11420	15350 15350	7000 7000	7000 7000
11	11	(SHELL 두께계산 높이) HIGH HIGH LIQUID LEVEL	HHLL =	mm	14500 14500	14500 14500	14500 14500	14500 14500	24000 24000	7600 7600	13480 13480	14080 14080	10740 10740	8070 8070
12	12	(Storage 용량계산 액높이) HIGH LIQUID LEVEL	HLL =	mm	14100 14100	14100 14100	14100 14100	14100 14100	24000 24000	7600 7600	13480 13480	12520 12520	10740 10740	8070 8070
13	13	LOW LIQUID LEVEL	LLL =	mm	2300 2300	2300 2300	2300 2300	2300 2300	1000 1000	1000 1000	1000 1000	2000 2000	2000 2000	2000 2000
14	14	LOW LOW LIQUID LEVEL	LLLL =	mm	2000 2000	2000 2000	2000 2000	2000 2000	1000 1000	1000 1000	1000 1000	1000 1000	1000 1000	1000 1000
15	15	DESIGN INTERNAL PRESSURE (DATA SHEET 상의 압력) 프로그램이 계산시 사용하는 압력은? [SI UNIT]	Pi =	kg/cm² kPa	21.6 2118.2364	18.0 1765.197	18.0 1765.197	18.0 1765.197	17.9 1755.39035	21.9239 2150.0001394	6.0 588.399	6.0 588.399	5.076147 497.7999698	5.076147 497.7999698
16	16	DESIGN EXTERNAL PRESSURE (DATA SHEET 상의 압력) 프로그램이 계산시 사용하는 압력은? [SI UNIT]	Pe =	kg/cm² kPa	1.033227 101.3249556	1.033227 101.3249556	1.033227 101.3249556	1.033227 101.3249556	1.05 102.969825	1.05 102.969825	0.517 50.7003805	1.033227 101.3249556	0.45 44.129925	0.45 44.129925
17	17	MIN.DESIGN METAL TEMPERATURE	MDMT =	℃	-15 -15	-15 -15	-15 -15	-15 -15	-10 -10	-46 -46	-15 -15	-19 -19	-19 -19	-19 -19
18	18	SHELL JOINT EFFICIENCY	E =		1.0 1	1.0 1	1.0 1	1.0 1	1 1	1 1	1 1	1 1	1 1	1 1
19	19	TANK QUANTITY (탱크수량 직접입력)	TQTY =	Unit	4.0 4	4.0 4	4.0 4	4.0 4	1 1	1 1	10 10	1 1	1 1	1 1
20	20	COLUMN QUANTITY (수량자동계산)	CQTY =	EA	10 10	10 10	10 10	10 10	14 14	6 6	10 10	10 10	8 8	6 6
21	21	SHELL SEGMENT QUANTITY (수량자동계산)	SQTY =	EA	8 8	9 9	9 9	9 9	10 10	5 5	8 8	8 8	7 7	5 5
22	22	CORROSION ALLOWANCE (Column/Brace)	CACB =	mm	3.0 / 3.0 0	3.0 / 3.0 0	3.0 / 3.0 0	3.0 / 3.0 0	3.0 / 3.0 0	1.5 / 1.5 0	1.5 / 1.5 0	1.5 / 1.5 0	1.5 / 1.5 0	1.5 / 1.5 0
23	23	Cylinderical Vessel Longitudinal Length ex) Mounded Bullet Vessel(Cylinderical) Length	L =	(m)	64.0 64	64.0 64	64.0 64	64.0 64	64 64	64 64	64 64	25.4 25.4	25.2 25.2	25.2 25.2
24	24	Req'd Thickness under Operating Cond. (Pi+Ps)	tdReq =	mm	43.87 43.87	39.63 39.63	39.56 39.56	39.48 39.48	83.10 83.1	39.68 39.68	22.07 22.07	22.13 22.13	9.84 9.84	7.47 7.47
25	25	Req'd Thickness under Hydro-test (MAWP) (Pt)	twReq =	mm	34.53 34.53	30.89 30.89	30.89 30.89	30.89 30.89	75.78 75.78	21.40 21.4	16.74 16.74	15.37 15.37	4.36 4.36	3.14 3.14
26	26	Req'd Thickness under Hydro-test (MAP) (Pt)	tmReq =	mm	31.55 31.55	28.26 28.26	28.26 28.26	28.26 28.26	69.48 69.48	21.40 21.4	16.74 16.74	15.37 15.37	4.36 4.36	3.14 3.14
27	27	Req'd Thickness under External Pressue (Pe)	teReq =	mm	15.33 15.33	18.36 18.36	18.39 18.39	18.42 18.42	16.58 16.58	7.76 7.76	17.68 17.68	33.05 33.05	9.52 9.52	5.8 5.8
28	28	● Top Shell Used Thickness	tTops =	mm	43.5 43.5	39.0 39	39.0 39	39.0 39	78.5 78.5	40.5 40.5	20.5 20.5	34.0 34	10.5 10.5	8.5 8.5
29	29	● Equator Used Thickness	tMids =	mm	44.5 44.5	40.5 40.5	40.0 40	40.0 40	83.5 83.5	40.5 40.5	22.5 22.5	34.0 34	11.0 11	8.5 8.5
30	30	● Bottom Shell Used Thickness	tBtms =	mm	45.0 45	40.5 40.5	40.5 40.5	40.5 40.5	84.0 84	40.5 40.5	23.0 23	34.0 34	11.0 11	8.5 8.5
31	31	● Max. (Spherical) Used Thickness	tUsed =	mm	45.0 45	40.5 40.5	40.5 40.5	40.5 40.5	84.0 84	40.5 40.5	23.0 23	34.0 34	11.0 11	8.5 8.5
32	32	If (tUsed ≤ 64mm) then Accetable Else (tUsed>64mm) Sd ReSelect	MSG =		OK 0	OK 0	OK 0	OK 0	두께64mm초과Sd 확인필요! 0	OK 0	OK 0	OK 0	OK 0	OK 0
33	33	(● Cylinder) Req'd Thickness under Oper. (Pi+Ps)	tdCyo =	mm	84.73 84.73	76.21 76.21	76.07 76.07	75.91 75.91	163.72 163.72	78.39 78.39	42.74 42.74	41.36 41.36	18.7 18.7	13.96 13.96
34	34	(● Cylinder) Req'd Thickness under Hydrotest(Pt)	ttCyt =	mm	72.41 72.41	65.09 65.09	65.09 65.09	65.09 65.09	155.02 155.02	44.46 44.46	35.05 35.05	33.8 33.8	9.72 9.72	7.29 7.29
35	35	● Max. (Cylinder) Used Thickness	tCyli =	mm	85.5 85.5	77.0 77	77.0 77	77.0 77	164.5 164.5	79.5 79.5	43.5 43.5	42.5 42.5	19.5 19.5	15.0 15

cAry[0].length=[12][12] END OF MYSQL_SPH_DATAREAD(), cAry.length = [36] dAry.length = [36]
]
cdAry[5] = []
rv=[sphereColumnSTD.jsp sph.WLEDING_LENGTH_CALC();

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 17,000 (m), Material SA537-CL2, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	10	10	43.5	2967.1	8901.2	1	8,568		17,802		43.5	2967.1	8901.2	3	8567.61	25702.8	1138.78	75.270
#2, 0	20	30	43.5	2967.1	7882	2	17,135	ø8500	31,528	6,390
#3, 3	20	50	43.5	2967.1	10228	4	29,671	ø13022.8	40,912		43.5	2967.1	9408.5	4	7417.69	29670.8	1897.53	86.890
#4, 4	16	66	43.5	8131.6	2373.6	6	36,592	ø15530.3	48,790	14,242	43.5	2710.5	8901.2	6	6098.63	36591.8	2006.43	107.158
#5, 5	64	130	44.5	2967.1	9611.9	18	166,433	ø17000		170,903	44.5	2967.1	9611.9	18	9246.28	166433.1	8920.95	476.442
#6, 8	20	150	45.0	2967.1	10228	4	30,694	ø13022.8	40,912		45.0	2967.1	9208.5	4	7673.47	30693.9	1897.53	86.890
#7, 9	20	170	45.0	2967.1	7882	2	17,726	ø8500	31,528	6,390	45.0	2967.1	8901.2	3	8863.04	26589.1	1138.78	75.270
#8, 9	10	180	45.0	2967.1	8901.2	1	8,863		17,802
Total Quantity and Shell Weight						38	315,681	kg	229.3 (m)	197.9 (m)				38		315681.5	17000.00	907.92
Total Site Weleding length (m)									427.2 (m)

myEQid[tid] = [ 4 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 18,000 (m), Material SA537-CL2, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	9	9	39.0	2827.4	8482.3	1	6,975		16,965		39.0	2827.4	8482.3	3	6975.32	20926.0	980.94	68.352
#2, 0	18	27	39.0	2827.4	7671	2	13,951	ø8171.8	30,684	5,796
#3, 3	18	45	39.0	2827.4	9996.5	4	24,710	ø12727.9	39,986		39.0	2827.4	9200	4	6177.57	24710.3	1655.1	80.713
#4, 4	14.5	59.5	39.0	8120.7	2277.7	6	31,095	ø15509.3	48,724	13,666	39.0	2436.2	9424.8	6	5182.51	31095.0	1796.11	101.568
#5, 5	61	120.5	40.0	2827.4	9679.7	20	162,216	ø18000		191,637	40.0	2827.4	9679.7	20	8110.81	162216.2	9135.7	516.612
#6, 8	14.5	135	40.5	8120.7	2277.7	6	32,291	ø15509.3	48,724	13,666	40.5	2436.2	9424.8	6	5381.83	32291.0	1796.11	101.568
#7, 9	18	153	40.5	2827.4	9996.5	4	25,661	ø12727.9	39,986		40.5	2827.4	9000	4	6415.17	25660.7	1655.1	80.713
#8, 10	18	171	40.5	2827.4	7671	2	14,487	ø8171.8	30,684	5,796	40.5	2827.4	8482.3	3	7243.60	21730.8	980.94	68.352
#9, 10	9	180	40.5	2827.4	8482.3	1	7,244		16,965
Total Quantity and Shell Weight						46	318,630	kg	272.7 (m)	230.6 (m)				46		318629.9	18000.00	1017.878
Total Site Weleding length (m)									503.3 (m)

myEQid[tid] = [ 4 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 18,000 (m), Material SA537-CL2, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	9	9	39.0	2827.4	8482.3	1	6,975		16,965		39.0	2827.4	8482.3	3	6975.32	20926.0	980.94	68.352
#2, 0	18	27	39.0	2827.4	7671	2	13,951	ø8171.8	30,684	5,796
#3, 3	18	45	39.0	2827.4	9996.5	4	24,710	ø12727.9	39,986		39.0	2827.4	9200	4	6177.57	24710.3	1655.1	80.713
#4, 4	14.5	59.5	39.0	8120.7	2277.7	6	31,095	ø15509.3	48,724	13,666	39.0	2436.2	9424.8	6	5182.51	31095.0	1796.11	101.568
#5, 5	61	120.5	40.0	2827.4	9679.7	20	162,216	ø18000		191,637	40.0	2827.4	9679.7	20	8110.81	162216.2	9135.7	516.612
#6, 8	14.5	135	40.0	8120.7	2277.7	6	31,892	ø15509.3	48,724	13,666	40.0	2436.2	9424.8	6	5315.39	31892.4	1796.11	101.568
#7, 9	18	153	40.5	2827.4	9996.5	4	25,661	ø12727.9	39,986		40.5	2827.4	9000	4	6415.17	25660.7	1655.1	80.713
#8, 10	18	171	40.5	2827.4	7671	2	14,487	ø8171.8	30,684	5,796	40.5	2827.4	8482.3	3	7243.60	21730.8	980.94	68.352
#9, 10	9	180	40.5	2827.4	8482.3	1	7,244		16,965
Total Quantity and Shell Weight						46	318,231	kg	272.7 (m)	230.6 (m)				46		318231.3	18000.00	1017.878
Total Site Weleding length (m)									503.3 (m)

myEQid[tid] = [ 4 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 18,000 (m), Material SA537-CL2, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	9	9	39.0	2827.4	8482.3	1	6,975		16,965		39.0	2827.4	8482.3	3	6975.32	20926.0	980.94	68.352
#2, 0	18	27	39.0	2827.4	7671	2	13,951	ø8171.8	30,684	5,796
#3, 3	18	45	39.0	2827.4	9996.5	4	24,710	ø12727.9	39,986		39.0	2827.4	9200	4	6177.57	24710.3	1655.1	80.713
#4, 4	14.5	59.5	39.0	8120.7	2277.7	6	31,095	ø15509.3	48,724	13,666	39.0	2436.2	9424.8	6	5182.51	31095.0	1796.11	101.568
#5, 5	61	120.5	40.0	2827.4	9679.7	20	162,216	ø18000		191,637	40.0	2827.4	9679.7	20	8110.81	162216.2	9135.7	516.612
#6, 8	14.5	135	40.0	8120.7	2277.7	6	31,892	ø15509.3	48,724	13,666	40.0	2436.2	9424.8	6	5315.39	31892.4	1796.11	101.568
#7, 9	18	153	40.5	2827.4	9996.5	4	25,661	ø12727.9	39,986		40.5	2827.4	9000	4	6415.17	25660.7	1655.1	80.713
#8, 10	18	171	40.5	2827.4	7671	2	14,487	ø8171.8	30,684	5,796	40.5	2827.4	8482.3	3	7243.60	21730.8	980.94	68.352
#9, 10	9	180	40.5	2827.4	8482.3	1	7,244		16,965
Total Quantity and Shell Weight						46	318,231	kg	272.7 (m)	230.6 (m)				46		318231.3	18000.00	1017.878
Total Site Weleding length (m)									503.3 (m)

myEQid[tid] = [ 4 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 25,000 (m), Material SA516-65, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	6.4	6.4	78.0	2792.5	8377.6	1	13,608		16,755		78.0	2792.5	8377.6	3	13608.37	40825.1	695.3	66.675
#2, 0	12.8	19.2	78.0	2792.5	7943.1	2	27,217	ø8221.7	31,773	5,045
#3, 3	12.8	32	78.5	2792.5	10404.9	4	50,841	ø13248	41,620		78.5	2792.5	9567.7	4	12710.26	50841.0	1204.1	82.504
#4, 4	9.5	41.5	78.5	8673.7	2072.6	6	59,948	ø16565.5	52,042	12,435	78.5	1858.6	8726.6	9	6660.91	59948.2	1238.65	97.283
#5, 5	45.5	87	81.0	2801.1	9926.6	28	434,861	ø24965.7	78,432	277,944	81.0	2801.1	9970	28	15530.75	434861.0	8707.75	683.905
#6, 6	51.5	138.5	83.5	2805	11297.4	28	515,641	ø25000		314,596	83.5	2805	11297.4	28	18415.73	515640.6	10016.15	786.667
#7, 9	9.5	148	83.5	8673.7	2072.6	6	63,767	ø16565.5	52,042	12,435	83.5	1858.6	8726.6	9	7085.18	63766.6	1238.65	97.283
#8, 10	12.8	160.8	84.0	2792.5	10404.9	4	54,403	ø13248	41,620		84.0	2792.5	9367.7	4	13600.78	54403.1	1204.1	82.504
#9, 11	12.8	173.6	84.0	2792.5	7943.1	2	29,310	ø8221.7	31,773	5,045	84.0	2792.5	8377.6	3	14655.16	43965.5	695.3	66.675
#10, 11	6.4	180	84.0	2792.5	8377.6	1	14,655		16,755
Total Quantity and Shell Weight						82	1,264,251	kg	362.8 (m)	627.5 (m)				88		1264251.1	25000.00	1963.496
Total Site Weleding length (m)									990.3 (m)

myEQid[tid] = [ 5 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 11,000 (m), Material SA537-CL2, HEAD TYPE : WATER MELON

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	15	15	40.0	2879.8	8639.4	1	7,422		17,279		40.0	2879.8	8639.4	3	7421.60	22264.8	1610.91	70.907
#2, 0	30	45	40.0	2879.8	8434.5	2	14,843	ø7778.2	24,436
#3, 3	90	135	40.5	2879.8	8830	12	85,457	ø11000		103,673	40.5	2879.8	8830	12	7121.39	85456.7	7778.18	268.795
#4, 6	30	165	40.5	2879.8	8434.5	2	15,029	ø7778.2	24,436		40.5	2879.8	8639.4	3	7514.37	22543.1	1610.91	70.907
#5, 6	15	180	40.5	2879.8	8639.4	1	7,514		17,279
Total Quantity and Shell Weight						18	130,265	kg	83.4 (m)	103.7 (m)				18		130264.6	11000.00	410.609
Total Site Weleding length (m)									187.1 (m)

myEQid[tid] = [ 2 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 16,840 (m), Material SA516-70, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	10	10	20.5	2939.1	8817.4	1	3,962		17,635		20.5	2939.1	8817.4	3	3961.92	11885.8	1128.07	73.859
#2, 0	20	30	20.5	2939.1	7807.8	2	7,924	ø8420	31,231	6,330
#3, 3	20	50	20.5	2939.1	10131.8	4	13,721	ø12900.2	40,527		20.5	2939.1	9321.8	4	3430.24	13720.9	1879.66	85.263
#4, 4	16	66	21.0	8055.1	2351.3	6	17,334	ø15384.1	48,331	14,108	21.0	2685	8817.4	6	2889.00	17334.0	1987.55	105.150
#5, 5	64	130	22.5	2939.1	9521.5	18	82,575	ø16840		169,294	22.5	2939.1	9521.5	18	4587.50	82575.0	8836.99	467.516
#6, 8	20	150	23.0	2939.1	10131.8	4	15,394	ø12900.2	40,527		23.0	2939.1	9121.8	4	3848.56	15394.2	1879.66	85.263
#7, 9	20	170	23.0	2939.1	7807.8	2	8,890	ø8420	31,231	6,330	23.0	2939.1	8817.4	3	4445.08	13335.2	1128.07	73.859
#8, 9	10	180	23.0	2939.1	8817.4	1	4,445		17,635
Total Quantity and Shell Weight						38	154,245	kg	227.1 (m)	196.1 (m)				38		154245.2	16840.00	890.91
Total Site Weleding length (m)									423.2 (m)

myEQid[tid] = [ 4 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 15,650 (m), Material SA516-70, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	10	10	26.5	2731.4	8194.3	1	4,423		16,389		26.5	2731.4	8194.3	3	4423.24	13269.7	1048.35	63.789
#2, 0	20	30	26.5	2731.4	7256.1	2	8,846	ø7825	29,024	5,883
#3, 3	20	50	26.5	2731.4	9415.8	4	15,319	ø11988.6	37,663		26.5	2731.4	8677.2	4	3829.69	15318.8	1746.84	73.639
#4, 4	16	66	26.5	7485.9	2185.2	6	18,892	ø14297	44,915	13,111	26.5	2495.3	8194.3	6	3148.60	18891.6	1847.1	90.814
#5, 5	64	130	26.5	2731.4	8848.6	18	83,996	ø15650		157,331	26.5	2731.4	8848.6	18	4666.42	83995.5	8212.52	403.776
#6, 8	20	150	26.5	2731.4	9415.8	4	15,319	ø11988.6	37,663		26.5	2731.4	8477.2	4	3829.69	15318.8	1746.84	73.639
#7, 9	20	170	26.5	2731.4	7256.1	2	8,846	ø7825	29,024	5,883	26.5	2731.4	8194.3	3	4423.24	13269.7	1048.35	63.789
#8, 9	10	180	26.5	2731.4	8194.3	1	4,423		16,389
Total Quantity and Shell Weight						38	160,064	kg	211.1 (m)	182.2 (m)				38		160064	15650.00	769.446
Total Site Weleding length (m)									393.3 (m)

myEQid[tid] = [ 4 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 12,000 (m), Material SA553-TYPE1, HEAD TYPE : FOOT BALL

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	10	10	13.5	2094.4	6283.2	1	1,325		12,566		13.5	2094.4	6283.2	3	1324.86	3974.6	803.85	37.505
#2, 0	20	30	13.5	2094.4	5563.8	2	2,650	ø6000	22,255	4,511
#3, 3	20	50	13.5	2094.4	7219.8	4	4,588	ø9192.5	28,879		13.5	2094.4	6700.1	4	1147.02	4588.1	1339.42	43.294
#4, 4	80	130	13.5	2692.8	8527.9	14	30,817	ø12000		117,286	13.5	2692.8	8527.9	14	2201.18	30816.6	7713.46	290.791
#5, 7	20	150	13.5	2094.4	7219.8	4	4,588	ø9192.5	28,879		13.5	2094.4	6500.1	4	1147.02	4588.1	1339.42	43.294
#6, 8	20	170	13.5	2094.4	5563.8	2	2,650	ø6000	22,255	4,511	13.5	2094.4	6283.2	3	1324.86	3974.6	803.85	37.505
#7, 8	10	180	13.5	2094.4	6283.2	1	1,325		12,566
Total Quantity and Shell Weight						28	47,942	kg	127.4 (m)	126.3 (m)				28		47941.9	12000.00	452.389
Total Site Weleding length (m)									253.7 (m)

myEQid[tid] = [ 3 ]
CalcRpt[tid][0].length() = [10] Bytes

1. Shell Plate 현장 용접길이 계산, Tank Dia. D = 9,000 (m), Material SA553-TYPE1, HEAD TYPE : WATER MELON

Weight Summary and SITE Welding Length											Strength Calculation Result, sWt[][][]
No.	Each Angle θ, deg	Sum Angle φ, deg	Shell Thk mm	Shell Width mm	Shell Length mm	Qty SHT	Net Weight kg	수평용접부 단면경 øD, mm	수평용접 hWeld L=øD,mm	수직용접 vWeld L, mm	Shell Thk mm	Width mm	Length mm	Qty Sht	Unit WT kg/sht	Net Weight kg	각단 높이 mm	표면적 A=πD*m (m²)
#1, 0	15	15	11.0	2356.2	7068.6	1	1,366		14,137		11.0	2356.2	7068.6	3	1366.26	4098.8	1318.02	47.467
#2, 0	30	45	11.0	2356.2	6901	2	2,733	ø6364	19,993
#3, 3	90	135	11.0	2827.4	7294.3	10	15,538	ø9000		70,686	11.0	2827.4	7294.3	10	1553.76	15537.6	6363.96	179.937
#4, 6	30	165	11.0	2356.2	6901	2	2,733	ø6364	19,993		11.0	2356.2	7068.6	3	1366.26	4098.8	1318.02	47.467
#5, 6	15	180	11.0	2356.2	7068.6	1	1,366		14,137
Total Quantity and Shell Weight						16	23,735	kg	68.3 (m)	70.7 (m)				16		23735.1	9000.00	274.871
Total Site Weleding length (m)									138.9 (m)

myEQid[tid] = [ 2 ]
CalcRpt[tid][0].length() = [10] Bytes
1. CAPACITY CALCULATION

탱크 공칭 및 저장용량											하중조건 (Loading Data)
No	TNO	Liquid Name	SG	D	DLL	Vnom	Vsto	Vhil	vRatio	탱크 표면적	4.Empty Steel	5,저장 액체	6.운전 중량	7.수압 수중량	8.수압 테스트중량
				mm	mm	ｍ³	ｍ³	ｍ³	(%)	m2	Ton
1	T-3201(4)	Propylene	0.538	17,000	14,500	2572.44	2421.91	150.53	5.9 (%)	907.92	341.42	1302.98	1644.41	2572.44	2913.86
2	T-3205(3)	Butadiene	0.649	18,000	14,500	3053.63	2752.17	301.46	9.9 (%)	1017.88	348.06	1786.16	2134.22	3053.63	3401.69
3	T-3208(3)	Crude C4	0.625	18,000	14,500	3053.63	2752.17	301.46	9.9 (%)	1017.88	347.67	1720.1	2067.77	3053.63	3401.29
4	T-3213(3)	HP Petrochemical	0.596	18,000	14,500	3053.63	2752.17	301.46	9.9 (%)	1017.88	347.67	1640.29	1987.96	3053.63	3401.29
5	TKK	Mixed C4	0.6	25,000	24,000	8181.23	8143.01	38.22	0.5 (%)	1963.5	1366.21	4885.81	6252.01	8181.23	9547.44
6	알제리	LPG	0.536	11,000	7,600	696.91	538.33	158.58	22.8 (%)	380.13	135.39	288.54	423.93	696.91	832.3
7	롯데 G1	C4	0.646	16,840	13,480	2500.49	2241.58	258.91	10.4 (%)	890.91	178.67	1448.06	1626.73	2500.49	2679.16
8	말레이시아	1.3 BUTADIENE	0.6215	15,650	14,080	2006.97	1950.43	56.54	2.8 (%)	769.45	180.23	1212.19	1392.42	2006.97	2187.21
9	SN2388	LNG FUEL	0.5	12,000	10,740	904.78	876.95	27.83	3.1 (%)	452.39	55.12	438.47	493.6	904.78	959.9
10	SN2345	LNG FUEL	0.5	9,000	8,070	381.7	370.32	11.38	3 (%)	254.47	26.5	185.16	211.66	381.7	408.2

공간용적비(%) = 공간용적 / 공칭용량 * 100
Ratio of vapour Space, vRatio = Vhil / Vnom * 100(%)
uAry[1][3] = [ 0 | kg/cm² | 입력 압력단위 (Pressue Input Unit) = kg/cm² | ]
uAry[1][3].substring(0,1).trim() = [0]
uid = [0]
cAry.length = [36] cAry[0].length = [12]
sph.MYANG_SET();
sph.CODE_CALC( );
DESIGN DATA AND MATERIAL LIST

No.	F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10	F11	F12	F13	F14	F15	F16	F17	F18	F19	F20	F21	F22	F23	F24	F25	F26	F27	F28	F29	F30	F31	F32	F33	F34	Cylindrical Shell
No.	TNO	CODE	CONTENT	SG	Di	CA	HT	HHLL	Pi	Pe	MDMT	DTEMP	CQTY	MSG	MATL	Sd	gtReq Used Thk	6Roark tRoark	1_ASME tASME	td_2 tTest	td_3 tMAWP	td_5 tMAP	td_5 tVacuum	Shell Qty	Net Weight Ton	Column Qty	Tank Height BASE to EQ. Line (mm)	Upp. Colume Height(mm)	Low. Colume Height(mm)	Column PCD mm	BRACE 부착각도 (o)deg.	Column Size	Shell 각도 분할수	Spherical Top ~ Btm 두께(mm)	Shell matl id, Sd MPa	Cyl. td (mm)	Cyl. tt (mm)	Cyl. tt(MAWP) (mm)	Cyl. tt(MAP) (mm)
1	T-3201(4)	DIV. 2	Propylene	0.538	17000	3.2	12000	14500	21.6	1.033227	-15	70	10	OK	SA537-CL2	230.00	43.5 ~ 45	43.77	43.87	30.39	30.98	33.5	25.38	38	315.681	9 EA	11500	3590	7910	16600	35.6695	ø 863.6x9.65t	11	43.5 ~ 45	matid=6, Sd= 230.0 MPa, t ≤ 64t	84.73	60.90	62.07	67.14
2	T-3205(3)	DIV. 2	Butadiene	0.649	18000	3.2	12000	14500	18.0	1.033227	-15	70	10	OK	SA537-CL2	230.00	39 ~ 40.5	39.56	39.63	27.24	27.88	30.44	26.69	46	318.630	10 EA	12000	3700	8300	17600	33.2354	ø 863.6x9.65t	12	39 ~ 40.5	matid=6, Sd= 230.0 MPa, t ≤ 64t	76.21	54.56	55.84	60.99
3	T-3208(3)	DIV. 2	Crude C4	0.625	18000	3.2	12000	14500	18.0	1.033227	-15	70	10	OK	SA537-CL2	230.00	39 ~ 40.5	39.49	39.56	27.24	27.79	30.44	26.69	46	318.231	10 EA	12000	3700	8300	17600	33.2354	ø 863.6x9.65t	12	39 ~ 40.5	matid=6, Sd= 230.0 MPa, t ≤ 64t	76.07	54.56	55.67	60.99
4	T-3213(3)	DIV. 2	HP Petrochemical	0.596	18000	3.2	12000	14500	18.0	1.033227	-15	70	10	OK	SA537-CL2	230.00	39 ~ 40.5	39.41	39.48	27.24	27.84	30.44	26.69	46	318.231	10 EA	12000	3700	8300	17600	33.2354	ø 863.6x9.65t	12	39 ~ 40.5	matid=6, Sd= 230.0 MPa, t ≤ 64t	75.91	54.56	55.77	60.99
5	TKK	DIV. 2	Mixed C4	0.6	25000	3.0	15500	24000	17.9	1.05	-10	87	14	두께64mm초과Sd 확인필요!	SA516-65	148.49	78 ~ 84	82.85	83.11	72.13	72.87	75.56	35.96	88	1,264.251	14 EA	15500	4730	10770	24530	26.8767	ø 1066.8x15.09t	13	78 ~ 84	matid=2, Sd= 148.486 MPa,	163.72	144.68	146.17	151.59
6	알제리	DIV. 1	LPG	0.536	11000	1.5	9000	7600	21.9239	1.05	-46	100	6	OK	SA537-CL2	158.00	40 ~ 40.5	39.63	39.68	21.39	21.84	22.77	17.01	18	130.265	6 EA	8500	2450	6050	10740	41.5924	ø 558.8x6.35t	8	40 ~ 40.5	matid=6, Sd= 158.0 MPa, t ≤ 64t	78.39	42.90	43.80	45.68
7	롯데 G1	DIV. 1	C4	0.646	16840	1.5	11420	13480	6.0	0.517	-15	80	10	OK	SA516-70	138.00	20.5 ~ 23	22.06	22.07	16.74	17.45	18.68	18.55	38	154.245	9 EA	11420	3580	7840	16430	35.6314	ø 863.6x9.65t	11	20.5 ~ 23	matid=3, Sd= 138.0 MPa,	42.74	33.52	34.95	37.42
8	말레이시아	DIV. 1	1.3 BUTADIENE	0.6215	15650	3.0	15350	14080	6.0	1.033227	-19	68	10	OK	SA516-70	138.00	26.5 ~ 26.5	22.12	22.13	15.36	18.71	22.88	25.42	38	160.064	9 EA	10825	3380	7445	15260	35.0319	ø 812.8x8.74t	11	26.5 ~ 26.5	matid=3, Sd= 138.0 MPa,	41.36	30.76	37.47	45.82

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : T-3201(4)자재 중량표				Rev. No.	[AAA4]

(1/10) Tank No. : [T-3201(4)] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 2, Di = 17000 mm, DLL = 14500 mm, CA = 3.2 mm, SG = 0.538, Pg = 2118.236 kPa, Pe = 101.325 kPa
, SA537-CL2 matid=6, Sd= 230.0 MPa, St= 394.25 MPa, Thick Limit : t ≤ 64t

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	17000.0	42.36	42.45	29.18	31.70	25.38	43.5	#1	30.0o	SA537-CL2	43.5	2967.1	8901.2	3	8,568	25,703	typ=0
	10.0o	10.0o	16870.9	42.36	42.45	29.19	31.71	25.38	43.5										typ=4
	20.0o	30.0o	15861.2	42.36	42.45	29.30	31.82	25.38	43.5										typ=4
2	20.0o	50.0o	13963.7	42.41	42.50	29.50	32.02	25.38	43.5	#2	20.0o	SA537-CL2	43.5	2967.1	9408.5	4	7,418	29,671	typ=3
3	16.0o	66.0o	11957.3	42.60	42.69	29.71	32.23	25.38	43.5	#3	16.0o	SA537-CL2	43.5	2710.5	8901.2	6	6,099	36,592	typ=3
4	24.0o	90.0o	8500.0	42.84	43.03	30.08	32.60	25.38	44.5	#4	64.0o	SA537-CL2	44.5	2967.1	9594.6	18	9,246	166,433	typ=1
	40.0o	130.0o	3036.3	43.47	43.57	30.66	33.18	25.38	44.5										typ=4
5	20.0o	150.0o	1138.8	43.66	43.76	30.86	33.38	25.38	45.0	#5	20.0o	SA537-CL2	45.0	2967.1	9208.5	4	7,673	30,694	typ=3
6	20.0o	170.0o	129.1	43.76	43.85	30.97	33.49	25.38	45.0	#6	30.0o	SA537-CL2	45.0	2967.1	8901.2	3	8,863	26,589	typ=2
	10.0o	180.0o	0.0	43.77	43.87	30.98	33.50	25.38	45.0										typ=4
Sub-Total																38	Sht	315,681	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO102]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : T-3205(3)자재 중량표				Rev. No.	[AAA4]

(2/10) Tank No. : [T-3205(3)] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 2, Di = 18000 mm, DLL = 14500 mm, CA = 3.2 mm, SG = 0.649, Pg = 1765.197 kPa, Pe = 101.325 kPa
, SA537-CL2 matid=6, Sd= 230.0 MPa, St= 394.25 MPa, Thick Limit : t ≤ 64t

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	18000.0	37.75	37.82	25.85	28.42	26.69	39.0	#1	27.0o	SA537-CL2	39.0	2827.4	8482.3	3	6,975	20,926	typ=0
	9.0o	9.0o	17889.2	37.75	37.82	25.87	28.44	26.69	39.0										typ=4
	18.0o	27.0o	17019.1	37.75	37.82	25.96	28.53	26.69	39.0										typ=4
2	18.0o	45.0o	15364.0	37.75	37.82	26.15	28.72	26.69	39.0	#2	18.0o	SA537-CL2	39.0	2827.4	9200.0	4	6,178	24,710	typ=3
3	14.5o	59.5o	13567.8	37.87	37.93	26.35	28.92	26.69	39.0	#3	14.5o	SA537-CL2	39.0	2436.2	9424.8	6	5,183	31,095	typ=3
4	30.5o	90.0o	9000.0	38.32	38.50	26.87	29.43	26.69	40.0	#4	61.0o	SA537-CL2	40.0	2827.4	9681.9	20	8,111	162,216	typ=1
	30.5o	120.5o	4432.2	39.01	39.07	27.38	29.95	26.69	40.0										typ=4
5	14.5o	135.0o	2636.0	39.23	39.30	27.58	30.15	26.69	40.5	#5	14.5o	SA537-CL2	40.5	2436.2	9424.8	6	5,382	32,291	typ=3
6	18.0o	153.0o	980.9	39.43	39.51	27.77	30.33	26.69	40.5	#6	18.0o	SA537-CL2	40.5	2827.4	9000.0	4	6,415	25,661	typ=3
7	18.0o	171.0o	110.8	39.54	39.62	27.86	30.43	26.69	40.5	#7	27.0o	SA537-CL2	40.5	2827.4	8482.3	3	7,244	21,731	typ=2
	9.0o	180.0o	0.0	39.56	39.63	27.88	30.44	26.69	40.5										typ=4
Sub-Total																46	Sht	318,630	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO103]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : T-3208(3)자재 중량표				Rev. No.	[AAA4]

(3/10) Tank No. : [T-3208(3)] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 2, Di = 18000 mm, DLL = 14500 mm, CA = 3.2 mm, SG = 0.625, Pg = 1765.197 kPa, Pe = 101.325 kPa
, SA537-CL2 matid=6, Sd= 230.0 MPa, St= 394.25 MPa, Thick Limit : t ≤ 64t

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	18000.0	37.75	37.82	25.77	28.42	26.69	39.0	#1	27.0o	SA537-CL2	39.0	2827.4	8482.3	3	6,975	20,926	typ=0
	9.0o	9.0o	17889.2	37.75	37.82	25.78	28.44	26.69	39.0										typ=4
	18.0o	27.0o	17019.1	37.75	37.82	25.88	28.53	26.69	39.0										typ=4
2	18.0o	45.0o	15364.0	37.75	37.82	26.07	28.72	26.69	39.0	#2	18.0o	SA537-CL2	39.0	2827.4	9200.0	4	6,178	24,710	typ=3
3	14.5o	59.5o	13567.8	37.86	37.93	26.27	28.92	26.69	39.0	#3	14.5o	SA537-CL2	39.0	2436.2	9424.8	6	5,183	31,095	typ=3
4	30.5o	90.0o	9000.0	38.30	38.48	26.78	29.43	26.69	40.0	#4	61.0o	SA537-CL2	40.0	2827.4	9681.9	20	8,111	162,216	typ=1
	30.5o	120.5o	4432.2	38.96	39.03	27.29	29.95	26.69	40.0										typ=4
5	14.5o	135.0o	2636.0	39.17	39.24	27.50	30.15	26.69	40.0	#5	14.5o	SA537-CL2	40.0	2436.2	9424.8	6	5,315	31,892	typ=3
6	18.0o	153.0o	980.9	39.37	39.44	27.68	30.33	26.69	40.5	#6	18.0o	SA537-CL2	40.5	2827.4	9000.0	4	6,415	25,661	typ=3
7	18.0o	171.0o	110.8	39.48	39.55	27.78	30.43	26.69	40.5	#7	27.0o	SA537-CL2	40.5	2827.4	8482.3	3	7,244	21,731	typ=2
	9.0o	180.0o	0.0	39.49	39.56	27.79	30.44	26.69	40.5										typ=4
Sub-Total																46	Sht	318,231	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO104]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : T-3213(3)자재 중량표				Rev. No.	[AAA4]

(4/10) Tank No. : [T-3213(3)] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 2, Di = 18000 mm, DLL = 14500 mm, CA = 3.2 mm, SG = 0.596, Pg = 1765.197 kPa, Pe = 101.325 kPa
, SA537-CL2 matid=6, Sd= 230.0 MPa, St= 394.25 MPa, Thick Limit : t ≤ 64t

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	18000.0	37.75	37.82	25.82	28.42	26.69	39.0	#1	27.0o	SA537-CL2	39.0	2827.4	8482.3	3	6,975	20,926	typ=0
	9.0o	9.0o	17889.2	37.75	37.82	25.83	28.44	26.69	39.0										typ=4
	18.0o	27.0o	17019.1	37.75	37.82	25.93	28.53	26.69	39.0										typ=4
2	18.0o	45.0o	15364.0	37.75	37.82	26.12	28.72	26.69	39.0	#2	18.0o	SA537-CL2	39.0	2827.4	9200.0	4	6,178	24,710	typ=3
3	14.5o	59.5o	13567.8	37.86	37.92	26.32	28.92	26.69	39.0	#3	14.5o	SA537-CL2	39.0	2436.2	9424.8	6	5,183	31,095	typ=3
4	30.5o	90.0o	9000.0	38.27	38.45	26.83	29.43	26.69	40.0	#4	61.0o	SA537-CL2	40.0	2827.4	9681.9	20	8,111	162,216	typ=1
	30.5o	120.5o	4432.2	38.90	38.97	27.34	29.95	26.69	40.0										typ=4
5	14.5o	135.0o	2636.0	39.11	39.18	27.54	30.15	26.69	40.0	#5	14.5o	SA537-CL2	40.0	2436.2	9424.8	6	5,315	31,892	typ=3
6	18.0o	153.0o	980.9	39.30	39.37	27.73	30.33	26.69	40.5	#6	18.0o	SA537-CL2	40.5	2827.4	9000.0	4	6,415	25,661	typ=3
7	18.0o	171.0o	110.8	39.40	39.47	27.83	30.43	26.69	40.5	#7	27.0o	SA537-CL2	40.5	2827.4	8482.3	3	7,244	21,731	typ=2
	9.0o	180.0o	0.0	39.41	39.48	27.84	30.44	26.69	40.5										typ=4
Sub-Total																46	Sht	318,231	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO105]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : TKK자재 중량표				Rev. No.	[AAA4]

(5/10) Tank No. : [TKK] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 2, Di = 25000 mm, DLL = 24000 mm, CA = 3 mm, SG = 0.6, Pg = 1755.39 kPa, Pe = 102.97 kPa
, SA516-65 matid=2, Sd= 148.486 MPa, St= 228.0 MPa,

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	25000.0	76.91	77.12	66.11	68.80	35.96	78.0	#1	19.2o	SA516-65	78.0	2792.5	8377.6	3	13,608	40,825	typ=0
	6.4o	6.4o	24922.1	76.91	77.12	66.14	68.83	35.96	78.0										typ=4
	12.8o	19.2o	24304.7	76.91	77.12	66.30	68.99	35.96	78.0										typ=4
2	12.8o	32.0o	23100.6	77.13	77.35	66.63	69.32	35.96	78.5	#2	12.8o	SA516-65	78.5	2792.5	9567.7	4	12,710	50,841	typ=3
3	9.5o	41.5o	21862.0	77.44	77.66	66.96	69.65	35.96	78.5	#3	9.5o	SA516-65	78.5	1858.6	8726.6	9	6,661	59,948	typ=3
4	45.5o	87.0o	13154.2	79.66	79.83	69.32	72.01	35.96	81.0	#4	45.5o	SA516-65	81.0	2801.1	9970.0	28	15,531	434,861	typ=3
5	3.0o	90.0o	12500.0	79.41	79.99	69.49	72.18	35.96	83.5	#5	51.5o	SA516-65	83.5	2805.0	11335.6	28	18,416	515,641	typ=1
	48.5o	138.5o	3138.0	82.08	82.33	72.02	74.72	35.96	83.5										typ=4
6	9.5o	148.0o	1899.4	82.38	82.64	72.36	75.05	35.96	83.5	#6	9.5o	SA516-65	83.5	1858.6	8726.6	9	7,085	63,767	typ=3
7	12.8o	160.8o	695.3	82.68	82.93	72.68	75.37	35.96	84.0	#7	12.8o	SA516-65	84.0	2792.5	9367.7	4	13,601	54,403	typ=3
8	12.8o	173.6o	77.9	82.83	83.09	72.85	75.54	35.96	84.0	#8	19.2o	SA516-65	84.0	2792.5	8377.6	3	14,655	43,965	typ=2
	6.4o	180.0o	0.0	82.85	83.11	72.87	75.56	35.96	84.0										typ=4
Sub-Total																88	Sht	1,264,251	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO106]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 알제리자재 중량표				Rev. No.	[AAA4]

(6/10) Tank No. : [알제리] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 1, Di = 11000 mm, DLL = 7600 mm, CA = 1.5 mm, SG = 0.536, Pg = 2150 kPa, Pe = 102.97 kPa
, SA537-CL2 matid=6, Sd= 158.0 MPa, St= 373.5 MPa, Thick Limit : t ≤ 64t

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	11000.0	38.93	38.98	21.04	21.98	17.01	40.0	#1	45.0o	SA537-CL2	40.0	2879.8	8639.4	3	7,422	22,265	typ=0
	15.0o	15.0o	10812.6	38.93	38.98	21.05	21.99	17.01	40.0										typ=4
	30.0o	45.0o	9389.1	38.93	38.98	21.16	22.09	17.01	40.0										typ=4
2	45.0o	90.0o	5500.0	39.18	39.17	21.44	22.37	17.01	40.5	#2	90.0o	SA537-CL2	40.5	2879.8	8739.4	12	7,121	85,457	typ=1
	45.0o	135.0o	1610.9	39.48	39.53	21.72	22.66	17.01	40.5										typ=4
3	30.0o	165.0o	187.4	39.61	39.66	21.82	22.76	17.01	40.5	#3	45.0o	SA537-CL2	40.5	2879.8	8639.4	3	7,514	22,543	typ=2
	15.0o	180.0o	0.0	39.63	39.68	21.84	22.77	17.01	40.5										typ=4
Sub-Total																18	Sht	130,265	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO107]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 롯데 G1자재 중량표				Rev. No.	[AAA4]

(7/10) Tank No. : [롯데 G1] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 1, Di = 16840 mm, DLL = 13480 mm, CA = 1.5 mm, SG = 0.646, Pg = 588.399 kPa, Pe = 50.7 kPa
, SA516-70 matid=3, Sd= 138.0 MPa, St= 234.0 MPa,

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	16840.0	19.45	19.46	14.48	15.71	18.55	20.5	#1	30.0o	SA516-70	20.5	2939.1	8817.4	3	3,962	11,886	typ=0
	10.0o	10.0o	16712.1	19.45	19.46	14.50	15.74	18.55	20.5										typ=4
	20.0o	30.0o	15711.9	19.45	19.46	14.68	15.91	18.55	20.5										typ=4
2	20.0o	50.0o	13832.3	19.45	19.46	15.01	16.24	18.55	20.5	#2	20.0o	SA516-70	20.5	2939.1	9321.8	4	3,430	13,721	typ=3
3	16.0o	66.0o	11844.7	19.78	19.78	15.36	16.59	18.55	21.0	#3	16.0o	SA516-70	21.0	2685.0	8817.4	6	2,889	17,334	typ=3
4	24.0o	90.0o	8420.0	20.68	20.44	15.97	17.20	18.55	22.5	#4	64.0o	SA516-70	22.5	2939.1	9505.2	18	4,588	82,575	typ=1
	40.0o	130.0o	3007.7	21.49	21.49	16.92	18.15	18.55	22.5										typ=4
5	20.0o	150.0o	1128.1	21.84	21.85	17.25	18.49	18.55	23.0	#5	20.0o	SA516-70	23.0	2939.1	9121.8	4	3,849	15,394	typ=3
6	20.0o	170.0o	127.9	22.03	22.05	17.43	18.66	18.55	23.0	#6	30.0o	SA516-70	23.0	2939.1	8817.4	3	4,445	13,335	typ=2
	10.0o	180.0o	0.0	22.06	22.07	17.45	18.68	18.55	23.0										typ=4
Sub-Total																38	Sht	154,245	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO108]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 말레이시아자재 중량표				Rev. No.	[AAA4]

(8/10) Tank No. : [말레이시아] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 1, Di = 15650 mm, DLL = 14080 mm, CA = 3 mm, SG = 0.6215, Pg = 588.399 kPa, Pe = 101.325 kPa
, SA516-70 matid=3, Sd= 138.0 MPa, St= 234.0 MPa,

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	15650.0	19.69	19.70	16.14	20.31	25.42	26.5	#1	30.0o	SA516-70	26.5	2731.4	8194.3	3	4,423	13,270	typ=0
	10.0o	10.0o	15531.1	19.69	19.70	16.16	20.33	25.42	26.5										typ=4
	20.0o	30.0o	14601.6	19.69	19.70	16.31	20.48	25.42	26.5										typ=4
2	20.0o	50.0o	12854.8	19.90	19.91	16.60	20.77	25.42	26.5	#2	20.0o	SA516-70	26.5	2731.4	8677.2	4	3,830	15,319	typ=3
3	16.0o	66.0o	11007.7	20.23	20.23	16.90	21.07	25.42	26.5	#3	16.0o	SA516-70	26.5	2495.3	8194.3	6	3,149	18,892	typ=3
4	24.0o	90.0o	7825.0	20.99	20.78	17.42	21.59	25.42	26.5	#4	64.0o	SA516-70	26.5	2731.4	8840.6	18	4,666	83,996	typ=1
	40.0o	130.0o	2795.2	21.64	21.65	18.25	22.42	25.42	26.5										typ=4
5	20.0o	150.0o	1048.4	21.94	21.95	18.53	22.70	25.42	26.5	#5	20.0o	SA516-70	26.5	2731.4	8477.2	4	3,830	15,319	typ=3
6	20.0o	170.0o	118.9	22.10	22.11	18.69	22.86	25.42	26.5	#6	30.0o	SA516-70	26.5	2731.4	8194.3	3	4,423	13,270	typ=2
	10.0o	180.0o	0.0	22.12	22.13	18.71	22.88	25.42	26.5										typ=4
Sub-Total																38	Sht	160,064	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO109]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : SN2388자재 중량표				Rev. No.	[AAA4]

(9/10) Tank No. : [SN2388] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 1, Di = 12000 mm, DLL = 10740 mm, CA = 1 mm, SG = 0.5, Pg = 497.8 kPa, Pe = 44.13 kPa
, SA553-TYPE1 matid=0, Sd= -99.999 MPa, St= -99.999 MPa,

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	12000.0	0.00	0.00	0.00	0.00	12.30	13.5	#1	30.0o	SA553-TYPE1	13.5	2094.4	6283.2	3	1,325	3,975	typ=0
	10.0o	10.0o	11908.8	0.00	0.00	0.00	0.00	12.30	13.5										typ=4
	20.0o	30.0o	11196.2	0.00	0.00	0.00	0.00	12.30	13.5										typ=4
2	20.0o	50.0o	9856.7	0.00	0.00	0.00	0.00	12.30	13.5	#2	20.0o	SA553-TYPE1	13.5	2094.4	6700.1	4	1,147	4,588	typ=3
3	40.0o	90.0o	6000.0	0.00	0.00	0.00	0.00	12.30	13.5	#3	80.0o	SA553-TYPE1	13.5	2692.8	8477.6	14	2,201	30,817	typ=1
	40.0o	130.0o	2143.3	0.00	0.00	0.00	0.00	12.30	13.5										typ=4
4	20.0o	150.0o	803.8	0.00	0.00	0.00	0.00	12.30	13.5	#4	20.0o	SA553-TYPE1	13.5	2094.4	6500.1	4	1,147	4,588	typ=3
5	20.0o	170.0o	91.2	0.00	0.00	0.00	0.00	12.30	13.5	#5	30.0o	SA553-TYPE1	13.5	2094.4	6283.2	3	1,325	3,975	typ=2
	10.0o	180.0o	0.0	0.00	0.00	0.00	0.00	12.30	13.5										typ=4
Sub-Total																28	Sht	47,942	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO110]

S-Tank Engineering	Spherical Tank Calculation				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : SN2345자재 중량표				Rev. No.	[AAA4]

(10/10) Tank No. : [SN2345] 자재 중량표 CALC_SPH_BODY_WEIGHT()

Design Code : Div. 1, Di = 9000 mm, DLL = 8070 mm, CA = 1 mm, SG = 0.5, Pg = 497.8 kPa, Pe = 44.13 kPa
, SA553-TYPE1 matid=0, Sd= -99.999 MPa, St= -99.999 MPa,

Calculation Result of Required Thickness, (mm)										Used Thickness, (mm)
No.	Each Angle	Sum. Angle	Hmm	1)tShear Theory σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed thick.	PNo	SEG. Angle	Matl	tUsed thick.	Width	Height	Qty	Unit WT	Net WT	Remark
P	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.		mm	mm	mm	SHT	kg/sht	kg
1	0.0o	0.0o	9000.0	0.00	0.00	0.00	0.00	10.00	11.0	#1	45.0o	SA553-TYPE1	11.0	2356.2	7068.6	3	1,366	4,099	typ=0
	15.0o	15.0o	8846.7	0.00	0.00	0.00	0.00	10.00	11.0										typ=4
	30.0o	45.0o	7682.0	0.00	0.00	0.00	0.00	10.00	11.0										typ=4
2	45.0o	90.0o	4500.0	0.00	0.00	0.00	0.00	10.00	11.0	#2	90.0o	SA553-TYPE1	11.0	2827.4	7168.6	10	1,554	15,538	typ=1
	45.0o	135.0o	1318.0	0.00	0.00	0.00	0.00	10.00	11.0										typ=4
3	30.0o	165.0o	153.3	0.00	0.00	0.00	0.00	10.00	11.0	#3	45.0o	SA553-TYPE1	11.0	2356.2	7068.6	3	1,366	4,099	typ=2
	15.0o	180.0o	0.0	0.00	0.00	0.00	0.00	10.00	11.0										typ=4
Sub-Total																16	Sht	23,735	kg

[여기에 현장 용접 길이를 넣는다.INSERTTANKNO111]

CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [1 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 0. T-3201(4)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 17000 mm, CA = 3.2 mm, SG = 0.538, Pg= 21.6 kg/cm2(=2118.236 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2718.8 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	17006.4	0	0	2118.2	2118.2	42.36	42.45	43.5	0.7+0.35	2.1750	2.3481			1.0	σeq = 223.467	1 / 11
P1	10.0o	10.0o	16877.2	0	0		2118.2	42.36	42.45	43.5	0.7+0.35	2.1750	2.3481			1.0	σeq = 223.467	2 / 11
P2	20.0o	30.0o	15867.2	0	0		2118.2	42.36	42.45	43.5	0.7+0.35	2.1750	2.3481			1.0	σeq = 223.467	3 / 11
P3	20.0o	50.0o	13969.0	534.2	2.8		2121.0	42.41	42.50	43.5	0.7+0.30	2.1722	2.3481			1.0	σeq = 223.765	4 / 11
P4	16.0o	66.0o	11961.8	2541.4	13.4		2131.6	42.60	42.69	43.5	0.7+0.11	2.1616	2.3481			1.0	σeq = 224.891	5 / 11
P5	24.0o	90.0o	8503.2	6000.0	31.7		2149.9	42.84	43.03	44.5	0.7+0.27	2.1702	2.3750			1.0	σeq = 223.439	6 / 11
	40.0o	130.0o	3037.4	11465.8	60.5		2178.7	43.47	43.57	44.5	0.7+0.23	2.1683	2.4020			1.0	σeq = 224.289	8 / 11
P6	20.0o	150.0o	1139.2	13364.0	70.5		2188.7	43.66	43.76	45.0	0.7+0.54	2.1852	2.4289			1.0	σeq = 222.621	9 / 11
P7	20.0o	170.0o	129.2	14374.0	75.8		2194.0	43.76	43.85	45.0	0.7+0.45	2.1799	2.4289			1.0	σeq = 223.162	10 / 11
P8	10.0o	180.0o	0	14503.2	76.5		2194.7	43.77	43.87	45.0	0.7+0.43	2.1792	2.4289	2.1616	2.3481	1.0	σeq = 223.231	11 / 11

Div.2　 tReq = R · [ EXP(  0.5 · P 　  S · E 　 ) － 1 ] ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	2.1182	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	2.1616	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	2.3481	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [1 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 0. T-3201(4)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 17000 mm, CA = 3.2 mm, SG = 0.538, Pg= 21.6 kg/cm2(=2118.236 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2702 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	17000.0	0	0	2702.0	2702.0	28.59	29.18	31.70	43.5	2.1750	2.3481	σeq = 375.098	1 / 11
P1	10.0o	10.0o	16870.9	129.1	1.3		2703.3	28.61	29.19	31.71	43.5	2.1750	2.3481	σeq = 375.322	2 / 11
P2	20.0o	30.0o	15861.2	1138.8	11.2		2713.2	28.71	29.30	31.82	43.5	2.1750	2.3481	σeq = 377.079	3 / 11
P3	20.0o	50.0o	13963.7	3036.3	29.8		2731.8	28.91	29.50	32.02	43.5	2.1722	2.3481	σeq = 380.402	4 / 11
P4	16.0o	66.0o	11957.3	5042.7	49.5		2751.5	29.13	29.71	32.23	43.5	2.1616	2.3481	σeq = 376.117	5 / 11
P5	24.0o	90.0o	8500.0	8500.0	83.4		2785.4	29.49	30.08	32.60	44.5	2.1702	2.3750	σeq = 381.646	6 / 11
	40.0o	130.0o	3036.3	13963.7	136.9		2838.9	30.07	30.66	33.18	44.5	2.1683	2.4020	σeq = 375.884	8 / 11
P6	20.0o	150.0o	1138.8	15861.2	155.5		2857.5	30.27	30.86	33.38	45.0	2.1852	2.4289	σeq = 378.961	9 / 11
P7	20.0o	170.0o	129.1	16870.9	165.4		2867.4	30.38	30.97	33.49	45.0	2.1799	2.4289	σeq = 380.608	10 / 11
P8	10.0o	180.0o	0	17000.0	166.7		2868.7	30.39	30.98	33.50	45.0	2.1792	2.4289	σeq = 380.819	11 / 11

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

2.1182

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.6478

27.0000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

2.1616

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.7020

27.5527

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

2.3481

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.9351

29.9297

S-Tank Engineering	AAA Spherical Tank Calculation [1 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 0. T-3201(4)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 17000 mm, CA = 3.2 mm, SG = 0.538, Pg= 21.6 kg/cm2(=2118.236 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2702 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	17006.4	0	0	17000.0	0	0	40.30	43.5	2.1750	2.3481	333.0890	1 / 11
P1	10.0o	10.0o	16877.2	0	0	16870.9	129.1	1.3	40.30	43.5	2.1750	2.3481	333.0890	2 / 11
P2	20.0o	30.0o	15867.2	0	0	15861.2	1138.8	11.2	40.30	43.5	2.1750	2.3481	333.0890	3 / 11
P3	20.0o	50.0o	13969.0	534.2	2.8	13963.7	3036.3	29.8	40.30	43.5	2.1722	2.3481	333.0890	4 / 11
P4	16.0o	66.0o	11961.8	2541.4	13.4	11957.3	5042.7	49.5	40.30	43.5	2.1616	2.3481	333.0890	5 / 11
P5	24.0o	90.0o	8503.2	6000.0	31.7	8500.0	8500.0	83.4	40.80	44.0	2.1702	2.3750	341.3655	6 / 11
	40.0o	130.0o	3037.4	11465.8	60.5	3036.3	13963.7	136.9	41.30	44.5	2.1683	2.4020	349.7426	8 / 11
P6	20.0o	150.0o	1139.2	13364.0	70.5	1138.8	15861.2	155.5	41.80	45.0	2.1852	2.4289	358.2203	9 / 11
P7	20.0o	170.0o	129.2	14374.0	75.8	129.1	16870.9	165.4	41.80	45.0	2.1799	2.4289	358.2203	10 / 11
P8	10.0o	180.0o	0	14503.2	76.5	0	17000.0	166.7	41.80	45.0	2.1792	2.4289	358.2203	11 / 11

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

2.1182

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.6478

27.0000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

2.1616

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.7020

27.5527

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

2.3481

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.9351

29.9297

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

101.3250

SA537-CL2

Maximum. Allowable External Pressure

MAEP =

333.089

3.3966

CS-4

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=333.089 kPa)

S-Tank Engineering	AAA Spherical Tank Calculation [1 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 0. T-3201(4)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 17000 mm, CA = 3.2 mm, SG = 0.538, Pg= 21.6 kg/cm2(=2118.236 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2702 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	42.36	42.4	29.18	31.70	25.38	43.5	0.7+0.35	#1	30.0	43.5	2967.1	8901.2	3	8,568	25,703	1 / 11
P1	10.0o	10.0o	42.36	42.4	29.19	31.71	25.38	43.5	0.7+0.35									2 / 11
P2	20.0o	30.0o	42.36	42.4	29.30	31.82	25.38	43.5	0.7+0.35									3 / 11
P3	20.0o	50.0o	42.41	42.5	29.50	32.02	25.38	43.5	0.7+0.30	#2	20.0	43.5	2967.1	9408.5	4	7,418	29,671	4 / 11
P4	16.0o	66.0o	42.60	42.7	29.71	32.23	25.38	43.5	0.7+0.11	#3	16.0	43.5	2710.5	8901.2	6	6,099	36,592	5 / 11
P5	24.0o	90.0o	42.84	43.0	30.08	32.60	25.38	44.5	0.7+0.27	#4	64.0	44.5	2967.1	9594.6	18	9,246	166,433	6 / 11
	40.0o	130.0o	43.47	43.6	30.66	33.18	25.38	44.5	0.7+0.23									8 / 11
P6	20.0o	150.0o	43.66	43.8	30.86	33.38	25.38	45.0	0.7+0.54	#5	20.0	45.0	2967.1	9208.5	4	7,673	30,694	9 / 11
P7	20.0o	170.0o	43.76	43.8	30.97	33.49	25.38	45.0	0.7+0.45	#6	30.0	45.0	2967.1	8901.2	3	8,863	26,589	10 / 11
P8	10.0o	180.0o	43.77	43.9	30.98	33.50	25.38	45.0	0.7+0.43									11 / 11

], CalcRpt[i][1]=[Spherical tank, / External Pressure calc Result !!
DivNo = 2, teReq = 25.38 mm; Pe :101.32 kPa ≤ Pa = 101.33 kPa = 2*Fha*(tc/Ro)*1000; Fhe=38.947; Fic=38.947 MPa; Fha=19.473 MPa; FS=2

S-Tank Engineering	Spherical Tank Calculation [1 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=17000 (cm), Sd=230 MPa, Pg=2.1182 (MPa), HT_UPPCOL = 35800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=246.839 (N-mm), Nφ=22.337 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	17000	mm	1700.0	cm
3	R = Inside Radius in Corroded Condition	R =	8503.2	mm	850.32	cm
4	L = Design Liquid level	L =	14500	mm	1450.0	cm
5	CA = Corrosion Allowance	CA =	3.2	mm	0.32	cm
6	Wt = Total Weight at Operating Condition	Wt =	15,923,141	N	1623708.5	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 230MPa	S =	230.0	MPa	2345.347	Kg/cm²
8	P = Design internal GAS Pressure	P =	2.118	MPa	21.6	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.538		0.538
10	γ = Liquid Density	γ =	5.275978E-6	N/mm³	538.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	9.0	columns	9	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.90889	degree	0.43474	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	45.12061	degree	0.7875	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9947440		0.9947440
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1243168		1.1243168
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4211765		0.4211765
20	C5 = 22 / φ	C5 =	0.8832190		0.8832190
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4211765		0.4211765
22	Calculation Result :
23	PM = P×R/2	PM =	9005.739	N-mm	91.833	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	246.839	N-mm	2.517	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	22.337	N-mm	0.228	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	9421.4	N/mm	9607.154	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	8764.85	N/mm	8937.66	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	43.87	mm	4.387	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	42.84	mm	4.284	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	218.093	MPa	2223.93	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	866,215,614	N-mm	8832.941×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	321,723,017	N-mm	3280.662×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	435,763,397	N-mm	4443.55×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	149,592,999	N-mm	1525.424×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	228.726	N/mm	233.236	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	499,944,245	N-mm	5098.013×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	265,283,128	N-mm	2705.135×103	Kg-cm
39	Za = IH / LA × t	Za =	98,359,900	mm³	98.36×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	3,976,844,927	mm³	3976.845×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.1424E-5		2.1424E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.782795E-3		6.782795E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1819.421	mm	181.942	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	59.91	N/mm	61.091	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	46,629,711	N-mm	475.491×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	23,457,810	N-mm	239.203×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	778,336	mm³	7783.358	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	206,517,299	mm³	206.517×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	265.332	mm	26.533	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	525.647	mm	52.565	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	263.23	N/mm	268.42	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	181.471	N/mm	185.049	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,335,734	N	136206.9	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	35913.087	N	3662.1	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7162.696	mm	716.27	cm

piDeg=[24.90888529672981] piRad=[0.43474206142953997] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=17000 (cm), Sd=230 MPa, Pg=2.1182 (MPa), HT_UPPCOL = 35800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	17006.4	0	0	2.1182	9005.74							9005.74	9005.74	223.47	< OK	230	42.36	42.45	43.5	0.09	2.84	0	0	0	0
P1	10	16877.2	0	0	2.1182	9005.74							9005.74	9005.74	223.47	< OK	230	42.36	42.45	43.5	0.09	2.84	0	0	0	0
P2	30	15867.2	0	0	2.1182	9005.74							9005.74	9005.74	223.47	< OK	230	42.36	42.45	43.5	0.09	2.84	0	0	0	0
P3	50	13969.0	534.2	0.0028	2.121	9005.74	23.12	0.85					9028.86	9006.59	223.76	< OK	230	42.41	42.50	43.5	0.09	2.71	0.364	0.013	0.061	0.002
P4	66	11961.8	2541.4	0.0134	2.1316	9005.74	103.68	10.34					9109.42	9016.08	224.89	< OK	230	42.60	42.69	43.5	0.09	2.22	1.631	0.163	0.272	0.027
P5	90	8503.2	6000.0	0.0317	2.1499	9005.74	246.84	22.34	228.73	59.91	263.23	181.47	9421.40	8764.85	223.44	< OK	230	42.84	43.03	44.0	0.19	2.85	3.882	0.351	0.647	0.059	Column Attached Equator Plate
	130	3037.4	11465.8	0.0605	2.1787	9005.74	220.66	293.73					9226.40	9299.47	224.29	< OK	230	43.47	43.57	44.5	0.10	2.48	3.471	4.62	0.578	0.77
P6	150	1139.2	13364.0	0.0705	2.1887	9005.74	286.69	312.86					9292.43	9318.59	222.62	< OK	230	43.66	43.76	45.0	0.10	3.21	4.509	4.921	0.752	0.82
P7	170	129.2	14374.0	0.0758	2.194	9005.74	320.98	323.88					9326.72	9329.62	223.16	< OK	230	43.76	43.85	45.0	0.09	2.97	5.048	5.094	0.841	0.849
P8	180	0	14503.2	0.0765	2.1947	9005.74	325.33	325.33					9331.07	9331.07	223.23	< OK	230	43.77	43.87	45.0	0.10	2.94	5.117	5.117	0.853	0.853

S-Tank Engineering	Spherical Tank Calculation [1 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=17000 (cm), Syt=394.25 MPa, MAWP=2.64775 (MPa), HT_UPPCOL = 35900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=590.442 (N-mm), Nφ=118.088 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	17000	mm	1700.0	cm
3	R = Inside Radius in Corroded Condition	R =	8500	mm	850.0	cm
4	L = Hydrostatic-test Water Level	L =	17000	mm	1700.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	27,428,678	N	2796946.7	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 394.25MPa	S =	394.25	MPa	4020.231	Kg/cm²
8	P = Design internal GAS Pressure	P =	2.118	MPa	21.6	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	9.0	columns	9	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.98323	degree	0.43604	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9946013		0.9946013
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1274573		1.1274573
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4223529		0.4223529
20	C5 = 22 / φ	C5 =	0.8805908		0.8805908
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4223529		0.4223529
22	Calculation Result :
23	PM = P×R/2	PM =	9002.35	N-mm	91.798	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	590.442	N-mm	6.021	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	118.088	N-mm	1.204	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	9882.37	N/mm	10077.213	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	8668.19	N/mm	8839.094	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	24.67	mm	2.467	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	23.72	mm	2.372	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	366.68	MPa	3739.095	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,491,552,916	N-mm	15209.607×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	552,232,975	N-mm	5631.209×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	750,349,167	N-mm	7651.432×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	256,881,443	N-mm	2619.462×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	391.907	N/mm	399.634	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	860,881,370	N-mm	8778.547×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	456,675,399	N-mm	4656.793×103	Kg-cm
39	Za = IH / LA × t	Za =	69,194,303	mm³	69.194×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,006,661,411	mm³	4006.661×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.1744E-5		2.1744E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.843321E-3		6.843321E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1823.992	mm	182.399	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	102.333	N/mm	104.351	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	80,295,960	N-mm	818.791×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	40,394,146	N-mm	411.906×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	784,652	mm³	7846.521	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	209,347,167	mm³	209.347×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	266.803	mm	26.68	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	528.53	mm	52.853	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	452.252	N/mm	461.169	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	312.089	N/mm	318.242	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	2,303,046	N	234845.4	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	62250.067	N	6347.7	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7180.0	mm	718.0	cm

piDeg=[24.983227870794817] piRad=[0.436039584121382] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=17000 (cm), Syt=394.25 MPa, MAWP=2.64775 (MPa), HT_UPPCOL = 35900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	17000.0	0	0	2.1182	9002.35							9002.35	9002.35	375.10	< OK	394.25	22.83	22.86	24.0	0.03	4.86	0	0	0	0
P1	10	16870.9	129.1	0.0013	2.1195	9002.35	8.08	2.68					9010.43	9005.03	375.32	< OK	394.25	22.85	22.88	24.0	0.03	4.80	0.068	0.023	0.011	0.004
P2	30	15861.2	1138.8	0.0112	2.1294	9002.35	71.76	23.16					9074.11	9025.51	377.08	< OK	394.25	22.95	22.99	24.0	0.04	4.36	0.608	0.196	0.101	0.033
P3	50	13963.7	3036.3	0.0298	2.148	9002.35	194.41	58.69					9196.76	9061.04	380.40	< OK	394.25	23.16	23.19	24.0	0.03	3.51	1.646	0.497	0.274	0.083
P4	66	11957.3	5042.7	0.0495	2.1677	9002.35	330.03	90.31					9332.38	9092.66	376.12	< OK	394.25	23.37	23.40	24.5	0.03	4.60	2.795	0.765	0.466	0.127
P5	90	8500.0	8500.0	0.0834	2.2016	9002.35	590.44	118.09	391.91	102.33	452.25	312.09	9882.37	8668.19	381.65	< OK	394.25	23.72	23.77	24.5	0.05	3.20	5	1	0.833	0.167	Column Attached Equator Plate
	130	3036.3	13963.7	0.1369	2.2551	9002.35	514.12	649.84					9516.47	9652.19	375.88	< OK	394.25	24.31	24.35	25.5	0.04	4.66	4.354	5.503	0.726	0.917
P6	150	1138.8	15861.2	0.1555	2.2737	9002.35	636.77	685.37					9639.12	9687.72	378.96	< OK	394.25	24.51	24.55	25.5	0.04	3.88	5.392	5.804	0.899	0.967
P7	170	129.1	16870.9	0.1654	2.2836	9002.35	700.45	705.85					9702.80	9708.20	380.61	< OK	394.25	24.62	24.65	25.5	0.03	3.46	5.932	5.977	0.989	0.996
P8	180	0	17000.0	0.1667	2.2849	9002.35	708.53	708.53					9710.88	9710.88	380.82	< OK	394.25	24.63	24.67	25.5	0.04	3.41	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 38
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 315681.48
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 17000
MRA(sWt[tid][20][10])= 907.92
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	9	Columns
2. gCol[tid][2] =	Column OD	OD =	863.6	mm
3. gCol[tid][3] =	Column thk	thk =	9.65	mm
4. gCol[tid][4] =	Tank Height	Htank =	11500	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	3590	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	7910	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	16600	mm
8. gCol[tid][8] =	Brace Angle	BRang =	35.6695	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.4537	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA537-CL2	t43.5 ~ 45	SHT	38	315.682	385.131	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t45, t12×3013×3590	SHT	9	11.274	12.402	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø863.6×9.65t × 7910L	PCS	9	14.467	14.467	000,000	000,000	3
4	BRACE ( PIPE, θ= 35.6695 deg.)	null	Ø0×0t × 9737L	PCS	18			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA537-CL2(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA537-CL2	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				74	341.422	412.000	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [2 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 1. T-3205(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.649, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2281.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	18006.4	0	0	1765.2	1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	1 / 12
P1	9.0o	9.0o	17895.6	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	2 / 12
P2	18.0o	27.0o	17025.1	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	3 / 12
P3	18.0o	45.0o	15369.4	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	4 / 12
P4	14.5o	59.5o	13572.7	930.5	5.9		1771.1	37.87	37.93	39.0	0.7+0.37	1.8196	1.9890			1.0	σeq = 222.709	5 / 12
P5	30.5o	90.0o	9003.2	5500.0	35.0		1800.2	38.32	38.50	40.0	0.7+0.30	1.8159	2.0145			1.0	σeq = 222.549	6 / 12
	30.5o	120.5o	4433.7	10069.5	64.1		1829.3	39.01	39.07	40.0	0.7+0.23	1.8123	2.0399			1.0	σeq = 223.794	8 / 12
P6	14.5o	135.0o	2637.0	11866.2	75.5		1840.7	39.23	39.30	40.5	0.7+0.50	1.8263	2.0654			1.0	σeq = 222.158	9 / 12
P7	18.0o	153.0o	981.3	13521.9	86.1		1851.3	39.43	39.51	40.5	0.7+0.29	1.8157	2.0654			1.0	σeq = 223.423	10 / 12
P8	18.0o	171.0o	110.8	14392.4	91.6		1856.8	39.54	39.62	40.5	0.7+0.18	1.8102	2.0654			1.0	σeq = 224.09	11 / 12
P9	9.0o	180.0o	0	14503.2	92.3		1857.5	39.56	39.63	40.5	0.7+0.17	1.8095	2.0654	1.8095	1.989	1.0	σeq = 224.176	12 / 12

Div.2　 tReq = R · [ EXP(  0.5 · P 　  S · E 　 ) － 1 ] ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	1.7652	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	1.8095	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	1.9890	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [2 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 1. T-3205(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.649, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2261.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	18000.0	0	0	2261.9	2261.9	25.22	25.85	28.42	39.0	1.8255	1.9890	σeq = 378.257	1 / 12
P1	9.0o	9.0o	17889.2	110.8	1.1		2263.0	25.23	25.87	28.44	39.0	1.8255	1.9890	σeq = 378.49	2 / 12
P2	18.0o	27.0o	17019.1	980.9	9.6		2271.5	25.33	25.96	28.53	39.0	1.8255	1.9890	σeq = 371.478	3 / 12
P3	18.0o	45.0o	15364.0	2636.0	25.9		2287.8	25.52	26.15	28.72	39.0	1.8255	1.9890	σeq = 374.904	4 / 12
P4	14.5o	59.5o	13567.8	4432.2	43.5		2305.4	25.72	26.35	28.92	39.0	1.8196	1.9890	σeq = 378.658	5 / 12
P5	30.5o	90.0o	9000.0	9000.0	88.3		2350.2	26.23	26.87	29.43	40.0	1.8159	2.0145	σeq = 379.07	6 / 12
	30.5o	120.5o	4432.2	13567.8	133.1		2395.0	26.74	27.38	29.95	40.0	1.8123	2.0399	σeq = 379.743	8 / 12
P6	14.5o	135.0o	2636.0	15364.0	150.7		2412.6	26.95	27.58	30.15	40.5	1.8263	2.0654	σeq = 374.873	9 / 12
P7	18.0o	153.0o	980.9	17019.1	166.9		2428.8	27.13	27.77	30.33	40.5	1.8157	2.0654	σeq = 378.023	10 / 12
P8	18.0o	171.0o	110.8	17889.2	175.4		2437.3	27.23	27.86	30.43	40.5	1.8102	2.0654	σeq = 379.689	11 / 12
P9	9.0o	180.0o	0	18000.0	176.5		2438.4	27.24	27.88	30.44	40.5	1.8095	2.0654	σeq = 379.902	12 / 12

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7652

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2065

22.5000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.8095

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2619

23.0650

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.9890

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.4863

25.3532

S-Tank Engineering	AAA Spherical Tank Calculation [2 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 1. T-3205(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.649, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2261.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	18006.4	0	0	18000.0	0	0	35.80	39.0	1.8255	1.9890	234.8265	1 / 12
P1	9.0o	9.0o	17895.6	0	0	17889.2	110.8	1.1	35.80	39.0	1.8255	1.9890	234.8265	2 / 12
P2	18.0o	27.0o	17025.1	0	0	17019.1	980.9	9.6	35.80	39.0	1.8255	1.9890	234.8265	3 / 12
P3	18.0o	45.0o	15369.4	0	0	15364.0	2636.0	25.9	35.80	39.0	1.8255	1.9890	234.8265	4 / 12
P4	14.5o	59.5o	13572.7	930.5	5.9	13567.8	4432.2	43.5	35.80	39.0	1.8196	1.9890	234.8265	5 / 12
P5	30.5o	90.0o	9003.2	5500.0	35.0	9000.0	9000.0	88.3	36.30	39.5	1.8159	2.0145	241.4050	6 / 12
	30.5o	120.5o	4433.7	10069.5	64.1	4432.2	13567.8	133.1	36.80	40.0	1.8123	2.0399	248.0736	8 / 12
P6	14.5o	135.0o	2637.0	11866.2	75.5	2636.0	15364.0	150.7	37.30	40.5	1.8263	2.0654	254.8324	9 / 12
P7	18.0o	153.0o	981.3	13521.9	86.1	980.9	17019.1	166.9	37.30	40.5	1.8157	2.0654	254.8324	10 / 12
P8	18.0o	171.0o	110.8	14392.4	91.6	110.8	17889.2	175.4	37.30	40.5	1.8102	2.0654	254.8324	11 / 12
P9	9.0o	180.0o	0	14503.2	92.3	0	18000.0	176.5	37.30	40.5	1.8095	2.0654	254.8324	12 / 12

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7652

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2065

22.5000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.8095

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2619

23.0650

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.9890

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.4863

25.3532

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

101.3250

SA537-CL2

Maximum. Allowable External Pressure

MAEP =

234.8265

2.3946

CS-4

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=234.8265 kPa)

S-Tank Engineering	AAA Spherical Tank Calculation [2 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 1. T-3205(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.649, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2261.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	37.75	37.8	25.85	28.42	26.69	39.0	0.7+0.48	#1	27.0	39.0	2827.4	8482.3	3	6,975	20,926	1 / 12
P1	9.0o	9.0o	37.75	37.8	25.87	28.44	26.69	39.0	0.7+0.48									2 / 12
P2	18.0o	27.0o	37.75	37.8	25.96	28.53	26.69	39.0	0.7+0.48									3 / 12
P3	18.0o	45.0o	37.75	37.8	26.15	28.72	26.69	39.0	0.7+0.48	#2	18.0	39.0	2827.4	9200.0	4	6,178	24,710	4 / 12
P4	14.5o	59.5o	37.87	37.9	26.35	28.92	26.69	39.0	0.7+0.37	#3	14.5	39.0	2436.2	9424.8	6	5,183	31,095	5 / 12
P5	30.5o	90.0o	38.32	38.5	26.87	29.43	26.69	40.0	0.7+0.30	#4	61.0	40.0	2827.4	9681.9	20	8,111	162,216	6 / 12
	30.5o	120.5o	39.01	39.1	27.38	29.95	26.69	40.0	0.7+0.23									8 / 12
P6	14.5o	135.0o	39.23	39.3	27.58	30.15	26.69	40.5	0.7+0.50	#5	14.5	40.5	2436.2	9424.8	6	5,382	32,291	9 / 12
P7	18.0o	153.0o	39.43	39.5	27.77	30.33	26.69	40.5	0.7+0.29	#6	18.0	40.5	2827.4	9000.0	4	6,415	25,661	10 / 12
P8	18.0o	171.0o	39.54	39.6	27.86	30.43	26.69	40.5	0.7+0.18	#7	27.0	40.5	2827.4	8482.3	3	7,244	21,731	11 / 12
P9	9.0o	180.0o	39.56	39.6	27.88	30.44	26.69	40.5	0.7+0.17									12 / 12

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [1 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 0. T-3201(4)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 17000 mm, CA = 3.2 mm, SG = 0.538, Pg= 21.6 kg/cm²(=2118.236 kPa), Pe= 1.033227 kg/cm²(=101.325 kPa), 수압테스트압력 GsetMAWP=2702 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	42.36	42.4	29.18	31.70	25.38	43.5	0.7+0.35	#1	30.0	43.5	2967.1	8901.2	3	8,568	25,703	1 / 11
P1	10.0o	10.0o	42.36	42.4	29.19	31.71	25.38	43.5	0.7+0.35									2 / 11
P2	20.0o	30.0o	42.36	42.4	29.30	31.82	25.38	43.5	0.7+0.35									3 / 11
P3	20.0o	50.0o	42.41	42.5	29.50	32.02	25.38	43.5	0.7+0.30	#2	20.0	43.5	2967.1	9408.5	4	7,418	29,671	4 / 11
P4	16.0o	66.0o	42.60	42.7	29.71	32.23	25.38	43.5	0.7+0.11	#3	16.0	43.5	2710.5	8901.2	6	6,099	36,592	5 / 11
P5	24.0o	90.0o	42.84	43.0	30.08	32.60	25.38	TD90USED	0.7+0.27	#4	64.0	44.5	2967.1	9594.6	18	9,246	166,433	6 / 11
	40.0o	130.0o	43.47	43.6	30.66	33.18	25.38	44.5	0.7+0.23									8 / 11
P6	20.0o	150.0o	43.66	43.8	30.86	33.38	25.38	45.0	0.7+0.54	#5	20.0	45.0	2967.1	9208.5	4	7,673	30,694	9 / 11
P7	20.0o	170.0o	43.76	43.8	30.97	33.49	25.38	45.0	0.7+0.45	#6	30.0	45.0	2967.1	8901.2	3	8,863	26,589	10 / 11
P8	10.0o	180.0o	43.77	43.9	30.98	33.50	25.38	45.0	0.7+0.43									11 / 11

Spherical tank, / External Pressure calc Result !!
DivNo = 2, teReq = 26.69 mm; Pe :101.32 kPa ≤ Pa = 101.37 kPa = 2*Fha*(tc/Ro)*1000; Fhe=38.956; Fic=38.956 MPa; Fha=19.478 MPa; FS=2

S-Tank Engineering	Spherical Tank Calculation [2 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=18000 (cm), Sd=230 MPa, Pg=1.7652 (MPa), HT_UPPCOL = 36900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=295.553 (N-mm), Nφ=19.602 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	18000	mm	1800.0	cm
3	R = Inside Radius in Corroded Condition	R =	9003.2	mm	900.32	cm
4	L = Design Liquid level	L =	14500	mm	1450.0	cm
5	CA = Corrosion Allowance	CA =	3.2	mm	0.32	cm
6	Wt = Total Weight at Operating Condition	Wt =	20,689,715	N	2109763.8	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 230MPa	S =	230.0	MPa	2345.347	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.765	MPa	18.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.649		0.649
10	γ = Liquid Density	γ =	6.364516E-6	N/mm³	649.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	10.0	columns	10	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.20483	degree	0.42245	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	52.34583	degree	0.91361	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9960751		0.9960751
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0944815		1.0944815
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4100000		0.4100000
20	C5 = 22 / φ	C5 =	0.9089093		0.9089093
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4100000		0.4100000
22	Calculation Result :
23	PM = P×R/2	PM =	7946.224	N-mm	81.029	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	295.553	N-mm	3.014	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	19.602	N-mm	0.2	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	8421.4	N/mm	8587.438	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	7666.64	N/mm	7817.797	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	39.63	mm	3.963	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	38.32	mm	3.832	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	216.583	MPa	2208.532	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	963,766,321	N-mm	9827.681×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	366,545,705	N-mm	3737.726×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	484,273,514	N-mm	4938.216×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	172,155,062	N-mm	1755.493×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	240.952	N/mm	245.703	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	558,806,125	N-mm	5698.237×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	293,952,251	N-mm	2997.479×103	Kg-cm
39	Za = IH / LA × t	Za =	93,925,995	mm³	93.926×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,345,188,157	mm³	4345.188×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.8569E-5		1.8569E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.227031E-3		6.227031E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1873.604	mm	187.36	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	61.331	N/mm	62.54	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	49,152,614	N-mm	501.217×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	24,698,216	N-mm	251.852×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	801,429	mm³	8014.295	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	212,712,858	mm³	212.713×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	265.417	mm	26.542	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	526.095	mm	52.61	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	299.186	N/mm	305.085	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	207.688	N/mm	211.783	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,574,933	N	160598.5	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	41652.593	N	4247.4	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7382.624	mm	738.262	cm

piDeg=[24.204834801458325] piRad=[0.42245406218675574] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=18000 (cm), Sd=230 MPa, Pg=1.7652 (MPa), HT_UPPCOL = 36900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	18006.4	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P1	9	17895.6	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P2	27	17025.1	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P3	45	15369.4	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P4	59.5	13572.7	930.5	0.0059	1.7711	7946.22	51.31	2.01					7997.53	7948.24	222.71	< OK	230	37.87	37.93	39.0	0.06	3.17	0.597	0.023	0.099	0.004
P5	90	9003.2	5500.0	0.0350	1.8002	7946.22	295.55	19.60	240.95	61.33	299.19	207.69	8421.40	7666.64	222.55	< OK	230	38.32	38.50	39.5	0.18	3.24	3.437	0.228	0.573	0.038	Column Attached Equator Plate
	120.5	4433.7	10069.5	0.0641	1.8293	7946.22	218.07	358.93					8164.29	8305.15	223.79	< OK	230	39.01	39.07	40.0	0.06	2.70	2.536	4.174	0.423	0.696
P6	135	2637.0	11866.2	0.0755	1.8407	7946.22	300.04	379.91					8246.26	8326.13	222.16	< OK	230	39.23	39.30	40.5	0.07	3.41	3.49	4.418	0.582	0.736
P7	153	981.3	13521.9	0.0861	1.8513	7946.22	373.08	401.74					8319.31	8347.96	223.42	< OK	230	39.43	39.51	40.5	0.08	2.86	4.339	4.672	0.723	0.779
P8	171	110.8	14392.4	0.0916	1.8568	7946.22	410.76	413.94					8356.98	8360.16	224.09	< OK	230	39.54	39.62	40.5	0.08	2.57	4.777	4.814	0.796	0.802
P9	180	0	14503.2	0.0923	1.8575	7946.22	415.52	415.52					8361.75	8361.75	224.18	< OK	230	39.56	39.63	40.5	0.07	2.53	4.833	4.833	0.805	0.805

S-Tank Engineering	Spherical Tank Calculation [2 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=18000 (cm), Syt=394.25 MPa, MAWP=2.2065 (MPa), HT_UPPCOL = 37000.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=661.949 (N-mm), Nφ=132.39 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	18000	mm	1800.0	cm
3	R = Inside Radius in Corroded Condition	R =	9000	mm	900.0	cm
4	L = Hydrostatic-test Water Level	L =	18000	mm	1800.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	32,139,894	N	3277357.1	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 394.25MPa	S =	394.25	MPa	4020.231	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.765	MPa	18.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	10.0	columns	10	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.27465	degree	0.42367	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9959448		0.9959448
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0974476		1.0974476
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4111111		0.4111111
20	C5 = 22 / φ	C5 =	0.9062952		0.9062952
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4111111		0.4111111
22	Calculation Result :
23	PM = P×R/2	PM =	7943.4	N-mm	81.0	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	661.949	N-mm	6.75	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	132.39	N-mm	1.35	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	8883.26	N/mm	9058.404	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	7612.2	N/mm	7762.284	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	22.19	mm	2.219	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	21.15	mm	2.115	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	362.589	MPa	3697.379	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,496,605,307	N-mm	15261.127×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	567,379,312	N-mm	5785.659×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	752,014,566	N-mm	7668.414×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	266,573,697	N-mm	2718.295×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	372.415	N/mm	379.758	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	867,867,174	N-mm	8849.782×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	456,414,316	N-mm	4654.131×103	Kg-cm
39	Za = IH / LA × t	Za =	65,250,509	mm³	65.251×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,376,861,061	mm³	4376.861×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.8838E-5		1.8838E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.280747E-3		6.280747E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1878.179	mm	187.818	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	94.501	N/mm	96.364	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	76,331,568	N-mm	778.365×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	38,355,103	N-mm	391.113×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	807,732	mm³	8077.324	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	215,536,570	mm³	215.537×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	266.842	mm	26.684	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	528.891	mm	52.889	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	463.59	N/mm	472.73	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	322.105	N/mm	328.456	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	2,448,674	N	249695.2	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	65095.462	N	6637.9	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7400.0	mm	740.0	cm

piDeg=[24.27465219458477] piRad=[0.4236726055719715] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=18000 (cm), Syt=394.25 MPa, MAWP=2.2065 (MPa), HT_UPPCOL = 37000.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	18000.0	0	0	1.7652	7943.4							7943.40	7943.40	378.26	< OK	394.25	20.15	20.17	21.0	0.02	4.06	0	0	0	0
P1	9	17889.2	110.8	0.0011	1.7663	7943.4	7.34	2.44					7950.74	7945.84	378.49	< OK	394.25	20.16	20.18	21.0	0.02	4.00	0.055	0.018	0.009	0.003
P2	27	17019.1	980.9	0.0096	1.7748	7943.4	65.35	21.23					8008.75	7964.63	371.48	< OK	394.25	20.26	20.28	21.5	0.02	5.78	0.494	0.16	0.082	0.027
P3	45	15364.0	2636.0	0.0259	1.7911	7943.4	177.82	54.84					8121.22	7998.24	374.90	< OK	394.25	20.44	20.47	21.5	0.03	4.91	1.343	0.414	0.224	0.069
P4	59.5	13567.8	4432.2	0.0435	1.8087	7943.4	304.03	87.15					8247.43	8030.55	378.66	< OK	394.25	20.65	20.67	21.5	0.02	3.95	2.297	0.658	0.383	0.11
P5	90	9000.0	9000.0	0.0883	1.8535	7943.4	661.95	132.39	372.42	94.50	463.59	322.10	8883.26	7612.20	379.07	< OK	394.25	21.15	21.18	22.0	0.03	3.85	5	1	0.833	0.167	Column Attached Equator Plate
	120.5	4432.2	13567.8	0.1331	1.8983	7943.4	490.30	707.19					8433.70	8650.59	379.74	< OK	394.25	21.67	21.69	22.5	0.02	3.68	3.703	5.342	0.617	0.89
P6	135	2636.0	15364.0	0.1507	1.9159	7943.4	616.52	739.50					8559.92	8682.90	374.87	< OK	394.25	21.87	21.89	23.0	0.02	4.91	4.657	5.586	0.776	0.931
P7	153	980.9	17019.1	0.1669	1.9321	7943.4	728.99	773.11					8672.39	8716.51	378.02	< OK	394.25	22.05	22.08	23.0	0.03	4.12	5.506	5.84	0.918	0.973
P8	171	110.8	17889.2	0.1754	1.9406	7943.4	787.00	791.90					8730.40	8735.30	379.69	< OK	394.25	22.15	22.18	23.0	0.03	3.69	5.945	5.982	0.991	0.997
P9	180	0	18000.0	0.1765	1.9417	7943.4	794.34	794.34					8737.74	8737.74	379.90	< OK	394.25	22.16	22.19	23.0	0.03	3.64	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 46
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 318629.945
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 18000
MRA(sWt[tid][20][10])= 1017.878
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	10	Columns
2. gCol[tid][2] =	Column OD	OD =	863.6	mm
3. gCol[tid][3] =	Column thk	thk =	9.65	mm
4. gCol[tid][4] =	Tank Height	Htank =	12000	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	3700	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	8300	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	17600	mm
8. gCol[tid][8] =	Brace Angle	BRang =	33.2354	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.1015	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA537-CL2	t39 ~ 40.5	SHT	46	318.630	388.728	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t40.5, t12×3013×3700	SHT	10	12.567	13.823	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø863.6×9.65t × 8300L	PCS	10	16.867	16.867	000,000	000,000	3
4	BRACE ( PIPE, θ= 33.2354 deg.)	null	Ø0×0t × 9923L	PCS	20			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA537-CL2(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA537-CL2	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				86	348.063	419.418	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [3 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 2. T-3208(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.625, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2281.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	18006.4	0	0	1765.2	1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	1 / 12
P1	9.0o	9.0o	17895.6	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	2 / 12
P2	18.0o	27.0o	17025.1	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	3 / 12
P3	18.0o	45.0o	15369.4	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	4 / 12
P4	14.5o	59.5o	13572.7	930.5	5.7		1770.9	37.86	37.93	39.0	0.7+0.37	1.8198	1.9890			1.0	σeq = 222.682	5 / 12
P5	30.5o	90.0o	9003.2	5500.0	33.7		1798.9	38.30	38.48	40.0	0.7+0.32	1.8172	2.0145			1.0	σeq = 222.38	6 / 12
	30.5o	120.5o	4433.7	10069.5	61.7		1826.9	38.96	39.03	40.0	0.7+0.27	1.8147	2.0399			1.0	σeq = 223.503	8 / 12
P6	14.5o	135.0o	2637.0	11866.2	72.7		1837.9	39.17	39.24	40.0	0.7+0.06	1.8037	2.0399			1.0	σeq = 224.834	9 / 12
P7	18.0o	153.0o	981.3	13521.9	82.9		1848.1	39.37	39.44	40.5	0.7+0.36	1.8189	2.0654			1.0	σeq = 223.039	10 / 12
P8	18.0o	171.0o	110.8	14392.4	88.2		1853.4	39.48	39.55	40.5	0.7+0.25	1.8136	2.0654			1.0	σeq = 223.682	11 / 12
P9	9.0o	180.0o	0	14503.2	88.9		1854.1	39.49	39.56	40.5	0.7+0.24	1.8129	2.0654	1.8037	1.989	1.0	σeq = 223.764	12 / 12

Div.2　 tReq = R · [ EXP(  0.5 · P 　  S · E 　 ) － 1 ] ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	1.7652	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	1.8037	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	1.9890	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [3 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 2. T-3208(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.625, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2254.6 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	18000.0	0	0	2254.6	2254.6	25.22	25.77	28.42	39.0	1.8255	1.9890	σeq = 378.257	1 / 12
P1	9.0o	9.0o	17889.2	110.8	1.1		2255.7	25.23	25.78	28.44	39.0	1.8255	1.9890	σeq = 378.49	2 / 12
P2	18.0o	27.0o	17019.1	980.9	9.6		2264.2	25.33	25.88	28.53	39.0	1.8255	1.9890	σeq = 371.478	3 / 12
P3	18.0o	45.0o	15364.0	2636.0	25.9		2280.5	25.52	26.07	28.72	39.0	1.8255	1.9890	σeq = 374.904	4 / 12
P4	14.5o	59.5o	13567.8	4432.2	43.5		2298.1	25.72	26.27	28.92	39.0	1.8198	1.9890	σeq = 378.658	5 / 12
P5	30.5o	90.0o	9000.0	9000.0	88.3		2342.9	26.23	26.78	29.43	40.0	1.8172	2.0145	σeq = 379.07	6 / 12
	30.5o	120.5o	4432.2	13567.8	133.1		2387.7	26.74	27.29	29.95	40.0	1.8147	2.0399	σeq = 379.743	8 / 12
P6	14.5o	135.0o	2636.0	15364.0	150.7		2405.3	26.95	27.50	30.15	40.0	1.8037	2.0399	σeq = 374.873	9 / 12
P7	18.0o	153.0o	980.9	17019.1	166.9		2421.5	27.13	27.68	30.33	40.5	1.8189	2.0654	σeq = 378.023	10 / 12
P8	18.0o	171.0o	110.8	17889.2	175.4		2430.0	27.23	27.78	30.43	40.5	1.8136	2.0654	σeq = 379.689	11 / 12
P9	9.0o	180.0o	0	18000.0	176.5		2431.1	27.24	27.79	30.44	40.5	1.8129	2.0654	σeq = 379.902	12 / 12

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7652

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2065

22.5000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.8037

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2546

22.9905

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.9890

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.4863

25.3532

S-Tank Engineering	AAA Spherical Tank Calculation [3 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 2. T-3208(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.625, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2254.6 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	18006.4	0	0	18000.0	0	0	35.80	39.0	1.8255	1.9890	234.8265	1 / 12
P1	9.0o	9.0o	17895.6	0	0	17889.2	110.8	1.1	35.80	39.0	1.8255	1.9890	234.8265	2 / 12
P2	18.0o	27.0o	17025.1	0	0	17019.1	980.9	9.6	35.80	39.0	1.8255	1.9890	234.8265	3 / 12
P3	18.0o	45.0o	15369.4	0	0	15364.0	2636.0	25.9	35.80	39.0	1.8255	1.9890	234.8265	4 / 12
P4	14.5o	59.5o	13572.7	930.5	5.7	13567.8	4432.2	43.5	35.80	39.0	1.8198	1.9890	234.8265	5 / 12
P5	30.5o	90.0o	9003.2	5500.0	33.7	9000.0	9000.0	88.3	36.30	39.5	1.8172	2.0145	241.4050	6 / 12
	30.5o	120.5o	4433.7	10069.5	61.7	4432.2	13567.8	133.1	36.80	40.0	1.8147	2.0399	248.0736	8 / 12
P6	14.5o	135.0o	2637.0	11866.2	72.7	2636.0	15364.0	150.7	36.80	40.0	1.8037	2.0399	248.0736	9 / 12
P7	18.0o	153.0o	981.3	13521.9	82.9	980.9	17019.1	166.9	37.30	40.5	1.8189	2.0654	254.8324	10 / 12
P8	18.0o	171.0o	110.8	14392.4	88.2	110.8	17889.2	175.4	37.30	40.5	1.8136	2.0654	254.8324	11 / 12
P9	9.0o	180.0o	0	14503.2	88.9	0	18000.0	176.5	37.30	40.5	1.8129	2.0654	254.8324	12 / 12

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7652

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2065

22.5000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.8037

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2546

22.9905

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.9890

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.4863

25.3532

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

101.3250

SA537-CL2

Maximum. Allowable External Pressure

MAEP =

234.8265

2.3946

CS-4

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=234.8265 kPa)

S-Tank Engineering	AAA Spherical Tank Calculation [3 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 2. T-3208(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.625, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2254.6 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	37.75	37.8	25.77	28.42	26.69	39.0	0.7+0.48	#1	27.0	39.0	2827.4	8482.3	3	6,975	20,926	1 / 12
P1	9.0o	9.0o	37.75	37.8	25.78	28.44	26.69	39.0	0.7+0.48									2 / 12
P2	18.0o	27.0o	37.75	37.8	25.88	28.53	26.69	39.0	0.7+0.48									3 / 12
P3	18.0o	45.0o	37.75	37.8	26.07	28.72	26.69	39.0	0.7+0.48	#2	18.0	39.0	2827.4	9200.0	4	6,178	24,710	4 / 12
P4	14.5o	59.5o	37.86	37.9	26.27	28.92	26.69	39.0	0.7+0.37	#3	14.5	39.0	2436.2	9424.8	6	5,183	31,095	5 / 12
P5	30.5o	90.0o	38.30	38.5	26.78	29.43	26.69	40.0	0.7+0.32	#4	61.0	40.0	2827.4	9681.9	20	8,111	162,216	6 / 12
	30.5o	120.5o	38.96	39.0	27.29	29.95	26.69	40.0	0.7+0.27									8 / 12
P6	14.5o	135.0o	39.17	39.2	27.50	30.15	26.69	40.0	0.7+0.06	#5	14.5	40.0	2436.2	9424.8	6	5,315	31,892	9 / 12
P7	18.0o	153.0o	39.37	39.4	27.68	30.33	26.69	40.5	0.7+0.36	#6	18.0	40.5	2827.4	9000.0	4	6,415	25,661	10 / 12
P8	18.0o	171.0o	39.48	39.6	27.78	30.43	26.69	40.5	0.7+0.25	#7	27.0	40.5	2827.4	8482.3	3	7,244	21,731	11 / 12
P9	9.0o	180.0o	39.49	39.6	27.79	30.44	26.69	40.5	0.7+0.24									12 / 12

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [2 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 1. T-3205(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.649, Pg= 18.0 kg/cm²(=1765.197 kPa), Pe= 1.033227 kg/cm²(=101.325 kPa), 수압테스트압력 GsetMAWP=2261.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	37.75	37.8	25.85	28.42	26.69	39.0	0.7+0.48	#1	27.0	39.0	2827.4	8482.3	3	6,975	20,926	1 / 12
P1	9.0o	9.0o	37.75	37.8	25.87	28.44	26.69	39.0	0.7+0.48									2 / 12
P2	18.0o	27.0o	37.75	37.8	25.96	28.53	26.69	39.0	0.7+0.48									3 / 12
P3	18.0o	45.0o	37.75	37.8	26.15	28.72	26.69	39.0	0.7+0.48	#2	18.0	39.0	2827.4	9200.0	4	6,178	24,710	4 / 12
P4	14.5o	59.5o	37.87	37.9	26.35	28.92	26.69	39.0	0.7+0.37	#3	14.5	39.0	2436.2	9424.8	6	5,183	31,095	5 / 12
P5	30.5o	90.0o	38.32	38.5	26.87	29.43	26.69	TD90USED	0.7+0.30	#4	61.0	40.0	2827.4	9681.9	20	8,111	162,216	6 / 12
	30.5o	120.5o	39.01	39.1	27.38	29.95	26.69	40.0	0.7+0.23									8 / 12
P6	14.5o	135.0o	39.23	39.3	27.58	30.15	26.69	40.5	0.7+0.50	#5	14.5	40.5	2436.2	9424.8	6	5,382	32,291	9 / 12
P7	18.0o	153.0o	39.43	39.5	27.77	30.33	26.69	40.5	0.7+0.29	#6	18.0	40.5	2827.4	9000.0	4	6,415	25,661	10 / 12
P8	18.0o	171.0o	39.54	39.6	27.86	30.43	26.69	40.5	0.7+0.18	#7	27.0	40.5	2827.4	8482.3	3	7,244	21,731	11 / 12
P9	9.0o	180.0o	39.56	39.6	27.88	30.44	26.69	40.5	0.7+0.17									12 / 12

Spherical tank, / External Pressure calc Result !!
DivNo = 2, teReq = 26.69 mm; Pe :101.32 kPa ≤ Pa = 101.37 kPa = 2*Fha*(tc/Ro)*1000; Fhe=38.956; Fic=38.956 MPa; Fha=19.478 MPa; FS=2

S-Tank Engineering	Spherical Tank Calculation [3 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=18000 (cm), Sd=230 MPa, Pg=1.7652 (MPa), HT_UPPCOL = 36900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=284.624 (N-mm), Nφ=18.877 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	18000	mm	1800.0	cm
3	R = Inside Radius in Corroded Condition	R =	9003.2	mm	900.32	cm
4	L = Design Liquid level	L =	14500	mm	1450.0	cm
5	CA = Corrosion Allowance	CA =	3.2	mm	0.32	cm
6	Wt = Total Weight at Operating Condition	Wt =	20,041,966	N	2043711.8	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 230MPa	S =	230.0	MPa	2345.347	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.765	MPa	18.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.625		0.625
10	γ = Liquid Density	γ =	6.129156E-6	N/mm³	625.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	10.0	columns	10	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.20483	degree	0.42245	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	52.34583	degree	0.91361	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9960751		0.9960751
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0944815		1.0944815
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4100000		0.4100000
20	C5 = 22 / φ	C5 =	0.9089093		0.9089093
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4100000		0.4100000
22	Calculation Result :
23	PM = P×R/2	PM =	7946.224	N-mm	81.029	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	284.624	N-mm	2.902	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	18.877	N-mm	0.192	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	8404.85	N/mm	8570.562	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	7675.28	N/mm	7826.607	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	39.56	mm	3.956	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	38.3	mm	3.83	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	216.418	MPa	2206.849	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	933,592,940	N-mm	9519.999×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	355,069,974	N-mm	3620.706×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	469,111,987	N-mm	4783.611×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	166,765,270	N-mm	1700.532×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	233.408	N/mm	238.01	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	541,311,148	N-mm	5519.838×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	284,749,259	N-mm	2903.634×103	Kg-cm
39	Za = IH / LA × t	Za =	93,925,995	mm³	93.926×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,345,188,157	mm³	4345.188×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.8569E-5		1.8569E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.227031E-3		6.227031E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1873.604	mm	187.36	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	59.411	N/mm	60.582	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	47,613,755	N-mm	485.525×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	23,924,970	N-mm	243.967×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	801,429	mm³	8014.295	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	212,712,858	mm³	212.713×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	265.417	mm	26.542	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	526.095	mm	52.61	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	289.819	N/mm	295.533	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	201.185	N/mm	205.152	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,525,625	N	155570.5	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	40348.543	N	4114.4	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7382.624	mm	738.262	cm

piDeg=[24.204834801458325] piRad=[0.42245406218675574] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=18000 (cm), Sd=230 MPa, Pg=1.7652 (MPa), HT_UPPCOL = 36900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	18006.4	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P1	9	17895.6	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P2	27	17025.1	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P3	45	15369.4	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P4	59.5	13572.7	930.5	0.0057	1.7709	7946.22	49.41	1.94					7995.64	7948.16	222.68	< OK	230	37.86	37.93	39.0	0.07	3.18	0.597	0.023	0.099	0.004
P5	90	9003.2	5500.0	0.0337	1.7989	7946.22	284.62	18.88	233.41	59.41	289.82	201.18	8404.85	7675.28	222.38	< OK	230	38.30	38.48	39.5	0.18	3.31	3.437	0.228	0.573	0.038	Column Attached Equator Plate
	120.5	4433.7	10069.5	0.0617	1.8269	7946.22	210.00	345.65					8156.23	8291.88	223.50	< OK	230	38.96	39.03	40.0	0.07	2.82	2.536	4.174	0.423	0.696
P6	135	2637.0	11866.2	0.0727	1.8379	7946.22	288.94	365.86					8235.17	8312.08	224.83	< OK	230	39.17	39.24	40.0	0.07	2.25	3.49	4.418	0.582	0.736
P7	153	981.3	13521.9	0.0829	1.8481	7946.22	359.29	386.88					8305.51	8333.10	223.04	< OK	230	39.37	39.44	40.5	0.07	3.03	4.339	4.672	0.723	0.779
P8	171	110.8	14392.4	0.0882	1.8534	7946.22	395.57	398.63					8341.79	8344.86	223.68	< OK	230	39.48	39.55	40.5	0.07	2.75	4.777	4.814	0.796	0.802
P9	180	0	14503.2	0.0889	1.8541	7946.22	400.16	400.16					8346.38	8346.38	223.76	< OK	230	39.49	39.56	40.5	0.07	2.71	4.833	4.833	0.805	0.805

S-Tank Engineering	Spherical Tank Calculation [3 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=18000 (cm), Syt=394.25 MPa, MAWP=2.2065 (MPa), HT_UPPCOL = 37000.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=661.949 (N-mm), Nφ=132.39 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	18000	mm	1800.0	cm
3	R = Inside Radius in Corroded Condition	R =	9000	mm	900.0	cm
4	L = Hydrostatic-test Water Level	L =	18000	mm	1800.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	32,139,894	N	3277357.1	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 394.25MPa	S =	394.25	MPa	4020.231	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.765	MPa	18.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	10.0	columns	10	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.27465	degree	0.42367	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9959448		0.9959448
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0974476		1.0974476
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4111111		0.4111111
20	C5 = 22 / φ	C5 =	0.9062952		0.9062952
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4111111		0.4111111
22	Calculation Result :
23	PM = P×R/2	PM =	7943.4	N-mm	81.0	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	661.949	N-mm	6.75	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	132.39	N-mm	1.35	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	8883.26	N/mm	9058.404	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	7612.2	N/mm	7762.284	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	22.19	mm	2.219	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	21.15	mm	2.115	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	362.589	MPa	3697.379	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,496,605,307	N-mm	15261.127×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	567,379,312	N-mm	5785.659×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	752,014,566	N-mm	7668.414×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	266,573,697	N-mm	2718.295×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	372.415	N/mm	379.758	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	867,867,174	N-mm	8849.782×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	456,414,316	N-mm	4654.131×103	Kg-cm
39	Za = IH / LA × t	Za =	65,250,509	mm³	65.251×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,376,861,061	mm³	4376.861×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.8838E-5		1.8838E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.280747E-3		6.280747E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1878.179	mm	187.818	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	94.501	N/mm	96.364	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	76,331,568	N-mm	778.365×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	38,355,103	N-mm	391.113×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	807,732	mm³	8077.324	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	215,536,570	mm³	215.537×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	266.842	mm	26.684	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	528.891	mm	52.889	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	463.59	N/mm	472.73	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	322.105	N/mm	328.456	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	2,448,674	N	249695.2	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	65095.462	N	6637.9	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7400.0	mm	740.0	cm

piDeg=[24.27465219458477] piRad=[0.4236726055719715] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=18000 (cm), Syt=394.25 MPa, MAWP=2.2065 (MPa), HT_UPPCOL = 37000.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	18000.0	0	0	1.7652	7943.4							7943.40	7943.40	378.26	< OK	394.25	20.15	20.17	21.0	0.02	4.06	0	0	0	0
P1	9	17889.2	110.8	0.0011	1.7663	7943.4	7.34	2.44					7950.74	7945.84	378.49	< OK	394.25	20.16	20.18	21.0	0.02	4.00	0.055	0.018	0.009	0.003
P2	27	17019.1	980.9	0.0096	1.7748	7943.4	65.35	21.23					8008.75	7964.63	371.48	< OK	394.25	20.26	20.28	21.5	0.02	5.78	0.494	0.16	0.082	0.027
P3	45	15364.0	2636.0	0.0259	1.7911	7943.4	177.82	54.84					8121.22	7998.24	374.90	< OK	394.25	20.44	20.47	21.5	0.03	4.91	1.343	0.414	0.224	0.069
P4	59.5	13567.8	4432.2	0.0435	1.8087	7943.4	304.03	87.15					8247.43	8030.55	378.66	< OK	394.25	20.65	20.67	21.5	0.02	3.95	2.297	0.658	0.383	0.11
P5	90	9000.0	9000.0	0.0883	1.8535	7943.4	661.95	132.39	372.42	94.50	463.59	322.10	8883.26	7612.20	379.07	< OK	394.25	21.15	21.18	22.0	0.03	3.85	5	1	0.833	0.167	Column Attached Equator Plate
	120.5	4432.2	13567.8	0.1331	1.8983	7943.4	490.30	707.19					8433.70	8650.59	379.74	< OK	394.25	21.67	21.69	22.5	0.02	3.68	3.703	5.342	0.617	0.89
P6	135	2636.0	15364.0	0.1507	1.9159	7943.4	616.52	739.50					8559.92	8682.90	374.87	< OK	394.25	21.87	21.89	23.0	0.02	4.91	4.657	5.586	0.776	0.931
P7	153	980.9	17019.1	0.1669	1.9321	7943.4	728.99	773.11					8672.39	8716.51	378.02	< OK	394.25	22.05	22.08	23.0	0.03	4.12	5.506	5.84	0.918	0.973
P8	171	110.8	17889.2	0.1754	1.9406	7943.4	787.00	791.90					8730.40	8735.30	379.69	< OK	394.25	22.15	22.18	23.0	0.03	3.69	5.945	5.982	0.991	0.997
P9	180	0	18000.0	0.1765	1.9417	7943.4	794.34	794.34					8737.74	8737.74	379.90	< OK	394.25	22.16	22.19	23.0	0.03	3.64	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 46
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 318231.293
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 18000
MRA(sWt[tid][20][10])= 1017.878
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	10	Columns
2. gCol[tid][2] =	Column OD	OD =	863.6	mm
3. gCol[tid][3] =	Column thk	thk =	9.65	mm
4. gCol[tid][4] =	Tank Height	Htank =	12000	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	3700	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	8300	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	17600	mm
8. gCol[tid][8] =	Brace Angle	BRang =	33.2354	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.1015	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA537-CL2	t39 ~ 40.5	SHT	46	318.231	388.242	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t40.5, t12×3013×3700	SHT	10	12.567	13.823	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø863.6×9.65t × 8300L	PCS	10	16.867	16.867	000,000	000,000	3
4	BRACE ( PIPE, θ= 33.2354 deg.)	null	Ø0×0t × 9923L	PCS	20			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA537-CL2(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA537-CL2	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				86	347.665	418.932	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [4 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 3. T-3213(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.596, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2281.9 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	18006.4	0	0	1765.2	1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	1 / 12
P1	9.0o	9.0o	17895.6	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	2 / 12
P2	18.0o	27.0o	17025.1	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	3 / 12
P3	18.0o	45.0o	15369.4	0	0		1765.2	37.75	37.82	39.0	0.7+0.48	1.8255	1.9890			1.0	σeq = 221.961	4 / 12
P4	14.5o	59.5o	13572.7	930.5	5.4		1770.6	37.86	37.92	39.0	0.7+0.38	1.8201	1.9890			1.0	σeq = 222.648	5 / 12
P5	30.5o	90.0o	9003.2	5500.0	32.1		1797.3	38.27	38.45	40.0	0.7+0.35	1.8188	2.0145			1.0	σeq = 222.177	6 / 12
	30.5o	120.5o	4433.7	10069.5	58.9		1824.1	38.90	38.97	40.0	0.7+0.33	1.8175	2.0399			1.0	σeq = 223.15	8 / 12
P6	14.5o	135.0o	2637.0	11866.2	69.4		1834.6	39.11	39.18	40.0	0.7+0.12	1.8070	2.0399			1.0	σeq = 224.421	9 / 12
P7	18.0o	153.0o	981.3	13521.9	79.0		1844.2	39.30	39.37	40.5	0.7+0.43	1.8228	2.0654			1.0	σeq = 222.574	10 / 12
P8	18.0o	171.0o	110.8	14392.4	84.1		1849.3	39.40	39.47	40.5	0.7+0.33	1.8177	2.0654			1.0	σeq = 223.188	11 / 12
P9	9.0o	180.0o	0	14503.2	84.8		1850.0	39.41	39.48	40.5	0.7+0.32	1.8170	2.0654	1.807	1.989	1.0	σeq = 223.266	12 / 12

Div.2　 tReq = R · [ EXP(  0.5 · P 　  S · E 　 ) － 1 ] ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	1.7652	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	1.8070	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	1.9890	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [4 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 3. T-3213(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.596, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2258.8 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	18000.0	0	0	2258.8	2258.8	25.22	25.82	28.42	39.0	1.8255	1.9890	σeq = 378.257	1 / 12
P1	9.0o	9.0o	17889.2	110.8	1.1		2259.9	25.23	25.83	28.44	39.0	1.8255	1.9890	σeq = 378.49	2 / 12
P2	18.0o	27.0o	17019.1	980.9	9.6		2268.4	25.33	25.93	28.53	39.0	1.8255	1.9890	σeq = 371.478	3 / 12
P3	18.0o	45.0o	15364.0	2636.0	25.9		2284.7	25.52	26.12	28.72	39.0	1.8255	1.9890	σeq = 374.904	4 / 12
P4	14.5o	59.5o	13567.8	4432.2	43.5		2302.3	25.72	26.32	28.92	39.0	1.8201	1.9890	σeq = 378.658	5 / 12
P5	30.5o	90.0o	9000.0	9000.0	88.3		2347.1	26.23	26.83	29.43	40.0	1.8188	2.0145	σeq = 379.07	6 / 12
	30.5o	120.5o	4432.2	13567.8	133.1		2391.9	26.74	27.34	29.95	40.0	1.8175	2.0399	σeq = 379.743	8 / 12
P6	14.5o	135.0o	2636.0	15364.0	150.7		2409.5	26.95	27.54	30.15	40.0	1.8070	2.0399	σeq = 374.873	9 / 12
P7	18.0o	153.0o	980.9	17019.1	166.9		2425.7	27.13	27.73	30.33	40.5	1.8228	2.0654	σeq = 378.023	10 / 12
P8	18.0o	171.0o	110.8	17889.2	175.4		2434.2	27.23	27.83	30.43	40.5	1.8177	2.0654	σeq = 379.689	11 / 12
P9	9.0o	180.0o	0	18000.0	176.5		2435.3	27.24	27.84	30.44	40.5	1.8170	2.0654	σeq = 379.902	12 / 12

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7652

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2065

22.5000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.8070

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2588

23.0333

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.9890

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.4863

25.3532

S-Tank Engineering	AAA Spherical Tank Calculation [4 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 3. T-3213(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.596, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2258.8 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	18006.4	0	0	18000.0	0	0	35.80	39.0	1.8255	1.9890	234.8265	1 / 12
P1	9.0o	9.0o	17895.6	0	0	17889.2	110.8	1.1	35.80	39.0	1.8255	1.9890	234.8265	2 / 12
P2	18.0o	27.0o	17025.1	0	0	17019.1	980.9	9.6	35.80	39.0	1.8255	1.9890	234.8265	3 / 12
P3	18.0o	45.0o	15369.4	0	0	15364.0	2636.0	25.9	35.80	39.0	1.8255	1.9890	234.8265	4 / 12
P4	14.5o	59.5o	13572.7	930.5	5.4	13567.8	4432.2	43.5	35.80	39.0	1.8201	1.9890	234.8265	5 / 12
P5	30.5o	90.0o	9003.2	5500.0	32.1	9000.0	9000.0	88.3	36.30	39.5	1.8188	2.0145	241.4050	6 / 12
	30.5o	120.5o	4433.7	10069.5	58.9	4432.2	13567.8	133.1	36.80	40.0	1.8175	2.0399	248.0736	8 / 12
P6	14.5o	135.0o	2637.0	11866.2	69.4	2636.0	15364.0	150.7	36.80	40.0	1.8070	2.0399	248.0736	9 / 12
P7	18.0o	153.0o	981.3	13521.9	79.0	980.9	17019.1	166.9	37.30	40.5	1.8228	2.0654	254.8324	10 / 12
P8	18.0o	171.0o	110.8	14392.4	84.1	110.8	17889.2	175.4	37.30	40.5	1.8177	2.0654	254.8324	11 / 12
P9	9.0o	180.0o	0	14503.2	84.8	0	18000.0	176.5	37.30	40.5	1.8170	2.0654	254.8324	12 / 12

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7652

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2065

22.5000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.8070

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.2588

23.0333

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.9890

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.4863

25.3532

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

101.3250

SA537-CL2

Maximum. Allowable External Pressure

MAEP =

234.8265

2.3946

CS-4

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=234.8265 kPa)

S-Tank Engineering	AAA Spherical Tank Calculation [4 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 3. T-3213(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.596, Pg= 18.0 kg/cm2(=1765.197 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=2258.8 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	37.75	37.8	25.82	28.42	26.69	39.0	0.7+0.48	#1	27.0	39.0	2827.4	8482.3	3	6,975	20,926	1 / 12
P1	9.0o	9.0o	37.75	37.8	25.83	28.44	26.69	39.0	0.7+0.48									2 / 12
P2	18.0o	27.0o	37.75	37.8	25.93	28.53	26.69	39.0	0.7+0.48									3 / 12
P3	18.0o	45.0o	37.75	37.8	26.12	28.72	26.69	39.0	0.7+0.48	#2	18.0	39.0	2827.4	9200.0	4	6,178	24,710	4 / 12
P4	14.5o	59.5o	37.86	37.9	26.32	28.92	26.69	39.0	0.7+0.38	#3	14.5	39.0	2436.2	9424.8	6	5,183	31,095	5 / 12
P5	30.5o	90.0o	38.27	38.4	26.83	29.43	26.69	40.0	0.7+0.35	#4	61.0	40.0	2827.4	9681.9	20	8,111	162,216	6 / 12
	30.5o	120.5o	38.90	39.0	27.34	29.95	26.69	40.0	0.7+0.33									8 / 12
P6	14.5o	135.0o	39.11	39.2	27.54	30.15	26.69	40.0	0.7+0.12	#5	14.5	40.0	2436.2	9424.8	6	5,315	31,892	9 / 12
P7	18.0o	153.0o	39.30	39.4	27.73	30.33	26.69	40.5	0.7+0.43	#6	18.0	40.5	2827.4	9000.0	4	6,415	25,661	10 / 12
P8	18.0o	171.0o	39.40	39.5	27.83	30.43	26.69	40.5	0.7+0.33	#7	27.0	40.5	2827.4	8482.3	3	7,244	21,731	11 / 12
P9	9.0o	180.0o	39.41	39.5	27.84	30.44	26.69	40.5	0.7+0.32									12 / 12

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [3 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 2. T-3208(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.625, Pg= 18.0 kg/cm²(=1765.197 kPa), Pe= 1.033227 kg/cm²(=101.325 kPa), 수압테스트압력 GsetMAWP=2254.6 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	37.75	37.8	25.77	28.42	26.69	39.0	0.7+0.48	#1	27.0	39.0	2827.4	8482.3	3	6,975	20,926	1 / 12
P1	9.0o	9.0o	37.75	37.8	25.78	28.44	26.69	39.0	0.7+0.48									2 / 12
P2	18.0o	27.0o	37.75	37.8	25.88	28.53	26.69	39.0	0.7+0.48									3 / 12
P3	18.0o	45.0o	37.75	37.8	26.07	28.72	26.69	39.0	0.7+0.48	#2	18.0	39.0	2827.4	9200.0	4	6,178	24,710	4 / 12
P4	14.5o	59.5o	37.86	37.9	26.27	28.92	26.69	39.0	0.7+0.37	#3	14.5	39.0	2436.2	9424.8	6	5,183	31,095	5 / 12
P5	30.5o	90.0o	38.30	38.5	26.78	29.43	26.69	TD90USED	0.7+0.32	#4	61.0	40.0	2827.4	9681.9	20	8,111	162,216	6 / 12
	30.5o	120.5o	38.96	39.0	27.29	29.95	26.69	40.0	0.7+0.27									8 / 12
P6	14.5o	135.0o	39.17	39.2	27.50	30.15	26.69	40.0	0.7+0.06	#5	14.5	40.0	2436.2	9424.8	6	5,315	31,892	9 / 12
P7	18.0o	153.0o	39.37	39.4	27.68	30.33	26.69	40.5	0.7+0.36	#6	18.0	40.5	2827.4	9000.0	4	6,415	25,661	10 / 12
P8	18.0o	171.0o	39.48	39.6	27.78	30.43	26.69	40.5	0.7+0.25	#7	27.0	40.5	2827.4	8482.3	3	7,244	21,731	11 / 12
P9	9.0o	180.0o	39.49	39.6	27.79	30.44	26.69	40.5	0.7+0.24									12 / 12

Spherical tank, / External Pressure calc Result !!
DivNo = 2, teReq = 26.69 mm; Pe :101.32 kPa ≤ Pa = 101.37 kPa = 2*Fha*(tc/Ro)*1000; Fhe=38.956; Fic=38.956 MPa; Fha=19.478 MPa; FS=2

S-Tank Engineering	Spherical Tank Calculation [4 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=18000 (cm), Sd=230 MPa, Pg=1.7652 (MPa), HT_UPPCOL = 36900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=271.417 (N-mm), Nφ=18.001 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	18000	mm	1800.0	cm
3	R = Inside Radius in Corroded Condition	R =	9003.2	mm	900.32	cm
4	L = Design Liquid level	L =	14500	mm	1450.0	cm
5	CA = Corrosion Allowance	CA =	3.2	mm	0.32	cm
6	Wt = Total Weight at Operating Condition	Wt =	19,259,269	N	1963898.9	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 230MPa	S =	230.0	MPa	2345.347	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.765	MPa	18.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.596		0.596
10	γ = Liquid Density	γ =	5.844763E-6	N/mm³	596.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	10.0	columns	10	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.20483	degree	0.42245	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	52.34583	degree	0.91361	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9960751		0.9960751
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0944815		1.0944815
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4100000		0.4100000
20	C5 = 22 / φ	C5 =	0.9089093		0.9089093
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4100000		0.4100000
22	Calculation Result :
23	PM = P×R/2	PM =	7946.224	N-mm	81.029	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	271.417	N-mm	2.768	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	18.001	N-mm	0.184	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	8384.84	N/mm	8550.157	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	7685.73	N/mm	7837.263	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	39.48	mm	3.948	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	38.27	mm	3.827	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	216.22	MPa	2204.83	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	897,133,424	N-mm	9148.215×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	341,203,460	N-mm	3479.307×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	450,791,801	N-mm	4596.797×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	160,252,601	N-mm	1634.122×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	224.293	N/mm	228.715	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	520,171,375	N-mm	5304.272×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	273,628,974	N-mm	2790.239×103	Kg-cm
39	Za = IH / LA × t	Za =	93,925,995	mm³	93.926×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,345,188,157	mm³	4345.188×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.8569E-5		1.8569E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.227031E-3		6.227031E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1873.604	mm	187.36	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	57.091	N/mm	58.217	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	45,754,300	N-mm	466.564×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	22,990,631	N-mm	234.439×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	801,429	mm³	8014.295	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	212,712,858	mm³	212.713×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	265.417	mm	26.542	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	526.095	mm	52.61	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	278.501	N/mm	283.992	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	193.329	N/mm	197.141	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,466,045	N	149495.0	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	38772.815	N	3953.7	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7382.624	mm	738.262	cm

piDeg=[24.204834801458325] piRad=[0.42245406218675574] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=18000 (cm), Sd=230 MPa, Pg=1.7652 (MPa), HT_UPPCOL = 36900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	18006.4	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P1	9	17895.6	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P2	27	17025.1	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P3	45	15369.4	0	0	1.7652	7946.22							7946.22	7946.22	221.96	< OK	230	37.75	37.82	39.0	0.07	3.50	0	0	0	0
P4	59.5	13572.7	930.5	0.0054	1.7706	7946.22	47.12	1.85					7993.34	7948.07	222.65	< OK	230	37.86	37.92	39.0	0.06	3.20	0.597	0.023	0.099	0.004
P5	90	9003.2	5500.0	0.0321	1.7973	7946.22	271.42	18.00	224.29	57.09	278.50	193.33	8384.84	7685.73	222.18	< OK	230	38.27	38.45	39.5	0.18	3.40	3.437	0.228	0.573	0.038	Column Attached Equator Plate
	120.5	4433.7	10069.5	0.0589	1.8241	7946.22	200.26	329.61					8146.48	8275.84	223.15	< OK	230	38.90	38.97	40.0	0.07	2.98	2.536	4.174	0.423	0.696
P6	135	2637.0	11866.2	0.0694	1.8346	7946.22	275.54	348.88					8221.76	8295.11	224.42	< OK	230	39.11	39.18	40.0	0.07	2.43	3.49	4.418	0.582	0.736
P7	153	981.3	13521.9	0.0790	1.8442	7946.22	342.61	368.93					8288.84	8315.15	222.57	< OK	230	39.30	39.37	40.5	0.07	3.23	4.339	4.672	0.723	0.779
P8	171	110.8	14392.4	0.0841	1.8493	7946.22	377.21	380.14					8323.44	8326.36	223.19	< OK	230	39.40	39.47	40.5	0.07	2.96	4.777	4.814	0.796	0.802
P9	180	0	14503.2	0.0848	1.85	7946.22	381.59	381.59					8327.81	8327.81	223.27	< OK	230	39.41	39.48	40.5	0.07	2.93	4.833	4.833	0.805	0.805

S-Tank Engineering	Spherical Tank Calculation [4 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=18000 (cm), Syt=394.25 MPa, MAWP=2.2065 (MPa), HT_UPPCOL = 37000.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=661.949 (N-mm), Nφ=132.39 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	18000	mm	1800.0	cm
3	R = Inside Radius in Corroded Condition	R =	9000	mm	900.0	cm
4	L = Hydrostatic-test Water Level	L =	18000	mm	1800.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	32,139,894	N	3277357.1	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 394.25MPa	S =	394.25	MPa	4020.231	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.765	MPa	18.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	10.0	columns	10	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	24.27465	degree	0.42367	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9959448		0.9959448
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0974476		1.0974476
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4111111		0.4111111
20	C5 = 22 / φ	C5 =	0.9062952		0.9062952
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4111111		0.4111111
22	Calculation Result :
23	PM = P×R/2	PM =	7943.4	N-mm	81.0	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	661.949	N-mm	6.75	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	132.39	N-mm	1.35	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	8883.26	N/mm	9058.404	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	7612.2	N/mm	7762.284	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	22.19	mm	2.219	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	21.15	mm	2.115	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	362.589	MPa	3697.379	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,496,605,307	N-mm	15261.127×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	567,379,312	N-mm	5785.659×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	752,014,566	N-mm	7668.414×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	266,573,697	N-mm	2718.295×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	372.415	N/mm	379.758	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	867,867,174	N-mm	8849.782×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	456,414,316	N-mm	4654.131×103	Kg-cm
39	Za = IH / LA × t	Za =	65,250,509	mm³	65.251×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	4,376,861,061	mm³	4376.861×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.8838E-5		1.8838E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.280747E-3		6.280747E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1878.179	mm	187.818	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	94.501	N/mm	96.364	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	76,331,568	N-mm	778.365×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	38,355,103	N-mm	391.113×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	807,732	mm³	8077.324	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	215,536,570	mm³	215.537×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	266.842	mm	26.684	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	528.891	mm	52.889	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	463.59	N/mm	472.73	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	322.105	N/mm	328.456	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	2,448,674	N	249695.2	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	65095.462	N	6637.9	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7400.0	mm	740.0	cm

piDeg=[24.27465219458477] piRad=[0.4236726055719715] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=18000 (cm), Syt=394.25 MPa, MAWP=2.2065 (MPa), HT_UPPCOL = 37000.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	18000.0	0	0	1.7652	7943.4							7943.40	7943.40	378.26	< OK	394.25	20.15	20.17	21.0	0.02	4.06	0	0	0	0
P1	9	17889.2	110.8	0.0011	1.7663	7943.4	7.34	2.44					7950.74	7945.84	378.49	< OK	394.25	20.16	20.18	21.0	0.02	4.00	0.055	0.018	0.009	0.003
P2	27	17019.1	980.9	0.0096	1.7748	7943.4	65.35	21.23					8008.75	7964.63	371.48	< OK	394.25	20.26	20.28	21.5	0.02	5.78	0.494	0.16	0.082	0.027
P3	45	15364.0	2636.0	0.0259	1.7911	7943.4	177.82	54.84					8121.22	7998.24	374.90	< OK	394.25	20.44	20.47	21.5	0.03	4.91	1.343	0.414	0.224	0.069
P4	59.5	13567.8	4432.2	0.0435	1.8087	7943.4	304.03	87.15					8247.43	8030.55	378.66	< OK	394.25	20.65	20.67	21.5	0.02	3.95	2.297	0.658	0.383	0.11
P5	90	9000.0	9000.0	0.0883	1.8535	7943.4	661.95	132.39	372.42	94.50	463.59	322.10	8883.26	7612.20	379.07	< OK	394.25	21.15	21.18	22.0	0.03	3.85	5	1	0.833	0.167	Column Attached Equator Plate
	120.5	4432.2	13567.8	0.1331	1.8983	7943.4	490.30	707.19					8433.70	8650.59	379.74	< OK	394.25	21.67	21.69	22.5	0.02	3.68	3.703	5.342	0.617	0.89
P6	135	2636.0	15364.0	0.1507	1.9159	7943.4	616.52	739.50					8559.92	8682.90	374.87	< OK	394.25	21.87	21.89	23.0	0.02	4.91	4.657	5.586	0.776	0.931
P7	153	980.9	17019.1	0.1669	1.9321	7943.4	728.99	773.11					8672.39	8716.51	378.02	< OK	394.25	22.05	22.08	23.0	0.03	4.12	5.506	5.84	0.918	0.973
P8	171	110.8	17889.2	0.1754	1.9406	7943.4	787.00	791.90					8730.40	8735.30	379.69	< OK	394.25	22.15	22.18	23.0	0.03	3.69	5.945	5.982	0.991	0.997
P9	180	0	18000.0	0.1765	1.9417	7943.4	794.34	794.34					8737.74	8737.74	379.90	< OK	394.25	22.16	22.19	23.0	0.03	3.64	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 46
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 318231.293
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 18000
MRA(sWt[tid][20][10])= 1017.878
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	10	Columns
2. gCol[tid][2] =	Column OD	OD =	863.6	mm
3. gCol[tid][3] =	Column thk	thk =	9.65	mm
4. gCol[tid][4] =	Tank Height	Htank =	12000	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	3700	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	8300	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	17600	mm
8. gCol[tid][8] =	Brace Angle	BRang =	33.2354	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.1015	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA537-CL2	t39 ~ 40.5	SHT	46	318.231	388.242	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t40.5, t12×3013×3700	SHT	10	12.567	13.823	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø863.6×9.65t × 8300L	PCS	10	16.867	16.867	000,000	000,000	3
4	BRACE ( PIPE, θ= 33.2354 deg.)	null	Ø0×0t × 9923L	PCS	20			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA537-CL2(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA537-CL2	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				86	347.665	418.932	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [5 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 4. TKK				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 25000 mm, CA = 3 mm, SG = 0.6, Pg= 17.9 kg/cm2(=1755.39 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2406.6 kPa
Material : SA516-65, EXTERNAL CHART NO. [CS-2], DTEMP = 87 ℃, Sd = 148.486 MPa, St = 228 MPa, Samb = 161 MPa, LSR = Samb/Sd = 1.084, Ft = 450 MPa, Fy = 240 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	25006.0	0	0	1755.4	1755.4	76.91	77.12	78.0	0.7+0.18	1.7761	1.8473			1.084	σeq = 146.318	1 / 13
P1	6.4o	6.4o	24928.1	0	0		1755.4	76.91	77.12	78.0	0.7+0.18	1.7761	1.8473			1.084	σeq = 146.318	2 / 13
P2	12.8o	19.2o	24310.5	0	0		1755.4	76.91	77.12	78.0	0.7+0.18	1.7761	1.8473			1.084	σeq = 146.318	3 / 13
P3	12.8o	32.0o	23106.1	896.9	5.3		1760.7	77.13	77.35	78.5	0.7+0.45	1.7826	1.8592			1.084	σeq = 145.788	4 / 13
P4	9.5o	41.5o	21867.2	2135.8	12.6		1768.0	77.44	77.66	78.5	0.7+0.14	1.7753	1.8592			1.084	σeq = 146.395	5 / 13
P5	45.5o	87.0o	13157.4	10845.6	63.8		1819.2	79.66	79.83	81.0	0.7+0.47	1.7831	1.9182			1.084	σeq = 145.938	6 / 13
P6	3.0o	90.0o	12503.0	11500.0	67.7		1823.1	79.41	79.99	83.5	0.7+0.31	1.7792	1.9182			1.084	σeq = 146.397	7 / 13
	48.5o	138.5o	3138.8	20864.2	122.8		1878.2	82.08	82.33	83.5	0.7+0.47	1.7831	1.9772			1.084	σeq = 145.861	9 / 13
P7	9.5o	148.0o	1899.9	22103.1	130.1		1885.5	82.38	82.64	83.5	0.7+0.16	1.7758	1.9772			1.084	σeq = 146.423	10 / 13
P8	12.8o	160.8o	695.5	23307.5	137.1		1892.5	82.68	82.93	84.0	0.7+0.37	1.7806	1.9890			1.084	σeq = 146.065	11 / 13
P9	12.8o	173.6o	77.9	23925.1	140.8		1896.2	82.83	83.09	84.0	0.7+0.21	1.7769	1.9890			1.084	σeq = 146.345	12 / 13
P10	6.4o	180.0o	0	24003.0	141.2		1896.6	82.85	83.11	84.0	0.7+0.19	1.7765	1.9890	1.7753	1.8473	1.084	σeq = 146.38	13 / 13

Div.2　 tReq = R · [ EXP(  0.5 · P 　  S · E 　 ) － 1 ] ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	1.7554	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	1.7753	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	1.8473	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [5 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 4. TKK				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 25000 mm, CA = 3 mm, SG = 0.6, Pg= 17.9 kg/cm2(=1755.39 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2405.5 kPa
Material : SA516-65, EXTERNAL CHART NO. [CS-2], DTEMP = 87 ℃, Sd = 148.486 MPa, St = 228 MPa, Samb = 161 MPa, LSR = Samb/Sd = 1.084, Ft = 450 MPa, Fy = 240 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	25000.0	0	0	2405.5	2405.5	65.37	66.11	68.80	78.0	1.7761	1.8473	σeq = 223.903	1 / 13
P1	6.4o	6.4o	24922.1	77.9	0.8		2406.3	65.40	66.14	68.83	78.0	1.7761	1.8473	σeq = 224	2 / 13
P2	12.8o	19.2o	24304.7	695.3	6.8		2412.3	65.56	66.30	68.99	78.0	1.7761	1.8473	σeq = 222.504	3 / 13
P3	12.8o	32.0o	23100.6	1899.4	18.6		2424.1	65.89	66.63	69.32	78.5	1.7826	1.8592	σeq = 224.003	4 / 13
P4	9.5o	41.5o	21861.9	3138.1	30.8		2436.3	66.22	66.96	69.65	78.5	1.7753	1.8592	σeq = 223.299	5 / 13
P5	45.5o	87.0o	13154.2	11845.8	116.2		2521.7	68.58	69.32	72.01	81.0	1.7831	1.9182	σeq = 223.349	6 / 13
P6	3.0o	90.0o	12500.0	12500.0	122.6		2528.1	68.75	69.49	72.18	83.5	1.7792	1.9182	σeq = 223.361	7 / 13
	48.5o	138.5o	3138.1	21861.9	214.4		2619.9	71.28	72.02	74.72	83.5	1.7831	1.9772	σeq = 223.862	9 / 13
P7	9.5o	148.0o	1899.4	23100.6	226.5		2632.0	71.62	72.36	75.05	83.5	1.7758	1.9772	σeq = 223.199	10 / 13
P8	12.8o	160.8o	695.3	24304.7	238.3		2643.8	71.94	72.68	75.37	84.0	1.7806	1.9890	σeq = 222.517	11 / 13
P9	12.8o	173.6o	77.9	24922.1	244.4		2649.9	72.11	72.85	75.54	84.0	1.7769	1.9890	σeq = 223.192	12 / 13
P10	6.4o	180.0o	0	25000.0	245.2		2650.7	72.13	72.87	75.56	84.0	1.7765	1.9890	σeq = 223.278	13 / 13

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7554

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.3786

24.2545

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.7753

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.4055

24.5293

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.8473

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.5031

25.5245

S-Tank Engineering	AAA Spherical Tank Calculation [5 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 4. TKK				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 25000 mm, CA = 3 mm, SG = 0.6, Pg= 17.9 kg/cm2(=1755.39 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2405.5 kPa
Material : SA516-65, EXTERNAL CHART NO. [CS-2], DTEMP = 87 ℃, Sd = 148.486 MPa, St = 228 MPa, Samb = 161 MPa, LSR = Samb/Sd = 1.084, Ft = 450 MPa, Fy = 240 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	25006.0	0	0	25000.0	0	0	75.00	78.0	1.7761	1.8473	529.8381	1 / 13
P1	6.4o	6.4o	24928.1	0	0	24922.1	77.9	0.8	75.00	78.0	1.7761	1.8473	529.8381	2 / 13
P2	12.8o	19.2o	24310.5	0	0	24304.7	695.3	6.8	75.00	78.0	1.7761	1.8473	529.8381	3 / 13
P3	12.8o	32.0o	23106.1	896.9	5.3	23100.6	1899.4	18.6	75.50	78.5	1.7826	1.8592	536.8835	4 / 13
P4	9.5o	41.5o	21867.2	2135.8	12.6	21861.9	3138.1	30.8	75.50	78.5	1.7753	1.8592	536.8835	5 / 13
P5	45.5o	87.0o	13157.4	10845.6	63.8	13154.2	11845.8	116.2	78.00	81.0	1.7831	1.9182	572.7996	6 / 13
P6	3.0o	90.0o	12503.0	11500.0	67.7	12500.0	12500.0	122.6	78.00	81.0	1.7792	1.9182	572.7996	7 / 13
	48.5o	138.5o	3138.8	20864.2	122.8	3138.1	21861.9	214.4	80.50	83.5	1.7831	1.9772	609.8636	9 / 13
P7	9.5o	148.0o	1899.9	22103.1	130.1	1899.4	23100.6	226.5	80.50	83.5	1.7758	1.9772	609.8636	10 / 13
P8	12.8o	160.8o	695.5	23307.5	137.1	695.3	24304.7	238.3	81.00	84.0	1.7806	1.9890	617.4140	11 / 13
P9	12.8o	173.6o	77.9	23925.1	140.8	77.9	24922.1	244.4	81.00	84.0	1.7769	1.9890	617.4140	12 / 13
P10	6.4o	180.0o	0	24003.0	141.2	0	25000.0	245.2	81.00	84.0	1.7765	1.9890	617.4140	13 / 13

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

1.7554

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.3786

24.2545

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

1.7753

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MWAP×LSR

Pset(MAWP) =

2.4055

24.5293

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

1.8473

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.25×MAP×LSR

Pset(MAP) =

2.5031

25.5245

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

102.9698

SA516-65

Maximum. Allowable External Pressure

MAEP =

529.8381

5.4028

CS-2

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=529.8381 kPa)

S-Tank Engineering	AAA Spherical Tank Calculation [5 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 4. TKK				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 25000 mm, CA = 3 mm, SG = 0.6, Pg= 17.9 kg/cm2(=1755.39 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2405.5 kPa
Material : SA516-65, EXTERNAL CHART NO. [CS-2], DTEMP = 87 ℃, Sd = 148.486 MPa, St = 228 MPa, Samb = 161 MPa, LSR = Samb/Sd = 1.084, Ft = 450 MPa, Fy = 240 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	76.91	77.1	66.11	68.80	35.96	78.0	0.7+0.18	#1	19.2	78.0	2792.5	8377.6	3	13,608	40,825	1 / 13
P1	6.4o	6.4o	76.91	77.1	66.14	68.83	35.96	78.0	0.7+0.18									2 / 13
P2	12.8o	19.2o	76.91	77.1	66.30	68.99	35.96	78.0	0.7+0.18									3 / 13
P3	12.8o	32.0o	77.13	77.4	66.63	69.32	35.96	78.5	0.7+0.45	#2	12.8	78.5	2792.5	9567.7	4	12,710	50,841	4 / 13
P4	9.5o	41.5o	77.44	77.7	66.96	69.65	35.96	78.5	0.7+0.14	#3	9.5	78.5	1858.6	8726.6	9	6,661	59,948	5 / 13
P5	45.5o	87.0o	79.66	79.8	69.32	72.01	35.96	81.0	0.7+0.47	#4	45.5	81.0	2801.1	9970.0	28	15,531	434,861	6 / 13
P6	3.0o	90.0o	79.41	80.0	69.49	72.18	35.96	83.5	0.7+0.31	#5	51.5	83.5	2805.0	11335.6	28	18,416	515,641	7 / 13
	48.5o	138.5o	82.08	82.3	72.02	74.72	35.96	83.5	0.7+0.47									9 / 13
P7	9.5o	148.0o	82.38	82.6	72.36	75.05	35.96	83.5	0.7+0.16	#6	9.5	83.5	1858.6	8726.6	9	7,085	63,767	10 / 13
P8	12.8o	160.8o	82.68	82.9	72.68	75.37	35.96	84.0	0.7+0.37	#7	12.8	84.0	2792.5	9367.7	4	13,601	54,403	11 / 13
P9	12.8o	173.6o	82.83	83.1	72.85	75.54	35.96	84.0	0.7+0.21	#8	19.2	84.0	2792.5	8377.6	3	14,655	43,965	12 / 13
P10	6.4o	180.0o	82.85	83.1	72.87	75.56	35.96	84.0	0.7+0.19									13 / 13

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [4 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 3. T-3213(3)				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 18000 mm, CA = 3.2 mm, SG = 0.596, Pg= 18.0 kg/cm²(=1765.197 kPa), Pe= 1.033227 kg/cm²(=101.325 kPa), 수압테스트압력 GsetMAWP=2258.8 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 70 ℃, Sd = 230 MPa, St = 394.25 MPa, Samb = 230 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	37.75	37.8	25.82	28.42	26.69	39.0	0.7+0.48	#1	27.0	39.0	2827.4	8482.3	3	6,975	20,926	1 / 12
P1	9.0o	9.0o	37.75	37.8	25.83	28.44	26.69	39.0	0.7+0.48									2 / 12
P2	18.0o	27.0o	37.75	37.8	25.93	28.53	26.69	39.0	0.7+0.48									3 / 12
P3	18.0o	45.0o	37.75	37.8	26.12	28.72	26.69	39.0	0.7+0.48	#2	18.0	39.0	2827.4	9200.0	4	6,178	24,710	4 / 12
P4	14.5o	59.5o	37.86	37.9	26.32	28.92	26.69	39.0	0.7+0.38	#3	14.5	39.0	2436.2	9424.8	6	5,183	31,095	5 / 12
P5	30.5o	90.0o	38.27	38.4	26.83	29.43	26.69	TD90USED	0.7+0.35	#4	61.0	40.0	2827.4	9681.9	20	8,111	162,216	6 / 12
	30.5o	120.5o	38.90	39.0	27.34	29.95	26.69	40.0	0.7+0.33									8 / 12
P6	14.5o	135.0o	39.11	39.2	27.54	30.15	26.69	40.0	0.7+0.12	#5	14.5	40.0	2436.2	9424.8	6	5,315	31,892	9 / 12
P7	18.0o	153.0o	39.30	39.4	27.73	30.33	26.69	40.5	0.7+0.43	#6	18.0	40.5	2827.4	9000.0	4	6,415	25,661	10 / 12
P8	18.0o	171.0o	39.40	39.5	27.83	30.43	26.69	40.5	0.7+0.33	#7	27.0	40.5	2827.4	8482.3	3	7,244	21,731	11 / 12
P9	9.0o	180.0o	39.41	39.5	27.84	30.44	26.69	40.5	0.7+0.32									12 / 12

Spherical tank, / External Pressure calc Result !!
DivNo = 2, teReq = 35.96 mm; Pe :102.97 kPa ≤ Pa = 103.02 kPa = 2*Fha*(tc/Ro)*1000; Fhe=39.181; Fic=39.181 MPa; Fha=19.59 MPa; FS=2

S-Tank Engineering	Spherical Tank Calculation [5 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=25000 (cm), Sd=148.486 MPa, Pg=1.7554 (MPa), HT_UPPCOL = 47100.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=726.738 (N-mm), Nφ=119.289 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	25000	mm	2500.0	cm
3	R = Inside Radius in Corroded Condition	R =	12503	mm	1250.3	cm
4	L = Design Liquid level	L =	24000	mm	2400.0	cm
5	CA = Corrosion Allowance	CA =	3.0	mm	0.3	cm
6	Wt = Total Weight at Operating Condition	Wt =	60,610,333	N	6180533.9	Kg
7	S = Allowable Stress for the Design Condition SA516-65, Sd = 148.486MPa	S =	148.486	MPa	1514.136	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.755	MPa	17.9	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.6		0.6
10	γ = Liquid Density	γ =	5.88399E-6	N/mm³	600.0	Kg/m³
11	d = Outsdie diameter of Column	d =	1066.8	mm	106.68	cm
12	N = Number of Support Column	N =	14.0	columns	14	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	22.13561	degree	0.38634	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	23.10617	degree	0.40328	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9997693		0.9997693
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0058552		1.0058552
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.3768000		0.3768000
20	C5 = 22 / φ	C5 =	0.9938738		0.9938738
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.3768000		0.3768000
22	Calculation Result :
23	PM = P×R/2	PM =	10973.883	N-mm	111.902	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	726.738	N-mm	7.411	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	119.289	N-mm	1.216	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	11941.03	N/mm	12176.462	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	10600.23	N/mm	10809.226	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	83.11	mm	8.311	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	79.41	mm	7.941	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	140.071	MPa	1428.327	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,993,942,002	N-mm	20332.55×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	794,009,651	N-mm	8096.645×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	999,487,769	N-mm	10191.939×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	382,039,563	N-mm	3895.719×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	317.386	N/mm	323.644	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	1,194,823,183	N-mm	12183.806×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	614,980,666	N-mm	6271.058×103	Kg-cm
39	Za = IH / LA × t	Za =	316,224,245	mm³	316.224×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	8,979,669,787	mm³	8979.67×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.189E-5		1.189E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	4.769617E-3		4.769617E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	2385.308	mm	238.531	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	76.973	N/mm	78.491	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	91,240,121	N-mm	930.39×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	45,735,224	N-mm	466.369×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	1,185,355	mm³	11853.551	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	365,937,910	mm³	365.938×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	308.716	mm	30.872	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	612.822	mm	61.282	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	492.945	N/mm	502.664	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	342.309	N/mm	349.058	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	3,316,322	N	338170.8	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	90996.756	N	9279.1	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	9422.261	mm	942.226	cm

piDeg=[22.13560759591294] piRad=[0.3863392344781473] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=25000 (cm), Sd=148.486 MPa, Pg=1.7554 (MPa), HT_UPPCOL = 47100.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	25006.0	0	0	1.7554	10973.88							10973.88	10973.88	146.32	< OK	148.486	76.91	77.12	78.0	0.21	1.46	0	0	0	0
P1	6.4	24928.1	0	0	1.7554	10973.88							10973.88	10973.88	146.32	< OK	148.486	76.91	77.12	78.0	0.21	1.46	0	0	0	0
P2	19.2	24310.5	0	0	1.7554	10973.88							10973.88	10973.88	146.32	< OK	148.486	76.91	77.12	78.0	0.21	1.46	0	0	0	0
P3	32	23106.1	896.9	0.0053	1.7607	10973.88	58.63	7.35					11032.51	10981.23	145.79	< OK	148.486	77.13	77.35	78.5	0.22	1.82	0.382	0.048	0.064	0.008
P4	41.5	21867.2	2135.8	0.0126	1.768	10973.88	132.49	24.63					11106.38	10998.52	146.40	< OK	148.486	77.44	77.66	78.5	0.22	1.41	0.864	0.161	0.144	0.027
P5	87	13157.4	10845.6	0.0638	1.8192	10973.88	679.39	118.50					11653.27	11092.38	145.94	< OK	148.486	79.66	79.83	81.0	0.17	1.72	4.432	0.773	0.739	0.129
P6	90	12503.0	11500.0	0.0677	1.8231	10973.88	726.74	119.29	317.39	76.97	492.94	342.31	11941.03	10600.23	146.40	< OK	148.486	79.41	79.99	80.5	0.58	1.41	4.741	0.778	0.79	0.13	Column Attached Equator Plate
	138.5	3138.8	20864.2	0.1228	1.8782	10973.88	706.97	827.95					11680.86	11801.84	145.86	< OK	148.486	82.08	82.32	83.5	0.24	1.77	4.612	5.401	0.769	0.9
P7	148	1899.9	22103.1	0.1301	1.8855	10973.88	777.14	848.94					11751.02	11822.82	146.42	< OK	148.486	82.38	82.63	83.5	0.25	1.39	5.069	5.538	0.845	0.923
P8	160.8	695.5	23307.5	0.1371	1.8925	10973.88	844.43	870.25					11818.31	11844.13	146.06	< OK	148.486	82.68	82.93	84.0	0.25	1.63	5.508	5.677	0.918	0.946
P9	173.6	77.9	23925.1	0.1408	1.8962	10973.88	878.62	881.49					11852.50	11855.37	146.34	< OK	148.486	82.83	83.09	84.0	0.26	1.44	5.731	5.75	0.955	0.958
P10	180	0	24003.0	0.1412	1.8966	10973.88	882.92	882.92					11856.80	11856.80	146.38	< OK	148.486	82.85	83.11	84.0	0.26	1.42	5.759	5.759	0.96	0.96

S-Tank Engineering	Spherical Tank Calculation [5 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=25000 (cm), Syt=228 MPa, MAWP=2.19425 (MPa), HT_UPPCOL = 47300.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=1276.908 (N-mm), Nφ=255.382 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	25000	mm	2500.0	cm
3	R = Inside Radius in Corroded Condition	R =	12500	mm	1250.0	cm
4	L = Hydrostatic-test Water Level	L =	25000	mm	2500.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	90,508,955	N	9229344.9	Kg
7	S = Allowable Stress for the Design Condition SA516-65, Sd = 228MPa	S =	228.0	MPa	2324.953	Kg/cm²
8	P = Design internal GAS Pressure	P =	1.755	MPa	17.9	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	1066.8	mm	106.68	cm
12	N = Number of Support Column	N =	14.0	columns	14	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	22.23461	degree	0.38807	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9995999		0.9995999
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.0101264		1.0101264
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.3784000		0.3784000
20	C5 = 22 / φ	C5 =	0.9894484		0.9894484
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.3784000		0.3784000
22	Calculation Result :
23	PM = P×R/2	PM =	10971.25	N-mm	111.876	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	1276.908	N-mm	13.021	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	255.382	N-mm	2.604	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	12605.02	N/mm	12853.543	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	10493.62	N/mm	10700.514	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	54.96	mm	5.496	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	51.43	mm	5.143	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	209.401	MPa	2135.296	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	2,976,824,175	N-mm	30355.159×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	1,178,727,152	N-mm	12019.672×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	1,492,169,456	N-mm	15215.894×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	567,341,146	N-mm	5785.27×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	470.299	N/mm	479.572	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	1,784,969,876	N-mm	18201.627×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	918,486,241	N-mm	9365.953×103	Kg-cm
39	Za = IH / LA × t	Za =	258,086,691	mm³	258.087×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	9,090,473,172	mm³	9090.473×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	1.2158E-5		1.2158E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	4.833577E-3		4.833577E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	2395.134	mm	239.513	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	113.438	N/mm	115.675	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	136,194,425	N-mm	1388.797×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	68,269,118	N-mm	696.151×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	1,200,605	mm³	12006.051	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	373,853,946	mm³	373.854×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	311.388	mm	31.139	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	618.085	mm	61.809	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	733.009	N/mm	747.461	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	509.725	N/mm	519.775	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	4,959,123	N	505689.8	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	137,121	N	13982.4	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	9460.0	mm	946.0	cm

piDeg=[22.234610135922413] piRad=[0.38806715476915005] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=25000 (cm), Syt=228 MPa, MAWP=2.19425 (MPa), HT_UPPCOL = 47300.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	25000.0	0	0	1.7554	10971.25							10971.25	10971.25	223.90	< OK	228	48.12	48.21	49.0	0.09	1.80	0	0	0	0
P1	6.4	24922.1	77.9	0.0008	1.7562	10971.25	7.16	2.38					10978.41	10973.63	224.00	< OK	228	48.14	48.23	49.0	0.09	1.75	0.028	0.009	0.005	0.002
P2	19.2	24304.7	695.3	0.0068	1.7622	10971.25	64.13	21.10					11035.38	10992.35	222.50	< OK	228	48.31	48.40	49.5	0.09	2.41	0.251	0.083	0.042	0.014
P3	32	23100.6	1899.4	0.0186	1.774	10971.25	176.22	56.61					11147.47	11027.86	224.00	< OK	228	48.63	48.72	49.5	0.09	1.75	0.69	0.222	0.115	0.037
P4	41.5	21861.9	3138.1	0.0308	1.7862	10971.25	293.11	91.57					11264.36	11062.82	223.30	< OK	228	48.97	49.06	50.0	0.09	2.06	1.148	0.359	0.191	0.06
P5	87	13154.2	11845.8	0.1162	1.8716	10971.25	1198.04	254.05					12169.29	11225.30	223.35	< OK	228	51.43	51.41	52.5	-0.02	2.04	4.691	0.995	0.782	0.166
P6	90	12500.0	12500.0	0.1226	1.878	10971.25	1276.91	255.38	470.30	113.44	733.01	509.72	12605.02	10493.62	223.36	< OK	228	51.43	51.59	52.5	0.16	2.03	5	1	0.833	0.167	Column Attached Equator Plate
	138.5	3138.1	21861.9	0.2144	1.9698	10971.25	1239.18	1440.72					12210.43	12411.97	223.86	< OK	228	54.00	54.11	55.0	0.11	1.81	4.852	5.641	0.809	0.94
P7	148	1899.4	23100.6	0.2265	1.9819	10971.25	1356.07	1475.68					12327.32	12446.93	223.20	< OK	228	54.33	54.45	55.5	0.12	2.11	5.31	5.778	0.885	0.963
P8	160.8	695.3	24304.7	0.2383	1.9937	10971.25	1468.16	1511.18					12439.41	12482.43	222.52	< OK	228	54.65	54.77	56.0	0.12	2.40	5.749	5.917	0.958	0.986
P9	173.6	77.9	24922.1	0.2444	1.9998	10971.25	1525.12	1529.90					12496.37	12501.15	223.19	< OK	228	54.82	54.94	56.0	0.12	2.11	5.972	5.991	0.995	0.998
P10	180	0	25000.0	0.2452	2.0006	10971.25	1532.29	1532.29					12503.54	12503.54	223.28	< OK	228	54.84	54.96	56.0	0.12	2.07	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 88
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 1264251.104
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 25000
MRA(sWt[tid][20][10])= 1963.496
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	14	Columns
2. gCol[tid][2] =	Column OD	OD =	1066.8	mm
3. gCol[tid][3] =	Column thk	thk =	15.09	mm
4. gCol[tid][4] =	Tank Height	Htank =	15500	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	4730	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	10770	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	24530	mm
8. gCol[tid][8] =	Brace Angle	BRang =	26.8767	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	11.1275	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA516-65	t78 ~ 84	SHT	88	1264.251	1542.386	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t84, t17×3651×4730	SHT	14	42.945	47.240	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø1066.8×15.09t × 10770L	PCS	14	59.010	59.010	000,000	000,000	3
4	BRACE ( PIPE, θ= 26.8767 deg.)	null	Ø0×0t × 12074L	PCS	28			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA516-65(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA516-65	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				144	1366.206	1648.635	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [6 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 5. 알제리				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 11000 mm, CA = 1.5 mm, SG = 0.536, Pg= 21.9239 kg/cm2(=2150 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2870.8 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 100 ℃, Sd = 158 MPa, St = 373.5 MPa, Samb = 158 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	11003.0	0	0	2150.0	2150.0	38.93	38.98	40.0	0.7+0.32	2.2083	2.2948			1.0	σeq = 153.613	1 / 8
P1	15.0o	15.0o	10815.5	0	0		2150.0	38.93	38.98	40.0	0.7+0.32	2.2083	2.2948			1.0	σeq = 153.613	2 / 8
P2	30.0o	45.0o	9391.6	0	0		2150.0	38.93	38.98	40.0	0.7+0.32	2.2083	2.2948			1.0	σeq = 153.613	3 / 8
P3	45.0o	90.0o	5501.5	2100.0	11.0		2161.0	39.18	39.17	40.5	0.7+0.12	2.1973	2.2948			1.0	σeq = 154.618	4 / 8
	45.0o	135.0o	1611.4	5990.1	31.5		2181.5	39.48	39.53	40.5	0.7+0.27	2.2054	2.3235			1.0	σeq = 153.866	6 / 8
P4	30.0o	165.0o	187.5	7414.0	39.0		2189.0	39.61	39.66	40.5	0.7+0.14	2.1979	2.3235			1.0	σeq = 154.393	7 / 8
P5	15.0o	180.0o	0	7601.5	40.0		2190.0	39.63	39.68	40.5	0.7+0.12	2.1969	2.3235	2.1969	2.2948	1.0	σeq = 154.462	8 / 8

A) Operating : 　　tReq =   P·R   2·S·E － 0.2·P     ＋ CA B) Test : 　　tReq =   P·Rc   2·St·E － 0.2·Pt     ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	2.1500	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	2.1969	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	2.2948	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [6 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 5. 알제리				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 11000 mm, CA = 1.5 mm, SG = 0.536, Pg= 21.9239 kg/cm2(=2150 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2856 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 100 ℃, Sd = 158 MPa, St = 373.5 MPa, Samb = 158 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	11000.0	0	0	2856.0	2856.0	20.59	21.04	21.98	40.0	2.2083	2.2948	σeq = 347.794	1 / 8
P1	15.0o	15.0o	10812.6	187.4	1.8		2857.8	20.60	21.05	21.99	40.0	2.2083	2.2948	σeq = 348.092	2 / 8
P2	30.0o	45.0o	9389.1	1610.9	15.8		2871.8	20.71	21.16	22.09	40.0	2.2083	2.2948	σeq = 350.358	3 / 8
P3	45.0o	90.0o	5500.0	5500.0	53.9		2909.9	20.99	21.44	22.37	40.5	2.1973	2.2948	σeq = 348.476	4 / 8
	45.0o	135.0o	1610.9	9389.1	92.1		2948.1	21.27	21.72	22.66	40.5	2.2054	2.3235	σeq = 352.333	6 / 8
P4	30.0o	165.0o	187.4	10812.6	106.0		2962.0	21.37	21.82	22.76	40.5	2.1979	2.3235	σeq = 354.52	7 / 8
P5	15.0o	180.0o	0	11000.0	107.9		2963.9	21.39	21.84	22.77	40.5	2.1969	2.3235	σeq = 354.809	8 / 8

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

2.1500

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

2.7950

28.5011

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

2.1969

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

2.8560

29.1231

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

2.2948

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

2.9832

30.4202

S-Tank Engineering	AAA Spherical Tank Calculation [6 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 5. 알제리				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 11000 mm, CA = 1.5 mm, SG = 0.536, Pg= 21.9239 kg/cm2(=2150 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2856 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 100 ℃, Sd = 158 MPa, St = 373.5 MPa, Samb = 158 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	11003.0	0	0	11000.0	0	0	38.50	40.0	2.2083	2.2948	630.3543	1 / 8
P1	15.0o	15.0o	10815.5	0	0	10812.6	187.4	1.8	38.50	40.0	2.2083	2.2948	630.3543	2 / 8
P2	30.0o	45.0o	9391.6	0	0	9389.1	1610.9	15.8	38.50	40.0	2.2083	2.2948	630.3543	3 / 8
P3	45.0o	90.0o	5501.5	2100.0	11.0	5500.0	5500.0	53.9	38.50	40.0	2.1973	2.2948	630.3543	4 / 8
	45.0o	135.0o	1611.4	5990.1	31.5	1610.9	9389.1	92.1	39.00	40.5	2.2054	2.3235	646.7227	6 / 8
P4	30.0o	165.0o	187.5	7414.0	39.0	187.4	10812.6	106.0	39.00	40.5	2.1979	2.3235	646.7227	7 / 8
P5	15.0o	180.0o	0	7601.5	40.0	0	11000.0	107.9	39.00	40.5	2.1969	2.3235	646.7227	8 / 8

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

2.1500

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

2.7950

28.5011

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

2.1969

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

2.8560

29.1231

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

2.2948

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

2.9832

30.4202

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

102.9698

SA537-CL2

Maximum. Allowable External Pressure

MAEP =

630.3543

6.4278

CS-4

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=630.3543 kPa)

● Shell Material MATL = SA537-CL2 - Modulus of Elasticity [SEC. II PART 'D' Table TM-1] Ey = 200133  MPa - Minimum Yield Strength [SEC. II PART 'D' Table 1A] Sy = 415.0  MPa - Allowable stress at Hydrostatic-test Conditions, Syt = 0.9 × Sy Syt = 373.5  MPa - Allowable stress at Test temperature (-12℃~30℃) [Table 1A] Samb = 158.0  MPa - Allowable stress at Design temperature (60.0 ℃) [Table 1A] S = 158.0  MPa - Lowest Stress Ratio, LSR = Samb / Sd LSR = 1.0   o Chart For Shell Thk. Under External Pressure (FACTOR A, B CURVE) CS-4 [see Bellow Curve] Initial thickness for Design External Pressure (after corroded) tc = 38.5  mm Outside Radius of tank top head Ro = 5540.0  mm Factor A = 0.125 / [Ro / tc] Factor A = 0.0008687 Factor B : (ASME Sec. II, Part D SUBPART 3 - FIG.CS-4) Factor B = 90.70553  MPa Design External Pressure, 　Pe = 1.05 (kg/cm²) Pe = 102.9698  kPa Max. Allowable External Pressure, MAEP = FACTOR B × tc/Ro ×1000 MAEP = 630.3543  kPa Check : Pe < MAEP O.K

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					[AAA1]	[AAA2]
	Doc. No. : 5. 알제리				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 11000 mm, CA = 1.5 mm, SG = 0.536, Pg= 21.9239 kg/cm2(=2150 kPa), Pe= 1.05 kg/cm2(=102.97 kPa), 수압테스트압력 GsetMAWP=2856 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 100 ℃, Sd = 158 MPa, St = 373.5 MPa, Samb = 158 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	38.93	39.0	21.04	21.98	17.01	40.0	0.7+0.32	#1	45.0	40.0	2879.8	8639.4	3	7,422	22,265	1 / 8
P1	15.0o	15.0o	38.93	39.0	21.05	21.99	17.01	40.0	0.7+0.32									2 / 8
P2	30.0o	45.0o	38.93	39.0	21.16	22.09	17.01	40.0	0.7+0.32									3 / 8
P3	45.0o	90.0o	39.18	39.2	21.44	22.37	17.01	40.5	0.7+0.12	#2	90.0	40.5	2879.8	8739.4	12	7,121	85,457	4 / 8
	45.0o	135.0o	39.48	39.5	21.72	22.66	17.01	40.5	0.7+0.27									6 / 8
P4	30.0o	165.0o	39.61	39.7	21.82	22.76	17.01	40.5	0.7+0.14	#3	45.0	40.5	2879.8	8639.4	3	7,514	22,543	7 / 8
P5	15.0o	180.0o	39.63	39.7	21.84	22.77	17.01	40.5	0.7+0.12									8 / 8

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [5 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 4. TKK				Rev. No.	[AAA4]

Design Code : Div. 2, Di = 25000 mm, CA = 3 mm, SG = 0.6, Pg= 17.9 kg/cm²(=1755.39 kPa), Pe= 1.05 kg/cm²(=102.97 kPa), 수압테스트압력 GsetMAWP=2405.5 kPa
Material : SA516-65, EXTERNAL CHART NO. [CS-2], DTEMP = 87 ℃, Sd = 148.486 MPa, St = 228 MPa, Samb = 161 MPa, LSR = Samb/Sd = 1.084, Ft = 450 MPa, Fy = 240 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	76.91	77.1	66.11	68.80	35.96	78.0	0.7+0.18	#1	19.2	78.0	2792.5	8377.6	3	13,608	40,825	1 / 13
P1	6.4o	6.4o	76.91	77.1	66.14	68.83	35.96	78.0	0.7+0.18									2 / 13
P2	12.8o	19.2o	76.91	77.1	66.30	68.99	35.96	78.0	0.7+0.18									3 / 13
P3	12.8o	32.0o	77.13	77.4	66.63	69.32	35.96	78.5	0.7+0.45	#2	12.8	78.5	2792.5	9567.7	4	12,710	50,841	4 / 13
P4	9.5o	41.5o	77.44	77.7	66.96	69.65	35.96	78.5	0.7+0.14	#3	9.5	78.5	1858.6	8726.6	9	6,661	59,948	5 / 13
P5	45.5o	87.0o	79.66	79.8	69.32	72.01	35.96	81.0	0.7+0.47	#4	45.5	81.0	2801.1	9970.0	28	15,531	434,861	6 / 13
P6	3.0o	90.0o	79.41	80.0	69.49	72.18	35.96	TD90USED	0.7+0.31	#5	51.5	83.5	2805.0	11335.6	28	18,416	515,641	7 / 13
	48.5o	138.5o	82.08	82.3	72.02	74.72	35.96	83.5	0.7+0.47									9 / 13
P7	9.5o	148.0o	82.38	82.6	72.36	75.05	35.96	83.5	0.7+0.16	#6	9.5	83.5	1858.6	8726.6	9	7,085	63,767	10 / 13
P8	12.8o	160.8o	82.68	82.9	72.68	75.37	35.96	84.0	0.7+0.37	#7	12.8	84.0	2792.5	9367.7	4	13,601	54,403	11 / 13
P9	12.8o	173.6o	82.83	83.1	72.85	75.54	35.96	84.0	0.7+0.21	#8	19.2	84.0	2792.5	8377.6	3	14,655	43,965	12 / 13
P10	6.4o	180.0o	82.85	83.1	72.87	75.56	35.96	84.0	0.7+0.19									13 / 13

Spherical tank, / External Pressure calc Result !!
DivNo = 1, teReq = 17.01 mm; Pe :102.97 kPa ≤ Pa = 103.05 kPa = Factor_B / (Ro/tc)*1000 ; Factor_A=0.0625*tc/Rc = 0.0003514; Factor_B = 36.654 MPa

S-Tank Engineering	Spherical Tank Calculation [6 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=11000 (cm), Sd=158 MPa, Pg=2.15 (MPa), HT_UPPCOL = 24300.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=59.253 (N-mm), Nφ=1.475 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	11000	mm	1100.0	cm
3	R = Inside Radius in Corroded Condition	R =	5501.5	mm	550.15	cm
4	L = Design Liquid level	L =	7600	mm	760.0	cm
5	CA = Corrosion Allowance	CA =	1.5	mm	0.15	cm
6	Wt = Total Weight at Operating Condition	Wt =	4,014,814	N	409397.1	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 158MPa	S =	158.0	MPa	1611.152	Kg/cm²
8	P = Design internal GAS Pressure	P =	2.15	MPa	21.924	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.536		0.536
10	γ = Liquid Density	γ =	5.256364E-6	N/mm³	536.0	Kg/m³
11	d = Outsdie diameter of Column	d =	558.8	mm	55.88	cm
12	N = Number of Support Column	N =	6.0	columns	6	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	26.21995	degree	0.45762	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	67.5601	degree	1.17915	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9921654		0.9921654
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1794191		1.1794191
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4418182		0.4418182
20	C5 = 22 / φ	C5 =	0.8390559		0.8390559
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4418182		0.4418182
22	Calculation Result :
23	PM = P×R/2	PM =	5914.113	N-mm	60.307	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	59.253	N-mm	0.604	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	1.475	N-mm	0.015	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	6115.65	N/mm	6236.227	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	5769.41	N/mm	5883.161	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	39.68	mm	3.968	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	39.18	mm	3.918	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	152.636	MPa	1556.454	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	321,265,734	N-mm	3275.999×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	109,713,630	N-mm	1118.768×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	162,866,854	N-mm	1660.78×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	47,590,312	N-mm	485.286×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	187.607	N/mm	191.306	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	189,350,383	N-mm	1930.837×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	105,461,929	N-mm	1075.412×103	Kg-cm
39	Za = IH / LA × t	Za =	40,876,328	mm³	40.876×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	1,248,488,933	mm³	1248.489×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.7667E-5		2.7667E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	7.903102E-3		7.903102E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1236.995	mm	123.699	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	45.326	N/mm	46.22	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	17,191,781	N-mm	175.307×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	8,715,437	N-mm	88872.724	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	379,290	mm³	3792.899	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	72,072,708	mm³	72.073×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	190.02	mm	19.002	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	376.059	mm	37.606	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	146.18	N/mm	149.062	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	103.707	N/mm	105.752	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	514,170	N	52430.8	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	10017.238	N	1021.5	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	4861.325	mm	486.133	cm

piDeg=[26.219945947374477] piRad=[0.45762438647662845] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=11000 (cm), Sd=158 MPa, Pg=2.15 (MPa), HT_UPPCOL = 24300.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	11003.0	0	0	2.15	5914.11							5914.11	5914.11	153.61	< OK	158	38.93	38.98	40.0	0.05	2.78	0	0	0	0
P1	15	10815.5	0	0	2.15	5914.11							5914.11	5914.11	153.61	< OK	158	38.93	38.98	40.0	0.05	2.78	0	0	0	0
P2	45	9391.6	0	0	2.15	5914.11							5914.11	5914.11	153.61	< OK	158	38.93	38.98	40.0	0.05	2.78	0	0	0	0
P3	90	5501.5	2100.0	0.0110	2.161	5914.11	59.25	1.47	187.61	45.33	146.18	103.71	6115.65	5769.41	154.62	< OK	158	39.18	39.17	40.0	-0.01	2.14	2.235	0.056	0.372	0.009	Column Attached Equator Plate
	135	1611.4	5990.1	0.0315	2.1815	5914.11	74.30	98.93					5988.41	6013.04	153.87	< OK	158	39.48	39.53	40.5	0.05	2.62	2.802	3.731	0.467	0.622
P4	165	187.5	7414.0	0.0390	2.189	5914.11	105.84	108.56					6019.95	6022.67	154.39	< OK	158	39.61	39.66	40.5	0.05	2.28	3.992	4.094	0.665	0.682
P5	180	0	7601.5	0.0400	2.19	5914.11	109.91	109.91					6024.02	6024.02	154.46	< OK	158	39.63	39.68	40.5	0.05	2.24	4.145	4.145	0.691	0.691

S-Tank Engineering	Spherical Tank Calculation [6 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=11000 (cm), Syt=373.5 MPa, MAWP=2.795 (MPa), HT_UPPCOL = 24500.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=247.209 (N-mm), Nφ=49.442 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	11000	mm	1100.0	cm
3	R = Inside Radius in Corroded Condition	R =	5500	mm	550.0	cm
4	L = Hydrostatic-test Water Level	L =	11000	mm	1100.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	7,492,780	N	764051.0	Kg
7	S = Allowable Stress for the Design Condition SA537-CL2, Sd = 373.5MPa	S =	373.5	MPa	3808.64	Kg/cm²
8	P = Design internal GAS Pressure	P =	2.15	MPa	21.924	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	558.8	mm	55.88	cm
12	N = Number of Support Column	N =	6.0	columns	6	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	26.45242	degree	0.46168	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9916946		0.9916946
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1891263		1.1891263
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4454545		0.4454545
20	C5 = 22 / φ	C5 =	0.8316818		0.8316818
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4454545		0.4454545
22	Calculation Result :
23	PM = P×R/2	PM =	5912.5	N-mm	60.291	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	247.209	N-mm	2.521	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	49.442	N-mm	0.504	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	6421.21	N/mm	6547.812	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	5691.45	N/mm	5803.664	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	16.63	mm	1.663	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	16.33	mm	1.633	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	348.476	MPa	3553.466	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	599,409,414	N-mm	6112.275×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	203,231,260	N-mm	2072.382×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	303,872,824	N-mm	3098.64×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	88,358,728	N-mm	901.008×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	343.867	N/mm	350.647	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	352,763,420	N-mm	3597.186×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	196,279,339	N-mm	2001.492×103	Kg-cm
39	Za = IH / LA × t	Za =	23,082,087	mm³	23.082×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	1,279,499,671	mm³	1279.5×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.8912E-5		2.8912E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	8.113675E-3		8.113675E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1247.233	mm	124.723	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	82.363	N/mm	83.987	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	32,049,292	N-mm	326.812×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	16,247,507	N-mm	165.678×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	389,121	mm³	3891.21	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	75,223,250	mm³	75.223×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	193.316	mm	19.332	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	382.509	mm	38.251	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	270.489	N/mm	275.822	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	192.509	N/mm	196.305	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	962,323	N	98129.7	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	19027.244	N	1940.2	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	4900.0	mm	490.0	cm

piDeg=[26.452424118557175] piRad=[0.46168189600278153] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=11000 (cm), Syt=373.5 MPa, MAWP=2.795 (MPa), HT_UPPCOL = 24500.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	11000.0	0	0	2.15	5912.5							5912.50	5912.50	347.79	< OK	373.5	15.83	15.84	17.0	0.01	6.88	0	0	0	0
P1	15	10812.6	187.4	0.0018	2.1518	5912.5	7.60	2.51					5920.10	5915.01	348.09	< OK	373.5	15.84	15.85	17.0	0.01	6.80	0.154	0.051	0.026	0.008
P2	45	9389.1	1610.9	0.0158	2.1658	5912.5	66.41	20.48					5978.91	5932.98	350.36	< OK	373.5	15.95	15.96	17.0	0.01	6.20	1.343	0.414	0.224	0.069
P3	90	5500.0	5500.0	0.0539	2.2039	5912.5	247.21	49.44	343.87	82.36	270.49	192.51	6421.21	5691.45	348.48	< OK	373.5	16.33	16.24	17.5	-0.09	6.70	5	1	0.833	0.167	Column Attached Equator Plate
	135	1610.9	9389.1	0.0921	2.2421	5912.5	230.24	276.17					6142.74	6188.67	352.33	< OK	373.5	16.51	16.52	17.5	0.01	5.67	4.657	5.586	0.776	0.931
P4	165	187.4	10812.6	0.1060	2.256	5912.5	289.06	294.14					6201.56	6206.64	354.52	< OK	373.5	16.61	16.62	17.5	0.01	5.08	5.846	5.949	0.974	0.992
P5	180	0	11000.0	0.1079	2.2579	5912.5	296.65	296.65					6209.15	6209.15	354.81	< OK	373.5	16.62	16.63	17.5	0.01	5.00	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 18
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 130264.56
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 11000
MRA(sWt[tid][20][10])= 410.609
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	6	Columns
2. gCol[tid][2] =	Column OD	OD =	558.8	mm
3. gCol[tid][3] =	Column thk	thk =	6.35	mm
4. gCol[tid][4] =	Tank Height	Htank =	8500	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	2450	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	6050	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	10740	mm
8. gCol[tid][8] =	Brace Angle	BRang =	41.5924	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.4821	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA537-CL2	t40 ~ 0	SHT	18	130.265	158.923	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t0, t8×2056×2450	SHT	6	1.981	2.179	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø558.8×6.35t × 6050L	PCS	6	3.140	3.140	000,000	000,000	3
4	BRACE ( PIPE, θ= 41.5924 deg.)	null	Ø0×0t × 8089L	PCS	12			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA537-CL2(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA537-CL2	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				42	135.386	164.242	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [7 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 6. 롯데 G1				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 16840 mm, CA = 1.5 mm, SG = 0.646, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 0.517 kg/cm2(=50.7 kPa), 수압테스트압력 GsetMAWP=809.1 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 80 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	16843.0	0	0	588.4	588.4	19.45	19.46	20.5	0.7+0.34	0.6224	0.6716			1.0	σeq = 130.401	1 / 11
P1	10.0o	10.0o	16715.1	0	0		588.4	19.45	19.46	20.5	0.7+0.34	0.6224	0.6716			1.0	σeq = 130.401	2 / 11
P2	20.0o	30.0o	15714.7	0	0		588.4	19.45	19.46	20.5	0.7+0.34	0.6224	0.6716			1.0	σeq = 130.401	3 / 11
P3	20.0o	50.0o	13834.7	0	0		588.4	19.45	19.46	20.5	0.7+0.34	0.6224	0.6716			1.0	σeq = 130.401	4 / 11
P4	16.0o	66.0o	11846.8	1634.7	10.4		598.8	19.78	19.78	21.0	0.7+0.52	0.6284	0.6880			1.0	σeq = 129.339	5 / 11
P5	24.0o	90.0o	8421.5	5060.0	32.1		620.5	20.68	20.44	22.5	0.7+0.12	0.6231	0.7044			1.0	σeq = 132.359	6 / 11
	40.0o	130.0o	3008.3	10473.2	66.3		654.7	21.49	21.49	22.5	0.7+0.31	0.6216	0.7371			1.0	σeq = 131.333	8 / 11
P6	20.0o	150.0o	1128.3	12353.2	78.3		666.7	21.84	21.85	23.0	0.7+0.45	0.6260	0.7535			1.0	σeq = 130.57	9 / 11
P7	20.0o	170.0o	127.9	13353.6	84.6		673.0	22.03	22.05	23.0	0.7+0.25	0.6197	0.7535			1.0	σeq = 131.806	10 / 11
P8	10.0o	180.0o	0	13481.5	85.4		673.8	22.06	22.07	23.0	0.7+0.23	0.6189	0.7535	0.6189	0.6716	1.0	σeq = 131.964	11 / 11

A) Operating : 　　tReq =   P·R   2·S·E － 0.2·P     ＋ CA B) Test : 　　tReq =   P·Rc   2·St·E － 0.2·Pt     ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	0.5884	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	0.6189	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	0.6716	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [7 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 6. 롯데 G1				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 16840 mm, CA = 1.5 mm, SG = 0.646, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 0.517 kg/cm2(=50.7 kPa), 수압테스트압력 GsetMAWP=804.6 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 80 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	16840.0	0	0	804.6	804.6	13.77	14.48	15.71	20.5	0.6224	0.6716	σeq = 215.405	1 / 11
P1	10.0o	10.0o	16712.1	127.9	1.3		805.9	13.79	14.50	15.74	20.5	0.6224	0.6716	σeq = 215.865	2 / 11
P2	20.0o	30.0o	15711.9	1128.1	11.1		815.7	13.96	14.68	15.91	20.5	0.6224	0.6716	σeq = 210.339	3 / 11
P3	20.0o	50.0o	13832.3	3007.7	29.5		834.1	14.30	15.01	16.24	20.5	0.6224	0.6716	σeq = 216.991	4 / 11
P4	16.0o	66.0o	11844.7	4995.3	49.0		853.6	14.65	15.36	16.59	21.0	0.6284	0.6880	σeq = 215.29	5 / 11
P5	24.0o	90.0o	8420.0	8420.0	82.6		887.2	15.25	15.97	17.20	22.5	0.6231	0.7044	σeq = 219.906	6 / 11
	40.0o	130.0o	3007.7	13832.3	135.6		940.2	16.21	16.92	18.15	22.5	0.6216	0.7371	σeq = 217.887	8 / 11
P6	20.0o	150.0o	1128.1	15711.9	154.1		958.7	16.54	17.25	18.49	23.0	0.6260	0.7535	σeq = 215.594	9 / 11
P7	20.0o	170.0o	127.9	16712.1	163.9		968.5	16.72	17.43	18.66	23.0	0.6197	0.7535	σeq = 218.424	10 / 11
P8	10.0o	180.0o	0	16840.0	165.1		969.7	16.74	17.45	18.68	23.0	0.6189	0.7535	σeq = 218.788	11 / 11

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.5884

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.7649

7.8000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

0.6189

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.8046

8.2046

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

0.6716

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

0.8731

8.9031

S-Tank Engineering	AAA Spherical Tank Calculation [7 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 6. 롯데 G1				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 16840 mm, CA = 1.5 mm, SG = 0.646, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 0.517 kg/cm2(=50.7 kPa), 수압테스트압력 GsetMAWP=804.6 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 80 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	16843.0	0	0	16840.0	0	0	19.00	20.5	0.6224	0.6716	62.9711	1 / 11
P1	10.0o	10.0o	16715.1	0	0	16712.1	127.9	1.3	19.00	20.5	0.6224	0.6716	62.9711	2 / 11
P2	20.0o	30.0o	15714.7	0	0	15711.9	1128.1	11.1	19.00	20.5	0.6224	0.6716	62.9711	3 / 11
P3	20.0o	50.0o	13834.7	0	0	13832.3	3007.7	29.5	19.00	20.5	0.6224	0.6716	62.9711	4 / 11
P4	16.0o	66.0o	11846.8	1634.7	10.4	11844.7	4995.3	49.0	19.50	21.0	0.6284	0.6880	66.3230	5 / 11
P5	24.0o	90.0o	8421.5	5060.0	32.1	8420.0	8420.0	82.6	20.00	21.5	0.6231	0.7044	69.7615	6 / 11
	40.0o	130.0o	3008.3	10473.2	66.3	3007.7	13832.3	135.6	21.00	22.5	0.6216	0.7371	76.8977	8 / 11
P6	20.0o	150.0o	1128.3	12353.2	78.3	1128.1	15711.9	154.1	21.50	23.0	0.6260	0.7535	80.5955	9 / 11
P7	20.0o	170.0o	127.9	13353.6	84.6	127.9	16712.1	163.9	21.50	23.0	0.6197	0.7535	80.5955	10 / 11
P8	10.0o	180.0o	0	13481.5	85.4	0	16840.0	165.1	21.50	23.0	0.6189	0.7535	80.5955	11 / 11

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.5884

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.7649

7.8000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

0.6189

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.8046

8.2046

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

0.6716

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

0.8731

8.9031

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

50.7004

SA516-70

Maximum. Allowable External Pressure

MAEP =

62.9711

0.6421

CS-2

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(0.5 atm = 50.6625 kPa) condition. Harf Vacuum(0.5 atm = 50.6625 kPa) < MAEP(MinMAEP=62.9711 kPa)

● Shell Material MATL = SA516-70 - Modulus of Elasticity [SEC. II PART 'D' Table TM-1] Ey = 200133  MPa - Minimum Yield Strength [SEC. II PART 'D' Table 1A] Sy = 260.0  MPa - Allowable stress at Hydrostatic-test Conditions, Syt = 0.9 × Sy Syt = 234.0  MPa - Allowable stress at Test temperature (-12℃~30℃) [Table 1A] Samb = 138.0  MPa - Allowable stress at Design temperature (60.0 ℃) [Table 1A] S = 138.0  MPa - Lowest Stress Ratio, LSR = Samb / Sd LSR = 1.0   o Chart For Shell Thk. Under External Pressure (FACTOR A, B CURVE) CS-2 [see Bellow Curve] Initial thickness for Design External Pressure (after corroded) tc = 19.0  mm Outside Radius of tank top head Ro = 8440.5  mm Factor A = 0.125 / [Ro / tc] Factor A = 0.0002814 Factor B : (ASME Sec. II, Part D SUBPART 3 - FIG.CS-2) Factor B = 27.97408  MPa Design External Pressure, 　Pe = 0.517 (kg/cm²) Pe = 50.7004  kPa Max. Allowable External Pressure, MAEP = FACTOR B × tc/Ro ×1000 MAEP = 62.9711  kPa Check : Pe < MAEP O.K

S-Tank Engineering	AAA Spherical Tank Calculation [7 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 6. 롯데 G1				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 16840 mm, CA = 1.5 mm, SG = 0.646, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 0.517 kg/cm2(=50.7 kPa), 수압테스트압력 GsetMAWP=804.6 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 80 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	19.45	19.5	14.48	15.71	18.55	20.5	0.7+0.34	#1	30.0	20.5	2939.1	8817.4	3	3,962	11,886	1 / 11
P1	10.0o	10.0o	19.45	19.5	14.50	15.74	18.55	20.5	0.7+0.34									2 / 11
P2	20.0o	30.0o	19.45	19.5	14.68	15.91	18.55	20.5	0.7+0.34									3 / 11
P3	20.0o	50.0o	19.45	19.5	15.01	16.24	18.55	20.5	0.7+0.34	#2	20.0	20.5	2939.1	9321.8	4	3,430	13,721	4 / 11
P4	16.0o	66.0o	19.78	19.8	15.36	16.59	18.55	21.0	0.7+0.52	#3	16.0	21.0	2685.0	8817.4	6	2,889	17,334	5 / 11
P5	24.0o	90.0o	20.68	20.4	15.97	17.20	18.55	22.5	0.7+0.12	#4	64.0	22.5	2939.1	9505.2	18	4,588	82,575	6 / 11
	40.0o	130.0o	21.49	21.5	16.92	18.15	18.55	22.5	0.7+0.31									8 / 11
P6	20.0o	150.0o	21.84	21.8	17.25	18.49	18.55	23.0	0.7+0.45	#5	20.0	23.0	2939.1	9121.8	4	3,849	15,394	9 / 11
P7	20.0o	170.0o	22.03	22.0	17.43	18.66	18.55	23.0	0.7+0.25	#6	30.0	23.0	2939.1	8817.4	3	4,445	13,335	10 / 11
P8	10.0o	180.0o	22.06	22.1	17.45	18.68	18.55	23.0	0.7+0.23									11 / 11

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [6 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 5. 알제리				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 11000 mm, CA = 1.5 mm, SG = 0.536, Pg= 21.9239 kg/cm²(=2150 kPa), Pe= 1.05 kg/cm²(=102.97 kPa), 수압테스트압력 GsetMAWP=2856 kPa
Material : SA537-CL2, EXTERNAL CHART NO. [CS-4], DTEMP = 100 ℃, Sd = 158 MPa, St = 373.5 MPa, Samb = 158 MPa, LSR = Samb/Sd = 1.0, Ft = 550 MPa, Fy = 415 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	38.93	39.0	21.04	21.98	17.01	40.0	0.7+0.32	#1	45.0	40.0	2879.8	8639.4	3	7,422	22,265	1 / 8
P1	15.0o	15.0o	38.93	39.0	21.05	21.99	17.01	40.0	0.7+0.32									2 / 8
P2	30.0o	45.0o	38.93	39.0	21.16	22.09	17.01	40.0	0.7+0.32									3 / 8
P3	45.0o	90.0o	39.18	39.2	21.44	22.37	17.01	TD90USED	0.7+0.12	#2	90.0	40.5	2879.8	8739.4	12	7,121	85,457	4 / 8
	45.0o	135.0o	39.48	39.5	21.72	22.66	17.01	40.5	0.7+0.27									6 / 8
P4	30.0o	165.0o	39.61	39.7	21.82	22.76	17.01	40.5	0.7+0.14	#3	45.0	40.5	2879.8	8639.4	3	7,514	22,543	7 / 8
P5	15.0o	180.0o	39.63	39.7	21.84	22.77	17.01	40.5	0.7+0.12									8 / 8

Spherical tank, / External Pressure calc Result !!
DivNo = 1, teReq = 18.55 mm; Pe :50.7 kPa ≤ Pa = 50.73 kPa = Factor_B / (Ro/tc)*1000 ; Factor_A=0.0625*tc/Rc = 0.0002526; Factor_B = 25.106 MPa

S-Tank Engineering	Spherical Tank Calculation [7 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=16840 (cm), Sd=138 MPa, Pg=0.5884 (MPa), HT_UPPCOL = 35800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=253.713 (N-mm), Nφ=16.243 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	16840	mm	1684.0	cm
3	R = Inside Radius in Corroded Condition	R =	8421.5	mm	842.15	cm
4	L = Design Liquid level	L =	13480	mm	1348.0	cm
5	CA = Corrosion Allowance	CA =	1.5	mm	0.15	cm
6	Wt = Total Weight at Operating Condition	Wt =	15,778,045	N	1608912.8	Kg
7	S = Allowable Stress for the Design Condition SA516-70, Sd = 138MPa	S =	138.0	MPa	1407.208	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.588	MPa	6.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.646		0.646
10	γ = Liquid Density	γ =	6.335096E-6	N/mm³	646.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	9.0	columns	9	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	25.16194	degree	0.43916	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	53.0697	degree	0.92624	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9942565		0.9942565
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1349991		1.1349991
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4251781		0.4251781
20	C5 = 22 / φ	C5 =	0.8743364		0.8743364
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4251781		0.4251781
22	Calculation Result :
23	PM = P×R/2	PM =	2477.605	N-mm	25.265	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	253.713	N-mm	2.587	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	16.243	N-mm	0.166	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	2897.12	N/mm	2954.24	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	2233.14	N/mm	2277.169	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	22.07	mm	2.207	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	20.68	mm	2.068	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	123.124	MPa	1255.515	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	850,075,515	N-mm	8668.358×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	312,354,708	N-mm	3185.132×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	427,643,866	N-mm	4360.754×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	145,441,382	N-mm	1483.089×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	224.47	N/mm	228.896	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	490,670,753	N-mm	5003.449×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	260,111,835	N-mm	2652.403×103	Kg-cm
39	Za = IH / LA × t	Za =	50,275,965	mm³	50.276×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	3,977,612,083	mm³	3977.612×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.2531E-5		2.2531E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.990277E-3		6.990277E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1819.658	mm	181.966	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	58.667	N/mm	59.824	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	46,152,076	N-mm	470.62×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	23,217,528	N-mm	236.753×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	786,674	mm³	7866.736	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	210,904,997	mm³	210.905×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	268.097	mm	26.81	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	531.022	mm	53.102	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	260.713	N/mm	265.853	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	179.79	N/mm	183.335	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,324,178	N	135028.5	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	36653.01	N	3737.6	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7161.276	mm	716.128	cm

piDeg=[25.16194007327985] piRad=[0.43915870046823663] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=16840 (cm), Sd=138 MPa, Pg=0.5884 (MPa), HT_UPPCOL = 35800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	16843.0	0	0	0.5884	2477.61							2477.61	2477.61	130.40	< OK	138	19.45	19.46	20.5	0.01	5.51	0	0	0	0
P1	10	16715.1	0	0	0.5884	2477.61							2477.61	2477.61	130.40	< OK	138	19.45	19.46	20.5	0.01	5.51	0	0	0	0
P2	30	15714.7	0	0	0.5884	2477.61							2477.61	2477.61	130.40	< OK	138	19.45	19.46	20.5	0.01	5.51	0	0	0	0
P3	50	13834.7	0	0	0.5884	2477.61							2477.61	2477.61	130.40	< OK	138	19.45	19.46	20.5	0.01	5.51	0	0	0	0
P4	66	11846.8	1634.7	0.0104	0.5988	2477.61	82.43	4.78					2560.04	2482.39	129.34	< OK	138	19.78	19.78	21.0		6.28	1.101	0.064	0.183	0.011
P5	90	8421.5	5060.0	0.0321	0.6205	2477.61	253.71	16.24	224.47	58.67	260.71	179.79	2897.12	2233.14	132.36	< OK	138	20.68	20.44	21.5	-0.24	4.09	3.388	0.217	0.565	0.036	Column Attached Equator Plate
	130	3008.3	10473.2	0.0663	0.6547	2477.61	236.35	322.41					2713.95	2800.02	131.33	< OK	138	21.49	21.49	22.5		4.83	3.156	4.306	0.526	0.718
P6	150	1128.3	12353.2	0.0783	0.6667	2477.61	314.12	344.94					2791.73	2822.54	130.57	< OK	138	21.84	21.85	23.0	0.01	5.38	4.195	4.606	0.699	0.768
P7	170	127.9	13353.6	0.0846	0.673	2477.61	354.50	357.92					2832.11	2835.53	131.81	< OK	138	22.03	22.04	23.0	0.01	4.49	4.734	4.78	0.789	0.797
P8	180	0	13481.5	0.0854	0.6738	2477.61	359.63	359.63					2837.23	2837.23	131.96	< OK	138	22.06	22.07	23.0	0.01	4.37	4.803	4.803	0.8	0.8

S-Tank Engineering	Spherical Tank Calculation [7 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=16840 (cm), Syt=234 MPa, MAWP=0.76492 (MPa), HT_UPPCOL = 35800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=579.38 (N-mm), Nφ=115.876 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	16840	mm	1684.0	cm
3	R = Inside Radius in Corroded Condition	R =	8420	mm	842.0	cm
4	L = Hydrostatic-test Water Level	L =	16840	mm	1684.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	25,721,643	N	2622877.6	Kg
7	S = Allowable Stress for the Design Condition SA516-70, Sd = 234MPa	S =	234.0	MPa	2386.136	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.588	MPa	6.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	863.6	mm	86.36	cm
12	N = Number of Support Column	N =	9.0	columns	9	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	25.16194	degree	0.43916	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9942565		0.9942565
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1349991		1.1349991
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4251781		0.4251781
20	C5 = 22 / φ	C5 =	0.8743364		0.8743364
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4251781		0.4251781
22	Calculation Result :
23	PM = P×R/2	PM =	2477.164	N-mm	25.26	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	579.38	N-mm	5.908	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	115.876	N-mm	1.182	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	3326.87	N/mm	3392.463	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	2167.95	N/mm	2210.694	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	13.56	mm	1.356	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	12.69	mm	1.269	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	204.74	MPa	2087.767	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,385,561,051	N-mm	14128.791×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	509,115,379	N-mm	5191.532×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	697,028,292	N-mm	7107.71×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	237,058,838	N-mm	2417.327×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	365.999	N/mm	373.215	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	799,757,517	N-mm	8155.257×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	423,963,308	N-mm	4323.223×103	Kg-cm
39	Za = IH / LA × t	Za =	38,239,826	mm³	38.24×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	3,975,487,038	mm³	3975.487×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.2531E-5		2.2531E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	6.990277E-3		6.990277E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1819.334	mm	181.933	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	95.675	N/mm	97.561	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	75,237,916	N-mm	767.213×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	37,849,618	N-mm	385.959×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	786,393	mm³	7863.933	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	210,792,320	mm³	210.792×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	268.049	mm	26.805	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	530.927	mm	53.093	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	425.094	N/mm	433.475	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	293.13	N/mm	298.909	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	2,158,573	N	220113.2	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	59763.019	N	6094.1	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	7160.0	mm	716.0	cm

piDeg=[25.16194007327985] piRad=[0.43915870046823663] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=16840 (cm), Syt=234 MPa, MAWP=0.76492 (MPa), HT_UPPCOL = 35800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	16840.0	0	0	0.5884	2477.16							2477.16	2477.16	215.40	< OK	234	10.59	10.59	11.5		7.95	0	0	0	0
P1	10	16712.1	127.9	0.0013	0.5897	2477.16	7.93	2.63					2485.09	2479.80	215.86	< OK	234	10.61	10.61	11.5		7.75	0.068	0.023	0.011	0.004
P2	30	15711.9	1128.1	0.0111	0.5995	2477.16	70.42	22.73					2547.58	2499.89	210.34	< OK	234	10.79	10.79	12.0		10.11	0.608	0.196	0.101	0.033
P3	50	13832.3	3007.7	0.0295	0.6179	2477.16	190.77	57.59					2667.93	2534.75	216.99	< OK	234	11.13	11.12	12.0	-0.01	7.27	1.646	0.497	0.274	0.083
P4	66	11844.7	4995.3	0.0490	0.6374	2477.16	323.85	88.62					2801.01	2565.79	215.29	< OK	234	11.50	11.47	12.5	-0.03	8.00	2.795	0.765	0.466	0.127
P5	90	8420.0	8420.0	0.0826	0.671	2477.16	579.38	115.88	366.00	95.67	425.09	293.13	3326.87	2167.95	219.91	< OK	234	12.69	12.08	13.5	-0.61	6.02	5	1	0.833	0.167	Column Attached Equator Plate
	130	3007.7	13832.3	0.1356	0.724	2477.16	504.49	637.67					2981.65	3114.83	217.89	< OK	234	13.04	13.03	14.0	-0.01	6.89	4.354	5.503	0.726	0.917
P6	150	1128.1	15711.9	0.1541	0.7425	2477.16	624.84	672.53					3102.00	3149.69	215.59	< OK	234	13.36	13.36	14.5		7.87	5.392	5.804	0.899	0.967
P7	170	127.9	16712.1	0.1639	0.7523	2477.16	687.33	692.62					3164.49	3169.79	218.42	< OK	234	13.53	13.54	14.5	0.01	6.66	5.932	5.977	0.989	0.996
P8	180	0	16840.0	0.1651	0.7535	2477.16	695.26	695.26					3172.42	3172.42	218.79	< OK	234	13.56	13.56	14.5		6.50	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 38
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 154245.181
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 16840
MRA(sWt[tid][20][10])= 890.91
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	9	Columns
2. gCol[tid][2] =	Column OD	OD =	863.6	mm
3. gCol[tid][3] =	Column thk	thk =	9.65	mm
4. gCol[tid][4] =	Tank Height	Htank =	11420	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	3580	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	7840	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	16430	mm
8. gCol[tid][8] =	Brace Angle	BRang =	35.6314	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.669	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA516-70	t20.5 ~ 23	SHT	38	154.245	188.179	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t23, t12×3013×3580	SHT	9	10.090	11.099	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø863.6×9.65t × 7840L	PCS	9	14.339	14.339	000,000	000,000	3
4	BRACE ( PIPE, θ= 35.6314 deg.)	null	Ø0×0t × 9646L	PCS	18			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA516-70(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA516-70	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				74	178.674	213.617	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [8 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 7. 말레이시아				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 15650 mm, CA = 3 mm, SG = 0.6215, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=1076.5 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 68 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	15656.0	0	0	588.4	588.4	19.69	19.70	26.5	0.7+0.38	0.8281	0.9341			1.0	σeq = 131.6	1 / 11
P1	10.0o	10.0o	15537.1	0	0		588.4	19.69	19.70	26.5	0.7+0.38	0.8281	0.9341			1.0	σeq = 131.6	2 / 11
P2	20.0o	30.0o	14607.2	0	0		588.4	19.69	19.70	26.5	0.7+0.38	0.8281	0.9341			1.0	σeq = 131.6	3 / 11
P3	20.0o	50.0o	12859.7	1223.3	7.5		595.9	19.90	19.91	26.5	0.7+0.38	0.8206	0.9341			1.0	σeq = 129.586	4 / 11
P4	16.0o	66.0o	11011.9	3071.1	18.7		607.1	20.23	20.23	26.5	0.7+0.38	0.8094	0.9341			1.0	σeq = 132.12	5 / 11
P5	24.0o	90.0o	7828.0	6255.0	38.1		626.5	20.99	20.78	26.5	0.7+0.38	0.7900	0.9341			1.0	σeq = 130.661	6 / 11
	40.0o	130.0o	2796.3	11286.7	68.8		657.2	21.64	21.65	26.5	0.7+0.38	0.7593	0.9341			1.0	σeq = 131.948	8 / 11
P6	20.0o	150.0o	1048.8	13034.2	79.4		667.8	21.94	21.95	26.5	0.7+0.38	0.7487	0.9341			1.0	σeq = 130.701	9 / 11
P7	20.0o	170.0o	118.9	13964.1	85.1		673.5	22.10	22.11	26.5	0.7+0.38	0.7430	0.9341			1.0	σeq = 131.806	10 / 11
P8	10.0o	180.0o	0	14083.0	85.8		674.2	22.12	22.13	26.5	0.7+0.38	0.7423	0.9341	0.7423	0.9341	1.0	σeq = 131.948	11 / 11

A) Operating : 　　tReq =   P·R   2·S·E － 0.2·P     ＋ CA B) Test : 　　tReq =   P·Rc   2·St·E － 0.2·Pt     ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	0.5884	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	0.7423	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	0.9341	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [8 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 7. 말레이시아				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 15650 mm, CA = 3 mm, SG = 0.6215, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=965 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 68 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	15650.0	0	0	965.0	965.0	12.79	16.14	20.31	26.5	0.8281	0.9341	σeq = 209.284	1 / 11
P1	10.0o	10.0o	15531.1	118.9	1.2		966.2	12.81	16.16	20.33	26.5	0.8281	0.9341	σeq = 209.698	2 / 11
P2	20.0o	30.0o	14601.6	1048.4	10.3		975.3	12.96	16.31	20.48	26.5	0.8281	0.9341	σeq = 212.965	3 / 11
P3	20.0o	50.0o	12854.8	2795.2	27.4		992.4	13.25	16.60	20.77	26.5	0.8206	0.9341	σeq = 209.689	4 / 11
P4	16.0o	66.0o	11007.7	4642.3	45.5		1010.5	13.55	16.90	21.07	26.5	0.8094	0.9341	σeq = 216.214	5 / 11
P5	24.0o	90.0o	7825.0	7825.0	76.7		1041.7	14.08	17.42	21.59	26.5	0.7900	0.9341	σeq = 216.834	6 / 11
	40.0o	130.0o	2795.2	12854.8	126.1		1091.1	14.90	18.25	22.42	26.5	0.7593	0.9341	σeq = 215.162	8 / 11
P6	20.0o	150.0o	1048.4	14601.6	143.2		1108.2	15.19	18.53	22.70	26.5	0.7487	0.9341	σeq = 220.199	9 / 11
P7	20.0o	170.0o	118.9	15531.1	152.3		1117.3	15.34	18.69	22.86	26.5	0.7430	0.9341	σeq = 214.668	10 / 11
P8	10.0o	180.0o	0	15650.0	153.5		1118.5	15.36	18.71	22.88	26.5	0.7423	0.9341	σeq = 215.006	11 / 11

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.5884

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.7649

7.8000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

0.7423

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.9650

9.8403

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

0.9341

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

1.2143

12.3824

S-Tank Engineering	AAA Spherical Tank Calculation [8 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 7. 말레이시아				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 15650 mm, CA = 3 mm, SG = 0.6215, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=965 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 68 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	15656.0	0	0	15650.0	0	0	23.50	26.5	0.8281	0.9341	111.3584	1 / 11
P1	10.0o	10.0o	15537.1	0	0	15531.1	118.9	1.2	23.50	26.5	0.8281	0.9341	111.3584	2 / 11
P2	20.0o	30.0o	14607.2	0	0	14601.6	1048.4	10.3	23.50	26.5	0.8281	0.9341	111.3584	3 / 11
P3	20.0o	50.0o	12859.7	1223.3	7.5	12854.8	2795.2	27.4	23.50	26.5	0.8206	0.9341	111.3584	4 / 11
P4	16.0o	66.0o	11011.9	3071.1	18.7	11007.7	4642.3	45.5	23.50	26.5	0.8094	0.9341	111.3584	5 / 11
P5	24.0o	90.0o	7828.0	6255.0	38.1	7825.0	7825.0	76.7	23.50	26.5	0.7900	0.9341	111.3584	6 / 11
	40.0o	130.0o	2796.3	11286.7	68.8	2795.2	12854.8	126.1	23.50	26.5	0.7593	0.9341	111.3584	8 / 11
P6	20.0o	150.0o	1048.8	13034.2	79.4	1048.4	14601.6	143.2	23.50	26.5	0.7487	0.9341	111.3584	9 / 11
P7	20.0o	170.0o	118.9	13964.1	85.1	118.9	15531.1	152.3	23.50	26.5	0.7430	0.9341	111.3584	10 / 11
P8	10.0o	180.0o	0	14083.0	85.8	0	15650.0	153.5	23.50	26.5	0.7423	0.9341	111.3584	11 / 11

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.5884

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.7649

7.8000

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

0.7423

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0.9650

9.8403

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

0.9341

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

1.2143

12.3824

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

101.3250

SA516-70

Maximum. Allowable External Pressure

MAEP =

111.3584

1.1355

CS-2

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(1 atm = 101.325 kPa) condition. Full Vacuum(1 atm = 101.325 kPa) < MAEP(MinMAEP=111.3584 kPa)

● Shell Material MATL = SA516-70 - Modulus of Elasticity [SEC. II PART 'D' Table TM-1] Ey = 200133  MPa - Minimum Yield Strength [SEC. II PART 'D' Table 1A] Sy = 260.0  MPa - Allowable stress at Hydrostatic-test Conditions, Syt = 0.9 × Sy Syt = 234.0  MPa - Allowable stress at Test temperature (-12℃~30℃) [Table 1A] Samb = 138.0  MPa - Allowable stress at Design temperature (60.0 ℃) [Table 1A] S = 138.0  MPa - Lowest Stress Ratio, LSR = Samb / Sd LSR = 1.0   o Chart For Shell Thk. Under External Pressure (FACTOR A, B CURVE) CS-2 [see Bellow Curve] Initial thickness for Design External Pressure (after corroded) tc = 23.5  mm Outside Radius of tank top head Ro = 7851.5  mm Factor A = 0.125 / [Ro / tc] Factor A = 0.0003741 Factor B : (ASME Sec. II, Part D SUBPART 3 - FIG.CS-2) Factor B = 37.20554  MPa Design External Pressure, 　Pe = 1.03323 (kg/cm²) Pe = 101.3250  kPa Max. Allowable External Pressure, MAEP = FACTOR B × tc/Ro ×1000 MAEP = 111.3584  kPa Check : Pe < MAEP O.K

S-Tank Engineering	AAA Spherical Tank Calculation [8 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 7. 말레이시아				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 15650 mm, CA = 3 mm, SG = 0.6215, Pg= 6.0 kg/cm2(=588.399 kPa), Pe= 1.033227 kg/cm2(=101.325 kPa), 수압테스트압력 GsetMAWP=965 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 68 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	19.69	19.7	16.14	20.31	25.42	26.5	0.7+0.38	#1	30.0	26.5	2731.4	8194.3	3	4,423	13,270	1 / 11
P1	10.0o	10.0o	19.69	19.7	16.16	20.33	25.42	26.5	0.7+0.38									2 / 11
P2	20.0o	30.0o	19.69	19.7	16.31	20.48	25.42	26.5	0.7+0.38									3 / 11
P3	20.0o	50.0o	19.90	19.9	16.60	20.77	25.42	26.5	0.7+0.38	#2	20.0	26.5	2731.4	8677.2	4	3,830	15,319	4 / 11
P4	16.0o	66.0o	20.23	20.2	16.90	21.07	25.42	26.5	0.7+0.38	#3	16.0	26.5	2495.3	8194.3	6	3,149	18,892	5 / 11
P5	24.0o	90.0o	20.99	20.8	17.42	21.59	25.42	26.5	0.7+0.38	#4	64.0	26.5	2731.4	8840.6	18	4,666	83,996	6 / 11
	40.0o	130.0o	21.64	21.6	18.25	22.42	25.42	26.5	0.7+0.38									8 / 11
P6	20.0o	150.0o	21.94	22.0	18.53	22.70	25.42	26.5	0.7+0.38	#5	20.0	26.5	2731.4	8477.2	4	3,830	15,319	9 / 11
P7	20.0o	170.0o	22.10	22.1	18.69	22.86	25.42	26.5	0.7+0.38	#6	30.0	26.5	2731.4	8194.3	3	4,423	13,270	10 / 11
P8	10.0o	180.0o	22.12	22.1	18.71	22.88	25.42	26.5	0.7+0.38									11 / 11

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [7 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 6. 롯데 G1				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 16840 mm, CA = 1.5 mm, SG = 0.646, Pg= 6.0 kg/cm²(=588.399 kPa), Pe= 0.517 kg/cm²(=50.7 kPa), 수압테스트압력 GsetMAWP=804.6 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 80 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	19.45	19.5	14.48	15.71	18.55	20.5	0.7+0.34	#1	30.0	20.5	2939.1	8817.4	3	3,962	11,886	1 / 11
P1	10.0o	10.0o	19.45	19.5	14.50	15.74	18.55	20.5	0.7+0.34									2 / 11
P2	20.0o	30.0o	19.45	19.5	14.68	15.91	18.55	20.5	0.7+0.34									3 / 11
P3	20.0o	50.0o	19.45	19.5	15.01	16.24	18.55	20.5	0.7+0.34	#2	20.0	20.5	2939.1	9321.8	4	3,430	13,721	4 / 11
P4	16.0o	66.0o	19.78	19.8	15.36	16.59	18.55	21.0	0.7+0.52	#3	16.0	21.0	2685.0	8817.4	6	2,889	17,334	5 / 11
P5	24.0o	90.0o	20.68	20.4	15.97	17.20	18.55	TD90USED	0.7+0.12	#4	64.0	22.5	2939.1	9505.2	18	4,588	82,575	6 / 11
	40.0o	130.0o	21.49	21.5	16.92	18.15	18.55	22.5	0.7+0.31									8 / 11
P6	20.0o	150.0o	21.84	21.8	17.25	18.49	18.55	23.0	0.7+0.45	#5	20.0	23.0	2939.1	9121.8	4	3,849	15,394	9 / 11
P7	20.0o	170.0o	22.03	22.0	17.43	18.66	18.55	23.0	0.7+0.25	#6	30.0	23.0	2939.1	8817.4	3	4,445	13,335	10 / 11
P8	10.0o	180.0o	22.06	22.1	17.45	18.68	18.55	23.0	0.7+0.23									11 / 11

Spherical tank, / External Pressure calc Result !!
DivNo = 1, teReq = 25.42 mm; Pe :101.32 kPa ≤ Pa = 101.38 kPa = Factor_B / (Ro/tc)*1000 ; Factor_A=0.0625*tc/Rc = 0.0003570; Factor_B = 35.499 MPa

S-Tank Engineering	Spherical Tank Calculation [8 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=15650 (cm), Sd=138 MPa, Pg=0.5884 (MPa), HT_UPPCOL = 33700.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=266.671 (N-mm), Nφ=31.757 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	15650	mm	1565.0	cm
3	R = Inside Radius in Corroded Condition	R =	7828	mm	782.8	cm
4	L = Design Liquid level	L =	14080	mm	1408.0	cm
5	CA = Corrosion Allowance	CA =	3.0	mm	0.3	cm
6	Wt = Total Weight at Operating Condition	Wt =	13,249,933	N	1351117.2	Kg
7	S = Allowable Stress for the Design Condition SA516-70, Sd = 138MPa	S =	138.0	MPa	1407.208	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.588	MPa	6.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.622		0.6215
10	γ = Liquid Density	γ =	6.094833E-6	N/mm³	621.5	Kg/m³
11	d = Outsdie diameter of Column	d =	812.8	mm	81.28	cm
12	N = Number of Support Column	N =	9.0	columns	9	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	25.51015	degree	0.44524	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	36.96007	degree	0.64507	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9935776		0.9935776
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1496619		1.1496619
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4306709		0.4306709
20	C5 = 22 / φ	C5 =	0.8624020		0.8624020
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4306709		0.4306709
22	Calculation Result :
23	PM = P×R/2	PM =	2302.998	N-mm	23.484	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	266.671	N-mm	2.719	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	31.757	N-mm	0.324	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	2715.79	N/mm	2769.335	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	2102.43	N/mm	2143.882	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	22.13	mm	2.213	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	20.99	mm	2.099	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	124.128	MPa	1265.753	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	663,558,731	N-mm	6766.416×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	240,258,313	N-mm	2449.953×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	333,813,662	N-mm	3403.952×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	112,080,716	N-mm	1142.905×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	197.564	N/mm	201.459	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	383,081,259	N-mm	3906.342×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	202,814,847	N-mm	2068.136×103	Kg-cm
39	Za = IH / LA × t	Za =	44,597,441	mm³	44.597×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	3,323,586,510	mm³	3323.587×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.4129E-5		2.4129E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	7.28256E-3		7.28256E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1714.056	mm	171.406	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	51.443	N/mm	52.457	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	36,419,331	N-mm	371.374×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	18,321,318	N-mm	186.825×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	707,956	mm³	7079.563	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	181,292,990	mm³	181.293×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	256.079	mm	25.608	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	507.08	mm	50.708	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	232.323	N/mm	236.904	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	160.315	N/mm	163.476	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,112,960	N	113490.3	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	32020.074	N	3265.1	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	6742.584	mm	674.258	cm

piDeg=[25.510146359306425] piRad=[0.4452360466355415] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=15650 (cm), Sd=138 MPa, Pg=0.5884 (MPa), HT_UPPCOL = 33700.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	15656.0	0	0	0.5884	2303.0							2303.00	2303.00	131.60	< OK	138	19.69	19.70	20.5	0.01	4.64	0	0	0	0
P1	10	15537.1	0	0	0.5884	2303.0							2303.00	2303.00	131.60	< OK	138	19.69	19.70	20.5	0.01	4.64	0	0	0	0
P2	30	14607.2	0	0	0.5884	2303.0							2303.00	2303.00	131.60	< OK	138	19.69	19.70	20.5	0.01	4.64	0	0	0	0
P3	50	12859.7	1223.3	0.0075	0.5959	2303.0	52.96	5.40					2355.96	2308.40	129.59	< OK	138	19.90	19.91	21.0	0.01	6.10	0.851	0.087	0.142	0.014
P4	66	11011.9	3071.1	0.0187	0.6071	2303.0	128.01	18.51					2431.01	2321.51	132.12	< OK	138	20.23	20.23	21.0		4.26	2.057	0.297	0.343	0.05
P5	90	7828.0	6255.0	0.0381	0.6265	2303.0	266.67	31.76	197.56	51.44	232.32	160.32	2715.79	2102.43	130.66	< OK	138	20.99	20.78	22.0	-0.21	5.32	4.284	0.51	0.714	0.085	Column Attached Equator Plate
	130	2796.3	11286.7	0.0688	0.6572	2303.0	233.48	305.02					2536.47	2608.01	131.95	< OK	138	21.64	21.65	22.5	0.01	4.39	3.751	4.9	0.625	0.817
P6	150	1048.8	13034.2	0.0794	0.6678	2303.0	298.13	323.74					2601.12	2626.74	130.70	< OK	138	21.94	21.95	23.0	0.01	5.29	4.789	5.201	0.798	0.867
P7	170	118.9	13964.1	0.0851	0.6735	2303.0	331.69	334.54					2634.69	2637.54	131.81	< OK	138	22.10	22.11	23.0	0.01	4.49	5.329	5.374	0.888	0.896
P8	180	0	14083.0	0.0858	0.6742	2303.0	335.95	335.95					2638.95	2638.95	131.95	< OK	138	22.12	22.13	23.0	0.01	4.39	5.397	5.397	0.9	0.9

S-Tank Engineering	Spherical Tank Calculation [8 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=15650 (cm), Syt=234 MPa, MAWP=0.76492 (MPa), HT_UPPCOL = 33800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=500.389 (N-mm), Nφ=100.078 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	15650	mm	1565.0	cm
3	R = Inside Radius in Corroded Condition	R =	7825	mm	782.5	cm
4	L = Hydrostatic-test Water Level	L =	15650	mm	1565.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	20,659,047	N	2106636.5	Kg
7	S = Allowable Stress for the Design Condition SA516-70, Sd = 234MPa	S =	234.0	MPa	2386.136	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.588	MPa	6.0	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	812.8	mm	81.28	cm
12	N = Number of Support Column	N =	9.0	columns	9	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	25.5913	degree	0.44665	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9934181		0.9934181
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1530734		1.1530734
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4319489		0.4319489
20	C5 = 22 / φ	C5 =	0.8596670		0.8596670
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4319489		0.4319489
22	Calculation Result :
23	PM = P×R/2	PM =	2302.115	N-mm	23.475	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	500.389	N-mm	5.103	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	100.078	N-mm	1.021	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	3029.32	N/mm	3089.047	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	2040.97	N/mm	2081.21	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	12.41	mm	1.241	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	11.58	mm	1.158	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	200.772	MPa	2047.305	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	1,034,211,828	N-mm	10546.026×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	373,184,492	N-mm	3805.423×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	520,276,536	N-mm	5305.344×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	174,165,027	N-mm	1775.989×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	306.306	N/mm	312.345	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	597,095,603	N-mm	6088.681×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	316,027,050	N-mm	3222.579×103	Kg-cm
39	Za = IH / LA × t	Za =	32,164,142	mm³	32.164×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	3,350,271,797	mm³	3350.272×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.4514E-5		2.4514E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	7.351823E-3		7.351823E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1718.668	mm	171.867	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	79.489	N/mm	81.056	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	56,763,105	N-mm	578.823×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	28,555,573	N-mm	291.186×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	714,103	mm³	7141.03	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	183,950,286	mm³	183.95×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	257.596	mm	25.76	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	510.051	mm	51.005	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	361.224	N/mm	368.346	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	249.525	N/mm	254.445	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	1,737,047	N	177129.5	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	50257.224	N	5124.8	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	6760.0	mm	676.0	cm

piDeg=[25.59130479672834] piRad=[0.44665252858432775] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=15650 (cm), Syt=234 MPa, MAWP=0.76492 (MPa), HT_UPPCOL = 33800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	15650.0	0	0	0.5884	2302.12							2302.12	2302.12	209.28	< OK	234	9.84	9.84	11.0		10.56	0	0	0	0
P1	10	15531.1	118.9	0.0012	0.5896	2302.12	6.85	2.27					2308.96	2304.39	209.70	< OK	234	9.86	9.86	11.0		10.39	0.068	0.023	0.011	0.004
P2	30	14601.6	1048.4	0.0103	0.5987	2302.12	60.82	19.63					2362.93	2321.75	212.96	< OK	234	10.01	10.01	11.0		8.99	0.608	0.196	0.101	0.033
P3	50	12854.8	2795.2	0.0274	0.6158	2302.12	164.76	49.74					2466.87	2351.85	209.69	< OK	234	10.31	10.30	11.5	-0.01	10.39	1.646	0.497	0.274	0.083
P4	66	11007.7	4642.3	0.0455	0.6339	2302.12	279.70	76.54					2581.81	2378.65	216.21	< OK	234	10.63	10.60	11.5	-0.03	7.60	2.795	0.765	0.466	0.127
P5	90	7825.0	7825.0	0.0767	0.6651	2302.12	500.39	100.08	306.31	79.49	361.22	249.52	3029.32	2040.97	216.83	< OK	234	11.58	11.12	12.5	-0.46	7.34	5	1	0.833	0.167	Column Attached Equator Plate
	130	2795.2	12854.8	0.1261	0.7145	2302.12	435.71	550.73					2737.82	2852.85	215.16	< OK	234	11.95	11.95	13.0		8.05	4.354	5.503	0.726	0.917
P6	150	1048.4	14601.6	0.1432	0.7316	2302.12	539.65	580.84					2841.77	2882.95	220.20	< OK	234	12.23	12.24	13.0	0.01	5.90	5.392	5.804	0.899	0.967
P7	170	118.9	15531.1	0.1523	0.7407	2302.12	593.62	598.19					2895.73	2900.31	214.67	< OK	234	12.38	12.39	13.5	0.01	8.26	5.932	5.977	0.989	0.996
P8	180	0	15650.0	0.1535	0.7419	2302.12	600.47	600.47					2902.58	2902.58	215.01	< OK	234	12.40	12.41	13.5	0.01	8.12	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 38
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 160064.008
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 15650
MRA(sWt[tid][20][10])= 769.446
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	9	Columns
2. gCol[tid][2] =	Column OD	OD =	812.8	mm
3. gCol[tid][3] =	Column thk	thk =	8.74	mm
4. gCol[tid][4] =	Tank Height	Htank =	10825	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	3380	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	7445	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	15260	mm
8. gCol[tid][8] =	Brace Angle	BRang =	35.0319	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.818	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA516-70	t26.5 ~ 26.5	SHT	38	160.064	195.278	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t26.5, t11×2853×3380	SHT	9	8.555	9.411	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø812.8×8.74t × 7445L	PCS	9	11.612	11.612	000,000	000,000	3
4	BRACE ( PIPE, θ= 35.0319 deg.)	null	Ø0×0t × 9092L	PCS	18			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA516-70(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA516-70	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				74	180.231	216.301	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [9 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 8. SN2388				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 12000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	12002.0	0	0	497.8	497.8	0.00	-13.93	13.5	0.7+0.50	-0.4164	-0.4498			0	σeq = 9223372036854776	1 / 10
P1	10.0o	10.0o	11910.8	0	0		497.8	0.00	-13.93	13.5	0.7+0.50	-0.4164	-0.4498			0	σeq = 9223372036854776	2 / 10
P2	20.0o	30.0o	11198.0	0	0		497.8	0.00	-13.93	13.5	0.7+0.50	-0.4164	-0.4498			0	σeq = 9223372036854776	3 / 10
P3	20.0o	50.0o	9858.4	882.6	4.3		502.1	0.00	-14.06	13.5	0.7+0.50	-0.4207	-0.4498			0	σeq = 9223372036854776	4 / 10
P4	40.0o	90.0o	6001.0	4740.0	23.2		521.0	0.00	-14.62	13.5	0.7+0.50	-0.4396	-0.4498			0	σeq = 9223372036854776	5 / 10
	40.0o	130.0o	2143.6	8597.4	42.2		540.0	0.00	-15.19	13.5	0.7+0.50	-0.4586	-0.4498			0	σeq = 9223372036854776	7 / 10
P5	20.0o	150.0o	804.0	9937.0	48.7		546.5	0.00	-15.39	13.5	0.7+0.50	-0.4651	-0.4498			0	σeq = 9223372036854776	8 / 10
P6	20.0o	170.0o	91.2	10649.8	52.2		550.0	0.00	-15.49	13.5	0.7+0.50	-0.4686	-0.4498			0	σeq = 9223372036854776	9 / 10
P7	10.0o	180.0o	0	10741.0	52.7		550.5	0.00	-15.51	13.5	0.7+0.50	-0.4691	-0.4498	-0.4691	-0.4498	0	σeq = 9223372036854776	10 / 10

A) Operating : 　　tReq =   P·R   2·S·E － 0.2·P     ＋ CA B) Test : 　　tReq =   P·Rc   2·St·E － 0.2·Pt     ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	0.4978	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	-0.4691	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	-0.4498	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [9 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 8. SN2388				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 12000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	12000.0	0	0	0	0	0.00	0.00	0.00	13.5	-0.4164	-0.4498	σeq = 1493.4	1 / 10
P1	10.0o	10.0o	11908.8	91.2	0.9		0.9	-0.03	-0.03	-0.03	13.5	-0.4164	-0.4498	σeq = 1496.087	2 / 10
P2	20.0o	30.0o	11196.2	803.8	7.9		7.9	-0.24	-0.24	-0.24	13.5	-0.4164	-0.4498	σeq = 1517.195	3 / 10
P3	20.0o	50.0o	9856.7	2143.3	21.0		21.0	-0.63	-0.63	-0.63	13.5	-0.4207	-0.4498	σeq = 1557.557	4 / 10
P4	40.0o	90.0o	6000.0	6000.0	58.8		58.8	-1.76	-1.76	-1.76	13.5	-0.4396	-0.4498	σeq = 1762.925	5 / 10
	40.0o	130.0o	2143.3	9856.7	96.7		96.7	-2.90	-2.90	-2.90	13.5	-0.4586	-0.4498	σeq = 1784.346	7 / 10
P5	20.0o	150.0o	803.8	11196.2	109.8		109.8	-3.29	-3.29	-3.29	13.5	-0.4651	-0.4498	σeq = 1822.911	8 / 10
P6	20.0o	170.0o	91.2	11908.8	116.8		116.8	-3.50	-3.50	-3.50	13.5	-0.4686	-0.4498	σeq = 1843.756	9 / 10
P7	10.0o	180.0o	0	12000.0	117.7		117.7	-3.53	-3.53	-3.53	13.5	-0.4691	-0.4498	σeq = 1846.44	10 / 10

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.4978

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

-0.4691

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

-0.4498

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

0

0

S-Tank Engineering	AAA Spherical Tank Calculation [9 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 8. SN2388				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 12000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	12002.0	0	0	12000.0	0	0	12.50	13.5	-0.4164	-0.4498	54.0102	1 / 10
P1	10.0o	10.0o	11910.8	0	0	11908.8	91.2	0.9	12.50	13.5	-0.4164	-0.4498	54.0102	2 / 10
P2	20.0o	30.0o	11198.0	0	0	11196.2	803.8	7.9	12.50	13.5	-0.4164	-0.4498	54.0102	3 / 10
P3	20.0o	50.0o	9858.4	882.6	4.3	9856.7	2143.3	21.0	12.50	13.5	-0.4207	-0.4498	54.0102	4 / 10
P4	40.0o	90.0o	6001.0	4740.0	23.2	6000.0	6000.0	58.8	12.50	13.5	-0.4396	-0.4498	54.0102	5 / 10
	40.0o	130.0o	2143.6	8597.4	42.2	2143.3	9856.7	96.7	12.50	13.5	-0.4586	-0.4498	54.0102	7 / 10
P5	20.0o	150.0o	804.0	9937.0	48.7	803.8	11196.2	109.8	12.50	13.5	-0.4651	-0.4498	54.0102	8 / 10
P6	20.0o	170.0o	91.2	10649.8	52.2	91.2	11908.8	116.8	12.50	13.5	-0.4686	-0.4498	54.0102	9 / 10
P7	10.0o	180.0o	0	10741.0	52.7	0	12000.0	117.7	12.50	13.5	-0.4691	-0.4498	54.0102	10 / 10

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.4978

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

-0.4691

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

-0.4498

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

0

0

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

44.1299

SA553-TYPE1

Maximum. Allowable External Pressure

MAEP =

54.0102

0.5508

CS-1

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(0.5 atm = 50.6625 kPa) condition. Harf Vacuum(0.5 atm = 50.6625 kPa) < MAEP(MinMAEP=54.0102 kPa)

● Shell Material MATL = SA553-TYPE1 - Modulus of Elasticity [SEC. II PART 'D' Table TM-1] Ey = 200133  MPa - Minimum Yield Strength [SEC. II PART 'D' Table 1A] Sy = -99.999  MPa - Allowable stress at Hydrostatic-test Conditions, Syt = 0.9 × Sy Syt = -99.999  MPa - Allowable stress at Test temperature (-12℃~30℃) [Table 1A] Samb = 0  MPa - Allowable stress at Design temperature (60.0 ℃) [Table 1A] S = -99.999  MPa - Lowest Stress Ratio, LSR = Samb / Sd LSR = 0   o Chart For Shell Thk. Under External Pressure (FACTOR A, B CURVE) CS-1 [see Bellow Curve] Initial thickness for Design External Pressure (after corroded) tc = 12.5  mm Outside Radius of tank top head Ro = 6013.5  mm Factor A = 0.125 / [Ro / tc] Factor A = 0.0002598 Factor B : (ASME Sec. II, Part D SUBPART 3 - FIG.CS-1) Factor B = 25.98320  MPa Design External Pressure, 　Pe = 0.45 (kg/cm²) Pe = 44.1299  kPa Max. Allowable External Pressure, MAEP = FACTOR B × tc/Ro ×1000 MAEP = 54.0102  kPa Check : Pe < MAEP O.K

S-Tank Engineering	AAA Spherical Tank Calculation [9 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 8. SN2388				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 12000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	0.00	-13.9	0.00	0.00	12.30	13.5	0.7+0.50	#1	30.0	13.5	2094.4	6283.2	3	1,325	3,975	1 / 10
P1	10.0o	10.0o	0.00	-13.9	-0.03	-0.03	12.30	13.5	0.7+0.50									2 / 10
P2	20.0o	30.0o	0.00	-13.9	-0.24	-0.24	12.30	13.5	0.7+0.50									3 / 10
P3	20.0o	50.0o	0.00	-14.1	-0.63	-0.63	12.30	13.5	0.7+0.50	#2	20.0	13.5	2094.4	6700.1	4	1,147	4,588	4 / 10
P4	40.0o	90.0o	0.00	-14.6	-1.76	-1.76	12.30	13.5	0.7+0.50	#3	80.0	13.5	2692.8	8477.6	14	2,201	30,817	5 / 10
	40.0o	130.0o	0.00	-15.2	-2.90	-2.90	12.30	13.5	0.7+0.50									7 / 10
P5	20.0o	150.0o	0.00	-15.4	-3.29	-3.29	12.30	13.5	0.7+0.50	#4	20.0	13.5	2094.4	6500.1	4	1,147	4,588	8 / 10
P6	20.0o	170.0o	0.00	-15.5	-3.50	-3.50	12.30	13.5	0.7+0.50	#5	30.0	13.5	2094.4	6283.2	3	1,325	3,975	9 / 10
P7	10.0o	180.0o	0.00	-15.5	-3.53	-3.53	12.30	13.5	0.7+0.50									10 / 10

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [8 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 7. 말레이시아				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 15650 mm, CA = 3 mm, SG = 0.6215, Pg= 6.0 kg/cm²(=588.399 kPa), Pe= 1.033227 kg/cm²(=101.325 kPa), 수압테스트압력 GsetMAWP=965 kPa
Material : SA516-70, EXTERNAL CHART NO. [CS-2], DTEMP = 68 ℃, Sd = 138 MPa, St = 234 MPa, Samb = 138 MPa, LSR = Samb/Sd = 1.0, Ft = 485 MPa, Fy = 260 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	19.69	19.7	16.14	20.31	25.42	26.5	0.7+0.38	#1	30.0	26.5	2731.4	8194.3	3	4,423	13,270	1 / 11
P1	10.0o	10.0o	19.69	19.7	16.16	20.33	25.42	26.5	0.7+0.38									2 / 11
P2	20.0o	30.0o	19.69	19.7	16.31	20.48	25.42	26.5	0.7+0.38									3 / 11
P3	20.0o	50.0o	19.90	19.9	16.60	20.77	25.42	26.5	0.7+0.38	#2	20.0	26.5	2731.4	8677.2	4	3,830	15,319	4 / 11
P4	16.0o	66.0o	20.23	20.2	16.90	21.07	25.42	26.5	0.7+0.38	#3	16.0	26.5	2495.3	8194.3	6	3,149	18,892	5 / 11
P5	24.0o	90.0o	20.99	20.8	17.42	21.59	25.42	TD90USED	0.7+0.38	#4	64.0	26.5	2731.4	8840.6	18	4,666	83,996	6 / 11
	40.0o	130.0o	21.64	21.6	18.25	22.42	25.42	26.5	0.7+0.38									8 / 11
P6	20.0o	150.0o	21.94	22.0	18.53	22.70	25.42	26.5	0.7+0.38	#5	20.0	26.5	2731.4	8477.2	4	3,830	15,319	9 / 11
P7	20.0o	170.0o	22.10	22.1	18.69	22.86	25.42	26.5	0.7+0.38	#6	30.0	26.5	2731.4	8194.3	3	4,423	13,270	10 / 11
P8	10.0o	180.0o	22.12	22.1	18.71	22.88	25.42	26.5	0.7+0.38									11 / 11

Spherical tank, / External Pressure calc Result !!
DivNo = 1, teReq = 12.3 mm; Pe :44.13 kPa ≤ Pa = 44.16 kPa = Factor_B / (Ro/tc)*1000 ; Factor_A=0.0625*tc/Rc = 0.0002349; Factor_B = 23.494 MPa

S-Tank Engineering	Spherical Tank Calculation [9 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=12000 (cm), Sd=-99.999 MPa, Pg=0.4978 (MPa), HT_UPPCOL = 26800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=124.971 (N-mm), Nφ=14.503 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	12000	mm	1200.0	cm
3	R = Inside Radius in Corroded Condition	R =	6001	mm	600.1	cm
4	L = Design Liquid level	L =	10740	mm	1074.0	cm
5	CA = Corrosion Allowance	CA =	1.0	mm	0.1	cm
6	Wt = Total Weight at Operating Condition	Wt =	3,812,394	N	388756.0	Kg
7	S = Allowable Stress for the Design Condition SA553-TYPE1, Sd = -99.999MPa	S =	-99.999	MPa	-1019.706	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.498	MPa	5.076	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.5		0.5
10	γ = Liquid Density	γ =	4.903325E-6	N/mm³	500.0	Kg/m³
11	d = Outsdie diameter of Column	d =	609.6	mm	60.96	cm
12	N = Number of Support Column	N =	7.0	columns	7	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	26.53002	degree	0.46304	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	37.82679	degree	0.6602	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9915365		0.9915365
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1923620		1.1923620
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4466667		0.4466667
20	C5 = 22 / φ	C5 =	0.8292492		0.8292492
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4466667		0.4466667
22	Calculation Result :
23	PM = P×R/2	PM =	1493.649	N-mm	15.231	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	124.971	N-mm	1.274	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	14.503	N-mm	0.148	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	1705.36	N/mm	1738.983	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	1400.35	N/mm	1427.96	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	-15.51	mm	-1.551	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	-14.81	mm	-1.481	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	9,223,372,036,854,776	MPa	9.223372036854776E15	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	243,263,010	N-mm	2480.592×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	84,293,326	N-mm	859.553×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	122,869,516	N-mm	1252.92×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	37,978,435	N-mm	387.272×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	114.562	N/mm	116.821	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	140,695,994	N-mm	1434.7×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	76,545,566	N-mm	780.548×103	Kg-cm
39	Za = IH / LA × t	Za =	-1.719362899E7	mm³	-17.194×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	1,676,002,686	mm³	1676.003×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.9337E-5		2.9337E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	8.184775E-3		8.184775E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1364.694	mm	136.469	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	27.821	N/mm	28.37	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	12,999,821	N-mm	132.561×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	6,566,069	N-mm	66955.272	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	467,275	mm³	4672.746	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	99,132,860	mm³	99.133×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	212.151	mm	21.215	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	419.751	mm	41.975	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	107.801	N/mm	109.926	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	76.551	N/mm	78.06	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	420,116	N	42839.9	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	9735.472	N	992.7	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	5360.893	mm	536.089	cm

piDeg=[26.53002101801117] piRad=[0.46303621738759276] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=12000 (cm), Sd=-99.999 MPa, Pg=0.4978 (MPa), HT_UPPCOL = 26800.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	12002.0	0	0	0.4978	1493.65							1493.65	1493.65	9223372036854776.00	> NG	-99.999	-13.94	-13.93	1.0	0.01	9223464271497592.00	0	0	0	0
P1	10	11910.8	0	0	0.4978	1493.65							1493.65	1493.65	9223372036854776.00	> NG	-99.999	-13.94	-13.93	1.0	0.01	9223464271497592.00	0	0	0	0
P2	30	11198.0	0	0	0.4978	1493.65							1493.65	1493.65	9223372036854776.00	> NG	-99.999	-13.94	-13.93	1.0	0.01	9223464271497592.00	0	0	0	0
P3	50	9858.4	882.6	0.0043	0.5021	1493.65	23.72	2.25					1517.37	1495.90	9223372036854776.00	> NG	-99.999	-14.07	-14.06	1.0	0.01	9223464271497592.00	0.806	0.077	0.134	0.013
P4	90	6001.0	4740.0	0.0232	0.521	1493.65	124.97	14.50	114.56	27.82	107.80	76.55	1705.36	1400.35	9223372036854776.00	> NG	-99.999	-14.81	-14.63	1.0	0.18	9223464271497592.00	4.246	0.493	0.708	0.082	Column Attached Equator Plate
	130	2143.6	8597.4	0.0422	0.54	1493.65	109.58	143.40					1603.23	1637.05	9223372036854776.00	> NG	-99.999	-15.20	-15.19	1.0	0.01	9223464271497592.00	3.723	4.873	0.621	0.812
P5	150	804.0	9937.0	0.0487	0.5465	1493.65	140.14	152.25					1633.79	1645.90	9223372036854776.00	> NG	-99.999	-15.40	-15.39	1.0	0.01	9223464271497592.00	4.762	5.173	0.794	0.862
P6	170	91.2	10649.8	0.0522	0.55	1493.65	156.01	157.36					1649.66	1651.01	9223372036854776.00	> NG	-99.999	-15.50	-15.49	1.0	0.01	9223464271497592.00	5.301	5.347	0.884	0.891
P7	180	0	10741.0	0.0527	0.5505	1493.65	158.03	158.03					1651.68	1651.68	9223372036854776.00	> NG	-99.999	-15.52	-15.51	1.0	0.01	9223464271497592.00	5.37	5.37	0.895	0.895

S-Tank Engineering	Spherical Tank Calculation [9 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=12000 (cm), Syt=-99.999 MPa, MAWP=0.64714 (MPa), HT_UPPCOL = 26900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=294.2 (N-mm), Nφ=58.84 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	12000	mm	1200.0	cm
3	R = Inside Radius in Corroded Condition	R =	6000	mm	600.0	cm
4	L = Hydrostatic-test Water Level	L =	12000	mm	1200.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	8,124,091	N	828426.7	Kg
7	S = Allowable Stress for the Design Condition SA553-TYPE1, Sd = -99.999MPa	S =	-99.999	MPa	-1019.706	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.498	MPa	5.076	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	609.6	mm	60.96	cm
12	N = Number of Support Column	N =	7.0	columns	7	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	26.6368	degree	0.4649	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9913182		0.9913182
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1968111		1.1968111
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4483333		0.4483333
20	C5 = 22 / φ	C5 =	0.8259250		0.8259250
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4483333		0.4483333
22	Calculation Result :
23	PM = P×R/2	PM =	1493.4	N-mm	15.228	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	294.2	N-mm	3.0	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	58.84	N-mm	0.6	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	1971.25	N/mm	2010.116	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	1323.4	N/mm	1349.492	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	-18.45	mm	-1.845	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	-17.63	mm	-1.763	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	1762.925	MPa	17976.832	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	518,299,376	N-mm	5285.183×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	178,925,924	N-mm	1824.537×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	261,787,411	N-mm	2669.489×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	80,678,903	N-mm	822.696×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	242.219	N/mm	246.995	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	299,659,095	N-mm	3055.672×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	162,957,230	N-mm	1661.701×103	Kg-cm
39	Za = IH / LA × t	Za =	-2.659853272E7	mm³	-26.599×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	1,694,586,418	mm³	1694.586×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.993E-5		2.993E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	8.283287E-3		8.283287E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1369.76	mm	136.976	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	58.573	N/mm	59.728	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	27,688,011	N-mm	282.339×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	13,984,915	N-mm	142.606×103	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	472,706	mm³	4727.059	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	101,068,420	mm³	101.068×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	213.808	mm	21.381	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	422.993	mm	42.299	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	228.838	N/mm	233.35	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	162.728	N/mm	165.936	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	896,390	N	91406.4	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	20913.782	N	2132.6	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	5380.0	mm	538.0	cm

piDeg=[26.636802529678082] piRad=[0.4648999063464371] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=12000 (cm), Syt=-99.999 MPa, MAWP=0.64714 (MPa), HT_UPPCOL = 26900.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	12000.0	0	0	0.4978	1493.4							1493.40	1493.40	1493.40	> NG	-99.999	-14.93	-14.93	1.0		1593.41	0	0	0	0
P1	10	11908.8	91.2	0.0009	0.4987	1493.4	4.03	1.34					1497.43	1494.74	1496.09	> NG	-99.999	-14.96	-14.95	1.0	0.01	1596.10	0.068	0.023	0.011	0.004
P2	30	11196.2	803.8	0.0079	0.5057	1493.4	35.76	11.54					1529.16	1504.94	1517.20	> NG	-99.999	-15.17	-15.16	1.0	0.01	1617.21	0.608	0.196	0.101	0.033
P3	50	9856.7	2143.3	0.0210	0.5188	1493.4	96.87	29.24					1590.27	1522.64	1557.56	> NG	-99.999	-15.58	-15.56	1.0	0.02	1657.57	1.646	0.497	0.274	0.083
P4	90	6000.0	6000.0	0.0588	0.5566	1493.4	294.20	58.84	242.22	58.57	228.84	162.73	1971.25	1323.40	1762.92	> NG	-99.999	-17.63	-16.69	1.0	0.94	1862.94	5	1	0.833	0.167	Column Attached Equator Plate
	130	2143.3	9856.7	0.0967	0.5945	1493.4	256.17	323.80					1749.57	1817.20	1784.35	> NG	-99.999	-17.84	-17.82	1.0	0.02	1884.36	4.354	5.503	0.726	0.917
P5	150	803.8	11196.2	0.1098	0.6076	1493.4	317.28	341.50					1810.68	1834.90	1822.91	> NG	-99.999	-18.23	-18.22	1.0	0.01	1922.93	5.392	5.804	0.899	0.967
P6	170	91.2	11908.8	0.1168	0.6146	1493.4	349.01	351.70					1842.41	1845.10	1843.76	> NG	-99.999	-18.44	-18.43	1.0	0.01	1943.77	5.932	5.977	0.989	0.996
P7	180	0	12000.0	0.1177	0.6155	1493.4	353.04	353.04					1846.44	1846.44	1846.44	> NG	-99.999	-18.46	-18.45	1.0	0.01	1946.46	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 28
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 47941.92
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 12000
MRA(sWt[tid][20][10])= 452.389
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	7	Columns
2. gCol[tid][2] =	Column OD	OD =	609.6	mm
3. gCol[tid][3] =	Column thk	thk =	6.35	mm
4. gCol[tid][4] =	Tank Height	Htank =	9000	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	2690	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	6310	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	11670	mm
8. gCol[tid][8] =	Brace Angle	BRang =	38.7451	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	13.468	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA553-TYPE1	t13.5 ~ 13.5	SHT	28	47.942	58.489	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t13.5, t8×2215×2690	SHT	7	3.010	3.311	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø609.6×6.35t × 6310L	PCS	7	4.172	4.172	000,000	000,000	3
4	BRACE ( PIPE, θ= 38.7451 deg.)	null	Ø0×0t × 8090L	PCS	14			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA553-TYPE1(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA553-TYPE1	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				56	55.124	65.972	000,000	000,000	12

]CalcRpt[i][0]=[null

S-Tank Engineering	AAA Spherical Tank Calculation [10 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 9. SN2345				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 9000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
1. Design (Operating) Condition

Segment	Each Angle	Angle α	H	Hs	Ps	Pg	P =Ps+Pg	tShear	tdReq	tUsed	Forming Margin 0.7+α	Pmax MAWP	Pmax MAP	Min.MAWP 찾기	MinMAP 찾기	LSR=Sa/S
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa	MPa	MPa	LSR
	0	0o	9002.0	0	0	497.8	497.8	0.00	-10.20	11.0	0.7+0.30	-0.4441	-0.4886			0	σeq = 9223372036854776	1 / 8
P1	15.0o	15.0o	8848.6	0	0		497.8	0.00	-10.20	11.0	0.7+0.30	-0.4441	-0.4886			0	σeq = 9223372036854776	2 / 8
P2	30.0o	45.0o	7683.7	387.3	1.9		499.7	0.00	-10.24	11.0	0.7+0.30	-0.4460	-0.4886			0	σeq = 9223372036854776	3 / 8
P3	45.0o	90.0o	4501.0	3570.0	17.5		515.3	0.00	-10.59	11.0	0.7+0.30	-0.4616	-0.4886			0	σeq = 9223372036854776	4 / 8
	45.0o	135.0o	1318.3	6752.7	33.1		530.9	0.00	-10.94	11.0	0.7+0.30	-0.4772	-0.4886			0	σeq = 9223372036854776	6 / 8
P4	30.0o	165.0o	153.4	7917.6	38.8		536.6	0.00	-11.07	11.0	0.7+0.30	-0.4829	-0.4886			0	σeq = 9223372036854776	7 / 8
P5	15.0o	180.0o	0	8071.0	39.6		537.4	0.00	-11.09	11.0	0.7+0.30	-0.4837	-0.4886	-0.4837	-0.4886	0	σeq = 9223372036854776	8 / 8

A) Operating : 　　tReq =   P·R   2·S·E － 0.2·P     ＋ CA B) Test : 　　tReq =   P·Rc   2·St·E － 0.2·Pt     ＋ CA

Test Case	escription	Formula	symbol	Min Value	Unit	Hydrostatic Test Condition	Selected
1	Max. Allowable Working Pressue	MAWP = (D.P) = Pg	MAWP =	0.4978	MPa	At Site (Hot & Corroded)	Selected
2	Max. Allowable Working Pressue	MAWP = CalcMAWP(Each Shell)	MAWP =	-0.4837	MPa	At Site (Hot & Corroded)	N/A
3	Max. Allowable Pressue	MAP = CalcMAP(Each Shell)	MAP =	-0.4886	MPa	At Shop ( New & Cold )	N/A

S-Tank Engineering	AAA Spherical Tank Calculation [10 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 9. SN2345				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 9000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
2. Hydrostatic-Test Condition (at Site) MAWP : Hot-Corroded

Segment	Each Angle	Angle α	H	Hs	Ps	Pset (Test Gage Pressure)	P =Ps+Pset	1)ttReq Pg (Basis)	2)ttReq MAWP	3)ttReq MAP 공장수압 시에만사용	tUsed	Pmax MAWP	Pmax MAP
No.	deg.	deg.	mm	mmH2O	kPa	kPa	kPa	mm	mm	mm	mm	MPa	MPa
	0	0o	9000.0	0	0	0	0	0.00	0.00	0.00	11.0	-0.4441	-0.4886	σeq = 1120.05	1 / 8
P1	15.0o	15.0o	8846.7	153.3	1.5		1.5	-0.03	-0.03	-0.03	11.0	-0.4441	-0.4886	σeq = 1123.434	2 / 8
P2	30.0o	45.0o	7682.0	1318.0	12.9		12.9	-0.29	-0.29	-0.29	11.0	-0.4460	-0.4886	σeq = 1149.438	3 / 8
P3	45.0o	90.0o	4500.0	4500.0	44.1		44.1	-0.99	-0.99	-0.99	11.0	-0.4616	-0.4886	σeq = 1348.123	4 / 8
	45.0o	135.0o	1318.0	7682.0	75.3		75.3	-1.69	-1.69	-1.69	11.0	-0.4772	-0.4886	σeq = 1289.83	6 / 8
P4	30.0o	165.0o	153.3	8846.7	86.8		86.8	-1.95	-1.95	-1.95	11.0	-0.4829	-0.4886	σeq = 1315.253	7 / 8
P5	15.0o	180.0o	0	9000.0	88.3		88.3	-1.99	-1.99	-1.99	11.0	-0.4837	-0.4886	σeq = 1318.63	8 / 8

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.4978

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

-0.4837

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

-0.4886

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

0

0

S-Tank Engineering	AAA Spherical Tank Calculation [10 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 9. SN2345				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 9000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
3. MAWP/MAP Calculation

Segment	Each Angle	Angle α	H Liquid Level	Hd	Ps	Ht Test Water Level	Ht	Pst	tc = tUsed - CA	tUsed	Pmax MAWP	Pmax MAP	MEP
No.	deg.	deg.	mm	mmH2O	kPa	mm	H2O	kPa	mm	mm	MPa	MPa	kPa
	0	0o	9002.0	0	0	9000.0	0	0	10.00	11.0	-0.4441	-0.4886	61.4277	1 / 8
P1	15.0o	15.0o	8848.6	0	0	8846.7	153.3	1.5	10.00	11.0	-0.4441	-0.4886	61.4277	2 / 8
P2	30.0o	45.0o	7683.7	387.3	1.9	7682.0	1318.0	12.9	10.00	11.0	-0.4460	-0.4886	61.4277	3 / 8
P3	45.0o	90.0o	4501.0	3570.0	17.5	4500.0	4500.0	44.1	10.00	11.0	-0.4616	-0.4886	61.4277	4 / 8
	45.0o	135.0o	1318.3	6752.7	33.1	1318.0	7682.0	75.3	10.00	11.0	-0.4772	-0.4886	61.4277	6 / 8
P4	30.0o	165.0o	153.4	7917.6	38.8	153.3	8846.7	86.8	10.00	11.0	-0.4829	-0.4886	61.4277	7 / 8
P5	15.0o	180.0o	0	8071.0	39.6	0	9000.0	88.3	10.00	11.0	-0.4837	-0.4886	61.4277	8 / 8

No.

MAWP and Hydrostatic-test gauge setting pressure

symbol

Value (MPa)

Test Gage Pressure (kg/cm2)

Hydro. Test Location

CASE 1

Design Internal Pressue (Pg = MAWP, BASIS)

MAWP = Pg =

0.4978

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 2

(Hot & Corroded) At Site : Max. Allowable Working Pressue

MAWP =

-0.4837

at Site

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MWAP×LSR

Pset(MAWP) =

0

0

CASE 3

( New & Cold ) At Shop : Max. Allowable Pressue

MAP =

-0.4886

at Shop

Hydrostatic-Test Gauge Setting Pressure, Pset = 1.3×MAP×LSR

Pset(MAP) =

0

0

No.

MAEP and performance in vacuum

symbol

Value kPa

Value kg/cm2

Material Chart No.

1

Design External Pressure

Pe =

44.1299

SA553-TYPE1

Maximum. Allowable External Pressure

MAEP =

61.4277

0.6264

CS-1

Pe < MAEP, OK

Pe < MAEP

OK

This tank is safe in full vacuum(0.5 atm = 50.6625 kPa) condition. Harf Vacuum(0.5 atm = 50.6625 kPa) < MAEP(MinMAEP=61.4277 kPa)

● Shell Material MATL = SA553-TYPE1 - Modulus of Elasticity [SEC. II PART 'D' Table TM-1] Ey = 200133  MPa - Minimum Yield Strength [SEC. II PART 'D' Table 1A] Sy = -99.999  MPa - Allowable stress at Hydrostatic-test Conditions, Syt = 0.9 × Sy Syt = -99.999  MPa - Allowable stress at Test temperature (-12℃~30℃) [Table 1A] Samb = 0  MPa - Allowable stress at Design temperature (60.0 ℃) [Table 1A] S = -99.999  MPa - Lowest Stress Ratio, LSR = Samb / Sd LSR = 0   o Chart For Shell Thk. Under External Pressure (FACTOR A, B CURVE) CS-1 [see Bellow Curve] Initial thickness for Design External Pressure (after corroded) tc = 10.0  mm Outside Radius of tank top head Ro = 4511.0  mm Factor A = 0.125 / [Ro / tc] Factor A = 0.0002771 Factor B : (ASME Sec. II, Part D SUBPART 3 - FIG.CS-1) Factor B = 27.71004  MPa Design External Pressure, 　Pe = 0.45 (kg/cm²) Pe = 44.1299  kPa Max. Allowable External Pressure, MAEP = FACTOR B × tc/Ro ×1000 MAEP = 61.4277  kPa Check : Pe < MAEP O.K

S-Tank Engineering	AAA Spherical Tank Calculation [10 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 9. SN2345				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 9000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm2(=497.8 kPa), Pe= 0.45 kg/cm2(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	0.00	-10.2	0.00	0.00	10.00	11.0	0.7+0.30	#1	45.0	11.0	2356.2	7068.6	3	1,366	4,099	1 / 8
P1	15.0o	15.0o	0.00	-10.2	-0.03	-0.03	10.00	11.0	0.7+0.30									2 / 8
P2	30.0o	45.0o	0.00	-10.2	-0.29	-0.29	10.00	11.0	0.7+0.30									3 / 8
P3	45.0o	90.0o	0.00	-10.6	-0.99	-0.99	10.00	11.0	0.7+0.30	#2	90.0	11.0	2827.4	7168.6	10	1,554	15,538	4 / 8
	45.0o	135.0o	0.00	-10.9	-1.69	-1.69	10.00	11.0	0.7+0.30									6 / 8
P4	30.0o	165.0o	0.00	-11.1	-1.95	-1.95	10.00	11.0	0.7+0.30	#3	45.0	11.0	2356.2	7068.6	3	1,366	4,099	7 / 8
P5	15.0o	180.0o	0.00	-11.1	-1.99	-1.99	10.00	11.0	0.7+0.30									8 / 8

], CalcRpt[i][1]=[

S-Tank Engineering	AAA Spherical Tank Calculation [9 / 10]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : 8. SN2388				Rev. No.	[AAA4]

Design Code : Div. 1, Di = 12000 mm, CA = 1 mm, SG = 0.5, Pg= 5.076147 kg/cm²(=497.8 kPa), Pe= 0.45 kg/cm²(=44.13 kPa), 수압테스트압력 GsetMAWP=0 kPa
Material : SA553-TYPE1, EXTERNAL CHART NO. [CS-1], DTEMP = 40 ℃, Sd = -99.999 MPa, St = -99.999 MPa, Samb = 0 MPa, LSR = Samb/Sd = 0, Ft = -99.999 MPa, Fy = -99.999 MPa
4. Summary of Shell Thickness

Segment	Each Angle	Angle α	1.tdReq σeq	2.tdReq ASME CODE	3.ttReq MAWP Site	4.ttReq MAP Shop	5.teReq External Pressure	tUsed 결정 두께	Forming Margin +0.7 mm	PNo	SEG. Angle	tUsed thick.	Width	Height	Qty	Unit WT	Net WT
No.	deg.	deg.	mm	mm	mm	mm	mm	mm	mm	#	deg.	mm	mm	mm	SHT	kg/sht	kg
	0	0o	0	-13.9	0	0	12.30	13.5	0.7+0.50	#1	30.0	13.5	2094.4	6283.2	3	1,325	3,975	1 / 10
P1	10.0o	10.0o	0	-13.9	-0.03	-0.03	12.30	13.5	0.7+0.50									2 / 10
P2	20.0o	30.0o	0	-13.9	-0.24	-0.24	12.30	13.5	0.7+0.50									3 / 10
P3	20.0o	50.0o	0	-14.1	-0.63	-0.63	12.30	13.5	0.7+0.50	#2	20.0	13.5	2094.4	6700.1	4	1,147	4,588	4 / 10
P4	40.0o	90.0o	0	-14.6	-1.76	-1.76	12.30	TD90USED	0.7+0.50	#3	80.0	13.5	2692.8	8477.6	14	2,201	30,817	5 / 10
	40.0o	130.0o	0	-15.2	-2.90	-2.90	12.30	13.5	0.7+0.50									7 / 10
P5	20.0o	150.0o	0	-15.4	-3.29	-3.29	12.30	13.5	0.7+0.50	#4	20.0	13.5	2094.4	6500.1	4	1,147	4,588	8 / 10
P6	20.0o	170.0o	0	-15.5	-3.50	-3.50	12.30	13.5	0.7+0.50	#5	30.0	13.5	2094.4	6283.2	3	1,325	3,975	9 / 10
P7	10.0o	180.0o	0	-15.5	-3.53	-3.53	12.30	13.5	0.7+0.50									10 / 10

Spherical tank, / External Pressure calc Result !!
DivNo = 1, teReq = 10 mm; Pe :44.13 kPa ≤ Pa = 49.78 kPa = Factor_B / (Ro/tc)*1000 ; Factor_A=0.0625*tc/Rc = 0.0002494; Factor_B = 24.945 MPa

S-Tank Engineering	Spherical Tank Calculation [10 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition
　　D=9000 (cm), Sd=-99.999 MPa, Pg=0.4978 (MPa), HT_UPPCOL = 20100.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=70.528 (N-mm), Nφ=8.261 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	9000	mm	900.0	cm
3	R = Inside Radius in Corroded Condition	R =	4501	mm	450.1	cm
4	L = Design Liquid level	L =	8070	mm	807.0	cm
5	CA = Corrosion Allowance	CA =	1.0	mm	0.1	cm
6	Wt = Total Weight at Operating Condition	Wt =	1,629,691	N	166182.3	Kg
7	S = Allowable Stress for the Design Condition SA553-TYPE1, Sd = -99.999MPa	S =	-99.999	MPa	-1019.706	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.498	MPa	5.076	Kg/cm²
9	SG = Design Specific Gravity	SG =	0.5		0.5
10	γ = Liquid Density	γ =	4.903325E-6	N/mm³	500.0	Kg/m³
11	d = Outsdie diameter of Column	d =	406.4	mm	40.64	cm
12	N = Number of Support Column	N =	5.0	columns	5	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	26.53002	degree	0.46304	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	37.51847	degree	0.65482	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9915365		0.9915365
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1923620		1.1923620
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4466667		0.4466667
20	C5 = 22 / φ	C5 =	0.8292492		0.8292492
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4466667		0.4466667
22	Calculation Result :
23	PM = P×R/2	PM =	1120.299	N-mm	11.424	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	70.528	N-mm	0.719	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	8.261	N-mm	0.084	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	1299.37	N/mm	1324.989	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	1042.54	N/mm	1063.095	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	-11.09	mm	-1.109	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	-10.97	mm	-1.097	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	9,223,372,036,854,776	MPa	9.223372036854776E15	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	154,930,744	N-mm	1579.854×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	49,720,581	N-mm	507.009×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	79,026,744	N-mm	805.849×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	20,476,764	N-mm	208.805×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	136.54	N/mm	139.232	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	94,334,555	N-mm	961.945×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	53,942,186	N-mm	550.057×103	Kg-cm
39	Za = IH / LA × t	Za =	-6563475.87	mm³	-6.563×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	707,181,464	mm³	707.181×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	2.9337E-5		2.9337E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	8.184775E-3		8.184775E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1023.577	mm	102.358	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	27.995	N/mm	28.547	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	7,359,059	N-mm	75041.515	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	3,753,693	N-mm	38277.016	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	262,871	mm³	2628.712	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	41,828,645	mm³	41.829×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	159.122	mm	15.912	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	314.831	mm	31.483	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	86.015	N/mm	87.711	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	63.669	N/mm	64.924	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	259,706	N	26482.7	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	3699.031	N	377.2	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	4020.893	mm	402.089	cm

piDeg=[26.53002101801117] piRad=[0.46303621738759276] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.1 At Design(Operating) Condition Equator Plate(A Point at 90 deg) Stress :
D=9000 (cm), Sd=-99.999 MPa, Pg=0.4978 (MPa), HT_UPPCOL = 20100.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	9002.0	0	0	0.4978	1120.3							1120.30	1120.30	9223372036854776.00	> NG	-99.999	-10.20	-10.20	1.0		9223464271497592.00	0	0	0	0
P1	15	8848.6	0	0	0.4978	1120.3							1120.30	1120.30	9223372036854776.00	> NG	-99.999	-10.20	-10.20	1.0		9223464271497592.00	0	0	0	0
P2	45	7683.7	387.3	0.0019	0.4997	1120.3	8.01	0.54					1128.31	1120.84	9223372036854776.00	> NG	-99.999	-10.25	-10.24	1.0	0.01	9223464271497592.00	0.484	0.033	0.081	0.005
P3	90	4501.0	3570.0	0.0175	0.5153	1120.3	70.53	8.26	136.54	27.99	86.01	63.67	1299.37	1042.54	9223372036854776.00	> NG	-99.999	-10.97	-10.59	1.0	0.38	9223464271497592.00	4.26	0.499	0.71	0.083	Column Attached Equator Plate
	135	1318.3	6752.7	0.0331	0.5309	1120.3	66.83	82.21					1187.12	1202.50	9223372036854776.00	> NG	-99.999	-10.95	-10.94	1.0	0.01	9223464271497592.00	4.036	4.965	0.673	0.828
P4	165	153.4	7917.6	0.0388	0.5366	1120.3	86.52	88.22					1206.82	1208.52	9223372036854776.00	> NG	-99.999	-11.08	-11.07	1.0	0.01	9223464271497592.00	5.226	5.329	0.871	0.888
P5	180	0	8071.0	0.0396	0.5374	1120.3	89.06	89.06					1209.36	1209.36	9223372036854776.00	> NG	-99.999	-11.09	-11.09	1.0		9223464271497592.00	5.379	5.379	0.897	0.897

S-Tank Engineering	Spherical Tank Calculation [10 / ??? ]				Page	[$CP] / [$TP]
					[AAA1]	[AAA2]
	Doc. No. : AAA3				Rev. No.	[AAA4]

SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition
　　D=9000 (cm), Syt=-99.999 MPa, MAWP=0.64714 (MPa), HT_UPPCOL = 20200.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)
　　　　Membrane Stres(By Roark Formula) Nθ=165.487 (N-mm), Nφ=33.097 (N-mm)

No	Description	Symbol	Value	SI Unit	Value	Metric Unit
1	Design Data :
2	D = Tank In-Diameter	D =	9000	mm	900.0	cm
3	R = Inside Radius in Corroded Condition	R =	4500	mm	450.0	cm
4	L = Hydrostatic-test Water Level	L =	9000	mm	900.0	cm
5	CA = Corrosion Allowance	CA =	0.0	mm	0	cm
6	Wt = Total Weight at Operating Condition	Wt =	3,449,387	N	351739.5	Kg
7	S = Allowable Stress for the Design Condition SA553-TYPE1, Sd = -99.999MPa	S =	-99.999	MPa	-1019.706	Kg/cm²
8	P = Design internal GAS Pressure	P =	0.498	MPa	5.076	Kg/cm²
9	SG = Design Specific Gravity	SG =	1.0		1
10	γ = Liquid Density	γ =	9.80665E-6	N/mm³	1000.0	Kg/m³
11	d = Outsdie diameter of Column	d =	406.4	mm	40.64	cm
12	N = Number of Support Column	N =	5.0	columns	5	columns
13	Δ = Angle of equator line to column top point	Δ =	0.0	degree	0	radians
14	φ = Angle of upper column from top to base	φ =	26.67242	degree	0.46552	radians
15	β = Angle of Liquid Level, β=Acos[(L+CA-R)/R]	β =	0.0	degree	0	radians
16	C1 = cos(Δ + φ/2) / cos(11)	C1 =	0.9912453		0.9912453
17	C2 = Factor	C2 =	1.0000000		1.0000000
18	C3 = { sin(Δ+φ ) - sin(Δ) } / sin(22)	C3 =	1.1982941		1.1982941
19	C4 = sin(Δ+φ ) + sin(Δ)	C4 =	0.4488889		0.4488889
20	C5 = 22 / φ	C5 =	0.8248221		0.8248221
21	C6 = sin(Δ+φ) + sin(Δ)	C6 =	0.4488889		0.4488889
22	Calculation Result :
23	PM = P×R/2	PM =	1120.05	N-mm	11.421	Kg-cm
24	Nθ = γR²/6 × [6×cosβ-6×cosθ-3×cosβ×cos²θ+4×cos³θ-cos³β)/(1-cos²θ)]	Nθ =	165.487	N-mm	1.687	Kg-cm
25	Nφ = γR²/6 × [( cos³β - 3×cos²θ×cosβ + 2×cos³θ) / ( 1-cos²θ)]	Nφ =	33.097	N-mm	0.337	Kg-cm
26	ΣNθ = Max. Latitude Membrane Force 　　ΣNθ = Nθ + PM + VB - HB	ΣNθ =	1513.0	N/mm	1542.831	Kg/cm
27	ΣNφ = Max. Meridional Membrane Force 　　ΣNφ = Nφ + PM - IP	ΣNφ =	972.02	N/mm	991.185	Kg/cm
28	Equator plate thk by Internal Pressure (by ASME Rules)	tASME =	-13.18	mm	-1.318	cm
29	t(Point A) = Min. required thickness at point at A 　tReq = √[ΣNθ²＋ ΣNφ² － ( ΣNθ x ΣNφ ) ＋ 3·τxy²] S ＋ CA	tReq =	-13.48	mm	-1.348	cm
30	Effective equivalent stress(Von-Mises), σeq < S then OK 　σeq = √[ΣNθ²＋ ΣNφ²－ ( ΣNθ x ΣNφ ) ＋ 3·τxy²] (tu － CA)	σeq =	1348.123	MPa	13747.029	Kg/cm²
31	Calculation Result :
32	Mo = Wt R cos(11) / N x { N / (2π)- 1 / (2 x Tan(π/N) ) }	Mo =	327,851,858	N-mm	3343.159×103	Kg-cm
33	ΔMo = 3 Wt R / 4π × [ 0.2616 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 0.88196.4 × C5/N - 1 ) / C5 ]	ΔMo =	104,823,050	N-mm	1068.898×103	Kg-cm
34	Mc = Wt R cos(11) / N x { 1 / 2 × sin(π/N)) - N / (2π) ) }	Mc =	167,229,978	N-mm	1705.271×103	Kg-cm
35	ΔMc = 3 Wt R / 4π × [-0.5232 × ( 1+0.88196.4 × C5/N) / N 　　+ 0.02804 × ( 1 - 0.88196.4 × C5/N ) / C5 ]	ΔMc =	43,250,235	N-mm	441.03×103	Kg-cm
36	VB : Membrance Force resulting from longitudinal bending moment 　VB = Mvs / Za × t	VB =	285.771	N/mm	291.405	Kg/cm
37	Mvs = Mo × C1 - ΔMo × C3	Mvs =	199,372,753	N-mm	2033.036×103	Kg-cm
38	Mvm = Mc × C1 - ΔMc × C3	Mvm =	113,939,420	N-mm	1161.859×103	Kg-cm
39	Za = IH / LA × t	Za =	-1.046498447E7	mm³	-10.465×103	cm³
40	IH = R³ × [ VI x sin( φ/2)² + HI x cos(φ/2)² ]	IH =	717,649,510	mm³	717.65×103	cm³
41	VI = φ / 2 + ( sinφ/2 × cosφ/2 ) - [ 4 x sin(Δ/2)² / φ ]	VI =	3.013E-5		3.013E-5
42	HI = φ / 2 - ( sinφ/2 × cosφ/2 )	HI =	8.316317E-3		8.316317E-3
43	LA = { R×sinφ/2×sinφ/2 } / ( φ/2 ) )	LA =	1028.644	mm	102.864	cm
44	HB : Membrance Force resulting from latitude bending moment 　HB = Mks / Zv	HB =	58.308	N/mm	59.458	Kg/cm
45	Mks = Mo x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mks =	15,565,452	N-mm	158.723×103	Kg-cm
46	Mkm = Mc x ( 18 / 4π ) × ( d / R ) × C1 × C5 × C6	Mkm =	7,939,593	N-mm	80961.314	Kg-cm
47	Zv = IV / Max(KA, KB)	Zv =	266,951	mm³	2669.507	cm²
48	IV = R³ × [ VI × cos( φ/2)² + HI × sin( φ/2)² ]	IV =	42,920,507	mm³	42.921×103	cm³
49	KA = R × [ 1 - cosφ/2 × sinφ/2 / (φ/2) ]	KA =	160.781	mm	16.078	cm
50	KB = R × [ cosφ/2 × sinφ/2 / (φ/2) - cosφ ]	KB =	318.075	mm	31.807	cm
51	IP : Membrance Force resulting from shear stress 　IP = 9×Wt / ( 2πN·R ) × C5	IP =	181.127	N/mm	184.698	Kg/cm
52	τxy : Shear Force, τxy = ( S' - P' ) / D'	τxy =	134.301	N/mm	136.949	Kg/cm
53	S' = Wt/N×[ 1 - ( 18/(4π)·d/R·C5·{cos(Δ) + cos(φ)} ) ]	S' =	550,491	N	56134.4	Kg
54	P' = d/R×Wt×[ 3/(4π)×{cos(Δ) - cos(Δ+φ) } ]	P' =	7913.831	N	807.0	Kg
55	D' = 2×R×[sin(Δ+φ) - sinΔ](용접접촉부 길이)	D' =	4040.0	mm	404.0	cm

piDeg=[26.6724185367116] piRad=[0.4655215229355854] SPH_IHI_EQPL_SHEAR.jsp SPH_IHI_EQPL_SHEAR()
1.2 At Hydrostatic-Test Condition Equator Plate(A Point at 90 deg) Stress :
D=9000 (cm), Syt=-99.999 MPa, MAWP=0.64714 (MPa), HT_UPPCOL = 20200.0 (mm), deg_22 = 22.0 (deg), cos11 = 0.9816272 (rad)

각도 Data						최대 변형에너지 Theory 이론에 의한 검증 by, Effective equivalent Stress(Von-Mises)												ASME DESIN RULE 에 의한 두께 와 최대변형에너지 Theory(Von-Mises Stress) 에 의한 두께 계산의 평가					Nθ, Nφ 계산상수 Coeif.
Segment Angle		Hmm	Hd Liquid Depth	Static Head Ps	Total Pressure Pt=Pg+Ps	PM = P*R/2	Nθ	Nφ	VB	HB	IP	τxy	ΣNθ	ΣNφ	σeq	평가	Sd	A)Shear tReq	B)ASME tReq	C)tu= Max(A,B)	A - B 두께차이	Design Margin (%)	Nθ coef.	Nφ coef.	Nθ coef. / 6	Nφ coef. / 6
No	deg.	mm	mm	MPa	MPa	N/mm						N/mm	N/mm	N/mm	MPa	< OK!	MPa	mm	mm	mm	mm	%
	0	9000.0	0	0	0.4978	1120.05							1120.05	1120.05	1120.05	> NG	-99.999	-11.20	-11.20	1.0		1220.06	0	0	0	0
P1	15	8846.7	153.3	0.0015	0.4993	1120.05	5.08	1.68					1125.13	1121.73	1123.43	> NG	-99.999	-11.23	-11.23	1.0		1223.45	0.154	0.051	0.026	0.008
P2	45	7682.0	1318.0	0.0129	0.5107	1120.05	44.45	13.71					1164.50	1133.76	1149.44	> NG	-99.999	-11.49	-11.49	1.0		1249.45	1.343	0.414	0.224	0.069
P3	90	4500.0	4500.0	0.0441	0.5419	1120.05	165.49	33.10	285.77	58.31	181.13	134.30	1513.00	972.02	1348.12	> NG	-99.999	-13.48	-12.19	1.0	1.29	1448.14	5	1	0.833	0.167	Column Attached Equator Plate
	135	1318.0	7682.0	0.0753	0.5731	1120.05	154.13	184.88					1274.18	1304.93	1289.83	> NG	-99.999	-12.90	-12.89	1.0	0.01	1389.84	4.657	5.586	0.776	0.931
P4	165	153.3	8846.7	0.0868	0.5846	1120.05	193.50	196.90					1313.55	1316.95	1315.25	> NG	-99.999	-13.15	-13.14	1.0	0.01	1415.27	5.846	5.949	0.974	0.992
P5	180	0	9000.0	0.0883	0.5861	1120.05	198.58	198.58					1318.63	1318.63	1318.63	> NG	-99.999	-13.19	-13.18	1.0	0.01	1418.64	6	6	1	1

], CalcRpt[i][2]=[SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT()

● WEIGHT SUMMARY SPH_IHI_SHEAR.jsp CALC_SPH_COL_BRA_ACCY_WEIGHT() BRACE AXIAL-FORCE DESIGN DATA
MRA(sWt[tid][20][1])= 0
MRA(sWt[tid][20][2])= 0
MRA(sWt[tid][20][3])= 16
MRA(sWt[tid][20][4])= 0
MRA(sWt[tid][20][5])= 23735.108
MRA(sWt[tid][20][6])= 0
MRA(sWt[tid][20][7])= 0
MRA(sWt[tid][20][8])= 0
MRA(sWt[tid][20][9])= 9000
MRA(sWt[tid][20][10])= 274.871
UPPER COLUMN : cbMatl[tid][0] = null
LOWER COLUMN : cbMatl[tid][1] = null
BRACE cbMatl[tid][2] = null

1. gCol[tid][1] =	Column Q'ty	Nc =	5	Columns
2. gCol[tid][2] =	Column OD	OD =	406.4	mm
3. gCol[tid][3] =	Column thk	thk =	6.35	mm
4. gCol[tid][4] =	Tank Height	Htank =	7500	mm
5. gCol[tid][5] =	Upper Column Height	UCHT =	2020	mm
6. gCol[tid][6] =	Lower Column Height	LCHT =	5480	mm
7. gCol[tid][7] =	Column P.C.D	PCD =	8780	mm
8. gCol[tid][8] =	Brace Angle	BRang =	43.2815	deg.
9. gCol[tid][9] =	Brace Angle of Tank center to Brace Center	BRang_CTR =	12.6945	deg
10. gCol[tid][10] =	Column CA	CA =	0	mm
11. gCol[tid][11] =	Brace OD	BR_OD =	0	mm
12. gCol[tid][12] =	Brace Thk	BR_Thk =	0	mm
13. gCol[tid][13] =	Brace CA	BR_CA =	0	mm

WEIGHT SUMMARY
A) TANK 제작비/자재비/도장비/외주비 부문

F0	F1	F2	F3	F4	F5	F6	F7	F8	F9	F10
No.	Description	Main Material	Thk. and Size	Unit	QTY	Net Wt kg	Gross Wt kg	자재비	제작비	No
1	SHELL PLATE	SA553-TYPE1	t11 ~ 0	SHT	16	23.735	28.957	000,000	000,000	1
2	UPPER COLUMN(PLATE) (재고확인)	null	t0, t8×1577×2020	SHT	5	1.044	1.148	000,000	000,000	2
3	LOWER COLUMN (PIPE)	null	Ø406.4×6.35t × 5480L	PCS	5	1.716	1.716	000,000	000,000	3
4	BRACE ( PIPE, θ= 43.2815 deg.)	null	Ø0×0t × 7528L	PCS	10			000,000	000,000	4
5	COLUMN ACC'Y (PLATE)	A36 OR SS400	-	LOT				000,000	000,000	5
6	BASE PLATE & ANCHOR BOLT (NO SITE PWHT = NO SLIDEING PLATE)	By SPEC.	SEE. Bellow TABLE 4)	LOT				000,000	000,000	6
7	NOZZLE & MANHOLE(DIP. PIPE)	Forging	Assumed Qty : 19	19				000,000	000,000	7
8	ROOF PLATFORM & STRINGER	CLIP:SA553-TYPE1(OR CS)	PLATE & SHAPE	LOT				000,000	000,000	8
9	WATER SPRAY (Only Proposal)	By SPEC.	PIPE & ACC'Y	15				000,000	000,000	9
10	INTERNAL LADDER (Only Proposal)	SA553-TYPE1	PLATE & SHAPE	LOT				000,000	000,000	10
11	INSULATION (Only Proposal)	By SPEC.	-	LOT				000,000	000,000	11
12	GRAND TOTAL				36	26.496	31.822	000,000	000,000	12

]CODE_CALC() 111 Tank Qty = iMax = [12]
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [5] mySum = [90.0] tUsed = [44.5]mm
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [5] mySum = [90.0] tUsed = [40.0]mm
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [5] mySum = [90.0] tUsed = [40.0]mm
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [5] mySum = [90.0] tUsed = [40.0]mm
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [6] mySum = [90.0] tUsed = [83.5]mm
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [3] mySum = [90.0] tUsed = [40.5]mm
CODE_CALC() 여기에 들어 왔는지 확인 필요 m = [2] j = [5] mySum = [90.0] tUsed = [22.5]mm
]

---

sph.uAry.length = [2] uAry[0].length = [5]
sph.bAry.length = [38] bAry[0].length = [15]
sph.cAry.length = [36] cAry[0].length = [12]
sph.dAry.length = [36] dAry[0].length = [12]
tReq=[

tReq =

P·R 2·S·E － 0.2·P

＋ CA

Div.1 tReq =

PR 2SE － 0.2P

＋ CA

Div.1 tReq =

P·R 2·S·E － 0.2·P

＋ CA

Div.1　 tReq =

P·Rc 2·S·E － 0.2·P

＋ CA

Div.2　 tReq = R · [ EXP(

0.5 · P 　  S · E

) － 1 ] ＋ CA

시작시간 = [2025-04-03 10:26:30.0207]
종료시간 = [2025-04-03 10:26:30.0427]

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