2. Design Calculation Report for Surge Vessel 28 09 17

MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 Project Name: COMMON COOLING WATER SYSTEM CAPACITY ENHANCEMENT MICP6/2015 Client: MAJIS INDUSTRIAL SERVICES SAOC Equipment description 15cuM SURGE VESSEL Manufacturer’s job no. - Manufacturer’s drawing no. MISS-GA-ST-001 REV 0 Document Title: DESIGN CALCULATION FOR SURGE VESSEL Document Number: - Manufacturer Serial No: UES-17122-MDC-001 Rev # 0 Date of Issue 27.09.17 Status Description Issued for Approval Originator MS Checker NS Approver NS MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 TABLE OF CONTENTS DESIGN DATA ………………………………………………………………………………………………..III APPLICABLE STANDARDS, SOFTWARE & REFERENCE DOCUMENTS……………………… …..IV APPLICABLE LOADING AS PER UG-22 ………………………………………………………….… …..V SUMMARY OF MATERIALS AND ALLOWABLE STRESSES ………………………………….………VI INSPECTION OPENING AS PER UG- 46(f) & DRAIN AS PER UG25 (f)….…………………..…..VII IMPACT TESTING REQUIREMENTS ……………………………………………………………….……VII PWHT REQUIREMENTS …………………………………………………………………………………..VIII RT REQUIREMENT AS PER UW-11(a)(5)(b) OF ASME SEC VIII DIV 1 ………… …….……………IX APPENDIX I – PV ELITE CALCULATION UES-17122-MDC-001 Page:2 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 DESIGN DATA Description Unit Code of Construction ASME SEC VIII DIV 1 EDITION 2015 Design Internal Pressure MPa 0.8 UG-21 Design External Pressure MPa NA UG-21 Design Temperature (Internal) 0 90 UG-20 0 MDMT (user defined) MAWP (Hot & Corroded) Hydro test Pressure (Vertical) Operating Pressure (Internal) C C MPa MPa MPa Operating Medium Values Remarks 0 @0.8 MPa UG-20 0 0.8 @ 90 C UG-98 UG 99(b) END NOTE 36 1.04 0.6 / WATER Specific Gravity (S.G) 1 Capacity 3 M 15 Corrosion allowance mm 1.0 Joint Efficiency Shell LS/CS 1.0 UW-12 Dish ends LS/CS 1.0 UW-12 Nozzle/Man way 1.0 UW-12 RT1 UG116(e)(1) Shell/Head 1.0 (AS PER UW12)/1.0 (AS PER UW12) UW-12 Head to Shell 1.0 (AS PER UW12)/1.0 (AS PER UW12) UW-12 Radiography PWHT No as per UW-2,UCS-56,UCS-79 Impact testing Exempted as per UG20(f), UCS 66(a)&Fig UCS 66(Note C) Special service No UW-2 Inspection opening PROVIDED AS PER UG 46 (f)(3) UG 46 (f) (3) Insulation No Fireproofing No Wind Load ASCE 2010, 120 KMPH, IF 1.0 Seismic Load UBC 1997, ZONE 1, IF 1.25 Vessel ID 2300mm Tan To Tan Length NOTE: PFHT -Not Applicable 3100mm 1 MPa=1N/mm2 As per Code Appendix GG for Soft Conversion PSI X 0.06894757 =BAR, Hence PSI = BAR/0.06894757 PSI X 0.0068948 =MPa, Hence PSI = MPa /0.0068948 MPa=BAR X0.068948/ 0.0068948 =BAR X 10= 10 BAR, Hence 1 MPa =10 BAR UES-17122-MDC-001 Page:3 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 APPLICABLE STANDARDS, SOFTWARE & REFERENCE DOCUMENTS SL NO DESCRIPTION 1 2 3 4 ASME Boiler and Pressure Vessel Code Section VIII Division 1 2015 Ed ASME Boiler and Pressure Vessel Code Section II Part ’A’ 2015 Ed (metric) ASME Boiler and Pressure Vessel Code Section II Part ’D’ 2015 Ed (metric) Wind Loads Calculation –ASCE-2010 120 km/hr 5 Earth Quake Calculation- UBC 1997 Zone 1 6 7 8 9 10 Seamless Carbon Steel Pipe- ASME B 36.10 – 2015 Coupling as per B16.11 Ed. 2016 Factory Made Wrought Butt welding Fittings ASME B16.9 2012 Flanges & Flanged Fittings (Up to DN 600) B 16.5 ED 2013 Design Software- PV Elite –Version 2017 UES-17122-MDC-001 Page:4 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 APPLICABLE LOADING AS PER UG-22 SL.NO 1 UG-22 SUB CLAUSE a 2 b c 3 d(1) 4 DESCRIPTION Internal design pressure External design pressure Weight of vessel and its normal contents under operating or test conditions, including additional head due to static head of medium Superimposed static reactions from weight of attached equipment , such as motors, machinery, other vessels piping, linings and insulation Attachment of internals, vessel APPLICABILITY Yes No Yes No No d(2) Supports, such as lugs, rings, skirts, saddles and legs. Yes e Cyclic and dynamic reactions due to pressure or thermal variations, or equipment mounted on a vessel, and, mechanical loadings. No 6 f 7 g Wind reaction Seismic reaction Snow reaction Impact reactions such as those due to fluid shocks Yes Yes No No 8 h Temperature gradients and differential thermal expansion No 9 i Abnormal pressures such as those caused by deflagration No 10 j Test pressure and coincident static head Acting during the test Yes 5 UES-17122-MDC-001 Page:5 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 SUMMARY OF MATERIALS AND ALLOWABLE STRESSES Allowable stress at design temp Sd (N/mm2) Allowable stress at hydrotest temp St (N/mm2) Stress ratio St/sd Component Material Shell SA 516 Gr. 70 138 138 1 Dished Head SA 516 Gr. 70 138 138 1 Couplings SA 105 138 138 1 Wear Pad SA 516 Gr 70 138 138 1 Nozzle neck SA106 Gr. B 118 118 1 Flanges SA 105 138 138 1 Governing stress ratio to be used for hydro test calculation = 1.0 UES-17122-MDC-001 Page:6 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 INSPECTION OPENING AS PER UG- 46(f) & DRAIN AS PER UG25 (f) As per Para UG-46 Sub clause(f) (I.D = 2300 mm) has been provided with 1 No. of DN 600 threaded Man Hole as Inspection opening 1) Vessel is less than 18in (450mm) No 2) Vessel between 18 in and 36 in No 3) Vessel more than 36 in Yes 3) Is there a manhole Yes 4) Is there 2 No’s inspection opening of at least DN 50 No So inspection opening as per UG-46 have met The vessel is provided with drain nozzle (N2) 2 inch., the requirement as per UG-25(f) is met. . UES-17122-MDC-001 Page:7 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 IMPACT TESTING REQUIREMENT MDMT OF VESSEL = 0 DEG. C IMPACT TEST REQUIREMENTS AS PER ASME SEC. VIII DIV.1 , UG 20 ( f ) MEETING REQUIREMENTs P No.1,Gr.No.1 & 2 DESCRIPTION P-No of the material used 1 1(a) 1(b) Thk. Of Material used which is listed in Curve A < 13 mm Thk. Of Material used listed in Curve B,C,D < 25 mm N.A. Yes 2 Completed vessel shall be Hydrotested as per UG 99(b )or ( c) Yes 3 Design Temp. < 345 deg. C MDMT >= - 29 deg. C Yes Yes 4 Thermal or Mechanical shock loadings are not controlling Yes design requirements. 5 Cyclic loadings are not controlling Yes design requirements. CONCLUSION : As per UG 20(f), all materials of this vessel are exempted for impact testing. For further exemption refer to UCS 66 (Below). SR NO COMPONENTS MATERIAL APPL CUR VE GOVERNING Min THK (mm) MDMT TEMP (Deg C) EXEMPTED FROM IMPACT TEST 1. BOLTING SA 193 GR B7 / SA 194 GR 2H N.A. - -48 YES AS PER Fig UCS-66(Note c) 2. FLANGE SA 105M N.A. - -29 YES AS PER UCS-66(c) Notes : Plate material (SA 516M Gr 485(Gr 70), Pipe material (SA 106M Gr B) , & Forging material (SA 105M) are exempted from Impact testing as per UG-20 (f).  Std Flanges as per ASME B 16.5 are exempted from Impact testing till -29 deg.C as per UCS66(c). Accordingly Impact testing as per UG-84 is not required for any component of this equipment. Detailed calculation is provided in MDMT summary of PV Elite Calculation UES-17122-MDC-001 Page:8 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 PWHT REQUIREMENTS A) SPECIAL SERVICE Vessel is not under any special / lethal service, hence PWHT requirements is not applicable as per UW-2, for further requirements/ exemptions, refer check as per UCS- 79 & UCS -56 below: B) HEAT TREATMENT AFTER FORMING NECK Heat treatment is not required after forming. C) PWHT REQUIREMENT CHECK AS PER UCS - 56 Vessel material qualifies in P- no 1 Gr.2. materials. As per note 2 (b) of table UCS-56 for p no 1 gr.2 material, PWHT is not mandatory up to welded thickness of 32mm without the requirements of any additional pre heating. As all welded thickness of this vessel is not more than 32 mm, as per ucs-56, post weld heat treatment is not required for the vessel. Hence PWHT is not required for the vessel. UES-17122-MDC-001 Page:9 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 RT Requirement as per UW-11 of ASME sec VIII Div 1 UW -11 SUB CL (a) 1 2 DESCRIPTION Full radiography requirements Lethal service application as per UW – 2 (a) Butt welds with least nominal thickness exceeding 1.25” (32mm) as per ucs-57 APPLICABILITY FULL RAD REQUIRED No No No No No No 3 Unfired steam boiler service with design pressure greater than 50 psi All butt welds in nozzles, communicating chambers etc attached to vessel section heads that required to be fully radiographed under (1) or (3) above Are all category a & d butt welds in shell and head designed based on joint efficiency as per UW 12 (a)? 4 5 5(a) 5(b) 6 7 In which case all category a & b welds connecting shell shall be of type 1 or 2 as per table uw12 Any category b & c butt welds (excluding category b &c welds in nozzles that neither exceeds 10 nps nor 11/8” wall thickness ) which intersect category a. Butt weld in the shell/ head or connecting seamless shell/ head which are not required to be fully radiographed as per point 1,2,3 shall as a minimum be spot radiographed Are butt welds joined by electro-slag welding/ electro- gas welding with any single UW-11(a)5(b) –Spot RT No No No -- No No (for type 1) (for type 1) No No No No No No Weld Joint Efficiency taken from Table-UW-12 Column-(a) Conclusion: Spot Radiography the whole vessel ( Category : RT 1) UES-17122-MDC-001 Page:10 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 COUPLING PIPE THICKNESS CALCULATION: (Ref:UG-31,UG-44) Coupling size : 2 inch 3000#, as per B 16.11 pipe schedule to be considered 160 having thickness 8.74mm TPI for 2 inch 11.5, 20/11.5 = 1.73 mm So the considered thickness of 2 inch pipe = 8.74*0.875 -1.73= 5.91mm Coupling size : 1 inch 6000#, as per B 16.11 pipe schedule to be considered XXS having thickness 9.09 mm TPI for 1 inch 11.5, 20/11.5 = 1.73 mm So the considered thickness of 1 inch pipe = 9.06*0.875 -1.73= 6.19 mm Coupling size : 1/2 inch 6000#, as per B 16.11 pipe schedule to be considered XXS having thickness 7.47 mm TPI for 1/2 inch 14, 20/14 = 1.42 mm So the considered thickness of 1 inch pipe = 7.47*0.875 -1.42= 5.11 mm The above thickness is used in PV elite as nozzle thickness. UES-17122-MDC-001 Page:11 of 96 MECHANICAL DESIGN CALCULATION 15cuM SURGE VESSEL JOB No.: 17122 Document No.: UES‐17122‐MDC‐001 Rev. 0 Date: 27.09.17 APPENDIX I - PV ELITE CALCULATION UES-17122-MDC-001 Page:12 of 96 Table of Contents Cover Sheet .............................................................................................................................................. 2 Title Page................................................................................................................................................. 3 Warnings and Errors:......................................................................................................................... 4 Input Echo: .............................................................................................................................................. 5 XY Coordinate Calculations: ...................................................................................................... 10 Internal Pressure Calculations: ............................................................................................ 11 External Pressure Calculations: ............................................................................................ 16 Element and Detail Weights: ...................................................................................................... 18 Nozzle Flange MAWP: ......................................................................................................................... 20 Natural Frequency Calculation:............................................................................................... 21 Wind Load Calculation: .................................................................................................................. 22 Earthquake Load Calculation: ................................................................................................... 25 Wind/Earthquake Shear, Bending: ............................................................................................ 27 Wind Deflection: ................................................................................................................................ 28 Longitudinal Stress Constants:............................................................................................... 29 Longitudinal Allowable Stresses: .......................................................................................... 30 Longitudinal Stresses due to: ................................................................................................. 31 Stress due to Combined Loads: ................................................................................................. 33 Center of Gravity Calculation:............................................................................................... 37 Leg Check, (Operating Case): ................................................................................................... 38 Leg Check, (Filled w/Water): ................................................................................................... 40 Nozzle Summary:................................................................................................................................... 42 Nozzle Calcs.: N1_16_Inlet ...................................................................................................... 43 Nozzle Calcs.: N2_2_Drain ........................................................................................................ 49 Nozzle Calcs.: N3_1_Level S G............................................................................................... 52 Nozzle Calcs.: N4_1_Level S G............................................................................................... 55 Nozzle Calcs.: M_24_Man Hole ................................................................................................. 58 Nozzle Calcs.: N5_1_Air Relief ............................................................................................ 63 Nozzle Calcs.: N6_2_Spare ........................................................................................................ 66 Nozzle Calcs.: N7_1/2_P G ........................................................................................................ 69 Nozzle Calcs.: N8_1_Air Inlet............................................................................................... 72 Nozzle Calcs.: N9_2_Level Prob ............................................................................................ 75 Nozzle Schedule: ................................................................................................................................ 78 MDMT Summary: ....................................................................................................................................... 80 Vessel Design Summary: .................................................................................................................. 81 UES-17122-MDC-001 Page:13 of 96 Cover Page 2 DESIGN CALCULATION In Accordance with ASME Section VIII Division 1 ASME Code Version : 2015 Analysis Performed by : UNIVERSAL ENGINEERING SERVICES LLC. Job File : D:\PROJECTS\17122_VELOSI_SURGE VESSEL_UES\PV ELI Date of Analysis : Sep 27,2017 5:24pm PV Elite 2017, January 2017 UES-17122-MDC-001 Page:14 of 96 Title Page 3 Note: PV Elite performs all calculations internally in Imperial Units to remain compliant with the ASME Code and any built in assumptions in the ASME Code formulas. The finalized results are reflected to show the user's set of selected units. UES-17122-MDC-001 Page:15 of 96 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Warnings and Errors: Step: 0 5:24pm Sep 27,2017 Class From To : Basic Element Checks. ========================================================================== Class From To: Check of Additional Element Data ========================================================================== There were no geometry errors or warnings. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:16 of 96 4 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Input Echo: Step: 1 5:24pm Sep 27,2017 PV Elite Vessel Analysis Program: Input Data Design Internal Pressure (for Hydrotest) Design Internal Temperature Type of Hydrotest Hydrotest Position Projection of Nozzle from Vessel Top Projection of Nozzle from Vessel Bottom Minimum Design Metal Temperature Type of Construction Special Service Degree of Radiography Use Higher Longitudinal Stresses (Flag) Select t for Internal Pressure (Flag) Select t for External Pressure (Flag) Select t for Axial Stress (Flag) Select Location for Stiff. Rings (Flag) Consider Vortex Shedding Perform a Corroded Hydrotest Is this a Heat Exchanger User Defined Hydro. Press. (Used if > 0) User defined MAWP User defined MAPnc Load Load Load Load Load Load Load Load Load Load Load Load Load Load Load Load Load Load Load Case Case Case Case Case Case Case Case Case Case Case Case Case Case Case Case Case Case Case 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 8 90 UG-99(b) Note [36] Vertical 0 0 0 Welded Air/Water/Steam RT 1 Y N N N N N N No 11 0 0 mm. mm. °C bars bars bars NP+EW+WI+FW+BW NP+EW+EE+FS+BS NP+OW+WI+FW+BW NP+OW+EQ+FS+BS NP+HW+HI NP+HW+HE IP+OW+WI+FW+BW IP+OW+EQ+FS+BS EP+OW+WI+FW+BW EP+OW+EQ+FS+BS HP+HW+HI HP+HW+HE IP+WE+EW IP+WF+CW IP+VO+OW IP+VE+EW NP+VO+OW FS+BS+IP+OW FS+BS+EP+OW Wind Design Code Wind Load Reduction Scale Factor Basic Wind Speed [V] Surface Roughness Category Importance Factor Type of Surface Base Elevation Percent Wind for Hydrotest Using User defined Wind Press. Vs Elev. Height of Hill or Escarpment H or Hh Distance Upwind of Crest Lh Distance from Crest to the Vessel x Type of Terrain ( Hill, Escarpment ) Damping Factor (Beta) for Wind (Ope) Damping Factor (Beta) for Wind (Empty) Damping Factor (Beta) for Wind (Filled) ASCE-7 2010 0.600 120 C: Open Terrain 1.0 Moderately Smooth 0 33.0 N 0 0 0 Flat 0.0100 0.0000 0.0000 Seismic Design Code UBC Seismic Zone (1=1,2=2a,3=2b,4=3,5=4) UBC Importance Factor UBC Seismic Coefficient Ca UBC 1997 1 1.250 0.360 UES-17122-MDC-001 bars °C Km/hr mm. mm. mm. mm. Page:17 of 96 5 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Input Echo: Step: 1 5:24pm Sep 27,2017 UBC Seismic Coefficient Cv UBC Seismic Coefficient Nv UBC Horizontal Force Factor Apply Allowables per paragraph 1612.3.2 0.840 1.000 2.000 No Design Pressure + Static Head Consider MAP New and Cold in Noz. Design Consider External Loads for Nozzle Des. Use ASME VIII-1 Appendix 1-9 Material Database Year Y N Y N Current w/Addenda or Code Year Configuration Directives: Do not use Nozzle MDMT Interpretation VIII-1 01-37 Use Table G instead of exact equation for "A" Shell Head Joints are Tapered Compute "K" in corroded condition Use Code Case 2286 Use the MAWP to compute the MDMT Using Metric Material Databases, ASME II D Calculate B31.3 type stress for Nozzles with Loads Reduce the MDMT due to lower membrane stress No Yes Yes Yes No Yes No Yes Yes Complete Listing of Vessel Elements and Details: Element From Node Element To Node Element Type Description Distance "FROM" to "TO" Inside Diameter Element Thickness Internal Corrosion Allowance Nominal Thickness External Corrosion Allowance Design Internal Pressure Design Temperature Internal Pressure Design External Pressure Design Temperature External Pressure Effective Diameter Multiplier Material Name Allowable Stress, Ambient Allowable Stress, Operating Allowable Stress, Hydrotest Material Density P Number Thickness Yield Stress, Operating UCS-66 Chart Curve Designation External Pressure Chart Name UNS Number Product Form Efficiency, Longitudinal Seam Efficiency, Circumferential Seam Elliptical Head Factor 10 20 Elliptical BTM Head 50 mm. 2300 mm. 8.2 mm. 1 mm. 10 mm. 0 mm. 8 bars 90 °C 0 bars 0 °C 1.2 SA-516 70 137.9 N./mm² 137.9 N./mm² 179.27 N./mm² 0.00775 kg./cm³ 31.75 mm. 240.69 N./mm² B CS-2 K02700 Plate 1.0 1.0 2.0 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Height/Length of Liquid Liquid Density 10 Liquid LIQUID 10 -575 625 0.0009996 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist 10 Nozzle N1_16_Inlet 0 UES-17122-MDC-001 mm. mm. kg./cm³ mm. Page:18 of 96 6 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Input Echo: Step: 1 5:24pm Sep 27,2017 Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 16 XS 10 0.0 N 72.195 3E0 vR<=50 SA-106 B Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 10 Nozzle N2_2_Drain 574 3 None None 90.0 N 0.8294 None SA-105 in. Kgf mm. in. Kgf -------------------------------------------------------------------Element From Node Element To Node Element Type Description Distance "FROM" to "TO" Inside Diameter Element Thickness Internal Corrosion Allowance Nominal Thickness External Corrosion Allowance Design Internal Pressure Design Temperature Internal Pressure Design External Pressure Design Temperature External Pressure Effective Diameter Multiplier Material Name Efficiency, Longitudinal Seam Efficiency, Circumferential Seam 20 30 Cylinder Shell 3000 2300 8 1 8 0 8 90 0 0 1.2 SA-516 70 1.0 1.0 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Height/Length of Liquid Liquid Density 20 Liquid LQ2 0 3000 0.0009996 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 20 Nozzle N3_1_Level S G 150 2.25 None None 180.0 N 0.4608 None SA-105 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist 20 Nozzle N4_1_Level S G 2850 UES-17122-MDC-001 mm. mm. mm. mm. mm. mm. bars °C bars °C mm. mm. kg./cm³ mm. in. Kgf mm. Page:19 of 96 7 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Input Echo: Step: 1 5:24pm Sep 27,2017 Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 2.25 None None 180.0 N 0.4608 None SA-105 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 20 Nozzle M_24_Man Hole 650 24 None 150 90.0 Y 378.72 None SA-516 70 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Diameter at Leg Centerline Leg Orientation Number of Legs Section Identifier Length of Legs 20 Leg LEGS 300 2545.6 1 4 UC203X203X60 2117 in. Kgf mm. in. Kgf mm. mm. mm. -------------------------------------------------------------------Element From Node Element To Node Element Type Description Distance "FROM" to "TO" Inside Diameter Element Thickness Internal Corrosion Allowance Nominal Thickness External Corrosion Allowance Design Internal Pressure Design Temperature Internal Pressure Design External Pressure Design Temperature External Pressure Effective Diameter Multiplier Material Name Efficiency, Longitudinal Seam Efficiency, Circumferential Seam Elliptical Head Factor 30 40 Elliptical Top Head 50 mm. 2300 mm. 8.2 mm. 1 mm. 10 mm. 0 mm. 8 bars 90 °C 0 bars 0 °C 1.2 SA-516 70 1.0 1.0 2.0 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Height/Length of Liquid Liquid Density 30 Liquid LQ3 0 625 0.0009996 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule 30 Nozzle N5_1_Air Relief 0 2.25 None UES-17122-MDC-001 mm. mm. kg./cm³ mm. in. Page:20 of 96 8 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Input Echo: Step: 1 5:24pm Sep 27,2017 Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl None 0.0 N 0.4608 None SA-105 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 30 Nozzle N6_2_Spare 517 3 None None 180.0 N 0.8497 None SA-105 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 30 Nozzle N7_1/2_P G 517 1.5 None None 225.0 N 0.1888 None SA-105 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 30 Nozzle N8_1_Air Inlet 517 2.25 None None 270.0 N 0.4455 None SA-105 Element From Node Detail Type Detail ID Dist. from "FROM" Node / Offset dist Nozzle Diameter Nozzle Schedule Nozzle Class Layout Angle Blind Flange (Y/N) Weight of Nozzle ( Used if > 0 ) Grade of Attached Flange Nozzle Matl 30 Nozzle N9_2_Level Prob 517 3 None None 0.0 N 0.8497 None SA-105 Kgf mm. in. Kgf mm. in. Kgf mm. in. Kgf mm. in. Kgf PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:21 of 96 9 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF XY Coordinate Calculations: Step: 2 5:24pm Sep 27,2017 XY Coordinate Calculations: | | | | | | | To | X (Horiz.)| Y (Vert.) | DX (Horiz.)| DY (Vert.) | | | mm. | mm. | mm. | mm. | ---------------------------------------------------------------------BTM Head| ... | 50 | ... | 50 | Shell| ... | 3050 | ... | 3000 | Top Head| ... | 3100 | ... | 50 | ---------------------------------------------------------------------From PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:22 of 96 10 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Internal Pressure Calculations: Step: 3 5:24pm Sep 27,2017 Element Thickness, Pressure, Diameter and Allowable Stress : | | Int. Press | Nominal | Total Corr | Element | Allowable | | To | + Liq. Hd | Thickness | Allowance | Diameter | Stress(SE)| | | bars | mm. | mm. | mm. | N./mm² | ---------------------------------------------------------------------------------BTM Head| 8.4166 | 10 | 1 | 2300 | 137.9 | Shell| 8.3553 | 8 | 1 | 2300 | 137.9 | Top Head| 8.0613 | 10 | 1 | 2300 | 137.9 | ---------------------------------------------------------------------------------From Element Required Thickness and MAWP : | | Design | M.A.W.P. | M.A.P. | Minimum | Required | | To | Pressure | Corroded | New & Cold | Thickness | Thickness | | | bars | bars | bars | mm. | mm. | ---------------------------------------------------------------------------------BTM Head| 8 | 8.21373 | 9.82529 | 8.2 | 8.02158 | Shell| 8 | 8.00032 | 9.55261 | 8 | 7.99973 | Top Head| 8 | 8.57396 | 9.82529 | 8.2 | 7.72088 | ---------------------------------------------------------------------------------Minimum 8.000 9.553 From MAWP: 8.000 bars, limited by: Shell. Internal Pressure Calculation Results : ASME Code, Section VIII, Division 1, 2015 Elliptical Head From 10 To 20 SA-516 70 , UCS-66 Crv. B at 90 °C BTM Head Material UNS Number: K02700 Required Thickness due to Internal Pressure [tr]: = (P*D*Kcor)/(2*S*E-0.2*P) Appendix 1-4(c) = (8.417*2302.0002*0.999)/(2*137.9*1.0-0.2*8.417) = 7.0216 + 1.0000 = 8.0216 mm. Max. Allowable Working Pressure at given Thickness, corroded [MAWP]: Less Operating Hydrostatic Head Pressure of 0.417 bars = (2*S*E*t)/(Kcor*D+0.2*t) per Appendix 1-4 (c) = (2*137.9*1.0*7.2)/(0.999*2302.0002+0.2*7.2) = 8.630 - 0.417 = 8.214 bars Maximum Allowable Pressure, New and Cold [MAPNC]: = (2*S*E*t)/(K*D+0.2*t) per Appendix 1-4 (c) = (2*137.9*1.0*8.2)/(1.0*2300.0+0.2*8.2) = 9.825 bars Actual stress at given pressure and thickness, corroded [Sact]: = (P*(Kcor*D+0.2*t))/(2*E*t) = (8.417*(0.999*2302.0002+0.2*7.2))/(2*1.0*7.2) = 134.485 N./mm² Straight Flange Required Thickness: = (P*R)/(S*E-0.6*P) + c per UG-27 (c)(1) = (8.417*1151.0)/(137.9*1.0-0.6*8.417)+1.0 = 8.051 mm. Straight Flange Maximum Allowable Working Pressure: Less Operating Hydrostatic Head Pressure of 0.360 bars = (S*E*t)/(R+0.6*t) per UG-27 (c)(1) = (137.9 * 1.0 * 9.0)/(1151.0 + 0.6 * 9.0 ) UES-17122-MDC-001 Page:23 of 96 11 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Internal Pressure Calculations: Step: 3 5:24pm Sep 27,2017 = 10.732 - 0.360 = 10.372 bars Factor K, corroded condition [Kcor]: = ( 2 + ( Inside Diameter/( 2 * Inside Head Depth ))2)/6 = ( 2 + ( 2302.0/( 2 * 576.0 ))2)/6 = 0.998843 Percent Elong. per UCS-79, VIII-1-01-57 (75*tnom/Rf)*(1-Rf/Ro) 1.894 % MDMT Calculations in the Knuckle Portion: Govrn. thk, tg = 8.2, tr = 7.022, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.975, Temp. Reduction = 1 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -30 °C MDMT Calculations in the Head Straight Flange: Govrn. thk, tg = 10.0, tr = 7.051, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.783, Temp. Reduction = 12 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -41 °C Cylindrical Shell From 20 To 30 SA-516 70 , UCS-66 Crv. B at 90 °C Shell Material UNS Number: K02700 Required Thickness due to Internal Pressure [tr]: = (P*R)/(S*E-0.6*P) per UG-27 (c)(1) = (8.355*1151.0)/(137.9*1.0-0.6*8.355) = 6.9997 + 1.0000 = 7.9997 mm. Max. Allowable Working Pressure at given Thickness, corroded [MAWP]: Less Operating Hydrostatic Head Pressure of 0.355 bars = (S*E*t)/(R+0.6*t) per UG-27 (c)(1) = (137.9*1.0*7.0)/(1151.0+0.6*7.0) = 8.356 - 0.355 = 8.000 bars Maximum Allowable Pressure, New and Cold [MAPNC]: = (S*E*t)/(R+0.6*t) per UG-27 (c)(1) = (137.9*1.0*8.0)/(1150.0+0.6*8.0) = 9.553 bars Actual stress at given pressure and thickness, corroded [Sact]: = (P*(R+0.6*t))/(E*t) = (8.355*(1151.0+0.6*7.0))/(1.0*7.0) = 137.895 N./mm² % Elongation per Table UG-79-1 (50*tnom/Rf*(1-Rf/Ro)) 0.347 % Minimum Design Metal Temperature Results: Govrn. thk, tg = 8.0, tr = 7.0, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 1., Temp. Reduction = 0 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -29 °C Elliptical Head From 30 To 40 SA-516 70 , UCS-66 Crv. B at 90 °C Top Head UES-17122-MDC-001 Page:24 of 96 12 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Internal Pressure Calculations: Step: 3 5:24pm Sep 27,2017 Material UNS Number: K02700 Required Thickness due to Internal Pressure [tr]: = (P*D*Kcor)/(2*S*E-0.2*P) Appendix 1-4(c) = (8.056*2302.0002*0.999)/(2*137.9*1.0-0.2*8.056) = 6.7209 + 1.0000 = 7.7209 mm. Max. Allowable Working Pressure at given Thickness, corroded [MAWP]: Less Operating Hydrostatic Head Pressure of 0.056 bars = (2*S*E*t)/(Kcor*D+0.2*t) per Appendix 1-4 (c) = (2*137.9*1.0*7.2)/(0.999*2302.0002+0.2*7.2) = 8.630 - 0.056 = 8.574 bars Maximum Allowable Pressure, New and Cold [MAPNC]: = (2*S*E*t)/(K*D+0.2*t) per Appendix 1-4 (c) = (2*137.9*1.0*8.2)/(1.0*2300.0+0.2*8.2) = 9.825 bars Actual stress at given pressure and thickness, corroded [Sact]: = (P*(Kcor*D+0.2*t))/(2*E*t) = (8.056*(0.999*2302.0002+0.2*7.2))/(2*1.0*7.2) = 128.729 N./mm² Straight Flange Required Thickness: = (P*R)/(S*E-0.6*P) + c per UG-27 (c)(1) = (8.056*1151.0)/(137.9*1.0-0.6*8.056)+1.0 = 7.748 mm. Straight Flange Maximum Allowable Working Pressure: Less Operating Hydrostatic Head Pressure of 0.056 bars = (S*E*t)/(R+0.6*t) per UG-27 (c)(1) = (137.9 * 1.0 * 9.0)/(1151.0 + 0.6 * 9.0 ) = 10.732 - 0.056 = 10.675 bars Factor K, corroded condition [Kcor]: = ( 2 + ( Inside Diameter/( 2 * Inside Head Depth ))2)/6 = ( 2 + ( 2302.0/( 2 * 576.0 ))2)/6 = 0.998843 Percent Elong. per UCS-79, VIII-1-01-57 (75*tnom/Rf)*(1-Rf/Ro) 1.894 % MDMT Calculations in the Knuckle Portion: Govrn. thk, tg = 8.2, tr = 6.721, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.933, Temp. Reduction = 4 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -33 °C MDMT Calculations in the Head Straight Flange: Govrn. thk, tg = 10.0, tr = 6.748, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.75, Temp. Reduction = 14 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -43 °C Note: Heads and Shells Exempted to -20F (-29C) by paragraph UG-20F Hydrostatic Test Pressure Results: Pressure Pressure Pressure Pressure per per per per UG99b UG99b[36] UG99c UG100 = = = = UES-17122-MDC-001 1.3 1.3 1.3 1.1 * * * * M.A.W.P. * Sa/S Design Pres * Sa/S M.A.P. - Head(Hyd) M.A.W.P. * Sa/S 10.400 10.400 12.063 8.800 bars bars bars bars Page:25 of 96 13 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Internal Pressure Calculations: Step: 3 5:24pm Sep 27,2017 Pressure per PED = 1.43 * MAWP Pressure per App 27-4 = 1.3 * M.A.W.P. * Sa/S User Defined Hydrostatic Test Pressure at High Point 11.440 10.400 11.000 bars bars bars Vertical Test performed per: UG-99b (Note 36) Please note that Nozzle, Shell, Head, Flange, etc MAWPs are all considered when determining the hydrotest pressure for those test types that are based on the MAWP of the vessel. Stresses on Elements due to Test Pressure (N./mm² & bars): From To Stress Allowable Ratio Pressure ---------------------------------------------------------------------BTM Head 160.2 179.3 0.894 11.42 Shell 163.9 179.3 0.914 11.36 Top Head 155.2 179.3 0.866 11.06 ---------------------------------------------------------------------Stress ratios for Nozzle and Pad Materials (N./mm²): Description Pad/Nozzle Ambient Operating Ratio ---------------------------------------------------------------------N1_16_Inlet Nozzle 117.90 117.90 1.000 N1_16_Inlet Pad 137.90 137.90 1.000 N2_2_Drain Nozzle 137.90 137.90 1.000 N3_1_Level S G Nozzle 137.90 137.90 1.000 N4_1_Level S G Nozzle 137.90 137.90 1.000 M_24_Man Hole Nozzle 137.90 137.90 1.000 M_24_Man Hole Pad 137.90 137.90 1.000 N5_1_Air Relief Nozzle 137.90 137.90 1.000 N6_2_Spare Nozzle 137.90 137.90 1.000 N7_1/2_P G Nozzle 137.90 137.90 1.000 N8_1_Air Inlet Nozzle 137.90 137.90 1.000 N9_2_Level Prob Nozzle 137.90 137.90 1.000 ---------------------------------------------------------------------Minimum 1.000 Stress ratios for Pressurized Vessel Elements (N./mm²): Description Ambient Operating Ratio ---------------------------------------------------------------------BTM Head 137.90 137.90 1.000 Shell 137.90 137.90 1.000 Top Head 137.90 137.90 1.000 ---------------------------------------------------------------------Minimum 1.000 Hoop Stress in Nozzle Wall during Pressure Test (N./mm²): Description Stress Allowable Ratio ---------------------------------------------------------------------N1_16_Inlet 17.81 153.28 0.116 N2_2_Drain 6.90 179.27 0.039 N3_1_Level S G 4.78 179.27 0.027 N4_1_Level S G 4.67 179.27 0.026 M_24_Man Hole 35.10 179.30 0.196 N5_1_Air Relief 4.66 179.27 0.026 N6_2_Spare 6.69 179.27 0.037 N7_1/2_P G 3.68 179.27 0.021 N8_1_Air Inlet 4.66 179.27 0.026 N9_2_Level Prob 6.69 179.27 0.037 ---------------------------------------------------------------------Elements Suitable for Internal Pressure. UES-17122-MDC-001 Page:26 of 96 14 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Internal Pressure Calculations: Step: 3 5:24pm Sep 27,2017 PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:27 of 96 15 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF External Pressure Calculations: Step: 4 5:24pm Sep 27,2017 External Pressure Calculation Results : External Pressure Calculations: | | Section | Outside | Corroded | Factor | Factor | From| To | Length | Diameter | Thickness | A | B | | | mm. | mm. | mm. | | N./mm² | ----------------------------------------------------------------------------10| 20| No Calc | 2316.4 | 7.2 | 0.0004317 | 43.1607 | 20| 30| 3483.33 | 2316 | 7 | 0.00014622 | 14.619 | 30| 40| No Calc | 2316.4 | 7.2 | 0.0004317 | 43.1607 | ----------------------------------------------------------------------------External Pressure Calculations: | | External | External | External | External | From| To | Actual T. | Required T.| Design Pressure | M.A.W.P. | | | mm. | mm. | bars | bars | ----------------------------------------------------------------------10| 20| 8.2 | 3.5 | ... | 1.49053 | 20| 30| 8 | No Calc | ... | 0.5891 | 30| 40| 8.2 | 3.5 | ... | 1.49053 | ----------------------------------------------------------------------Minimum 0.589 External Pressure Calculations: | | Actual Length | Allowable Length | Ring Inertia | Ring Inertia | From| To | Bet. Stiffeners | Bet. Stiffeners | Required | Available | | | mm. | mm. | cm**4 | cm**4 | -------------------------------------------------------------------------------10| 20| No Calc | No Calc | No Calc | No Calc | 20| 30| 3483.33 | No Calc | No Calc | No Calc | 30| 40| No Calc | No Calc | No Calc | No Calc | -------------------------------------------------------------------------------Elements Suitable for External Pressure. ASME Code, Section VIII, Division 1, 2015 Elliptical Head From 10 to 20 Ext. Chart: CS-2 at 0 °C BTM Head Elastic Modulus from Chart: CS-2 at 0 °C : 0.200E+09 KPa. Results for Maximum Allowable External Pressure (MAEP): Tca OD D/t Factor A B 7.200 2316.40 321.72 0.0004317 43.16 EMAP = B/(K0*D/t) = 43.1607/( 0.9 *321.7223 ) = 1.4905 bars Check the requirements of UG-33(a)(1) using P = 1.67 * External Design pressure for this head. Material UNS Number: Max. = = = K02700 Allowable Working Pressure at given Thickness, corroded [MAWP]: ((2*S*E*t)/(Kcor*D+0.2*t))/1.67 per Appendix 1-4 (c) ((2*137.9*1.0*7.2)/(0.999*2302.0002+0.2*7.2))/1.67 5.168 bars Maximum Allowable External Pressure [MAEP]: = min( MAEP, MAWP ) = min( 1.49, 5.1679 ) UES-17122-MDC-001 Page:28 of 96 16 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF External Pressure Calculations: Step: 4 5:24pm Sep 27,2017 = 1.491 bars Cylindrical Shell From 20 to 30 Ext. Chart: CS-2 at 0 °C Shell Elastic Modulus from Chart: CS-2 at 0 °C : 0.200E+09 KPa. Results for Maximum Allowable External Pressure (MAEP): Tca OD SLEN D/t L/D Factor A 7.000 2316.00 3483.33 330.86 1.5040 0.0001462 EMAP = (4*B)/(3*(D/t)) = (4*14.619)/(3*330.8572) = 0.5891 bars B 14.62 Results for Maximum Stiffened Length (Slen): Tca OD SLEN D/t L/D Factor A 7.000 2316.00 3483.33 330.86 1.5040 0.0001462 EMAP = (4*B)/(3*(D/t)) = (4*14.619)/(3*330.8572) = 0.5891 bars B 14.62 Elliptical Head From 30 to 40 Ext. Chart: CS-2 at 0 °C Top Head Elastic Modulus from Chart: CS-2 at 0 °C : 0.200E+09 KPa. Results for Maximum Allowable External Pressure (MAEP): Tca OD D/t Factor A B 7.200 2316.40 321.72 0.0004317 43.16 EMAP = B/(K0*D/t) = 43.1607/( 0.9 *321.7223 ) = 1.4905 bars Check the requirements of UG-33(a)(1) using P = 1.67 * External Design pressure for this head. Material UNS Number: Max. = = = K02700 Allowable Working Pressure at given Thickness, corroded [MAWP]: ((2*S*E*t)/(Kcor*D+0.2*t))/1.67 per Appendix 1-4 (c) ((2*137.9*1.0*7.2)/(0.999*2302.0002+0.2*7.2))/1.67 5.168 bars Maximum Allowable External Pressure [MAEP]: = min( MAEP, MAWP ) = min( 1.49, 5.1679 ) = 1.491 bars PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:29 of 96 17 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Element and Detail Weights: Step: 5 5:24pm Sep 27,2017 Element and Detail Weights: | | Element | Element | Corroded | Corroded | Extra due | From| To | Metal Wgt. | ID Volume |Metal Wgt. | ID Volume | Misc % | | | kg. | Cm. | kg. | Cm. | kg. | --------------------------------------------------------------------------10| 20| 523.111 | 1800717 | 470.8 | 1805238 | ... | 20| 30| 1348.73 | 12466504 | 1180.64 | 12488195 | ... | 30| 40| 523.111 | 1800717 | 470.8 | 1805238 | ... | --------------------------------------------------------------------------Total | 2394 |16067938.00 | 2122 |16098671.00 | 0 | Weight of Details: | | Weight of | X Offset, | Y Offset, | From|Type| Detail | Dtl. Cent. |Dtl. Cent. | | | kg. | mm. | mm. | ------------------------------------------------10|Liqd| 1799.62 | ... | -287.5 | 10|Nozl| 72.1952 | ... | -575 | 10|Nozl| 0.82942 | ... | -498.253 | 20|Liqd| 12458.9 | ... | 1500 | 20|Nozl| 0.46084 | 1178.58 | 150 | 20|Nozl| 0.46084 | 1178.58 | 2850 | 20|Nozl| 378.721 | 1454.8 | 650 | 20|Legs| 643.554 | ... | -758.5 | 30|Liqd| 1799.62 | ... | 337.5 | 30|Nozl| 0.46084 | ... | 1184.6 | 30|Nozl| 0.84965 | -517 | 1123.22 | 30|Nozl| 0.18882 | -365.574 | 1123.22 | 30|Nozl| 0.44548 | ... | 1123.22 | 30|Nozl| 0.84965 | 517 | 1123.22 | ------------------------------------------------- Description LIQUID 10 N1_16_Inlet N2_2_Drain LQ2 N3_1_Level S G N4_1_Level S G M_24_Man Hole LEGS LQ3 N5_1_Air Relief N6_2_Spare N7_1/2_P G N8_1_Air Inlet N9_2_Level Prob Total Weight of Each Detail Type Total Weight of Liquid 16058.1 Total Weight of Nozzles 455.5 Total Weight of Legs 643.6 --------------------------------------------------------------Sum of the Detail Weights 17157.2 kg. Weight Summation: kg. Fabricated | Shop Test | Shipping | Erected | Empty | Operating | -----------------------------------------------------------------------------2395.0 | 3494.0 | 2395.0 | 3494.0 | 2395.0 | 3494.0 | ... | 16058.1 | ... | ... | ... | 16058.1 | 455.5 | ... | 455.5 | ... | ... | ... | 643.6 | ... | 643.6 | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | ... | 455.5 | ... | ... | ... | ... | ... | 643.6 | ... | 3494.0 | 19552.1 | 3494.0 | 3494.0 | 3494.0 | 19552.1 | Note: The shipping total has been modified because some items have been specified as being installed in the shop. Weight Summary Fabricated Wt. Shop Test Wt. Shipping Wt. - Bare Weight W/O Removable Internals - Fabricated Weight + Water ( Full ) - Fab. Wt + Rem. Intls.+ Shipping App. UES-17122-MDC-001 3494.0 kg. 19552.1 kg. 3494.0 kg. Page:30 of 96 18 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Element and Detail Weights: Step: 5 5:24pm Sep 27,2017 Erected Wt. Ope. Wt. no Liq Operating Wt. Field Test Wt. Mass of the Upper Fab. Wt + Rem. Intls.+ Insul. (etc) Fab. Wt + Intls. + Details + Wghts. Empty Wt + Operating Liq. Uncorroded Empty Weight + Water (Full) 1/3 of the Vertical Vessel 3494.0 3494.0 19552.1 19552.1 6745.2 kg. kg. kg. kg. kg. Outside Surface Areas of Elements: | | Surface | From| To | Area | | | cm² | ---------------------------10| 20| 61988.7 | 20| 30| 218278 | 30| 40| 61988.7 | ---------------------------Total 342255.219 cm² Element and Detail Weights: | To | Total Ele.| Total. Ele.|Total. Ele.| Total Dtl.| Oper. Wgt. | From| To | Empty Wgt.| Oper. Wgt.|Hydro. Wgt.| Offset Mom.| No Liquid | | | kg. | kg. | kg. | Kg-m. | kg. | --------------------------------------------------------------------------10| 20| 596.135 | 2395.75 | 2395.75 | ... | 596.135 | 20|Legs| 172.837 | 1418.73 | 1418.73 | 55.2061 | 172.837 | Legs| 30| 1555.54 | 12768.5 | 12768.5 | 496.854 | 1555.54 | 30| 40| 525.905 | 2325.52 | 2325.52 | 0.94758 | 525.905 | --------------------------------------------------------------------------Cumulative Vessel Weight | | Cumulative Ope | Cumulative | Cumulative | From| To | Wgt. No Liquid | Oper. Wgt. | Hydro. Wgt. | | | kg. | kg. | kg. | ------------------------------------------------------10| 20| ... | ... | ... | 20|Legs| -596.135 | -2395.75 | -2395.75 | Legs| 30| 2081.44 | 15094.1 | 15094.1 | 30| 40| 525.905 | 2325.52 | 2325.52 | ------------------------------------------------------Note: The cumulative operating weights no liquid in the column above are the cumulative operating weights minus the operating liquid weight minus any weights absent in the empty condition. Cumulative Vessel Moment | | Cumulative | Cumulative |Cumulative | From| To | Empty Mom. | Oper. Mom. |Hydro. Mom.| | | Kg-m. | Kg-m. | Kg-m. | ------------------------------------------------10| 20| ... | ... | ... | 20|Legs| 55.2061 | 55.2061 | 55.2061 | Legs| 30| 497.802 | 497.802 | 497.802 | 30| 40| 0.94758 | 0.94758 | 0.94758 | ------------------------------------------------PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:31 of 96 19 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Flange MAWP: Step: 6 5:24pm Sep 27,2017 Nozzle Flange MAWP Results : Nozzle Description Flange Rating Operating Ambient Temperature Class Grade/Group bars bars °C ---------------------------------------------------------------------------N1_16_Inlet 9.4 10.0 90 PN10 3E0 vR<=50 ---------------------------------------------------------------------------Minimum Rating 9.4 10.0 bars (for Core Elements) PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:32 of 96 20 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Natural Frequency Calculation: Step: 7 5:24pm Sep 27,2017 The Natural Frequencies for the vessel have been computed iteratively by solving a system of matrices. These matrices describe the mass and the stiffness of the vessel. This is the generalized eigenvalue/ eigenvector problem and is referenced in some mathematical texts. The Natural Frequency for the Vessel (Empty.) is 41.3046 Hz. The Natural Frequency for the Vessel (Ope...) is 15.7925 Hz. The Natural Frequency for the Vessel (Filled) is 15.9842 Hz. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:33 of 96 21 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Wind Load Calculation: Step: 8 5:24pm Sep 27,2017 Input Values: Wind Design Code Wind Load Reduction Scale Factor Basic Wind Speed [V] Surface Roughness Category Importance Factor Type of Surface Base Elevation Percent Wind for Hydrotest Using User defined Wind Press. Vs Elev. Height of Hill or Escarpment H or Hh Distance Upwind of Crest Lh Distance from Crest to the Vessel x Type of Terrain ( Hill, Escarpment ) Damping Factor (Beta) for Wind (Ope) Damping Factor (Beta) for Wind (Empty) Damping Factor (Beta) for Wind (Filled) ASCE-7 2010 0.600 120 C: Open Terrain 1.0 Moderately Smooth 0 33.0 N 0 0 0 Flat 0.0100 0.0000 0.0000 Km/hr mm. mm. mm. mm. Wind Analysis Results Static Gust-Effect Factor, Operating Case [G]: = min(0.85, 0.925((1 + 1.7 * gQ * Izbar * Q )/( 1 + 1.7 * gV * Izbar))) = min(0.85,0.925((1+1.7*3.4*0.228*0.96)/(1+1.7*3.4*0.228))) = min(0.85, 0.904 ) = 0.850 Natural Frequency of Vessel (Operating) Natural Frequency of Vessel (Empty) Natural Frequency of Vessel (Test) Force Coefficient Structure Height to Diameter ratio Height to top of Structure 15.792 Hz 41.305 Hz 15.984 Hz [Cf] 0.511 1.646 3683.200 mm. This is classified as a rigid structure. Static analysis performed. Sample Calculation for the First Element The ASCE code performs all calculations in Imperial Units only. The wind pressure is therefore computed in these units. Value of [Alpha] and [Zg]: Exposure Category: C from Table 26.9.1 Alpha = 9.5: Zg = 274320. mm. Effective Height [z]: = Centroid Height + Vessel Base Elevation = 362.503 + 0.0 = 362.503 mm. = 1.189 ft. Imperial Units Velocity Pressure coefficient evaluated at height z [Kz]: Because z (1.189 ft.) < 15 ft. = 2.01 * ( 15 / Zg ) 2 / Alpha = 2.01 * ( 15/900.0 )2/9.5 = 0.849 Type of Hill: No Hill Wind Directionality Factor [Kd]: = 0.95 per Table 26.6-1 As there is No Hill Present: [Kzt]: K1 = 0, K2 = 0, K3 = 0 UES-17122-MDC-001 Page:34 of 96 22 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Wind Load Calculation: Step: 8 5:24pm Sep 27,2017 Topographical Factor [Kzt]: = ( 1 + K1 * K2 * K3 )² = ( 1 + 0.0* 0.0* 0.0 )² = 1.0 Velocity Pressure evaluated at height z, Imperial Units [qz]: = min( 16, 0.00256 * Kz * Kzt * Kd * V(mph)² ) = min( 16, 0.00256 * 0.849 * 1.0 * 0.95 * 74.567² ) = 16.0 psf [78.12] Kgs/m² Force on the first element [F]: = qz * G * Cf * WindArea = 16.0 * 0.85 * 0.511 * 15.201 = 105.6 lbs. [47.9] Kgf Element Hgt (z) K1 K2 K3 Kz Kzt qz mm. Kgs/m² --------------------------------------------------------------------------BTM Head 362.5 0.000 0.000 0.000 0.849 1.000 78.120 Shell 2125.0 0.000 0.000 0.000 0.849 1.000 78.120 Top Head 3895.7 0.000 0.000 0.000 0.849 1.000 78.120 Wind Vibration Calculations This evaluation is based on work by Kanti Mahajan and Ed Zorilla Nomenclature Cf D Df Dr f f1 L Lc tb V30 Vc Vw W Ws Z Dl Vp P30 - Correction factor for natural frequency Average internal diameter of vessel mm. Damping Factor < 0.75 Unstable, > 0.95 Stable Average internal diameter of top half of vessel mm. Natural frequency of vibration (Hertz) Natural frequency of bare vessel based on a unit value of (D/L²)(104) Total height of structure mm. Total length of conical section(s) of vessel mm. Uncorroded plate thickness at bottom of vessel mm. Design Wind Speed provided by user Km/hr Critical wind velocity Km/hr Maximum wind speed at top of structure Km/hr Total corroded weight of structure Kgf Cor. vessel weight excl. weight of parts which do not effect stiff. Kgf Maximum amplitude of vibration at top of vessel mm. Logarithmic decrement ( taken as 0.03 for Welded Structures ) Vib. Chance, <= 0.320E-06 (High); 0.320E-06 < 0.400E-06 (Probable) wind pressure 30 feet above the base Check other Conditions and Basic Assumptions: #1 - Total Cone Length / Total Length < 0.5 0.0/3100.0 = 0.0 #2 - ( D / L² ) * 104 < 8.0 (English Units) - ( 7.6/10.17² ) * 104 = 734.569 [Geometry Violation] Compute the vibration possibility. If Vp > 0.400E-06 no chance. [Vp]: = W / ( L * Dr²) = 19279/( 3100.0 * 2302.0² ) = 0.11736E-05 Since Vp is > 0.400E-06 no further vibration analysis is required ! The Natural Frequency for the Vessel (Ope...) is 15.7925 Hz. Wind Load Calculation: UES-17122-MDC-001 Page:35 of 96 23 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Wind Load Calculation: Step: 8 5:24pm Sep 27,2017 | | Wind | Wind | Wind | Wind | Element | From| To | Height | Diameter | Area | Pressure | Wind Load | | | mm. | mm. | cm² | Kgs/m² | Kgf | --------------------------------------------------------------------------10| 20| 362.503 | 2779.68 | 14122 | 78.12 | 28.7379 | 20| 30| 2125 | 2779.2 | 83376 | 78.12 | 169.668 | 30| 40| 3895.7 | 2779.68 | 14122 | 78.12 | 28.7379 | --------------------------------------------------------------------------Note: The Wind Loads calculated and printed in the Wind Load calculation report have been factored by the input scalar/load reduction factor of: 0.600. Be sure the wind speed is in accordance with the specified wind design code. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:36 of 96 24 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Earthquake Load Calculation: Step: 9 5:24pm Sep 27,2017 Earthquake Analysis Results per UBC 1997 The The The The The The The The UBC Zone Factor for the Vessel is ............. Importance Factor as Specified by the User is . UBC Force Factor as Specified by the User is .. UBC Total Weight (W) for the Vessel is ........ UBC Total Shear (V) for the Vessel is ......... UBC Top Shear (Ft) for the Vessel is .......... UBC Seismic Coefficient Value Ca is ........... UBC Seismic Coefficient Value Cv is ........... 0.0750 1.250 2.000 18908.5 7594.1 0.0 0.360 0.840 Kgf Kgf Kgf Note: The base shear and top load printed above have been modified by the user defined Earthquake scalar. Calculation Steps for Computing the design Base Shear (V) per UBC 1997 Computation of V per equation (30-4): V = Cv * I * W / ( R * T ) V = 0.84 * 1.25 * 18909/( 2.0 * 0.0633 ) V = 156771.7 Kgf Computation of V per equation (30-5): V = 2.5 * Ca * I * W / R V = 2.5 * 0.36 * 1.25 * 18909/2.0 V = 10636.1 Kgf The computed base shear is the minimum of V from 30-4 and 30-5. Computation of V per equation (34-2), minimum V. V cannot be less than this value ! V = 0.56 * Ca * I * W V = 0.56 * 0.36 * 1.25 * 18909 V = 4765.0 Kgf Total Adjusted Base Shear V: = V * Scalar Multiplier = 10636.1 * 0.7140 = 7594.1 Kgf Next compute the top load per equation 30-14. The top load is zero if the period of vibration (T) is less than 0.7 seconds. Note: This value does not need to exceed 0.25V. Ft = Min( 0.07 * T * V, 0.25 * V ) Ft = Min( 0.07 * 0.063 * 10636, 0.25 * 10636 ) Ft = 0.0 Kgf Next Sum the earthquake weights times their heights (wi*hi): Current Current Current Current Sum Sum Sum Sum = = = = Prev. Prev. Prev. Prev. Sum Sum Sum Sum + + + + Wght Wght Wght Wght 2396. * Hght 25.000 = 60. 1419. * Hght 350.000 = 556. 12769. * Hght 1700.000 = 22263. 2326. * Hght 3075.000 = 29415. Compute the load at each level based on equation 30-15 and multiply by the load case scalar. The sum will be the total adjusted shear. Fx Fx Fx Fx Fx = = = = = (( V - Ft [(10636.) [(10636.) [(10636.) [(10636.) ) * * * * * wx * hx / ( sum of ( wi * hi ))) * EqFact 2396. * 25.000 / 29415.]*0.7140 = 15. 1419. * 350.000 / 29415.]*0.7140 = 128. 12769. * 1700.000 / 29415.]*0.7140 = 5604. 2326. * 3075.000 / 29415.]*0.7140 = 1846. The Natural Frequency for the Vessel (Ope...) is 15.7925 Hz. Earthquake Load Calculation: UES-17122-MDC-001 Page:37 of 96 25 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Earthquake Load Calculation: Step: 9 5:24pm Sep 27,2017 | | Earthquake | Earthquake | Element | Element | From| To | Height | Weight | Ope Load | Emp Load | | | mm. | Kgf | Kgf | Kgf | -------------------------------------------------------------10| 20| 25 | 2395.75 | 15.4635 | 2.20301 | 20|Legs| 350 | 1418.73 | 128.201 | 8.94203 | Legs| 30| 1700 | 12768.5 | 5604.23 | 390.894 | 30| 40| 3075 | 2325.52 | 1846.25 | 239.047 | -------------------------------------------------------------Top Load 5442.00 0 0 Note: The Earthquake Loads calculated and printed in the Earthquake Load calculation report have been factored by the input scalar/load reduction factor of: 0.714. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:38 of 96 26 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Wind/Earthquake Shear, Bending: Step: 10 5:24pm Sep 27,2017 The following table is for the Operating Case. Wind/Earthquake Shear, Bending: | | Distance to| Cumulative |Earthquake | Wind | Earthquake | From| To | Support| Wind Shear | Shear | Bending | Bending | | | mm. | Kgf | Kgf | Kg-m. | Kg-m. | --------------------------------------------------------------------------10| 20| 570.697 | ... | ... | ... | ... | 20|Legs| 150 | 28.7379 | 15.4635 | 7.77944 | 4.18601 | Legs| 30| 1350 | 210.177 | 7465.94 | 272.578 | 13022.6 | 30| 40| 2970.7 | 28.7379 | 1846.25 | 7.77944 | 499.786 | --------------------------------------------------------------------------Note: The Wind Shears/Moments and the Earthquake Shears/Moments calculated and printed in the Wind/Earthquake Shear and Bending report have been factored by the input Scalar/Load reductions factors of; Wind: 0.600; Earthquake: 0.714. Note: Review the Vessel Design Summary for the cumulative shear force and bending moment on the support. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:39 of 96 27 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Wind Deflection: Step: 11 5:24pm Sep 27,2017 Wind Deflection Calculations: The following table is for the Operating Case. Wind Deflection: | | Cumulative | Centroid | Elem. End | Elem. Ang. | From| To | Wind Shear | Deflection | Deflection | Rotation | | | Kgf | mm. | mm. | | --------------------------------------------------------------------10| 20| ... | 0.19563 | 0.19563 | 0.0001385 | 20|Legs| 28.7379 | 0.19564 | 0.19565 | 0.00013863 | Legs| 30| 210.177 | 0.19615 | 0.19697 | 0.00013913 | 30| 40| 28.7379 | 0.19698 | 0.197 | 0.00013913 | --------------------------------------------------------------------Critical Wind Velocity for Tower Vibration: | | 1st Crit. | 2nd Crit. | From| To | Wind Speed | Wind Speed | | | Km/hr | Km/hr | ------------------------------------10| 20| 788.036 | 4925.22 | 20| 30| 787.9 | 4924.37 | 30| 40| 788.036 | 4925.22 | ------------------------------------Allowable deflection at the Tower Top (Ope)( 6.000"/100ft. Criteria) Allowable deflection : 15.500 Actual Deflection : 0.197 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:40 of 96 28 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Longitudinal Stress Constants: Step: 12 5:24pm Sep 27,2017 Longitudinal Stress Constants: | | Metal Area | Metal Area |Section Modulus | Section Modulus | | To | New | Corroded | New | Corroded | | | cm² | cm² | mm.³ | mm.³ | -------------------------------------------------------------------------------10 | 20| 594.614 | 522.324 | 34191344 | 30060406 | 20 | 30| 580.061 | 507.771 | 33354430 | 29222780 | 30 | 40| 594.614 | 522.324 | 34191344 | 30060406 | -------------------------------------------------------------------------------From PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:41 of 96 29 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Longitudinal Allowable Stresses: Step: 13 5:24pm Sep 27,2017 Longitudinal Allowable Stresses: | | | Hydrotest | | Hydrotest | From| To | Tensile | Tensile | Compressive | Compressive | | | N./mm² | N./mm² | N./mm² | N./mm² | ------------------------------------------------------------------10| 20| 165.48 | 215.124 | -92.6006 | -97.746 | 20|Legs| 165.48 | 215.124 | -90.6532 | -96.7944 | Legs| 30| 165.48 | 215.124 | -90.6532 | -96.7944 | 30| 40| 165.48 | 215.124 | -92.6006 | -97.746 | ------------------------------------------------------------------PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:42 of 96 30 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Longitudinal Stresses due to: Step: 14 5:24pm Sep 27,2017 Longitudinal Stress Report Note: Longitudinal Operating and Empty Stresses are computed in the corroded condition. Stresses due to loads in the hydrostatic test cases have been computed in the new and cold condition. Longitudinal Pressure Stresses due to: | | Longitudinal Stress | Longitudinal Stress |Longitudinal Stress | From| To | Internal Pressure | External Presssure | Hydrotest Presure | | | N./mm² | N./mm² | N./mm² | ---------------------------------------------------------------------------10| 20| 63.7882 | ... | 76.9186 | 20| 30| 65.6152 | ... | 78.8471 | 30| 40| 63.7882 | ... | 76.9186 | ---------------------------------------------------------------------------Longitudinal Stresses due to Weight Loads for these Conditions: | | Wght. Str. | Wght. Str. |Wght. Str. | Wght. Str. | Wght. Str. | From| To | Empty | Operating |Hydrotest | Emp. Mom. | Opr. Mom. | | | N./mm² | N./mm² | N./mm² | N./mm² | N./mm² | --------------------------------------------------------------------------10| 20| ... | ... | ... | ... | ... | 20|Legs| 0.11513 | 0.4627 | 0.40504 | 0.018526 | 0.018526 | Legs| 30| -0.402 | -0.16137 | -0.3519 | 0.16705 | 0.16705 | 30| 40| -0.098741 | -0.098741 | -0.086736 | 0.00030913 | 0.00030913 | --------------------------------------------------------------------------Longitudinal Stresses due to Weight Loads and Bending for these Conditions: | | Wght. Str. | Bend. Str. |Bend. Str. | Bend. Str. | Bend. Str. | From| To | Hyd. Mom. | Oper. Wind |Oper. Equ. | Hyd. Wind | Hyd. Equ. | | | N./mm² | N./mm² | N./mm² | N./mm² | N./mm² | --------------------------------------------------------------------------10| 20| ... | ... | ... | ... | ... | 20|Legs| 0.016231 | 0.0026106 | 0.0014048 | 0.00075479 | ... | Legs| 30| 0.14636 | 0.091472 | 4.37014 | 0.026447 | ... | 30| 40| 0.00027178 | 0.0025379 | 0.16305 | 0.00073632 | ... | --------------------------------------------------------------------------Longitudinal Stresses due to these Conditions: | | Vortex Shedding | Vortex Shedding | Vortex Shedding | Earthquake | From| To | Operating Case | Empty Case | Test Case | Empty Case | | | N./mm² | N./mm² | N./mm² | N./mm² | -----------------------------------------------------------------------------10| 20| ... | ... | ... | ... | 20|Legs| ... | ... | ... | 0.00020013 | Legs| 30| ... | ... | ... | 0.41453 | 30| 40| ... | ... | ... | 0.021111 | -----------------------------------------------------------------------------Longitudinal Stresses due to Applied Axial Forces: | | Longitudinal Stress | Longitudinal Stress | From| To | Y Forces Wind | Y Forces Seismic | | | N./mm² | N./mm² | ------------------------------------------------------10| 20| ... | ... | 20|Legs| ... | ... | Legs| 30| ... | ... | 30| 40| ... | ... | ------------------------------------------------------- UES-17122-MDC-001 Page:43 of 96 31 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Longitudinal Stresses due to: Step: 14 5:24pm Sep 27,2017 Longitudinal Stresses due to User Forces and Moments: | |Wind For/Mom | Earthquake For/Mom | Wind For/Mom | Earthquake For/Mom | From| To | Corroded | Corroded | No Corrosion | No Corrosion | | | N./mm² | N./mm² | N./mm² | N./mm² | ----------------------------------------------------------------------------------10| 20| ... | ... | ... | ... | 20|Legs| ... | ... | ... | ... | Legs| 30| ... | ... | ... | ... | 30| 40| ... | ... | ... | ... | ----------------------------------------------------------------------------------PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:44 of 96 32 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Stress due to Combined Loads: Step: 15 5:24pm Sep 27,2017 Stress Combination Load Cases for Vertical Vessels: Load Case Definition Key IP EP HP NP EW OW HW WI EQ EE HI HE WE WF CW VO VE VF FW FS BW BS BN BU = = = = = = = = = = = = = = = = = = = = = = = = Longitudinal Stress due to Internal Pressure Longitudinal Stress due to External Pressure Longitudinal Stress due to Hydrotest Pressure No Pressure Longitudinal Stress due to Weight (No Liquid) Longitudinal Stress due to Weight (Operating) Longitudinal Stress due to Weight (Hydrotest) Bending Stress due to Wind Moment (Operating) Bending Stress due to Earthquake Moment (Operating) Bending Stress due to Earthquake Moment (Empty) Bending Stress due to Wind Moment (Hydrotest) Bending Stress due to Earthquake Moment (Hydrotest) Bending Stress due to Wind Moment (Empty) (no CA) Bending Stress due to Wind Moment (Filled) (no CA) Longitudinal Stress due to Weight (Empty) (no CA) Bending Stress due to Vortex Shedding Loads ( Ope ) Bending Stress due to Vortex Shedding Loads ( Emp ) Bending Stress due to Vortex Shedding Loads ( Test No CA. ) Axial Stress due to Vertical Forces for the Wind Case Axial Stress due to Vertical Forces for the Seismic Case Bending Stress due to Lat. Forces for the Wind Case, Corroded Bending Stress due to Lat. Forces for the Seismic Case, Corroded Bending Stress due to Lat. Forces for the Wind Case, UnCorroded Bending Stress due to Lat. Forces for the Seismic Case, UnCorroded General Notes: Case types HI and HE are in the Un-Corroded condition. Case types WE, WF, and CW are in the Un-Corroded condition. A blank stress and stress ratio indicates that the corresponding stress comprising those components that did not contribute to that type of stress. An asterisk (*) in the final column denotes overstress. Analysis of Load Case 1 : NP+EW+WI+FW+BW From Tensile All. Tens. Comp. Node Stress Stress Stress 10 0.00 165.48 0.00 20 0.14 165.48 20 165.48 -0.66 30 165.48 -0.10 All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.0000 0.0008 Analysis of Load Case 2 : NP+EW+EE+FS+BS From Tensile All. Tens. Comp. Node Stress Stress Stress 10 0.00 137.90 0.00 20 0.13 137.90 20 0.18 137.90 -0.98 30 137.90 -0.12 All. Comp. Stress 77.17 75.54 75.54 77.17 Tens. Ratio 0.0000 0.0010 0.0013 Comp. Ratio 0.0000 Analysis of Load Case 3 : NP+OW+WI+FW+BW From Tensile All. Tens. Comp. Node Stress Stress Stress 10 0.00 165.48 0.00 20 0.48 165.48 20 0.10 165.48 -0.42 All. Comp. Stress 92.60 90.65 90.65 Tens. Ratio 0.0000 0.0029 0.0006 Comp. Ratio 0.0000 UES-17122-MDC-001 Comp. Ratio 0.0000 0.0073 0.0011 0.0130 0.0016 0.0046 Page:45 of 96 33 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Stress due to Combined Loads: Step: 15 5:24pm Sep 27,2017 30 165.48 -0.10 92.60 Analysis of Load Case 4 : NP+OW+EQ+FS+BS From Tensile All. Tens. Comp. Node Stress Stress Stress 10 0.00 137.90 0.00 20 0.48 137.90 20 4.38 137.90 -4.70 30 0.06 137.90 -0.26 All. Comp. Stress 77.17 75.54 75.54 77.17 Tens. Ratio 0.0000 0.0035 0.0317 0.0005 Comp. Ratio 0.0000 Analysis of Load Case 5 : NP+HW+HI From Tensile All. Tens. Node Stress Stress 10 0.00 215.12 20 0.42 215.12 20 215.12 30 215.12 All. Comp. Stress 97.75 96.79 96.79 97.75 Tens. Ratio 0.0000 0.0020 Comp. Ratio 0.0000 Tens. Ratio 0.0000 0.0020 -0.50 -0.09 All. Comp. Stress 97.75 96.79 96.79 97.75 Analysis of Load Case 7 : IP+OW+WI+FW+BW From Tensile All. Tens. Comp. Node Stress Stress Stress 10 63.79 165.48 20 66.10 165.48 20 65.71 165.48 30 63.69 165.48 All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.3855 0.3994 0.3971 0.3849 Comp. Ratio Analysis of Load Case 8 : IP+OW+EQ+FS+BS From Tensile All. Tens. Comp. Node Stress Stress Stress 10 63.79 137.90 20 66.10 137.90 20 69.99 137.90 30 63.85 137.90 All. Comp. Stress 77.17 75.54 75.54 77.17 Tens. Ratio 0.4626 0.4793 0.5075 0.4630 Comp. Ratio Analysis of Load Case 9 : EP+OW+WI+FW+BW From Tensile All. Tens. Comp. Node Stress Stress Stress 10 0.00 165.48 0.00 20 0.48 165.48 20 0.10 165.48 -0.42 30 165.48 -0.10 All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.0000 0.0029 0.0006 Comp. Ratio 0.0000 Analysis of Load Case 10 : EP+OW+EQ+FS+BS From Tensile All. Tens. Comp. Node Stress Stress Stress 10 0.00 137.90 0.00 20 0.48 137.90 20 4.38 137.90 -4.70 30 0.06 137.90 -0.26 All. Comp. Stress 77.17 75.54 75.54 77.17 Tens. Ratio 0.0000 0.0035 0.0317 0.0005 Comp. Ratio 0.0000 Analysis of Load Case 11 : HP+HW+HI From Tensile All. Tens. Node Stress Stress 10 76.92 215.12 20 79.27 215.12 20 78.67 215.12 30 76.83 215.12 All. Comp. Stress 97.75 96.79 96.79 97.75 Tens. Ratio 0.3576 0.3685 0.3657 0.3572 Comp. Ratio Analysis of Load Case 6 : NP+HW+HE From Tensile All. Tens. Node Stress Stress 10 0.00 215.12 20 0.42 215.12 20 215.12 30 215.12 UES-17122-MDC-001 Comp. Stress 0.00 -0.52 -0.09 Comp. Stress 0.00 Comp. Stress 0.0011 0.0622 0.0034 0.0054 0.0009 Comp. Ratio 0.0000 0.0051 0.0009 0.0046 0.0011 0.0622 0.0034 Page:46 of 96 34 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Stress due to Combined Loads: Step: 15 5:24pm Sep 27,2017 Analysis of Load Case 12 : HP+HW+HE From Tensile All. Tens. Node Stress Stress 10 76.92 215.12 20 79.27 215.12 20 78.64 215.12 30 76.83 215.12 Analysis of Load Case 13 : IP+WE+EW From Tensile All. Tens. Node Stress Stress 10 63.79 165.48 20 65.75 165.48 20 65.38 165.48 30 63.69 165.48 Analysis of Load Case 14 : IP+WF+CW From Tensile All. Tens. Node Stress Stress 10 63.79 165.48 20 66.32 165.48 20 65.47 165.48 30 63.70 165.48 Analysis of Load Case 15 : IP+VO+OW From Tensile All. Tens. Node Stress Stress 10 63.79 165.48 20 66.10 165.48 20 65.62 165.48 30 63.69 165.48 Analysis of Load Case 16 : IP+VE+EW From Tensile All. Tens. Node Stress Stress 10 63.79 165.48 20 65.75 165.48 20 65.38 165.48 30 63.69 165.48 Analysis of Load Case 17 : NP+VO+OW From Tensile All. Tens. Node Stress Stress 10 0.00 165.48 20 0.48 165.48 20 0.01 165.48 30 165.48 Analysis of Load Case 18 : FS+BS+IP+OW From Tensile All. Tens. Node Stress Stress 10 63.79 165.48 20 66.10 165.48 20 65.62 165.48 30 63.69 165.48 Analysis of Load Case 19 : FS+BS+EP+OW From Tensile All. Tens. Node Stress Stress 10 0.00 165.48 20 0.48 165.48 20 0.01 165.48 30 165.48 Comp. Stress All. Comp. Stress 97.75 96.79 96.79 97.75 Tens. Ratio 0.3576 0.3685 0.3656 0.3572 Comp. Ratio Comp. Stress All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.3855 0.3973 0.3951 0.3849 Comp. Ratio Comp. Stress All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.3855 0.4008 0.3957 0.3849 Comp. Ratio Comp. Stress All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.3855 0.3994 0.3965 0.3849 Comp. Ratio Comp. Stress All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.3855 0.3973 0.3951 0.3849 Comp. Ratio Comp. Stress 0.00 All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.0000 0.0029 0.0000 Comp. Ratio 0.0000 Comp. Stress All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.3855 0.3994 0.3965 0.3849 Comp. Ratio Comp. Stress 0.00 All. Comp. Stress 92.60 90.65 90.65 92.60 Tens. Ratio 0.0000 0.0029 0.0000 Comp. Ratio 0.0000 -0.33 -0.10 -0.33 -0.10 Absolute Maximum of the all of the Stress Ratio's UES-17122-MDC-001 0.0036 0.0011 0.0036 0.0011 0.5075 Page:47 of 96 35 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Stress due to Combined Loads: Step: 15 5:24pm Sep 27,2017 Governing Element: Shell Governing Load Case 8 : IP+OW+EQ+FS+BS PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:48 of 96 36 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Center of Gravity Calculation: Step: 16 5:24pm Sep 27,2017 Shop/Field Installation Options : Note : The CG is computed from the first Element From Node Center of Gravity of Liquid Center of Gravity of Nozzles Center of Gravity of Legs 1550.000 mm. 518.809 mm. -708.500 mm. Center of Gravity of Bare Shell New and Cold Center of Gravity of Bare Shell Corroded 1550.000 mm. 1550.000 mm. Vessel CG in the Operating Condition Vessel CG in the Fabricated (Shop/Empty) Condition Vessel CG in the Test Condition 1450.249 mm. 999.584 mm. 1451.640 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:49 of 96 37 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Leg Check, (Operating Case): Step: 17 5:24pm Sep 27,2017 RESULTS FOR LEGS : Operating Case Description: LEGS Legs attached to: Shell Section Properties : I Beam UC203X203X60 United Kingdom BS 4 - 1993 Steel Table Overall Leg Length Effective Leg Length Distance Leg Up Side Number of Legs Cross Sectional Area Section Inertia ( Section Inertia ( Section Modulus ( Section Modulus ( Radius of Gyration ( Radius of Gyration ( 2117.000 1867.000 300.000 Nleg 4 Aleg 76.400 6124.993 2064.997 584000.500 201000.438 89.601 51.999 Leglen of Vessel for UC203X203X60 strong axis ) weak axis ) strong axis ) weak axis ) strong axis ) weak axis ) mm. mm. mm. cm² cm**4 cm**4 mm.³ mm.³ mm. mm. Leg Orientation - Strong Axis Overturning Moment at top of Legs Total Weight Load at top of Legs Total Shear force at top of Legs Additional force in Leg due to Bracing Occasional Load Factor Effective Leg End Condition Factor Fadd Occfac k 13022.6 18908.5 7594.1 0.0 1.333 1.000 Kg-m. Kgf Kgf Kgf C11P C22P Tpad 350.000 350.000 10.000 mm. mm. mm. W Note: The Legs are Not Cross Braced The Leg Shear Force includes Wind and Seismic Effects Pad Width along Circumference Pad Length along Vessel Axis Pad Thickness Maximum Shear at top of one Leg [Vleg]: = ( max( Wind, Seismic ) + applied forces )( Imax / Itot ) = ( 7594.1 )( 6133.6/16398.8 ) = 2840.44 Kgf Axial = = = Compression, Leg furthest from the Neutral Axis [Sma]: ((W/Nleg)+(Mleg/(Nlegm*Rn)))/Aleg) ((18909/4) + (13023/( 2 * 1272.8 )))/76.4 ) 12.63 N./mm² Axial = = = Compression, Leg closest to the Neutral Axis [Sva]: ( W / Nleg ) / Aleg ( 18909/4 )/76.4 6.07 N./mm² Allowable Comp. for the Selected Leg (KL/r < Cc ) [Sa]: = Occfac * ( 1-(kl/r)²/(2*Cc²))*Fy / ( 5/3+3*(Kl/r)/(8*Cc)-(Kl/r³)/(8*Cc³) = 1.33 * ( 1-( 35.9 )²/(2 * 127.18² )) * 248/ ( 5/3+3*( 35.9 )/(8* 127.18 )-( 35.9³)/(8* 127.18³) = 179.52 N./mm² Bending at the Bottom of the Leg closest to the N.A. [S]: = ( Vleg * Leglen / Smdsa ) = ( 2840.44 * 1867.0/584001 ) = 89.05 N./mm² Allowable Bending Stress[Sb]: = ( 0.6 * Fy * Occfac ) UES-17122-MDC-001 Page:50 of 96 38 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Leg Check, (Operating Case): Step: 17 5:24pm Sep 27,2017 = ( 0.6 * 248 * 1.33 ) = 198.53 N./mm² AISC Unity Check [Sc]( must be < or = to 1.00 ) : = (Sma/Sa)+(0.85*S)/((1-Sma/Spex)*Sb) = (13/180 )+( 0.85 *89.052 )/(( 1 -13/1083 ) *199 ) = 0.4562 Bolting Size Requirement for Leg Baseplates : Baseplate Material Baseplate Allowable Stress SBA Baseplate Length B Baseplate Width D Baseplate Thickness BTHK Leg Dimension Along Baseplate Length d Leg Dimension Along Baseplate Width b Dist. from the Leg Edge to Bolt Hole Center z Bolt Material Bolt Allowable Stress STBA Anchor Bolt Nominal Diameter BOD Number of Anchor Bolts in Tension per Leg NB Total Number of Anchors Bolt per Leg NBT Ultimate 28-day Concrete Strength FCPRIME SA-516 70 137.90 N./mm² 360.0000 mm. 360.0000 mm. 35.0000 mm. 209.6008 mm. 205.8009 mm. 80.0000 mm. SA-307 B 48.26 N./mm² 24.0000 mm. 1 2 20.685 N./mm² PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:51 of 96 39 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Leg Check, (Filled w/Water): Step: 18 5:24pm Sep 27,2017 RESULTS FOR LEGS : HydroTest Case Description: LEGS Legs attached to: Shell Section Properties : I Beam UC203X203X60 United Kingdom BS 4 - 1993 Steel Table Overall Leg Length Effective Leg Length Distance Leg Up Side Number of Legs Cross Sectional Area Section Inertia ( Section Inertia ( Section Modulus ( Section Modulus ( Radius of Gyration ( Radius of Gyration ( 2117.000 1867.000 300.000 Nleg 4 Aleg 76.400 6124.993 2064.997 584000.500 201000.438 89.601 51.999 Leglen of Vessel for UC203X203X60 strong axis ) weak axis ) strong axis ) weak axis ) strong axis ) weak axis ) mm. mm. mm. cm² cm**4 cm**4 mm.³ mm.³ mm. mm. Leg Orientation - Strong Axis Overturning Moment at top of Legs Total Weight Load at top of Legs Total Shear force at top of Legs Additional force in Leg due to Bracing Occasional Load Factor Effective Leg End Condition Factor Fadd Occfac k 90.0 18908.5 75.0 0.0 1.333 1.000 Kg-m. Kgf Kgf Kgf C11P C22P Tpad 350.000 350.000 10.000 mm. mm. mm. W Note: The Legs are Not Cross Braced The Leg Shear Force includes Wind and Seismic Effects Pad Width along Circumference Pad Length along Vessel Axis Pad Thickness Maximum Shear at top of one Leg [Vleg]: = ( max( Wind, Seismic ) + applied forces )( Imax / Itot ) = ( 75.0 )( 6133.6/16398.8 ) = 28.04 Kgf Axial = = = Compression, Leg furthest from the Neutral Axis [Sma]: ((W/Nleg)+(Mleg/(Nlegm*Rn)))/Aleg) ((18909/4) + (90/( 2 * 1272.8 )))/76.4 ) 6.11 N./mm² Axial = = = Compression, Leg closest to the Neutral Axis [Sva]: ( W / Nleg ) / Aleg ( 18909/4 )/76.4 6.07 N./mm² Allowable Comp. for the Selected Leg (KL/r < Cc ) [Sa]: = Occfac * ( 1-(kl/r)²/(2*Cc²))*Fy / ( 5/3+3*(Kl/r)/(8*Cc)-(Kl/r³)/(8*Cc³) = 1.33 * ( 1-( 35.9 )²/(2 * 127.18² )) * 248/ ( 5/3+3*( 35.9 )/(8* 127.18 )-( 35.9³)/(8* 127.18³) = 179.52 N./mm² Bending at the Bottom of the Leg closest to the N.A. [S]: = ( Vleg * Leglen / Smdsa ) = ( 28.04 * 1867.0/584001 ) = 0.88 N./mm² Allowable Bending Stress[Sb]: = ( 0.6 * Fy * Occfac ) UES-17122-MDC-001 Page:52 of 96 40 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Leg Check, (Filled w/Water): Step: 18 5:24pm Sep 27,2017 = ( 0.6 * 248 * 1.33 ) = 198.53 N./mm² AISC Unity Check [Sc]( must be < or = to 1.00 ) : = (Sma/Sa)+(0.85*S)/((1-Sma/Spex)*Sb) = (6/180 )+( 0.85 * 0.879 )/(( 1 -6/1083 ) *199 ) = 0.0378 Bolting Size Requirement for Leg Baseplates : Baseplate Material Baseplate Allowable Stress SBA Baseplate Length B Baseplate Width D Baseplate Thickness BTHK Leg Dimension Along Baseplate Length d Leg Dimension Along Baseplate Width b Dist. from the Leg Edge to Bolt Hole Center z Bolt Material Bolt Allowable Stress STBA Anchor Bolt Nominal Diameter BOD Number of Anchor Bolts in Tension per Leg NB Total Number of Anchors Bolt per Leg NBT Ultimate 28-day Concrete Strength FCPRIME SA-516 70 137.90 N./mm² 360.0000 mm. 360.0000 mm. 35.0000 mm. 209.6008 mm. 205.8009 mm. 80.0000 mm. SA-307 B 48.26 N./mm² 24.0000 mm. 1 2 20.685 N./mm² PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:53 of 96 41 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Summary: Step: 30 5:24pm Sep 27,2017 Nozzle Calculation Summary: Description | MAWP | Ext | MAPNC | UG-45 [tr] | Weld | Areas or | | bars | | bars | | mm. | Path | Stresses | ---------------------------------------------------------------------------------------------N1_16_Inlet | 8.21 | ... | ... | OK | 8.02 | OK | Passed | N2_2_Drain | 8.21 | ... | ... | OK | 5.80 | OK | No Calc[*] | N2_2_Drain | 8.21 | ... | ... | OK | 5.80 | OK | No Calc[*] | N3_1_Level S G | 8.00 | ... | ... | OK | 4.42 | OK | No Calc[*] | N4_1_Level S G | 8.00 | ... | ... | OK | 4.42 | OK | No Calc[*] | M_24_Man Hole | 8.29 | ... | ... | OK | 7.95 | OK | Passed | N5_1_Air Relief | 8.57 | ... | ... | OK | 4.42 | OK | No Calc[*] | N6_2_Spare | 8.57 | ... | ... | OK | 5.80 | OK | No Calc[*] | N7_1/2_P G | 8.57 | ... | ... | OK | 4.12 | OK | No Calc[*] | N8_1_Air Inlet | 8.57 | ... | ... | OK | 4.42 | OK | No Calc[*] | N9_2_Level Prob | 8.57 | ... | ... | OK | 5.80 | OK | No Calc[*] | ---------------------------------------------------------------------------------------------MAWP Summary: Minimum MAWP Nozzles : 8.000 Nozzle : N4_1_Level S G Minimum MAWP Shells/Flanges : 8.000 Element : Shell Minimum MAPnc Shells/Flanges : 9.553 Element : Shell -------------------------------------------------------------Computed Vessel M.A.W.P. : 8.000 bars [*] - This was a small opening and the areas were not computed or the MAWP of this connection could not be computed because the longitudinal bending stress was greater than the hoop stress. Note: MAWPs (Internal Case) shown above are at the High Point. Check the Spatial Relationship between the Nozzles From Node | Nozzle Description | Y Coordinate | Layout Angle | Dia. Limit | | | mm. | deg | mm. | -----------------------------------------------------------------------------10 | N1_16_Inlet | 0.000 | 0.000 | 766.000 | 10 | N2_2_Drain | 0.000 | 90.000 | 132.760 | 20 | N3_1_Level S G | 200.000 | 180.000 | 93.540 | 20 | N4_1_Level S G | 2900.000 | 180.000 | 93.540 | 20 | M_24_Man Hole | 700.000 | 90.000 | 1223.200 | 30 | N5_1_Air Relief | 0.000 | 0.000 | 93.540 | 30 | N6_2_Spare | 0.000 | 180.000 | 132.760 | 30 | N7_1/2_P G | 0.000 | 225.000 | 59.760 | 30 | N8_1_Air Inlet | 0.000 | 270.000 | 93.540 | 30 | N9_2_Level Prob | 0.000 | 0.000 | 132.760 | The nozzle spacing is computed by the following: = Sqrt( ll² + lc² ) where ll - Arc length along the inside vessel surface in the long. direction. lc - Arc length along the inside vessel surface in the circ. direction If any interferences/violations are found, they will be noted below. No interference violations have been detected ! PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:54 of 96 42 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N1_16_Inlet Nozl: 11 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N1_16_Inlet Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 10 P Temp 8.417 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Sv Sva Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 0.0000 mm. User Entered Minimum Design Metal Temperature mm. 0.00 °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna SA-106 B K03006 Smls. pipe 117.90 N./mm² 117.90 N./mm² Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Nominal Thickness ID 0.00 16.0000 tn deg in. Nominal XS Flange Material Flange Type SA-105 Weld Neck Flange Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi 142.0000 9.0000 8.0000 0.0000 0.0000 mm. mm. mm. mm. mm. Pad Material Pad Allowable Stress at Temperature Pad Allowable Stress At Ambient Diameter of Pad along vessel surface Thickness of Pad Weld leg size between Pad and Shell Groove weld depth between Pad and Nozzle Reinforcing Pad Width ASME Code Weld Type per UW-16 SA-516 70 137.90 137.90 750.0000 8.0000 8.0000 8.0000 171.8000 None N./mm² N./mm² mm. mm. mm. mm. mm. Sp Spa Dp te Wp Wgpn Class of attached Flange Grade of attached Flange PN10 3E0 vR<=50 The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | UES-17122-MDC-001 Page:55 of 96 43 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N1_16_Inlet Nozl: 11 5:24pm Sep 27,2017 | | | | __________/| | ____/|__________\| | | \ | | | \ | | |________________\|__| Insert/Set-in Nozzle With Pad, no Inside projection Reinforcement CALCULATION, Description: N1_16_Inlet ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Inside Diameter Used in Calculation Actual Thickness Used in Calculation 15.000 0.500 in. in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.42*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.42) = 6.3215 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*R)/(Sn*E-0.6*P) per UG-27 (c)(1) = (8.42*191.5)/(118*1.0-0.6*8.42) = 1.3730 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Dl Parallel to Vessel Wall, opening length d Normal to Vessel Wall (Thickness Limit), pad side Tlwp 766.0000 383.0000 18.0000 mm. mm. mm. Weld Strength Reduction Factor [fr1]: = min( 1, Sn/Sv ) = min( 1, 117.9/137.9 ) = 0.855 Weld Strength Reduction Factor [fr2]: = min( 1, Sn/Sv ) = min( 1, 117.9/137.9 ) = 0.855 Weld Strength Reduction Factor [fr4]: = min( 1, Sp/Sv ) = min( 1, 137.9/137.9 ) = 1.000 Weld Strength Reduction Factor [fr3]: = min( fr2, fr4 ) = min( 0.855, 1.0 ) = 0.855 Results of Nozzle Reinforcement Area Calculations: (cm²) AREA AVAILABLE, A1 to A5 | Design| External| Mapnc| --------------------------------------------------------------Area Required Ar | 24.426| NA| NA| Area in Shell A1 | 3.335| NA| NA| Area in Nozzle Wall A2 | 3.179| NA| NA| Area in Inward Nozzle A3 | 0.000| NA| NA| Area in Welds A41+A42+A43 | 1.333| NA| NA| Area in Element A5 | 27.488| NA| NA| TOTAL AREA AVAILABLE Atot | 35.334| NA| NA| UES-17122-MDC-001 Page:56 of 96 44 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N1_16_Inlet Nozl: 11 5:24pm Sep 27,2017 The Internal Pressure Case Governs the Analysis. Nozzle Angle Used in Area Calculations 90.00 Degs. The area available without a pad is Insufficient. The area available with the given pad is Sufficient. SELECTION OF POSSIBLE REINFORCING PADS: Based on given Pad Thickness: Based on given Pad Diameter: Based on Shell or Nozzle Thickness: Area = = = Diameter 613.6465 750.0000 608.5918 Thickness 8.0000 mm. 4.8253 mm. 8.2000 mm. Required [A]: ( d * tr*F + 2 * tn * tr*F * (1-fr1) ) UG-37(c) (383.0*6.3215*1.0+2*11.7*6.3215*1.0*(1-0.86)) 24.426 cm² Reinforcement Areas per Figure UG-37.1 Area Available in Shell [A1]: = d( E1*t - F*tr ) - 2 * tn( E1*t - F*tr ) * ( 1 - fr1 ) = 383.0( 1.0 * 7.2 - 1.0 * 6.321 ) - 2 * 11.7 ( 1.0 * 7.2 - 1.0 * 6.3215 ) * ( 1 - 0.855 ) = 3.335 cm² Area Available in Nozzle Wall Projecting Outward [A2]: = ( 2 * Tlwp ) * ( tn - trn ) * fr2 = ( 2 * 18.0 ) * ( 11.7 - 1.37 ) * 0.855 = 3.179 cm² Area Available in Welds [A41 + A42 + A43]: = Wo² * fr3 + (Wi-can/0.707)² * fr2 + Wp² * fr4 = 9.0² * 0.86 + (0.0)² * 0.86 + 8.0² * 1.0 = 1.333 cm² Area Available in Element [A5]: = (min(Dp,DL)-(Nozzle OD))*(min(tp,Tlwp,te)) * fr4 = ( 750.0 - 406.4 ) * 8.0 * 1.0 = 27.488 cm² UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 2.3730 3.5000 8.0216 8.0216 3.5000 9.3312 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 9.331, max( 8.0216, 3.5 ) ] = 8.0216 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 2.373, 8.0216 ) = 8.0216 mm. Available Nozzle Neck Thickness = 0.875 * 12.700 = 11.113 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of the Nozzle Neck to Flange Weld, Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 11.113, tr = 1.373, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.136, Temp. Reduction = 78 °C UES-17122-MDC-001 Page:57 of 96 45 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N1_16_Inlet Nozl: 11 5:24pm Sep 27,2017 Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Min Metal Temp. w/o impact per UG-20(f) -26 °C -103 °C -29 °C MDMT of Nozzle Neck to Pad Weld for the Nozzle, Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 8.0, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.878, Temp. Reduction = 7 °C Pad governing, Conservatively assuming Pad stress = Shell stress(Div. 1 L-9.3). Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -36 °C MDMT of Nozzle Neck to Pad Weld for Reinforcement pad, Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 8.0, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.878, Temp. Reduction = 7 °C Pad governing, Conservatively assuming Pad stress = Shell stress(Div. 1 L-9.3). Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -36 °C MDMT of Shell to Pad Weld at Pad OD for pad, Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 8.0, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.878, Temp. Reduction = 7 °C Pad governing, Conservatively assuming Pad stress = Shell stress(Div. 1 L-9.3). Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -36 °C MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 8.2, tr = 6.321, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.878, Temp. Reduction = 7 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -36 °C Governing MDMT of the Nozzle Governing MDMT of the Reinforcement Pad Governing MDMT of all the sub-joints of this Junction : : : -36 °C -36 °C -36 °C ANSI Flange MDMT including Temperature reduction per UCS-66.1: Unadjusted MDMT of ANSI B16.5/47 flanges per UCS-66(c) Flange MDMT with Temp reduction per UCS-66(b)(1)(b) Flange MDMT with Temp reduction per UCS-66(b)(1)(c) -29 °C -38 °C -104 °C Where the Stress Reduction Ratio per UCS-66(b)(1)(b) is : Design Pressure/Ambient Rating = 8.42/10.00 = 0.842 Note: Using the minimum value from (b)(1)(b) and (b)(1)(c) above as the calculated nozzle flange MDMT. Weld Size Calculations, Description: N1_16_Inlet Intermediate Calc. for nozzle/shell Welds Tmin Intermediate Calc. for pad/shell Welds TminPad 8.0000 8.0000 mm. mm. Results Per UW-16.1: Nozzle Weld Pad Weld Required Thickness 5.6000 = 0.7 * tmin. 4.0000 = 0.5*TminPad UES-17122-MDC-001 Actual Thickness 6.3630 = 0.7 * Wo mm. 5.6560 = 0.7 * Wp mm. Page:58 of 96 46 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N1_16_Inlet Nozl: 11 5:24pm Sep 27,2017 Weld Strength and Weld Loads per UG-41.1, Sketch (a) or (b) Weld Load [W]: = (A-A1+2*tn*fr1*(E1*t-tr))*Sv = (24.4258 - 3.3349 + 2 * 11.7 * 0.855 * (1.0 * 7.2 - 6.3215 ) ) * 138 = 29904.43 Kgf Note: F is always set to 1.0 throughout the calculation. Weld Load [W1]: = (A2+A5+A4-(Wi-Can/.707)²*fr2)*Sv = ( 3.1787 + 27.488 + 1.3326 - 0.0 * 0.86 ) * 138 = 44996.10 Kgf Weld Load [W2]: = (A2 + A3 + A4 + (2 * tn * t * fr1)) * Sv = ( 3.1787 + 0.0 + 0.6926 + ( 1.4405 ) ) * 138 = 7469.13 Kgf Weld Load [W3]: = (A2+A3+A4+A5+(2*tn*t*fr1))*S = ( 3.1787 + 0.0 + 1.3326 + 27.488 + ( 1.4405 ) ) * 138 = 47021.68 Kgf Strength of Connection Elements for Failure Path Analysis Shear, Outward Nozzle Weld [Sonw]: = (pi/2) * Dlo * Wo * 0.49 * Snw = ( 3.1416/2.0 ) * 406.4 * 9.0 * 0.49 * 118 = 33847. Kgf Shear, Pad Element Weld [Spew]: = (pi/2) * DP * WP * 0.49 * SEW = ( 3.1416/2.0 ) * 750.0 * 8.0 * 0.49 * 138 = 64939. Kgf Shear, Nozzle Wall [Snw]: = (pi *( Dlr + Dlo )/4 ) * ( Thk - Can ) * 0.7 * Sn = (3.1416 * 197.35) * ( 12.7 - 1.0 ) * 0.7 * 118 = 61048. Kgf Tension, Pad Groove Weld [Tpgw]: = ( pi/2) * Dlo * Wgpn * 0.74 * Seg = (3.1416/2 ) * 406.4 * 8.0 * 0.74 * 138 = 53141. Kgf Tension, Shell Groove Weld [Tngw]: = (pi/2) * Dlo * (Wgnvi-Cas) * 0.74 * Sng = ( 3.1416/2.0 ) * 406.4 * ( 8.0 - 1.0 ) * 0.74 * 138 = 46498. Kgf Strength of Failure Paths: PATH11 = ( PATH22 = ( = ( PATH33 = ( = ( SPEW + SNW ) = ( 64939 + 61048 ) = 125987 Kgf Sonw + Tpgw + Tngw + Sinw ) 33847 + 53141 + 46499 + 0 ) = 133486 Kgf Spew + Tngw + Sinw ) 64939 + 46499 + 0 ) = 111437 Kgf Summary of Failure Path Calculations: Path 1-1 = 125986 Kgf, must exceed W = 29904 Kgf or W1 = 44996 Kgf Path 2-2 = 133486 Kgf, must exceed W = 29904 Kgf or W2 = 7469 Kgf Path 3-3 = 111437 Kgf, must exceed W = 29904 Kgf or W3 = 47021 Kgf Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case UES-17122-MDC-001 8.630 bars Page:59 of 96 47 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N1_16_Inlet Nozl: 11 5:24pm Sep 27,2017 Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 9.9659 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 160.1660 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:60 of 96 48 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N2_2_Drain Nozl: 12 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N2_2_Drain Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 10 P Temp Sv Sva 8.409 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 574.0000 mm. User Entered Minimum Design Metal Temperature 0.00 mm. °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter OD 90.00 3.0000 Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² tn deg in. Actual 5.9100 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 82.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Note : Checking Nozzle in the Meridional direction. Reinforcement CALCULATION, Description: N2_2_Drain ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 UES-17122-MDC-001 Page:61 of 96 49 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N2_2_Drain Nozl: 12 5:24pm Sep 27,2017 Actual Outside Diameter Used in Calculation Actual Thickness Used in Calculation 3.000 0.233 in. in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.41*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.41) = 6.3158 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.41*38.1)/(138*1.0+0.4*8.41) = 0.2318 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 138.1446 69.0723 12.2750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N2_2_Drain. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 5.91, tr = 0.232, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.047, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N2_2_Drain Intermediate Calc. for nozzle/shell Welds Tmin 4.9100 mm. Results Per UW-16.1: Nozzle Weld Required Thickness 3.4370 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.623 bars Note: The MAWP of this junction was limited by the parent Shell/Head. Note : Checking Nozzle in the Latitudinal direction. Reinforcement CALCULATION, Description: N2_2_Drain ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation Actual Thickness Used in Calculation 3.000 0.233 in. in. Nozzle input data check completed without errors. UES-17122-MDC-001 Page:62 of 96 50 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N2_2_Drain Nozl: 12 5:24pm Sep 27,2017 Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.41*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.41) = 6.3158 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.41*38.1)/(138*1.0+0.4*8.41) = 0.2318 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 132.7600 66.3800 12.2750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N2_2_Drain. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.2318 3.5000 8.0153 8.0153 3.5000 5.8000 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 5.8, max( 8.0153, 3.5 ) ] = 5.8000 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.2318, 5.8 ) = 5.8000 mm. Available Nozzle Neck Thickness = 5.9100 mm. --> OK Weld Size Calculations, Description: N2_2_Drain Intermediate Calc. for nozzle/shell Welds Tmin 4.9100 mm. Results Per UW-16.1: Nozzle Weld Required Thickness 3.4370 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.623 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 11.3543 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 101.8854 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:63 of 96 51 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N3_1_Level S G Nozl: 13 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N3_1_Level S G Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 20 P Temp Sv Sva Inside Diameter of Cylindrical Shell Shell Finished (Minimum) Thickness Shell Internal Corrosion Allowance Shell External Corrosion Allowance D t c co Distance from Bottom/Left Tangent User Entered Minimum Design Metal Temperature 8.341 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² 2300.00 8.0000 1.0000 0.0000 mm. mm. mm. mm. 200.00 mm. 0.00 °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² OD 180.00 2.2500 tn deg in. Actual 6.1900 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 60.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 2.250 0.244 in. in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N3_1_Level S G ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation Actual Thickness Used in Calculation UES-17122-MDC-001 Page:64 of 96 52 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N3_1_Level S G Nozl: 13 5:24pm Sep 27,2017 Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Cylindrical Shell, Tr [Int. Press] = (P*R)/(Sv*E-0.6*P) per UG-27 (c)(1) = (8.34*1151.0)/(138*1.0-0.6*8.34) = 6.9874 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.34*28.575)/(138*1.0+0.4*8.34) = 0.1724 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 93.5400 46.7700 12.9750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N3_1_Level S G. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.1724 3.5000 7.9874 7.9874 3.5000 4.4200 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 4.42, max( 7.9874, 3.5 ) ] = 4.4200 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.1724, 4.42 ) = 4.4200 mm. Available Nozzle Neck Thickness = 6.1900 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 6.19, tr = 0.172, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.033, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N3_1_Level S G Intermediate Calc. for nozzle/shell Welds Tmin 5.1900 mm. Results Per UW-16.1: Required Thickness UES-17122-MDC-001 Actual Thickness Page:65 of 96 53 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N3_1_Level S G Nozl: 13 5:24pm Sep 27,2017 Nozzle Weld 3.6330 = 0.7 * tmin. 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.341 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.3550 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 68.3550 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:66 of 96 54 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N4_1_Level S G Nozl: 14 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N4_1_Level S G Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 20 P Temp Sv Sva Inside Diameter of Cylindrical Shell Shell Finished (Minimum) Thickness Shell Internal Corrosion Allowance Shell External Corrosion Allowance D t c co Distance from Bottom/Left Tangent User Entered Minimum Design Metal Temperature 8.076 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² 2300.00 8.0000 1.0000 0.0000 mm. mm. mm. mm. 2900.00 mm. 0.00 °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² OD 180.00 2.2500 tn deg in. Actual 6.1900 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 60.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 2.250 0.244 in. in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N4_1_Level S G ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation Actual Thickness Used in Calculation UES-17122-MDC-001 Page:67 of 96 55 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N4_1_Level S G Nozl: 14 5:24pm Sep 27,2017 Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Cylindrical Shell, Tr [Int. Press] = (P*R)/(Sv*E-0.6*P) per UG-27 (c)(1) = (8.08*1151.0)/(138*1.0-0.6*8.08) = 6.7649 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.08*28.575)/(138*1.0+0.4*8.08) = 0.1670 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 93.5400 46.7700 12.9750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N4_1_Level S G. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.1670 3.5000 7.7649 7.7649 3.5000 4.4200 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 4.42, max( 7.7649, 3.5 ) ] = 4.4200 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.167, 4.42 ) = 4.4200 mm. Available Nozzle Neck Thickness = 6.1900 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 6.19, tr = 0.167, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.032, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N4_1_Level S G Intermediate Calc. for nozzle/shell Welds Tmin 5.1900 mm. Results Per UW-16.1: Required Thickness UES-17122-MDC-001 Actual Thickness Page:68 of 96 56 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N4_1_Level S G Nozl: 14 5:24pm Sep 27,2017 Nozzle Weld 3.6330 = 0.7 * tmin. 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.076 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.3550 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 68.3550 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:69 of 96 57 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: M_24_Man Hole Nozl: 15 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: M_24_Man Hole Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 20 P Temp Sv Sva Inside Diameter of Cylindrical Shell Shell Finished (Minimum) Thickness Shell Internal Corrosion Allowance Shell External Corrosion Allowance D t c co Distance from Bottom/Left Tangent User Entered Minimum Design Metal Temperature 8.292 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² 2300.00 8.0000 1.0000 0.0000 mm. mm. mm. mm. 700.00 mm. 0.00 °C Type of Element Connected to the Shell : Nozzle Material [Normalized] Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Actual Thickness SA-516 70 K02700 Plate 137.90 N./mm² 137.90 N./mm² ID 90.00 24.0000 tn deg in. Actual 10.0000 mm. Flange Material Flange Type SA-105 Weld Neck Flange Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi 158.0000 9.0000 8.0000 0.0000 0.0000 mm. mm. mm. mm. mm. Pad Material Pad Allowable Stress at Temperature Pad Allowable Stress At Ambient Diameter of Pad along vessel surface Thickness of Pad Weld leg size between Pad and Shell Groove weld depth between Pad and Nozzle Reinforcing Pad Width ASME Code Weld Type per UW-16 Sp Spa Dp te Wp Wgpn SA-516 70 137.90 137.90 1120.0000 8.0000 8.0000 8.0000 245.2000 None N./mm² N./mm² mm. mm. mm. mm. mm. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | __________/| | | | | | UES-17122-MDC-001 Page:70 of 96 58 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: M_24_Man Hole Nozl: 15 5:24pm Sep 27,2017 ____/|__________\| | | \ | | | \ | | |________________\|__| Insert/Set-in Nozzle With Pad, no Inside projection Reinforcement CALCULATION, Description: M_24_Man Hole ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Inside Diameter Used in Calculation Actual Thickness Used in Calculation 24.000 0.394 in. in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Cylindrical Shell, Tr [Int. Press] = (P*R)/(Sv*E-0.6*P) per UG-27 (c)(1) = (8.29*1151.0)/(138*1.0-0.6*8.29) = 6.9462 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*R)/(Sn*E-0.6*P) per UG-27 (c)(1) = (8.29*305.8)/(138*1.0-0.6*8.29) = 1.8455 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Dl Parallel to Vessel Wall, opening length d Normal to Vessel Wall (Thickness Limit), pad side Tlwp 1223.2001 611.6000 17.5000 mm. mm. mm. Weld Strength Reduction Factor [fr1]: = min( 1, Sn/Sv ) = min( 1, 137.9/137.9 ) = 1.000 Weld Strength Reduction Factor [fr2]: = min( 1, Sn/Sv ) = min( 1, 137.9/137.9 ) = 1.000 Weld Strength Reduction Factor [fr4]: = min( 1, Sp/Sv ) = min( 1, 137.9/137.9 ) = 1.000 Weld Strength Reduction Factor [fr3]: = min( fr2, fr4 ) = min( 1., 1.0 ) = 1.000 Results of Nozzle Reinforcement Area Calculations: (cm²) AREA AVAILABLE, A1 to A5 | Design| External| Mapnc| --------------------------------------------------------------Area Required Ar | 42.483| NA| NA| Area in Shell A1 | 0.329| NA| NA| Area in Nozzle Wall A2 | 2.504| NA| NA| Area in Inward Nozzle A3 | 0.000| NA| NA| Area in Welds A41+A42+A43 | 1.450| NA| NA| Area in Element A5 | 39.232| NA| NA| TOTAL AREA AVAILABLE Atot | 43.515| NA| NA| The Internal Pressure Case Governs the Analysis. Nozzle Angle Used in Area Calculations UES-17122-MDC-001 90.00 Degs. Page:71 of 96 59 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: M_24_Man Hole Nozl: 15 5:24pm Sep 27,2017 The area available without a pad is Insufficient. The area available with the given pad is Sufficient. SELECTION OF POSSIBLE REINFORCING PADS: Diameter Based on given Pad Thickness: 1107.0922 Based on given Pad Diameter: 1120.0000 Based on Shell or Nozzle Thickness: 1107.0922 Area = = = Thickness 8.0000 mm. 7.7894 mm. 8.0000 mm. Required [A]: ( d * tr*F + 2 * tn * tr*F * (1-fr1) ) UG-37(c) (611.6*6.9462*1.0+2*9.0*6.9462*1.0*(1-1.)) 42.483 cm² Reinforcement Areas per Figure UG-37.1 Area Available in Shell [A1]: = d( E1*t - F*tr ) - 2 * tn( E1*t - F*tr ) * ( 1 - fr1 ) = 611.6( 1.0 * 7.0 - 1.0 * 6.946 ) - 2 * 9.0 ( 1.0 * 7.0 - 1.0 * 6.9462 ) * ( 1 - 1. ) = 0.329 cm² Area Available in Nozzle Wall Projecting Outward [A2]: = ( 2 * Tlwp ) * ( tn - trn ) * fr2 = ( 2 * 17.5 ) * ( 9.0 - 1.85 ) * 1. = 2.504 cm² Area Available in Welds [A41 + A42 + A43]: = Wo² * fr3 + (Wi-can/0.707)² * fr2 + Wp² * fr4 = 9.0² * 1. + (0.0)² * 1. + 8.0² * 1.0 = 1.450 cm² Area Available in Element [A5]: = (min(Dp,DL)-(Nozzle OD))*(min(tp,Tlwp,te)) * fr4 = ( 1120.0 - 629.6 ) * 8.0 * 1.0 = 39.232 cm² UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 2.8455 3.5000 7.9462 7.9462 3.5000 9.3312 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 9.331, max( 7.9462, 3.5 ) ] = 7.9462 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 2.8455, 7.9462 ) = 7.9462 mm. Available Nozzle Neck Thickness = 10.0000 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of the Nozzle Neck to Flange Weld, Curve: D ---------------------------------------------------------------------Govrn. thk, tg = 10.0, tr = 1.845, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.205, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve D Min Metal Temp. at Required thickness (UCS 66.1) UES-17122-MDC-001 -48 °C -104 °C Page:72 of 96 60 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: M_24_Man Hole Nozl: 15 5:24pm Sep 27,2017 MDMT of Nozzle Neck to Pad Weld for the Nozzle, Curve: D ---------------------------------------------------------------------Govrn. thk, tg = 8.0, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.992, Temp. Reduction = 0 °C Pad governing, Conservatively assuming Pad stress = Shell stress(Div. 1 L-9.3). Min Metal Temp. w/o impact per UCS-66, Curve D -48 °C MDMT of Nozzle Neck to Pad Weld for Reinforcement pad, Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 8.0, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.992, Temp. Reduction = 0 °C Pad governing, Conservatively assuming Pad stress = Shell stress(Div. 1 L-9.3). Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -29 °C MDMT of Shell to Pad Weld at Pad OD for pad, Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 8.0, tr = 6.946, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.992, Temp. Reduction = 0 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) -29 °C -29 °C MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: D ---------------------------------------------------------------------Govrn. thk, tg = 8.0, tr = 6.946, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.992, Temp. Reduction = 0 °C Min Metal Temp. w/o impact per UCS-66, Curve D Governing MDMT of the Nozzle Governing MDMT of the Reinforcement Pad Governing MDMT of all the sub-joints of this Junction -48 °C : : : -48 °C -29 °C -29 °C Weld Size Calculations, Description: M_24_Man Hole Intermediate Calc. for nozzle/shell Welds Tmin Intermediate Calc. for pad/shell Welds TminPad 8.0000 7.0000 mm. mm. Results Per UW-16.1: Nozzle Weld Pad Weld Required Thickness 5.6000 = 0.7 * tmin. 3.5000 = 0.5*TminPad Actual Thickness 6.3630 = 0.7 * Wo mm. 5.6560 = 0.7 * Wp mm. Weld Strength and Weld Loads per UG-41.1, Sketch (a) or (b) Weld Load [W]: = (A-A1+2*tn*fr1*(E1*t-tr))*Sv = (42.4827 - 0.3293 + 2 * 9.0 * 1. * (1.0 * 7.0 - 6.9462 ) ) * 138 = 59288.25 Kgf Note: F is always set to 1.0 throughout the calculation. Weld Load [W1]: = (A2+A5+A4-(Wi-Can/.707)²*fr2)*Sv = ( 2.5041 + 39.232 + 1.45 - 0.0 * 1. ) * 138 = 60726.67 Kgf Weld Load [W2]: = (A2 + A3 + A4 + (2 * tn * t * fr1)) * Sv = ( 2.5041 + 0.0 + 0.81 + ( 1.26 ) ) * 138 = 6431.91 Kgf UES-17122-MDC-001 Page:73 of 96 61 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: M_24_Man Hole Nozl: 15 5:24pm Sep 27,2017 Weld Load [W3]: = (A2+A3+A4+A5+(2*tn*t*fr1))*S = ( 2.5041 + 0.0 + 1.45 + 39.232 + ( 1.26 ) ) * 138 = 62498.43 Kgf Strength of Connection Elements for Failure Path Analysis Shear, Outward Nozzle Weld [Sonw]: = (pi/2) * Dlo * Wo * 0.49 * Snw = ( 3.1416/2.0 ) * 629.6 * 9.0 * 0.49 * 138 = 61328. Kgf Shear, Pad Element Weld [Spew]: = (pi/2) * DP * WP * 0.49 * SEW = ( 3.1416/2.0 ) * 1120.0 * 8.0 * 0.49 * 138 = 96975. Kgf Shear, Nozzle Wall [Snw]: = (pi *( Dlr + Dlo )/4 ) * ( Thk - Can ) * 0.7 * Sn = (3.1416 * 310.3) * ( 10.0 - 1.0 ) * 0.7 * 138 = 86359. Kgf Tension, Pad Groove Weld [Tpgw]: = ( pi/2) * Dlo * Wgpn * 0.74 * Seg = (3.1416/2 ) * 629.6 * 8.0 * 0.74 * 138 = 82327. Kgf Tension, Shell Groove Weld [Tngw]: = (pi/2) * Dlo * (Wgnvi-Cas) * 0.74 * Sng = ( 3.1416/2.0 ) * 629.6 * ( 8.0 - 1.0 ) * 0.74 * 138 = 72036. Kgf Strength of Failure Paths: PATH11 = ( PATH22 = ( = ( PATH33 = ( = ( SPEW + SNW ) = ( 96975 + 86359 ) = 183334 Kgf Sonw + Tpgw + Tngw + Sinw ) 61328 + 82327 + 72036 + 0 ) = 215691 Kgf Spew + Tngw + Sinw ) 96975 + 72036 + 0 ) = 169011 Kgf Summary of Failure Path Calculations: Path 1-1 = 183334 Kgf, must exceed W = 59288 Kgf or W1 = 60726 Kgf Path 2-2 = 215690 Kgf, must exceed W = 59288 Kgf or W2 = 6431 Kgf Path 3-3 = 169011 Kgf, must exceed W = 59288 Kgf or W3 = 62498 Kgf Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.583 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 43.9254 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 209.9254 mm. Percent Elongation Calculations: % Elongation per Table UG-79-1 (50*tnom/Rf*(1-Rf/Ro)) 1.614 % PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:74 of 96 62 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N5_1_Air Relief Nozl: 16 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N5_1_Air Relief From : 30 Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient P Temp Sv Sva 8.000 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 0.0000 mm. User Entered Minimum Design Metal Temperature 0.00 mm. °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² OD 0.00 2.2500 tn deg in. Actual 6.1900 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 60.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 2.250 in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N5_1_Air Relief ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation UES-17122-MDC-001 Page:75 of 96 63 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N5_1_Air Relief Nozl: 16 5:24pm Sep 27,2017 Actual Thickness Used in Calculation 0.244 in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.0*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.0) = 6.0084 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.0*28.575)/(138*1.0+0.4*8.0) = 0.1654 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 93.5400 46.7700 12.9750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N5_1_Air Relief. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.1654 3.5000 7.6738 7.6738 3.5000 4.4200 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 4.42, max( 7.6738, 3.5 ) ] = 4.4200 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.1654, 4.42 ) = 4.4200 mm. Available Nozzle Neck Thickness = 6.1900 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 6.19, tr = 0.165, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.032, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N5_1_Air Relief Intermediate Calc. for nozzle/shell Welds Tmin 5.1900 mm. Results Per UW-16.1: UES-17122-MDC-001 Page:76 of 96 64 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N5_1_Air Relief Nozl: 16 5:24pm Sep 27,2017 Nozzle Weld Required Thickness 3.6330 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.574 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.1965 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 68.3966 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:77 of 96 65 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N6_2_Spare Nozl: 17 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N6_2_Spare Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 30 P Temp Sv Sva 8.006 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 517.0000 mm. User Entered Minimum Design Metal Temperature 0.00 mm. °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter OD 180.00 3.0000 Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² tn deg in. Actual 5.9100 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 84.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 3.000 in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N6_2_Spare ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation UES-17122-MDC-001 Page:78 of 96 66 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N6_2_Spare Nozl: 17 5:24pm Sep 27,2017 Actual Thickness Used in Calculation 0.233 in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.01*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.01) = 6.0129 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.01*38.1)/(138*1.0+0.4*8.01) = 0.2207 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 132.7600 66.3800 12.2750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N6_2_Spare. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.2207 3.5000 7.6789 7.6789 3.5000 5.8000 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 5.8, max( 7.6789, 3.5 ) ] = 5.8000 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.2207, 5.8 ) = 5.8000 mm. Available Nozzle Neck Thickness = 5.9100 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 5.91, tr = 0.221, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.045, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N6_2_Spare Intermediate Calc. for nozzle/shell Welds Tmin 4.9100 mm. Results Per UW-16.1: UES-17122-MDC-001 Page:79 of 96 67 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N6_2_Spare Nozl: 17 5:24pm Sep 27,2017 Nozzle Weld Required Thickness 3.4370 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.580 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.3496 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 92.5497 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:80 of 96 68 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N7_1/2_P G Nozl: 18 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N7_1/2_P G Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 30 P Temp Sv Sva 8.006 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 517.0000 mm. User Entered Minimum Design Metal Temperature 0.00 mm. °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter OD 225.00 1.5000 Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² tn deg in. Actual 5.1100 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 46.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 1.500 in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N7_1/2_P G ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation UES-17122-MDC-001 Page:81 of 96 69 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N7_1/2_P G Nozl: 18 5:24pm Sep 27,2017 Actual Thickness Used in Calculation 0.201 in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.01*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.01) = 6.0129 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.01*19.05)/(138*1.0+0.4*8.01) = 0.1103 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 59.7600 29.8800 10.2750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N7_1/2_P G. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.1103 3.5000 7.6789 7.6789 3.5000 4.1200 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 4.12, max( 7.6789, 3.5 ) ] = 4.1200 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.1103, 4.12 ) = 4.1200 mm. Available Nozzle Neck Thickness = 5.1100 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 5.11, tr = 0.11, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.027, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N7_1/2_P G Intermediate Calc. for nozzle/shell Welds Tmin 4.1100 mm. Results Per UW-16.1: UES-17122-MDC-001 Page:82 of 96 70 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N7_1/2_P G Nozl: 18 5:24pm Sep 27,2017 Nozzle Weld Required Thickness 2.8770 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.580 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.0874 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 54.2875 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:83 of 96 71 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N8_1_Air Inlet Nozl: 19 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N8_1_Air Inlet Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient From : 30 P Temp Sv Sva 8.006 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 517.0000 mm. User Entered Minimum Design Metal Temperature 0.00 mm. °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² OD 270.00 2.2500 tn deg in. Actual 6.1900 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 58.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 2.250 in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N8_1_Air Inlet ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation UES-17122-MDC-001 Page:84 of 96 72 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N8_1_Air Inlet Nozl: 19 5:24pm Sep 27,2017 Actual Thickness Used in Calculation 0.244 in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.01*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.01) = 6.0129 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.01*28.575)/(138*1.0+0.4*8.01) = 0.1655 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 93.5400 46.7700 12.9750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N8_1_Air Inlet. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.1655 3.5000 7.6789 7.6789 3.5000 4.4200 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 4.42, max( 7.6789, 3.5 ) ] = 4.4200 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.1655, 4.42 ) = 4.4200 mm. Available Nozzle Neck Thickness = 6.1900 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 6.19, tr = 0.166, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.032, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N8_1_Air Inlet Intermediate Calc. for nozzle/shell Welds Tmin 5.1900 mm. Results Per UW-16.1: UES-17122-MDC-001 Page:85 of 96 73 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N8_1_Air Inlet Nozl: 19 5:24pm Sep 27,2017 Nozzle Weld Required Thickness 3.6330 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.580 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.1965 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 66.3966 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:86 of 96 74 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N9_2_Level Prob Nozl: 20 5:24pm Sep 27,2017 INPUT VALUES, Nozzle Description: N9_2_Level Prob From : 30 Pressure for Reinforcement Calculations Temperature for Internal Pressure Shell Material Shell Allowable Stress at Temperature Shell Allowable Stress At Ambient P Temp Sv Sva 8.006 90 bars °C SA-516 70 137.90 N./mm² 137.90 N./mm² Inside Diameter of Elliptical Head Aspect Ratio of Elliptical Head Head Finished (Minimum) Thickness Head Internal Corrosion Allowance Head External Corrosion Allowance D Ar t c co 2300.00 2.00 8.2000 1.0000 0.0000 mm. mm. mm. Distance from Head Centerline L1 517.0000 mm. User Entered Minimum Design Metal Temperature 0.00 mm. °C Type of Element Connected to the Shell : Nozzle Material Material UNS Number Material Specification/Type Allowable Stress at Temperature Allowable Stress At Ambient Sn Sna Diameter Basis (for tr calc only) Layout Angle Diameter Size and Thickness Basis Actual Thickness Corrosion Allowance Joint Efficiency of Shell Seam at Nozzle Joint Efficiency of Nozzle Neck SA-105 K03504 Forgings 137.90 N./mm² 137.90 N./mm² OD 0.00 3.0000 tn deg in. Actual 5.9100 mm. can E1 En 1.0000 1.00 1.00 mm. Outside Projection ho Weld leg size between Nozzle and Pad/Shell Wo Groove weld depth between Nozzle and Vessel Wgnv Inside Projection h Weld leg size, Inside Element to Shell Wi ASME Code Weld Type per UW-16 84.0000 9.0000 8.0000 0.0000 0.0000 A mm. mm. mm. mm. mm. 3.000 in. The Pressure Design option was Design Pressure + static head. Nozzle Sketch (may not represent actual weld type/configuration) | | | | | | | | ____________/| | | \ | | | \ | | |____________\|__| Insert/Set-in Nozzle No Pad, no Inside projection Reinforcement CALCULATION, Description: N9_2_Level Prob ASME Code, Section VIII, Div. 1, 2015, UG-37 to UG-45 Actual Outside Diameter Used in Calculation UES-17122-MDC-001 Page:87 of 96 75 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N9_2_Level Prob Nozl: 20 5:24pm Sep 27,2017 Actual Thickness Used in Calculation 0.233 in. Nozzle input data check completed without errors. Reqd thk per UG-37(a)of Elliptical Head, Tr [Int. Press] = (P*K1*D))/(2*Sv*E-0.2*P) per UG-37(a)(3) = (8.01*0.899*2302.0002)/(2 *137.9*1.0-0.2*8.01) = 6.0129 mm. Reqd thk per UG-37(a)of Nozzle Wall, Trn [Int. Press] = (P*Ro)/(Sn*E+0.4*P) per Appendix 1-1 (a)(1) = (8.01*38.1)/(138*1.0+0.4*8.01) = 0.2207 mm. UG-40, Limits of Reinforcement : [Internal Pressure] Parallel to Vessel Wall (Diameter Limit) Parallel to Vessel Wall, opening length Normal to Vessel Wall (Thickness Limit), no pad Dl d Tlnp 132.7600 66.3800 12.2750 mm. mm. mm. Note: Taking a UG-36(c)(3)(a) exemption for nozzle: N9_2_Level Prob. This calculation is valid for nozzles that meet all the requirements of paragraph UG-36. Please check the Code carefully, especially for nozzles that are not isolated or do not meet Code spacing requirements. To force the computation of areas for small nozzles go to Tools->Configuration and check the box to force the UG-37 small nozzle area calculation or force the Appendix 1-10 computation in Nozzle Design Options. UG-45 Minimum Nozzle Neck Thickness Requirement: [Int. Press.] Wall Thickness for Internal/External pressures ta Wall Thickness per UG16(b), tr16b Wall Thickness, shell/head, internal pressure trb1 Wall Thickness tb1 = max(trb1, tr16b) Wall Thickness tb2 = max(trb2, tr16b) Wall Thickness per table UG-45 tb3 = = = = = = 1.2207 3.5000 7.6789 7.6789 3.5000 5.8000 mm. mm. mm. mm. mm. mm. Determine Nozzle Thickness candidate [tb]: = min[ tb3, max( tb1,tb2) ] = min[ 5.8, max( 7.6789, 3.5 ) ] = 5.8000 mm. Minimum Wall Thickness of Nozzle Necks [tUG-45]: = max( ta, tb ) = max( 1.2207, 5.8 ) = 5.8000 mm. Available Nozzle Neck Thickness = 5.9100 mm. --> OK Nozzle Junction Minimum Design Metal Temperature (MDMT) Calculations: MDMT of Nozzle-Shell/Head Weld for the Nozzle (UCS-66(a)1(b)), Curve: B ---------------------------------------------------------------------Govrn. thk, tg = 5.91, tr = 0.221, c = 1.0 mm., E* = 1.0 Stress Ratio = tr * (E*)/(tg - c) = 0.045, Temp. Reduction = 78 °C Min Metal Temp. w/o impact per UCS-66, Curve B Min Metal Temp. at Required thickness (UCS 66.1) Governing MDMT of all the sub-joints of this Junction -29 °C -104 °C : -104 °C Weld Size Calculations, Description: N9_2_Level Prob Intermediate Calc. for nozzle/shell Welds Tmin 4.9100 mm. Results Per UW-16.1: UES-17122-MDC-001 Page:88 of 96 76 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Calcs.: N9_2_Level Prob Nozl: 20 5:24pm Sep 27,2017 Nozzle Weld Required Thickness 3.4370 = 0.7 * tmin. Actual Thickness 6.3630 = 0.7 * Wo mm. Maximum Allowable Pressure for this Nozzle at this Location: Converged Max. Allow. Pressure in Operating case 8.580 bars Note: The MAWP of this junction was limited by the parent Shell/Head. The Drop for this Nozzle is : 0.3496 mm. The Cut Length for this Nozzle is, Drop + Ho + H + T : 92.5497 mm. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:89 of 96 77 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Schedule: Step: 29 5:24pm Sep 27,2017 78 Nozzle Schedule: Nominal or | Schd | Flg | Nozzle | Wall | Reinforcing Pad | Cut | Flg | Actual | or FVC | Type | O/Dia | Thk | Diameter Thk | Length | Class | Description Size | Type | | in | mm. | mm. mm. | mm. | | --------------------------------------------------------------------------------------------------N7_1/2_P G | 1.500 in | Actual | None| 1.500 | 5.110 | ... | ... | 54.29 | ... | N3_1_Level S G | 2.250 in | Actual | None| 2.250 | 6.190 | ... | ... | 68.36 | ... | N4_1_Level S G | 2.250 in | Actual | None| 2.250 | 6.190 | ... | ... | 68.36 | ... | N5_1_Air Relief | 2.250 in | Actual | None| 2.250 | 6.190 | ... | ... | 68.40 | ... | N8_1_Air Inlet | 2.250 in | Actual | None| 2.250 | 6.190 | ... | ... | 66.40 | ... | N2_2_Drain | 3.000 in | Actual | None| 3.000 | 5.910 | ... | ... | 101.89 | ... | N6_2_Spare | 3.000 in | Actual | None| 3.000 | 5.910 | ... | ... | 92.55 | ... | N9_2_Level Prob | 3.000 in | Actual | None| 3.000 | 5.910 | ... | ... | 92.55 | ... | N1_16_Inlet | 16.000 in | XS | WNF| 16.000 | 12.700 | 750.00 | 8.00 | 160.17 | 10 | M_24_Man Hole | 24.000 in | Actual | WNF| 24.787 | 10.000 | 1120.00 | 8.00 | 209.93 | ... | General Notes for the above table: The Cut Length is the Outside Projection + Inside Projection + Drop + In Plane Shell Thickness. This value does not include weld gaps, nor does it account for shrinkage. In the case of Oblique Nozzles, the Outside Diameter must be increased. The Re-Pad WIDTH around the nozzle is calculated as follows: Width of Pad = (Pad Outside Dia. (per above) - Nozzle Outside Dia.)/2 For hub nozzles, the thickness and diameter shown are those of the smaller and thinner section. Nozzle Material and Weld Fillet Leg Size Details (mm.): | | Shl Grve | Noz Shl/Pad | Pad OD | Pad Grve | Inside | Description | Material | Weld | Weld | Weld | Weld | Weld | ----------------------------------------------------------------------------------------------N7_1/2_P G | SA-105 | 8.000 | 9.000 | ... | ... | ... | N3_1_Level | SA-105 | 8.000 | 9.000 | ... | ... | ... | N4_1_Level | SA-105 | 8.000 | 9.000 | ... | ... | ... | N5_1_Air Re | SA-105 | 8.000 | 9.000 | ... | ... | ... | N8_1_Air In | SA-105 | 8.000 | 9.000 | ... | ... | ... | N2_2_Drain | SA-105 | 8.000 | 9.000 | ... | ... | ... | N6_2_Spare | SA-105 | 8.000 | 9.000 | ... | ... | ... | N9_2_Level | SA-105 | 8.000 | 9.000 | ... | ... | ... | N1_16_Inlet | SA-106 B | 8.000 | 9.000 | 8.000 | 8.000 | ... | M_24_Man Ho | SA-516 70 | 8.000 | 9.000 | 8.000 | 8.000 | ... | Note: The Outside projections below do not include the flange thickness. Nozzle Miscellaneous Data: | Elev/Distance | UES-17122-MDC-001 Layout | Proj | Proj | Installed in | Page:90 of 96 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Nozzle Schedule: Step: 29 5:24pm Sep 27,2017 Description | From Datum | Angle | Outside | Inside | Component | | mm.| deg | mm.| mm.| | --------------------------------------------------------------------------------------------N7_1/2_P G | ... | 225.0 | 46.00 | 0.00 | Top Head | N3_1_Level S G | 200.000 | 180.0 | 60.00 | 0.00 | Shell | N4_1_Level S G | 2900.000 | 180.0 | 60.00 | 0.00 | Shell | N5_1_Air Relief | ... | 0.0 | 60.00 | 0.00 | Top Head | N8_1_Air Inlet | ... | 270.0 | 58.00 | 0.00 | Top Head | N2_2_Drain | ... | 90.0 | 82.00 | 0.00 | BTM Head | N6_2_Spare | ... | 180.0 | 84.00 | 0.00 | Top Head | N9_2_Level Prob | ... | 0.0 | 84.00 | 0.00 | Top Head | N1_16_Inlet | ... | 0.0 | 142.00 | 0.00 | BTM Head | M_24_Man Hole | 700.000 | 90.0 | 158.00 | 0.00 | Shell | PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:91 of 96 79 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF MDMT Summary: Step: 31 5:24pm Sep 27,2017 Minimum Design Metal Temperature Results Summary : Curve Basic Reduced UG-20(f) Thickness Gov E* MDMT MDMT MDMT ratio Thk Notes °C °C °C mm. ---------------------------------------------------------------------------BTM Head [10] B -29 -30 -29 0.975 8.200 1.000 BTM Head [7] B -29 -41 -29 0.783 10.000 1.000 Shell [8] B -29 -29 -29 1.000 8.000 1.000 Top Head [10] B -29 -33 -29 0.933 8.200 1.000 Top Head [7] B -29 -43 -29 0.750 10.000 1.000 N1_16_Inlet [1] B -29 -36 -29 0.878 8.000 1.000 Nozzle Flg [4] -29 -104 0.136 N2_2_Drain [1] B -29 -104 0.047 5.910 1.000 N3_1_Level S G[1] B -29 -104 0.033 6.190 1.000 N4_1_Level S G[1] B -29 -104 0.032 6.190 1.000 M_24_Man Hole [1] B -29 -29 -29 0.992 8.000 1.000 N5_1_Air Relie[1] B -29 -104 0.032 6.190 1.000 N6_2_Spare [1] B -29 -104 0.045 5.910 1.000 N7_1/2_P G [1] B -29 -104 0.027 5.110 1.000 N8_1_Air Inlet[1] B -29 -104 0.032 6.190 1.000 N9_2_Level Pro[1] B -29 -104 0.045 5.910 1.000 ---------------------------------------------------------------------------Warmest MDMT: -29 -29 Description Required Minimum Design Metal Temperature Warmest Computed Minimum Design Metal Temperature 0 -29 °C °C Notes: [ ! ] - This was an impact tested material. [ 1] - Governing Nozzle Weld. [ 4] - ANSI Flange MDMT Calcs; Thickness ratio per UCS-66(b)(1)(c). [ 5] - ANSI Flange MDMT Calcs; Thickness ratio per UCS-66(b)(1)(b). [ 6] - MDMT Calculations at the Shell/Head Joint. [ 7] - MDMT Calculations for the Straight Flange. [ 8] - Cylinder/Cone/Flange Junction MDMT. [ 9] - Calculations in the Spherical Portion of the Head. [10] - Calculations in the Knuckle Portion of the Head. [11] - Calculated (Body Flange) Flange MDMT. [12] - Calculated Flat Head MDMT per UCS-66.3 [13] - Tubesheet MDMT, shell side, if applicable [14] - Tubesheet MDMT, tube side, if applicable [15] - Nozzle Material [16] - Shell or Head Material [17] - Impact Testing required [18] - Impact Testing not required, see UCS-66(b)(3) UG-84(b)(2) was not considered. UCS-66(g) was not considered. UCS-66(i) was not considered. Notes: Impact test temps were not entered in and not considered in the analysis. UCS-66(i) applies to impact tested materials not by specification and UCS-66(g) applies to materials impact tested per UG-84.1 General Note (c). The Basic MDMT includes the (30F) PWHT credit if applicable. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:92 of 96 80 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Vessel Design Summary: Step: 32 5:24pm Sep 27,2017 ASME Code, Section VIII, Division 1, 2015 Diameter Spec : 2300.000 mm. ID Vessel Design Length, Tangent to Tangent Distance of Bottom Tangent above Grade Specified Datum Line Distance 3100.00 mm. 0.00 0.00 mm. mm. Shell Material Nozzle Material Nozzle Material Nozzle Material Re-Pad Material SA-516 70 SA-106 B SA-105 SA-516 70 [Normalized] SA-516 70 Internal Design Temperature Internal Design Pressure 90 8.000 External Design Temperature 0 Maximum Allowable Working Pressure Hydrostatic Test Pressure 8.000 11.000 Required Minimum Design Metal Temperature Warmest Computed Minimum Design Metal Temperature Wind Design Code Earthquake Design Code 0 -29 °C bars °C bars bars °C °C ASCE-2010 UBC-97 Element Pressures and MAWP (bars): Element Description | Design Pres. | External | M.A.W.P | Corrosion | | + Stat. head | Pressure | | Allowance | ------------------------------------------------------------------------------BTM Head | 8.417 | 0.000 | 8.214 | 1.0000 | Shell | 8.355 | 0.000 | 8.000 | 1.0000 | Top Head | 8.061 | 0.000 | 8.574 | 1.0000 | Liquid Level: 4250.00 mm. Dens.: 0.001 kg./cm³ Sp. Gr.: 1.000 Element Types and Properties: Element "To" Elev Length Element Thk R e q d T h k Joint Eff Type mm. mm. mm. Int. Ext. Long Circ ----------------------------------------------------------------------Ellipse 50.0 50.0 10.0 8.0 3.5 1.00 1.00 Cylinder 3050.0 3000.0 8.0 8.0 No Calc 1.00 1.00 Ellipse 3100.0 50.0 10.0 7.7 3.5 1.00 1.00 Element thicknesses are shown as Nominal if specified, otherwise are Minimum Loads for Foundation/Support Design: Total Wind Shear on top of all Legs Total Earthquake Shear on top of all Legs Total Wind Moment at top of all Legs Total Earthquake Moment at top of all Legs Max. Max. Max. Max. Max. Max. Wind Shear on one Leg (top & bottom) Earthq. Shear on one Leg (top & bottom) Wind Moment at base of one Leg Earthquake Moment at base of one Leg Vertical Load (Wt. + Wind) on one Leg Vertical Load (Wt. + Eq.) on one Leg 227. 7594. 273. 13023. Kgf Kgf Kg-m. Kg-m. 85. 2840. 180. 6013. 4834. 9843. Kgf Kgf Kg-m. Kg-m. Kgf Kgf Note: Wind and Earthquake moments include the effects of user defined forces and moments if any exist in the job and were specified UES-17122-MDC-001 Page:93 of 96 81 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Vessel Design Summary: Step: 32 5:24pm Sep 27,2017 to act (compute loads and stresses) during these cases. Also included are moment effects due to eccentric weights if any are present in the input. Weights: Fabricated Shop Test Shipping Erected Empty Operating Field Test - Bare W/O Removable Internals Fabricated + Water ( Full ) Fab. + Rem. Intls.+ Shipping App. Fab. + Rem. Intls.+ Insul. (etc) Fab. + Intls. + Details + Wghts. Empty + Operating Liquid (No CA) Empty Weight + Water (Full) 3494.0 19552.1 3494.0 3494.0 3494.0 19552.1 19552.1 kg. kg. kg. kg. kg. kg. kg. PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:94 of 96 82 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Vessel Design Summary: Step: 32 5:24pm Sep 27,2017 Input Echo, Leg & Lug Item 1, Description: LIFTING LUGS Design Internal Pressure Design Temperature for Attachment Vessel Outside Diameter Vessel Wall Thickness Vessel Corrosion Allowance Vessel Material Vessel Allowable Stress at Design Analysis Type: TEMP OD Ts Cas S Empty Weight of Vessel Operating Weight of Vessel (vertical load ) Lifting Lug Material Lifting Lug Material UNS Number Lifting Lug Yield Stress Wemp W 3500.00 0.00 YIELD SA-36 K02600 228.20 Lifting Lug Orientation to Vessel Width of Lifting Lug w Thickness of Lifting Lug t Diameter of Hole in Lifting Lug dh Radius of Semi-Circular Arc of Lifting Lug r Height of Lug from bottom to Center of Hole h Offset from Vessel OD to Center of Hole off Minimum thickness of Fillet Weld around Lug tw Length of weld along side of Lifting Lug wl Length of Weld along Bottom of Lifting Lug wb Lift Orientation Force Along Vessel Axis Fax Force Normal to Vessel Fn Force Tangential to Vessel Ft Impact Factor Impfac Occasional Load Factor (AISC A5.2) Results for lifting lugs, Description : Weld Group Inertia about the Weld Group Centroid distance Dist. of Weld Group Centroid Weld Group Inertia about the Weld Group Centroid Distance 8.00 bars 90.00 C 2300.000 mm. 8.0000 mm. 1.0000 mm. A-516 70 159.36 N./mm^2 Lifting Lug Kgf Kgf N./mm^2 Flat 350.0000 20.0000 50.0000 130.0000 220.0000 5.0000 8.0000 130.0000 20.0000 Vertical 1750.00 1000.00 0.00 1.50 Occfac mm. mm. mm. mm. mm. mm. mm. mm. mm. Kgf Kgf Kgf 1.00 LIFTING LUGS Circumferential Axis ILC in the Long. Direction YLL from Lug bottom YLL_B Longitudinal Axis ILL in the Circ. Direction YLC 363.753 69.929 60.071 9.131 10.000 cm**4 mm. mm. cm**4 mm. Applying the Impact factor to the loads: Fax = 1750.00 * 1.50 = 2625.00 Kgf Fn = 1000.00 * 1.50 = 1500.00 Kgf Primary Shear Stress in the Welds due to Shear Loads [Ssll]: = Sqrt( Fax^2+Ft^2+Fn^2 ) / ( (2*wl+wb) * tw ) = Sqrt(2625^2+0^2+1500^2) / ( (2*130.0 +20.0 ) * 8.0000 ) = 13.24 N./mm^2 Shear Stress in the Welds due to Bending Loads [Sblf]: = (Fn*(h-YLL_B)) *YLL/ILC + (Fax*off *YLL/ILC) + (Ft*off *YLC/ILL) = (1500 *(220.000 -60.071 )) * 69.929 /363.753 + (2625 *5.000 * 69.929 /363.753 ) + (0 *5.000 * 10.000 /9.131 ) = 47.70 N./mm^2 Total Shear Stress for Combined Loads [St]: = Ssll + Sblf = 13.236 + 47.701 = 60.94 N./mm^2 Allowable Shear Stress for Combined Loads [Sta]: UES-17122-MDC-001 Page:95 of 96 83 PV Elite 2017 Licensee: UNIVERSAL ENGINEERING SERVICES LLC. FileName : Surge Tank 15M3_27.09.17_AF Vessel Design Summary: Step: 32 5:24pm Sep 27,2017 = 0.4 * Yield * Occfac (AISC Shear All.) = 0.4 * 228 * 1.00 = 91.28 N./mm^2 Shear Stress in Lug above Hole [Shs]: = Sqrt( Fax^2 + Fn^2 + Ft^2 ) / Sha = Sqrt( 2625^2 + 1500^2 + 0^2 ) / 42.000 = 7.06 N./mm^2 Allowable Shear Stress in Lug above Hole [Sas]: = 0.4 * Yield * Occfac = 0.4 * 228 * 1.00 = 91.28 N./mm^2 Pin Hole = Sqrt( = Sqrt( = 25.74 Bearing Stress [Pbs]: Fax^2 + Ft^2 ) / ( t * dh ) 2625^2 + 0^2 ) / ( 20.000 * 50.000 ) N./mm^2 Allowable Bearing Stress [Pba]: = Min( 0.75 * Yield * Occfac, 0.9*Yield ) AISC Bearing All. = Min( 0.75 * 228 * 1.00 , 205.4 ) = 171.15 N./mm^2 Bending stress at the base of the lug [Fbs]: = Fn*(h-wl) / (w*t^2 / 6) + Ft*(h-wl) / (w^2*t / 6) = 1500 *(220.000 - 130.000 ) / (350.000 *20.000^2 / 6) + 0 *(220.000 - 130.000 ) / (350.000^2 *20.000 / 6) = 56.74 N./mm^2 Tensile stress at the base of the lug [Fa]: = Fax / (w * t) = 2625 / (350.000 * 20.000 ) = 3.68 N./mm^2 Total Combined Stress at the base of the lug: = Fbs + Fa = 60.4 N./mm^2 Lug Allowable Stress for Bending and Tension: = Min( 0.66 * Yield * Occfac, 0.75*Yield ) = Min( 0.66 * 228 * 1.00 , 171.1 ) = 150.6 N./mm^2 Note: Check the Shell Stresses using method such as WRC-107. Summary of Results Stress (N./mm2 -----------------------------------------------------------------------------Primary Shear Stress of Weld : 60.94 91.28 Ok | Shear Stress above Hole : 7.06 91.28 Ok | Pin Hole Bearing Stress : 25.74 171.15 Ok | Total Combined Stress at the base of the lug : 60.42 150.61 Ok | PV Elite is a trademark of Intergraph CADWorx & Analysis Solutions, Inc. 2017 UES-17122-MDC-001 Page:96 of 96 84

2. Design Calculation Report for Surge Vessel 28 09 17

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