Report No. 240046-R-001, 'Seismic Verification Review of Auxiliary ... · EQE International has...
Transcript of Report No. 240046-R-001, 'Seismic Verification Review of Auxiliary ... · EQE International has...
Report No. 240046-R.001
SEISMIC VERIFICATION REVIEW OF AUXILIARYSTEAM SYSTEM PIPINGTHREE MILE ISLAND UNIT I
REVISION I
June 5, 1998
Prepared for:
GPU NUCLEAR
' F I ADC00 F22
EQE INTERNATjONAL.. I
240046-R-001Revision 1June 5, 1998Page 2
SEISMIC VERIFICATION REVIEW OF AUXILIARYSTEAM SYSTEM PIPINGTHREE MILE ISLAND UNIT I
REVISION I
June 5, 1998
Prepared by:
EQE ENGINEERING CONSULTANTS
Prepared for
GPU NUCLEAR
THREE MILE ISLAND
Route 441
Middletown, PA 17057
46R1 REVI .DOC
240046-R-001Revision 1June 5, 1998Page 3
i) 1998 by EQE InternationalALL RIGHTS RESERVED
The information contained in this document isconfidential and proprietary data. No part of thisdocument may be reproduced or transmitted in anyform or by any means, electronic or mechanical,including photo-copying, recording, or by anyinformation storage and retrieval system, withoutpermission in writing from EQE Incorporated.
46R1 REV1.DOC
2q�.
240046-R-01Revision 1June 5, 1998Page 4
TABLE OF REVISIONS
Revision
0
1
Description of Revision
Original Issue
Minor clarifications onpages 6, 8, 9, 13 &14
Date Anoroved
April 30, 1998
June 5, 1998
46R1 REVI .DOC
'K-'
L
240046-R-001Revision 1June 5, 1998Page 5
APPROVAL COVER SHEET
TITLE: SEISMIC VERIFICATION REVIEW OF AUXILIARY STEAM
SYSTEM PIPING -THREE MILE ISLAND UNIT I
REPORT NUMBER:
CLIENT:
PROJECT NO.:
240046-R-001
GPU NUCLEAR
240046
REVISION RECORD
REV. NO. DATE PREPARED REVIEWED APPROVED
0 4130/98 @ibLi / Ia)
24046RTMI.DOC
240046-R-001Revision 1June 5, 1998Page 6
SUMMARY
EQE International has performed a seismic verification review of the Three MileIsland Unit 1 auxiliary steam piping which could adversely affect safety relatedequipment if pressure integrity is not maintained.
The review used acceptance criteria derived from earthquake experience data. Aseismic verification walkdown was performed by senior engineers familiar withearthquake experience data, seismic verification techniques developed by theSeismic Qualification Utility Group, and seismic margin assessment procedures.The walkdown was supplemented by a confirmatory analysis of a portion of thesystem. The analysis used seismic margin assessment criteria with the seismicmargin earthquake set to the plant SSE.
The results of the walkdown and the confirmatory analysis are that the systemmeets the seismic criteria in the applicable areas of the plant. It is concluded thatthe system has sufficient seismic margin to maintain pressure integrity during andfollowing a seismic event equal to the plant SSE.
-46R1 REVI .DOC
240046-R-001Revision 1June 5, 1998Page 7
TABLE OF CONTENTS
PageL SUMMARY . . 61.0 PURPOSE .8
| 2.0 SCOPE ... 92.1 PIPING REVIEWED .: 92.2 SCOPE OF REVIEW .10
3.0 CRITERIA .. 113.1 WALKDOWN SCREENING CRITERIA .11
3.2 SEISMIC MARGIN CRITERIA .13
L 4.0 WALKDOWN .15
5.0 ANALYSIS .16
6.0 CONCLUSIONS .18
7.0 REFERENCES .19
ATTACHMENTS
Page
1_ A. WALKDOWN DATA SHEETS .................................................. A1-A13
B. WALKDOWN PROCEDURE 240046-P-OO1 ........................................... B1-B30
C. TRAINING AND QUALIFICATIONS .................................................. C1-C4
D. ANALYSIS RESULTS - EQE CALCULATION 240046-C4001 .................. D1-D81
E. WALKDOWN PHOTOGRAPHS ................................................... E1-E12
L
14
k . 46R1 REV1 .DOC
240046-R-001Revision 1June 5, 1998Page 8
1.0 PURPOSE
The purpose of this project was to provide a seismic verification review of theThree Mile Island Unit 1 auxiliary steam system piping in certain areas of the plant.There are safety related equipment located in these areas which could be adverselyaffected by a steam line break.
The system is not safety related and was not designed to plant seismic design basisrequirements. The seismic verification review uses the results of research into theeffects of past strong earthquakes on similar piping to assess if the auxiliary steampiping will maintain pressure integrity during an earthquake equal to the plant safeshutdown earthquake. The review technique is similar to that used to verifyseismic adequacy of equipment using earthquake experience data. This wassupplemented by a seismic margin assessment of a portion of the system.
46R1 rovl .doc
240046-R-001Revision 1June 5, 1998Page 9
2.0 SCOPE
2.1 PIPING REVIEWED
[ The piping that requires seismic verification includes those portions of the auxiliary* steam system which run through the control building, fuel building and auxiliary
building. Isometric drawings of the extent of the main 8-inch diameter header ineach building are included in the walkdown notes in Attachment A. Branch linesfrom the main run were included up to their termination points or where they exitthe building. The piping layout is shown on Gilbert drawing E-304-751 Revision 10.
_ The auxiliary steam piping in the control building consists of an 8-inch diameterheader which runs along the H3 column line. The piping enters the control building(from the intermediate building) through wall penetration 1847 south of the 8bcolumn line. The pipe runs south along the H3 line at approximately elevation 362'-
X 6w. The piping then drops down to elevation 329'-0 at the 1 la column line,continues south approximately 9-feet, and turns west through a wall penetrationinto the fuel handling building.
The auxiliary steam piping in the fuel handling building includes the 8-inch diameterheader and a 2-inch diameter branch line which runs to three manual valves at threeelevations in the decontamination pit. The header enters the fuel building throughthe wall penetration south of the H3 line, and runs to anchor AS-1 55 in thereceiving and shipping area. The header then runs from the anchor to a loop whichturns west and crosses the J column line into the auxiliary building below theelevation 305' floor slab.
The in-scope auxiliary steam piping in the auxiliary building includes the 8-inchdiameter header west of the J column line, and east of the K column line to anchorAS-1 56 at elevation 294'IO. The piping includes branch lines at steam trap AS-ST-31 (as shown in section B-B on drawing E-304-751). piping and steam trapsattached to the L line wall (as shown in isometric view B on Drawing E-304-751),and condensate lines running to the auxiliary steam condensate return unit AS-P-2A/2B. Branch line piping beyond manual valve AS-V-102 is included to the extent
46R1 revi .doc
240046-R-o01Revision IJune 5, 1998Page 10
required for structural boundary only since this valve is normally closed. Auxiliarysteam piping west of the L line wall is not included in the scope since this piping isisolated in the A and B miscellaneous waste evaporator rooms, and in theconcentrated waste storage tank room.
2.2 SCOPE OF REVIEW
The scope of the review is analogous to that used for seismic verification ofmechanical equipment under the USI A-46 program. This methodology is describedin detail in References 3 and 4. The NRC has approved the methodology inReference 5. The extension of the methodology to piping is described inReference 6.
The scope of review consisted of a comparison to the piping in the earthquakeexperience database, a spectral comparison per Reference 4 to verify applicabilityof the database, and a walkdown by a qualified seismic review team to assure thatthe caveats of Reference 6 are met. A representative portion of the piping wasselected for a margin analysis as a benchmark for the walkdown screeningverification.
46Rlrovl.doc _
240046-R-001Revision IJune 5, 1998Page 1 1
3.0 CRITERIA
3.1 WALKDOWN SCREENING CRITERIA
In recent years, a great deal of field data has been collected on the performance ofpiping in earthquakes. EQE International has assembled an earthquake experiencedatabase on structures, equipment, and piping from more than 20 strong motionearthquakes. The database contains a very diverse and robust set of groundmotions, structures, and piping configurations.
Reference 8 contains an analysis of the piping failures (leaks, breaks, collapse, orloss of flow control) observed in the earthquake experience data. Reference 9contains a detailed study of the piping at 20 power plant units in the database inaddition to a literature review of the effects of 29 earthquakes from 1923 to 1985.For above ground welded steel piping, failures were found to be caused only byseismic anchor motion (terminal end equipment movement, header movements atsmall branch connections, or differential movements between buildings), excessivedeterioration of the wall thickness, progressive hanger failure, and seismic inter-action. Failures resulting from seismic inertia stresses were not observed.
These results are further supported by the results of full scale testing. Reference10 states:
Experience data collected by SQUG and others and high-level seismic tests onpiping conducted in foreign countries and in the U.S. show that piping is notsusceptible to failure resulting from seismic inertia loads. The only observedinstances of piping failure during the SQUG program to collect seismicexperience data were due to relative motion of anchor points and inadequate ornonexistent anchorage of tanks or equipment for sites with zero periodacceleration between 0.25g and 0.60g.f
Reference 6 contains guidelines for visually evaluating piping against the failuremodes observed in the earthquake experience data. The evaluation is performed bya seismic review team using procedures similar to those used for equipment under
46Rlrev1 .doc
240046-R-001Revision IJune 5, 1998Page 12
the USI A-46 program (Reference 4) and for piping under the EPRI seismic marginassessment guidelines (Reference 7). The detailed inspection procedures arecontained in EQE procedure 240046-P-001, included as Attachment B of thisreport.
A key element in the criteria is the experience and qualifications of the seismicreview team members. References 3 and 7 give qualifications for seismic reviewteam members. In summary, these are:
* Knowledge of earthquake experience data
* Knowledge of nuclear design standards and practice
* Ability to perform fragility/margins type evaluations
* General understanding of SPRA conclusions
* General knowledge of plant systems
* Minimum of five years applicable experience
* Professional Engineer registration
The experience data must be shown to be applicable to the piping underconsideration. As shown in Reference 9, the database contains an enormousamount of steam piping of size, construction, operating temperature and pressure,and support (primarily rod hung) similar to the auxiliary steam system piping at TMI.
The experience data must also be applicable in terms of level of excitation.Reference 4 gives criteria for this in the form of a generic bounding ground responsespectrum which must envelop the site design basis response spectrum at 5%damping. TMI-1 was determined to meet this criterion from USI A-46documentation.
46R1 rev l.doc
L 240046-R-001Revision IJune 5, 1998Page 13
3.2 SEISMIC MARGIN CRITERIA
A portion of the piping which includes the 8-inch diameter header from anchor AS-155 in the fuel handling building to anchor AS-1 56 in the auxiliary building wasselected for confirmatory analysis. This portion of the piping was selected becauseit contains branch lines which were judged to have the potential to restrain freemovement of the 8-inch header, resulting in high stresses at the branch lineconnection to the header, and which contain threaded connections susceptible tobrittle failures. The analysis was a seismic margin analysis using the conservativedeterministic failure margin (CDFM) approach as described in Reference 7. Thisapproach is summarized in Table 3-1.
For this project, the seismic margin earthquake (SME) was taken as the TMI-1 safeshutdown earthquake (SSE). Broadened floor response spectra from the TMI-1 USIA-46 review were conservatively used for seismic demand determination rather
than the unbroadened, median centered floor response spectra with frequencyshifting called for in Reference 7. The piping was linearly analyzed using 56
L; damping per Reference 7. Resulting stresses were compared to ANSI B31.1allowables equivalent to ASME Service Level D (comparing Equation 12 stresses to3.0 Sh). The 0.8 factor to account for inelastic energy'absorption wasconservatively not applied.
The analysis used the floor response spectra in the vertical and two horizontaldirections with stresses combined by SRSS.
L-L
0 X -46R~vtvl .oc
240046-R-01Revision IJune 5, 1998Page 14
TABLE 3-1
SUMMARY OF CONSERVATIVE DETERMINISTIC FAILURE MARGIN APPROACH(From Reference 7)
Load Combination: Normal + SMEGround Response Spectrum: Conservatively specified (84% Non-Exceedance
Probability)DConservative estimate of median dampingStructural Model: Best Estimate (Median) + Uncertainty Variation In
FrequencySoil-Structure-Interaction Best Estimate (Median + Parameter VariationMaterial Strength: Code specified minimum strength or 95%
exceedance actual strength if test data are available.Static Capacity Equations: Code ultimate strength (ACI), maximum strength(AISC), Service Level D (ASME), or functional limits.If test data are available to demonstrate excessiveconservatism of code equations, then use 84%exceedance of test data for capacity equation.
Inelastic Energy Absorption: For non-brittle failure modes and linear analysis, use80% of computed seismic stress in capacityevaluation to account for ductility benefits, or performnonlinear analysis and go to 95% exceedanceductility levels.*
In-Structure (Floor) Spectra Use frequency shifting* rather than peak broadeningGeneration: to use account for uncertainty plus use mediandamping.
*Conservatively not used in this evaluation
46Rlrevl .doc
240046-R-001Revision IJune 5, 1998Page 15
4.0 WALKDOWN
The walkdown covered the areas described in Section 2. The walkdownrequirements were specified in EQE Procedure 240046-P-001, which is included asAttachment B to this report. The seismic review team (SRT) was made up of twosenior EQE personnel who meet the SRT requirements of References 4 and 7. TheSRT qualification sheets are included as Attachment C.
The results were documented on screening and evaluation worksheets. Thecompleted worksheets are included as Attachment A to this report.
Hanger anchorages were visually inspected by the SRT and found to be acceptableper Procedure 240046-P-001. For anchorage using expansion anchors, the base.plate and anchor bolt arrangement was compared to standard industrial designpractice per the experience of the SRT members. Anchor bolts were inspected forsigns of looseness, lack of washers, oversize bolt holes, gaps under the base plate,and improper bolt spacing and edge distance. Welded anchorages were visuallyinspected for normal workmanship and thickness.
Since the main run piping is supported on rod and spring hangers without lateralrestraint capability, special attention was given to potentially damaging seismicinteractions between the piping and its supports, and the nearby structures,systems and components. Seismic movements of up to six inches in any horizontaldirection were assumed.
The results of the SRT walkdown were that the piping and supports met thewalkdown criteria, with one exception, and were judged by the SRT to be able tomaintain pressure integrity during the safe shutdown earthquake (SSE). The oneexception was the branch piping at steam trap AS-ST-31, which contained threadedconnections and had a rigid restraint in close proximity to the flexible main run.This piping was selected as the bounding case for further analysis.
46R1revl .doc
240046-R-001Revision IJune 5, 1998
l Page 16
5.0 ANALYSIS
A portion of the in-scope piping was analyzed by the conservative deterministicfailure margin (CDFM) method as described in Section 3. The portion of the piping
L analyzed was selected because it contained the only area of concern from thewalkdown. The seismic margin earthquake (SME) was set equal to the plant safe
L shutdown earthquake (SSE). The stresses were compared to 3.0 Sh, which is theASME Class 3 Level D service limit divided by 0.8 to account for inelastic energyabsorption.
The piping analyzed included the 8-inch diameter piping from anchor MK-AS-1 55 inL the fuel handling building to anchor MK-AS-1 56 in the auxiliary building. This piping
is shown on Gilbert Associates drawing E-304-751. The model also included theL branch piping to and from steam trap AS-ST-31. This piping is shown in section B-
B on drawing E-304-751. The two 1-inch diameter lines were modeled sufficientlyfrom the steam trap that the effects on the area of concern (the piping between the8-inch main run and the guide support on the 3/4 inch threaded piping) would be
L included.
The analysis included deadweight and thermal conditions, as well as two horizontalL and one vertical components of earthquake. The earthquake excitation consisted of
N-S, E-W, and vertical floor response spectra at 5% damping. Vertical responsespectra were taken as 2/3 of the horizontal.
The results were that the highest stress occurred in the 1-inch diameter branch atL the 2x1x3/4 inch tee immediately adjacent to the 8-inch main run piping. The
maximum stress was 35 ksi, or 83% of the CDFM capacity. Stresses in the 8-inchmain run were less than 10 ksi. Forces in the hangers on the main piping werecompared to the design loads on hanger drawings, and the hangers were judged tobe acceptable. Anchorage loads for the guide support on the branch piping werecomputed and found to be small.
L The maximum horizontal displacements were computed to be approximately four- inches. This compares favorably with the six inches assumed during the walkdown.
46R1 revl .doc
240046-R-001Revision 1June 5, 1998!- -Page 17
The analysis results are contained in Attachment D to this report. The analysis wasperformed in accordance with 1 OCFR 50 Appendix B Quality Assurance
L requirements under the EQE Engineering Quality Assurance Program.
46R1 revl .doc
240046-R-001Revision IJune 5, 1998Page 18
6.0 CONCLUSIONS
EQE International has performed a seismic verification walkdown of the applicableportions of the auxiliary steam supply system by a qualified seismic review team. Ithas also performed a confirmatory seismic margin analysis of a bounding portion ofthe system.
The results show that there is sufficient seismic margin inherent in the as-builtpiping to conclude that the probability of a pipe break occurring during a safeshutdown earthquake is extremely low. Therefore, it is concluded that this systemwill not adversely affect the operability of safety related equipment in the plant.
46R1 tevI .doc
240046-R-001Revision IJune 5,. 1998l iPage 19
!
7.0 REFERENCES
L 1. USNRC. February1997. GenericLetter87-02,VerificationofSeismicAdequacyof Mechanical and Electrical Equipment in Operating Reactors, Unresolved SafetyIssue (USI) A-46.m
2. EQE Incorporated, Piping Seismic Adequacy Criteria Recommendation Based onPerformance During and After Earthquakes,* 2 Volumes. Prepared for the ElectricPower Research Institute, RP-2635-1, February 1987.
3. SSRAP Report, "Use of Seismic Experience Data to Show Ruggedness ofEquipment in Nuclear Power Plants," Senior Seismic Review and Advisory Panel,
L Revision 4.0, February 28, 1991.
4. Bishop, Cook, Purcell and Reynolds; EQE Incorporated; MPR Associates, Inc.;Stevenson & Associates; URS Corporation/John A. Blume and Associates.December 1988. "Generic Implementation Procedure (GIP) for Seismic Verification
- of Nuclear Plant Equipment," Revision 2 corrected 2/28/91.
5. USNRC, "Supplemental Safety Evaluation Report No. 1 on SQUG GenericImplementation Procedure, Revision 1," June 29, 1990.
6. P.D. Baughman, et al., "Seismic Evaluation of Piping Using Experience Data,"Second Symposium on Current Issues Related to Nuclear Plant Structures,L Equipment and Piping, December, 1988.
7. EPRI NP-6041, Revision 1, uA Methodology for Assessment of Nuclear Power PlantSeismic Margin,", Electric Power Research Institute, Palo Alto, CA, prepared byL NTS Engineering, Long Beach, CA, and RPK Consulting, Yorba Unda CA, July1991.
L 8. P.D. Smith, et al., "Experience Data on the Performance of Piping Systems inEarthquakes," Proceedings of the 1985 ASME Pressure Vessels and PipingConference, June, 1985.
9. M.S. Silver, et al., "Piping Seismic Adequacy Criteria Recommendations Based onPiping Performance During and After Earthquakes," EPRI RP-2635-1, February,1987.
10. USNRC, "Regulatory Analysis for Resolution of Unresolved Safety Issue A-46,Seismic Qualification of Equipment in Operating Plants." NUREG-121 1, February,1987.
11. Senior Seismic Review and Advisory Panel (SSRAP), "Review Procedure to AssessK> Seismic Ruggedness of Cantilever Bracket Cable Tray Supports," Prepared forSeismic Qualification Utility Group, October, 1988.
46Rlrevl .doc
240046-R-M1Revision IJune 5, 1998
- Page A I
ATTACHMENT A:
WALKDOWN DATA SHEETS
46RrevlAdoc
.L I
stem Name
L Equip. ID No.
I Une Identifier
Bldg. C
SCREENING AND EVALUATION WORKSHEET (SEWS)
Aj4V$tG1Adf Srq 1V s, moM . Az/L,&4%-
V1/4 Equip. Class 23-Piolna System Without Dynamic Analysis/IA CDAV,7AS'L 4WuL
?#I SOQ,'y 6SWi47/- LI4', 5tC . N Iv0-1
I, Floor Elevation(s) 55•' 2
Drawing No. 64I ar x -3W- -75i "V 10
e..~-iA A~i0~f'd JJcdar - . ... 44. ~.I1 '~- 6--- w' -rII UWW411W V 0JJC:. INW. - - -If!:
L- Operating Pressure/Temperature
. -1 - �- . I � -� - W- I
PSIG °F___
' Pioina System Boundar
Description AUX -57tv41/ llA4/ 41iiWIW Mg( CO477AOL.. 6(1fL ,LO/W6, 1 P
/01,AI f1J1As -5 AS r 4P7X, 9.L- 34Z'-164 FIZeNl ITf I- COw,~ ,
ulvAzj. Jl('3 r Af ,/3 P/P ( f gL, '- 0 k T7 S
L or sketch (attach sheets as necessary)v,5!9£r 7Y!du1w 1qLL ,AFvYr/?40,'V.'J (7A*,F&CC 4(aLOV6r-.
nctionalitv Reauirement
-1J DuringSeismic~vn } ,4~~c 7-~^K J
L 2. After Seismic Event AMSo r /%OUz4.AY
Evaluation by -/4.d -
DatN U9 N U
Date #qZ/
L The piping system boundary Includes the piping configuration from component to component (or other anchorpoints). Other interconnections to the subject piping are included from the connection to the first anchor point
I or component. An anchor Is defined as a point at which the pipe Is restrained In 3 directions and 3 rotations ori through a series of supports which provide equivalent restraint of the pipe.
Caveats- Pi2ina
L 1. Does the piping configuration appear to have adequate flexibi-lity to accommodate the thermal loading?
2. No visible damage?L 3. No significant visible rust/corrosion deterioration?
4. Are all fittings standard?5. No potentially brittle connections (threaded joints, cast Iron
fittings, etc.)?6. Does the piping configuration appear to have adequate flexibil-
lity to accommodate differential movement of vibrating components?7. IDo the support spans appear to follow ANSI 631.1 requirements?
No unreinforced main/branch connections?No unusual pipe attachments?
U N/A
NNNN
U NfAU N/AU NfAU NJA
Y N U )
Y N$N
U N/AU N/A'U N/A
i tL SCREENING AND
I L~1p. ID No. AmU c5X4Gf /4/e COA'7oc. 6C//f4,,v6-
) EVALUATION WORKSHEET (SEWS)
Equip. Class 23-Pioina System Without Dynamic Analysis
10. No heavy valves supported by small bore vent and/or drain pipes11. Does the piping configuration at building joints appear to have
L adequate flexibility to accommodate seismic Induced differentialmovement?
12. No in-line components which can be subject to impact due to seismicInduced movements?
13. No fittings (bellow, flexible hoses, etc.) which can be adverselyaffected by seismic Induced differential movements?
14. Free of piping attached to poorly anchored equipment?A' 15. No stiff piping attached to flexible equipment?
16. No stiff branch piping attached to the main line with potentiallysignificant movements?
17. No other concerns (if no, comment on separate sheets and attach)?
N UN U
NfAN/A
0 N U N/A
() N U N/A
() N U NIA9 N U N/AO) * N U NfA
(I N UAre the caveats met?
L ( N U
Date - */i'4Evaluation by __ _ _ _ _
Caveats - Suimorts
1 No visible damage?No visible rust/corrosion deterioration?L iNo unusual design?No customized parts used in place of catalog parts, whichappear Inadequate?
D . Are the support settings (spring hangers, etc.) adequate?L 6. Free of any sliding surfaces which appear not to be performing
their intended function?7. No one-way guide support with the potential for the piping toL slide off during a seismic event8. Free of support details which appear to have been altered to
accommodate Interferences or other problems?9. Do nuts have full thread engagement?10. No friction beam clamps?11. Do concrete expansion bolts appear to have adequate
| Bolt centerline to plate edge distanceL Bolt centerline to bolt distance
Bolt centerline to concrete edge distanceBolt centerline to empty hole
Lx 12. Does the anchorage appear adequate (attach SEWS 25A through25.F, as required)?
13. No additional concerns (f no, document comments on separatesheet and attach).
Are the above caveats met?
Evaluation by__ __ __ __
N UN UN UN U
& N U
& N U
) N UN U
N/AN/AN/ANIA
N/AN/A
N/A
N/A
N/AN/A
I;) N U NYAUY N U NfA
O N N/A
O N U
Date 5.-U -Z9-f
SCREENING AND EVALUATIL, tC/ j. 57zm
I-~uip. ID No. Py' CONML 6'- Equip.Class
ION WORKSHEET (SEWS)
23-Pidno System Without Dynamic Analysis
Interaction EffectsI
1. Soft targets free from impact by nearby equipment or structures? 6 N U NWA2. Distribution branch lines have adequate flexibility? Alo 6Atfv' (,4rXs & N U3. No collapse of overhead equipment, distribution systems, or (& N U w
I masonry walls?4. No other concerns? (9 N U NIA
I ~Is equipment free of Interaction effects?
Evaluation by_ _ _ __ _ _
Is the piping system seismically adequate?
@) N U
Date ~-VZ-7ff
P N U
L Comments P/Pf4'6- INa.vO4S 7ME AOWLcN,,W- S-r.os/4,r:
ASIVY. hts-'q. '4's-1509 A-/S-
#511.3 AMxS-g
I All aspects of the equipment's seismic adequacy have been addressed.
L Evaluated by: J / (44
(ll team members) 6.-cAy?t . iI
Date: q-2 -i-f
-- 141.)k
[ JOB rA / ir / JOB NO. Z° '
SUBJECT AUXYIC44Y acEtI /A CON77ML eW& CALC NO.
! 9 J-2DATE3'as CHD _ DATE _______ SHEET NO. _OF
I 7 L~ 41
I A
co)p
1*0131
SCREENING AND EVALUATION WORKSHEET (SEWS)
R?14M4,/Z SA H4 IA] 'V4EL (4410AU1V6-- 3,uA1C-Kl-4sterm Name
- Equip. ID No. 4'14 EnUinU-.1 as 23-PiDIn_ System Without Dynamic Analvsis, "r _. _
Une Identifier
Bldg. F'
?' $5//#*'dY NR4D I,,. / LV f5(11L0'v-.-A, It A'6AcqICoV 'rlav 7a
f ta 77AVch, 64 V Floor Elevation(s) 9o;So'P.C#OVT4f/1(d4i7o&Al'pr
Drawing No. 6-iC-szr A- 3 o - 7S e, lo
Drawina SDec. No. W14o41L SA4.C. 54-5sYCA q 5596Operating PressurerTemperature PSIG °F
--------- -
Pioina System Boundary*
Description A jG 5 A4P ','kW6- WINH mA- Ae M40 moV& 4We6k
(Isuy /plo.) i9r X4 3i5z$ -~O#3 ofieA W ACvd~-f2:.S j'sC sv 0 ,: 11.t w s, 3z'reg 4fs 0>5 ors omox 7touw(tMAS- 4.r- 4L'A'S Fvoi'r AC/44. 101wr Ir A. y~'¶OA4Moo dM.1 21'} A#O WEsr 440,C. -&" 7D cOWS-S
_ or sketch (attach sheets as necessary) j tpjvC vtrM 4/y. e06t, #Ctd'WS ZA# 4dA41
-qlncionality Recuirernen UwP4;qPNWA7 A/W",-M1 0r
During Seismic Event? IYp, ,n r A0,nlf
2. After Seismic Event J
Evaluation by V I/C(
DtN UT) N U
Date V-Z4--!f
*Te piping system boundary Includes the piping configuration from component to component (or other anchorpoints). Other interconnections to the subject piping are included from the connection to the first anchor pointor component An anchor Is defined as a point at which the pipe Is restrained In 3 directions and 3 rotations orthrough a series of supports which provide equivalent restraint of the pipe.
Caveats - PipLna
1. Does the piping configuration appear to have adequate flexdbi-lity to accommodate the thermal loading?
2. No visible damage?3. No significant visible rustlcorroslon deterioration?4. Are all fittings standard?5. No potentially brittle connections (threaded joints, cast Iron
fitings, etc.)?6. Does the piping configuration appear to have adequate flexibil-
lity to accommodate differential movement of vibrating components?7. Do the support spans appear to follow ANSI B31.1 requirements?
No unreinforced main/branch connections?y No unusual pipe attachments?
0 N U N/A
N U N/AN U N/AN U N/AN U N/A
N U )
N U NJAN U NIAN U N/A
SCREENING AND EVALUATION WORKSHEET (SEWS)
> ID No. A? )e 5J4M4 IA/ Equip. Classm 23-Pioina Svstem Without Dvnamic AnalvsisFVFL% H4)Vf s i5L/ V6-
10. No heavy valves supported by small bore vent and/or drain pipes11. Does the piping configuration at building joints appear to have
adequate flexibility to accommodate seismic Induced differentialmovement?
12. No In-line components which can be subject to Impact due to seismicinduced movements?
13. No fittings (bellow, flexible hoses, etc.) which can be adverselyaffected by seismic induced differential movements?
14. Free of piping attached to poorly anchored equipment?15. No stiff piping attached to flexible equipment?16. No stiff branch piping attached to the main fine with potentially
significant movements?17. No other concerns (ff no, comment on separate sheets and attach)?
Are the caveats met?
N UN U
NZANIA
N U NWA
N U N/A
N U NWAN U NIAN U NMA
N U
N U
Evaluation by ' WC/ ( Date q -Z/-j(
Caveats - Suncorts
1. No visible damage?2. No visible rust/corrosion deterioration?
'No unusual design?_Jo customized parts used In place of catalog parts, which
appear Inadequate?;. Are the support settings (spring hangers. etc.) adequate?W. Free of any sliding surfaces which appear not to be performing
their Intended function?No one-way guide support with the potential for the piping toslide off during a seismic event.Free of support details which appear to have been altered toaccommodate Interferences or other problems?Do nuts have full thread engagement?
). No friction beam damps?Do concrete expansion bolts appear to have adequate
Bolt centerline to plate edge distanceBolt centerline to bolt distanceBolt centerline to concrete edge distanceSBolt centerline to empty hole
Does the anchorage appear adequate (attach SEWS 25A through26.F, as required)?No additional concerns (If no, document comments on separatesheet and attach).
the above caveats met?
NNNN
U N/AU N/AU NWAU N/A
N U WtAN U N/A
N U N/A
N U .NA
N U . NfAN U (E!3Y
NN
U N/AU NWA
N/A
U
Evaluation by Dew - .. Date My Z/
SCREENING AND EVALUATION WORKSHEET (SEWS)K> 14' 31SMA~f //V pU-1-L..
Equip. ID No. /4A'/IA'U (/LOW Equip. Class 23-Pilina System Without Dynamic Analvsis
Interaction Effects
- 1. Soft targets free from Impact by nearby equipment or structures? N U2. Distribution branch lines have adequate flexibility? N U3. No collapse of overhead equipment, distribution systems, or N U
masonmy walls?4. No other concerns? @j N U
L Is equipment free of Interaction effects? ( N U
Evaluation by -tI ( - - Date j
Is the piping system seismically adequate? ()N U
NIANWAN/A
NJA
Comments fk',shf- I4/LC . gage4Cwol, SimAgvr-
L4AS 4''-J/, S- fS7 4-/g3 s-J AS-/3
z9 Asv L : /N-37 /LW-yo1 ?v A/o rYwsmu~s s OVA6VINC- 71 7)MC O jos7Zrjn' Ar
_ All aspects of the equipment's seismic adequacy have been addressed. PAfOs "Li ,
Evaluated by: _
(All team members)
Vtm/(ny
jrAf4E5 7 -* //Date: Yg /w-f
/V h/s-
L-
f :I
JOB TAf £'er / JOB NO. 2Uoy6V SUBJECT i' tmdy s7EA MI >a/tL BC06-D CALC NO.
Y / DATE '4 'St CHK'D DATE. _______ SHEET NO. OF__
_ U- SA
fairlyvil, 301
4/
lI..ystem Name
Equip. ID No.
SCREENING AND EVALUATION WORKSHEET (SEWS)41VXRLzYf 5Xf INV AUXAay gofdl-
Equip. Class 23-Pimina System Without Dynamic AnalysisUne Identifier 9" f 51MY Me9Ahe -JW 4OXrLI4C ' 61I/LO/A- 7W WL 4gudi2. 4S-/S6
/F "src OlUAW W.V S ~ V f,Bld. Ah)I</4A Floor Elevation(s) W'-" 17 70 AVK, Sf4ADrawing No. 6-I L64.7- N1O, £ -0Y V -7/ /ifxV, /a C47/ZgTV*4 rcDrawing Sm No.n M14)J1AL 5B.r, SP - qcsuq v ci- < (A t5 -p2A )
-r,--. ---- - - - -.- ---- -1 -- I I -F -- W I
Operating PressuremTemperature PSIG
MPlina Svstem Boundary'
Description Wk 5T7AA P//bv P 1I1h7Yrf/ : VCY/tIoAl2, a '44'6-,0 *VAoYf~d4.E'x ),,,ws wiS-w 4/7wjvol l.J, AP,te. 7~3~M L1VT m Q
6 "~v- Q 7LVS T* 4v 1w,%g wrfr iv 4@o'Cjmoz/PN- Rz-rf 1W.41 F(g ,Lfwgz.sbus a a
or sketch (attach sheets as necessary) 1,r ( 4r @ (7 CJ PfAC 4k'/.qnctionalith Reguirement
- During Seismic Event7 MP4'- M1hf' 'Y#fAM/IW
2. After Seismic Event JEvaluation by __ _
Dat N U@ N U
Date Ys-U-tv
'The piping system boundary Includes the piping configuration from component to component (or other anchor- points). Other interconnections to the subject piping are Included from the connection to the first anchor pointor component. An anchor Is defined as a point at which the pipe Is restrained In 3 directions and 3 rotations orthrough a series of supports which provide equivalent restraint of the pipe.
Caveats - Pipina
L 1. Does the piping configuration appear to have adequate flexibi-lity to accommodate the thermal loading?
2. No visible damage?3. No significant visible rust/corosion deterioration?4. Are all fittings standard?5. No potentially brittle connections (threaded joints, cast Iron
fittings, etc.)?L 6. Does the piping configuration appear to have adequate flexibil-
Miy to accommodate differential movement of vibrating components?7. Do the support spans appear to follow ANSI B31.1 requirements?
U_ ' No unreinforced main/branch connections?y ~ No unusual pipe attachments?
N U NIA
U NIAU NJAU NfA r3/'4i ' erel#J4U N/A 1.4r SMW
U N/AU N/AU NfA
NNN
SCREENING AND EVALUATION WORKSHEET (SEWS)i I . W ux S ap r4/4' ES
i "uip.ID No. gme i yd&,% 114W6 Equip.Class -23-Pidna System Wdhout Dv'namic Analysis
10. No heavy valves supported by small bore vent and/or drain pipes11. Does the piping configuration at building joints appear to have
adequate flexibility to accommodate seismic induced differentialmovement?
12. No in-line components which can be subject to Impact due to seismicInduced movements?
L 13. No fittings (bellow, flexible hoses, etc.) which can be adverselyaffected by seismic Induced differential movements?
14. Free of piping attached to poorly anchored equipment?L 15. No stiff piping attached to flexible equipment?
16. No stiff branch piping attached to the main line with potentiallysignificant movements?
17. No other concerns (if no, comment on separate sheets and attach)?
Are the caveats met?
N(5N
(g N
M N
a6
Pi N
Date - 2 f-f
U N/AU N/A
U N/A
U N/A
U NIAU N/A a*c'e6wj AU NMA Ar %7, Y&V
(a~s 4t-106U CAG4o tb
U
Evaluation by 'ICt 4A'vk CI
Caveats - SUDDOrtS
1. No visible damage?No visible rust/corrosion deterioration?No unusual design?No customized parts used In place of catalog parts, whichappear Inadequate?! 5. Are the support settings (spring hangers, etc.) adequate?
L 6. Free of any sliding surfaces which appear not to be performingtheir Intended function?
7. No one-way guide support with the potential for the piping toL 8 slide off during a seismic event.8. Free of support details which appearto have been altered to
accommodate Interferences or other problems?9. Do nuts have full thread engagement?
L 10. No friction beam damps?11. Do concrete expansion bolts appear to have adequate
- Bolt centerdine to plate edge distanceL Bolt centerline to bolt distance
Bolt centerline to concrete edge distanceS Bolt centerline to empty hole
12. Does the anchorage appear adequate (attach SEWS 25A through25.F, as required)?
13. No additional concerns (If no, document comments on separatesheet and attach).
Are the above caveats met?
NNNN
U N/AU N/AU NIAU NIA
N UN U
N/AN/A
V
N U N/A
U N/AN
N U N/AN U __
U NIAU NIA
N/A
O N U
Date -ZEvaluation by .=
L SCREENING AND EVALUATION WORKSHEET (SEWS)L)p U) S 1-49AI 141
Equip. ID No. 140XU4'ty 4A11vi4 Equip. Class 23-Piping System Without Dynamic Analysis
Interaction Effects
I
L!
L
I. Sou wrlijs iree from Impac by nearby equipment or structures?2. DistrIbution branch lines have adequate flexibility?3. No collapse of overhead equipment, distribution systems, or
masonry walls?4. No other concerns?
Is equipment free of interaction effects?
Evaluation by_ ___ _
Is the piping system seismically adequate?
(3 N Ur2 N UDt N U.
& j N U
. D- N U
Date y Wl
oe' U
WANtANfA
NIA
Comments PAi06- /A'C(L'41ZS MeX rOc W 6 £ Mowqs.
L A : /ZSWvs-lg. , -?S-i/ q , 6s-,qb,45-,sfg SS/y-tPs&AM
I 'O'' ,2 L/ 6* es /Z 2L All aspects of the equipments seismic adequacy have been addressed.
Evaluated by: _ L t 1 .,/ Date: Y/
(All team members) _ 4/Li/f t
L _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
Li
L
il
LI YJBY Jv~W_
I-
JOB Jew £4tvr ' JOB NO. Z_ _____
SUBJECr 4VXIL,4.4 0 1Y A AUK CALC NO.
DATE a- 1Z'f CKD (7s DATE /Z 3/ ^ SHEET NO. OF
4-1
t*g'l
ei;b
~~4,"tni
I i
L'
240046-R-001Revision IJune 5, 1998Page B I of 30
ATTACHMENT B:
WALKDOWN PROCEDURE 240046-P-001
COVER SHEET AND 29 PAGES
Il
,I
6-I
: _46R1 revI .doc
EQE PROCEDURE TO PERFORM DATA GATHERING AND SCREENINGWALKDOWN FOR THE AUXILIARY STEAM SYSTEM PIPING
AT THREE MILE ISLAND UNIT 1
Project Performed For:
GPU Nuclear Corp.
K>PROCEDURE NO.:
REVISION NO.:
DATE:
240046-P-001
0
April 29, 1998
PREPARED BYIDATE:
- REVIEWED BY/DATE_
APPROVED BYIDATE_
.r/ A 9 4- 7-1go.. I d-7"9
�-!q f
- ,
IK)
Procedure 240046-P-001Revision 0April 30, 1998Page 3
TABLE OF REVISIONS
Revision Description of Revision Date Aporoved
0 Original Issue April 29, 1998
K>
24046PRO.DOC
Procedure 240046-P-001Revision 0April 30, 1998Page 4
L TABLE OF CONTENTS
PageLi1.0 SCOPE ......... 5
2.0 RESPONSIBILITIES .................. 6
LL 3.0 DEFINITIONS ......... '7
L 4.0 METHODOLOGY ......... 95.0 PROCEDURE ............................ 12
5.1 PIPING AND PIPE SUPPORTS .125.2 ANCHORAGE .16
L 6.0 SEISMIC INTERACTION REVIEW .19
7.0 REQUIRED DOCUMENTATION. 208.0 QUALIlY ASSURANCE .21
L 9.0 REFERENCES .22i
ATTACHMENTS
lA. TRAINING VERIFICATION SHEET .A-1 TO A-2
B. SEISMIC REVIEW TEAM MEMBER QUALIFICATION SHEET ...... B-1 TO B-2
L C. SCREENING AND EVALUATION WORKSHEETS .................................... C-1 TO C-4
24046PRO.DOC
Procedure 240046-P-001Revision 0April 30, 1998Page 5
1.0 SCOPE
This procedure describes the activities and required procedures for implementationof a data gathering and screening walkdown for seismic verification of the awdliarysteam piping system at Three Mile Island Unit 1.
The purpose of this activity is to gather and document the information required forverification of the seismic adequacy of this system.
All work performed for this project will be done in accordance with the latestrevision of the EQE Quality Assurance Manual (Reference 4).
24046PRO.doc
Procedure 240046-P-p01Revision 0April 30, 1998Page 6I
2.0 RESPONSIBILITIES
The project manager shall be responsible for ensuring the implementation of thisprocedure.
The project manager shall be responsible for ensuring that the seismic review teammembers are trained in accordance with this procedure prior to performing thewalkdown. This will be documented on training verification forms included asAttachment A to this procedure.
The project manager shall be responsible for organizing and directing thewalkdowns in accordance with this procedure. The individual seismic review teammembers shall be responsible for the. actual performance of the walkdowns anddocumentation of the results.
L24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998
L Page 7L
3.0 DEFINITIONS
LA. SEISMIC REVIEW TEAM
L The Seismic Review Team (SRT) engineers performing the evaluation must bedegreed engineers, with considerable experience in structural and/or earthquake
L engineering applicable to nuclear power plants. SRT engineers shall meet therequirements for seismic capability engineers as defined in References 3 and 8.I.The SRT engineers shall successfully complete a training course on the backgroundfor, the philosophy behind, and the use of these seismic evaluation guidelines. At
L least two SRT engineers shall comprise a team of which at least one shall be alicensed professional engineer.
L. As a group, the SRT shall possess knowledge in the performance of equipment,systems, and structures during strong-motion earthquakes in industrial process andpower plants. They shall also understand conduct of nuclear plant walkdowns;nuclear design codes and standards; and seismic design, analysis, and test
L qualification practices for nuclear power plants.
The core SRT may be supplemented by additional personnel for the purpose ofL documenting field conditions not shown on plant drawings. The qualifications forthese personnel will be determined by the project manager.
Each engineer involved in the walkdown or evaluation shall submit a resume ofqualifications and experience per Attachment B. In addition, documentation of
L having completed the required training shall also be on file.
B. EVALUATION
L An assessment of the seismic adequacy of the as-installed piping and pipe supportsusing the Screening and Evaluation Worksheets included as Attachment C. Theseworksheets were developed based on predicted failure modes as defined in
., Reference 9.
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 8
C. OUTUER
As-installed piping that does not meet the guidelines of this procedure. Outliers aredispositioned by office based review using analysis or other accepted means.
L
1.
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998
L -Page 9
4.0 METHODOLOGY
Very few components of nuclear plant systems are unique to nuclear facilities.Nuclear plant systems include electrical panels and switchgear, air compressors,
- tanks, piping, conduit, and many other' items that are common components ofconventional power plants and industrial facilities. The seismic experience database was developed to address the problem of seismic qualification for equipmentwhich was purchased as common "off the shelf" items or for commodities whichrequire an upgrade in seismic classification. By reviewing the performance offacilities that contain equipment similar to that found in nuclear plant, conclusionscan be drawn about the performance of nuclear plant equipment during and after adesign basis earthquake. Typical sources of seismic damage for different classes ofequipment and piping have been obtained and are explained in detail in References
L and 9.
Visual and design document review examination of piping systems are to beperformed to assess valve vulnerabilities and potential for pipe failure. SeismicL inertial effects in welded steel piping systems are not considered to be primaryfailure initiators. Inadequate piping system flexibility and excessive relative supportdeflections are the more likely contributors to seismically-induced failures thandynamic shaking effects for welded steel pipe. Impact of valve operators onadjacent structures or equipment are the only credible valve failure modes of
L concern. Items to be observed in the walkdown are:
1. Preferably, the piping systems should not be fabricated with threaded orvictaulic or other mechanical friction-type of connections. These detailsproduce a non-ductile system that is sensitive to inertia loads and supportconfigurations for strong motion earthquakes. When observed, these detailsneed to receive special attention.
2. The use of cast iron pipe is a potential problem since it does not have thestrength or ductility of steel, and usually has low capacity connections.
> 3. Branch lines out to their first support could be a potential concern if they donot have adequate flexibility. The necessary flexibility can come fromeither the supports or the pipe routing. Short, straight branch lines that are
| ~24046PRO~doe
Procedure 240046-P-001Revision 0L 0April 30, 1998Page 10
L..
connected to relatively rigid anchor points are candidates for failure if themajor run pipe is not restrained from motion close to the branch.
4. The connection of pipe into vessels, heat exchangers, and other equipmentanchor points could be of concern if the details used could transmitexcessive loads to the nozzles. This situation could result from:
a. Flexibility in the equipment support with the pipe system being rigidlysupported near the equipment.
b. Long unsupported runs of pipe adjacent to the equipment, particularly ifiJ heavy in-line components are mounted near the equipment.
L c. Pipe support failure near the equipment. Any indication of potentialweak links in these supports should be noted for further evaluation.
5. Proximity of valve operators to structures, components, or other subsystemsshould be examined. The principal concern for active valves is that theoperator support may be bent so that the valve will not change position ordemand. For passive valves, the only concern is fracture of the top worksL that could breach the pressure boundary.
6. Multiple failure of threaded rod supports (unzipping) on non-seismic pipingcould, in instances of potentially long runs of pipe, result in piping failure andsubsequent flooding problems.
7. The use of vibration or shock isolation systems on equipment to which pipingattaches could adversely affect the seismic performance if the piping system
L if the pipe segments to the first support on either side of this component areL not flexible enough to accommodate the equipment motion.
8. The piping details across seismic gaps or between two buildings should be* reviewed. Insufficient flexibilities in the routing detail could affect the pipeintegrity for seismic differential building motions.
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 11
9. The increased pipe seismic responses may produce seismic interactionconcerns. The following conditions should be reviewed during thewalkdowns:
a. That supports can accommodate motions in directions other than theprimary load path. This concern is applicable to the clevis ends ofstruts and snubbers, and is not a concern unless there exists follow-onconsequences, as seismic missiles or seismic interaction.
b. Relatively flexible spans that could have seismic interactionramifications.
c. Supports that only restrain dead weight loads and do not restrict theL pipe from sliding off.
24046PR0.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 12
5.0 PROCEDURE
5.1 PIPING AND PIPE SUPPORTS
Piping systems in the seismic experience database have performed very well inearthquakes, even though they were typically designed for dead and operating loadsonly, with little or no consideration for seismic loads (Reference 7). Databasepiping and selective analytical review are the basis for review of the auxiliary steamsystem piping.
In order to use experience data to evaluate piping the following must bedemonstrated: (1) database representation, and (2) known seismic vulnerabilities ofpiping must be addressed. Instances of seismic damage to database piping havebeen the result of seismic anchor movement (SAM), seismic systems interaction(and impact), and corrosion. The database has demonstrated that inertial failures ofpiping are not credible as long as standard industrial or better design practices areemployed.
5.1.1 Database Revresentation of Piging
In order to assure database representation of piping systems, the followingconditions must be met:
1. The design basis ground spectra for the nuclear facility are less than thebounding spectrum per Reference 2.
2. Piping installations must follow industry-standard practices (e.g., ANSIB31.1 spans and supports).
3. The piping system does not display known seismic vulnerabilities or employL. seismically sensitive characteristics, such as brittle joints or mechanicalcouplings which could be adversely affected by differential movement.
24046PRO~doc
Procedure 240046-P-001Revision 0April 30, 1998Page 13
KJ
Piping and pipe supports should be reviewed for the following to assure databaserepresentation:
The piping configuration must have adequate flexibility to accommodate itsthermal loading. The concern is that piping which appears highly stresseddue to normal operating loads may perform poorly under an additionalseismic load.
* Visible damage to piping or supports (e.g., broken supports, loose U-bolts)_ may adversely affect piping seismic performance.
* Unusual conditions (non-standard fittings, unusual pipe attachments,'.. unusual support design, customized parts used in place of catalog parts,
i pipe supports that have been modified) should be considered as potentialoutliers: judgement should be used to evaluate if these conditions representa deviation from piping systems in the experience database.
a Brittle connections (e.g., threaded joints, cast iron fittings) should beconsidered as potential outliers. The experience database has demonstrated
-: the seismic vulnerability of these connections. Unreinforced branchconnections should be reviewed as they may represent deviation fromnormal industrial installation practices.
* The adequacy of pipe support installation (e.g., spring hanger settings,sliding supports which may have been restrained to preclude pipe sliding,one-way guide supports which may not restrain the pipe from sliding off
|- under lateral seismic loads) should be reviewed by the SRT.
L Friction clamps should not be oriented in such a way that gravity loads areresisted only by the clamping or frictional forces developed by the clamps.
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 14
5.1.2 Seismic Anchor Movement
The experience database includes several instances of seismic damage to pipingand supports that were attributed to seismic anchor movement. Damage was theresult of excessive movement of terminal end equipment, differential movementbetween pipe supports in adjacent buildings, and excessive movements imposed onbranch lines by flexible headers.
As a result of these instances of damage, the following attributes must beevaluated by the seismic review team during their piping walkdown.
* Piping configurations at building joints and between buildings should haveadequate flexibility to accommodate seismically-induced differential buildingmovement.
* Fittings which can be adversely affected by seismically-induced differentialmovement (e.g., bellows, flexible hoses) should be evaluated for adequateflexible.
* Piping attached to unanchored or poorly anchored equipment should beconsidered an outlier. Stiff piping attached to flexible equipment should beevaluated to verify that the piping will not act as an equipment anchorage.In addition, the piping configuration should have adequate flexibility toaccommodate vibrating components.
* Conditions where stiffly supported branch lines are attached to flexibly-supported (e.g., rod-hung) mainlines or headers should be considered aspotential outliers. The seismic review team should evaluate thisconfiguration for potential damage due to seismically-induced differentialmovement.
24046PROdoc
Procedure 240046-P-001Revision 0April 30, 1998
_ Page 15
.KJ
5.1.3 Seismic Interaction Concerns for Pinina
Guidelines for evaluating potential interaction hazards to items, including pipingsystems, are presented in Section 6. Particular attention should be given tohazardous interactions to piping with threaded or bolted connections for possiblebreach of pressure boundary. In addition, interactions involving impact of valveoperators, vents and drains, and fragile appurtenances, should be evaluated indetail.
5.1.4 Pine Corrosion
The experience database includes instances of seismic damage to piping andsupports that were attributed to excessive corrosion. Therefore, the seismic reviewteam should evaluate both piping and pipe supports for rust or corrosion
Ldeterioration.
5.1.5 Selective Analytical Review
A sampling of the piping configurations and pipe supports shall be selected foranalytical review if it is considered appropriate by the SRT.
The sample size shall be determined by the SRT, based on the diversity, complexityand extent of the systems or areas being evaluated. Supports which are heavilyloaded or which appear to have marginal anchorages shall be selected.
Detailed sketches of the sample piping and supports shall be included in the fieldwalkdown notes. Sketches shall include the location, support configuration,dimensions, connection details, anchorage attributes, member sizes, and tributarylengths. The data sheet shall include notes describing the basis for selection ofeach sample. Any additional information that may be considered relevant to theseismic ruggedness of the sample support shall be noted.
_-
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 16
5.2 ANCHORAGE
Anchorage of pipe supports shall be visually inspected in accordance with theguidelines of Reference 3. The extent of tightness testing to be performed forexpansion anchor bolts shall be determined by the SRT based on accessibility ofequipment and the extent of estimated loadings.
5.2.1 Exnansion Anchor Bolts
5.2.1.1 Inspection Guidelines Expansion anchors shall be evaluated in the plant toensure that proper installation has been obtained. The sample size of thisevaluation shall be of sufficient quantity to satisfy the SRT engineers that properinstallation has been achieved. This visual inspection shall include the following:
* A washer is installed between the equipment base and the bolt head or nut.If the equipment base is made of structural steel plate, then a washer is notneeded if the bolt-hole diameter in the structural steel plate appears to beno greater that the nominal bolt diameter plus 1/16 inch.
* The concrete is sound with no significant cracks in the vicinity of the anchorLy bolt.
* The gap between the equipment base and the concrete surface is less thanL or equal to 1/4 inch.
L The bolt spacing is greater than about 10 times the bolt diameter.
* The distance between the bolt and any free concrete surface is greater thanapproximately 10 times the bolt diameter.
* The bolt is installed with at least the minimum embedment.
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 17
For shell type anchors, the minimum embedment is ensured if the shell does notprotrude above the surface of the concrete. For non-shell type anchors, theminimum embedment is ensured if the projection of the bolt above the surfaceL conforms with the following:
Bolt Allow. BoltDiameter Projection(Inches) (Inches)
3/8 1/2
1/2 5/8
5I8 7/8
314 1-1/2
1 *1-1/25.2.2 Cast-In-Place Anchor Bolts
5.2.2.1 Insoection Guidelines. Cast-in-place bolts shall be evaluated to ensure thatproper installation has been obtained. This visual inspection shall include thefollowing:
A washer is installed between the equipment base and the bolt head or nut. If theequipment base is made of structural steel plate, then a washer is not needed if thebolt-hole diameter in the structural steel plate appears to be no greater than thenominal bolt diameter plus 1/16 inch.
The concrete is sound with no significant cracks in the vicinity of the anchor bolt.
The gap between the equipment base and the concrete surface is less than or equalto 1/4 inch.
The bolt spacing is greater than about 10 times the bolt diameter.
The distance between the bolt and any free concrete surface is greater thanL. approximately 10 times the bolt diameter.
24046PRO.doc
L Procedure 240046-P-001Revision 0April 30,1998Page 18
5.2.3 Welded Anchoraces
5.2.3.1 Inspection Guides Welded anchorages shall be evaluated to ensure thatproper installation has been obtained. This visual inspection shall include the
L following:
L . Check for weld bum-through on thin sections.
* Limit weld thickness, t, to thickness of thinner part being connected.
* If plug welds are found and required to take tension loads, they are to beconsidered as an outlier.
5.2.4 Allowable Values
L Realistic capacity estimates should be used when performing the vertical andhorizontal load capability checks. Realistic capacity values, shear-tensioninteraction formulas, and reduction factors for edge distance and center to centerspacing for anchors and welds are defined in EPRI report "Seismic AnchorageGuidelines for Nuclear Plant Equipment* (Reference 5).
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 19
6.0 SEISMIC INTERACTION REVIEW
L The seismic interaction review is a visual inspection of structures, piping, orequipment adjacent to the equipment under evaluation. The seismic interactionreview also includes the identification of all seismically induced failures ordisplacements of any adjacent structures, piping, or equipment that could adverselyaffect the capability of the equipment under consideration. Particular attentionshould be given to adjacent non-safety-related structures, piping, and equipment.
- The review team should identify and evaluate all credible and significant interactionhazards in the immediate vicinity of the equipment being evaluated. Evaluation ofinteraction effects shall consider detrimental effects on the capability of equipmentand systems to function, taking into account equipment attributes such as mass,size, support configuration, and material hardness in conjunction with the physicalrelationships of interacting equipment, systems, and structures. In the evaluation ofproximity effects and overhead or adjacent equipment failure and interactions, theeffects of intervening structures and equipment which would preclude impact
! should be considered.
Damage from interaction in earthquakes results from unusual circumstances or fromL. generic, simple details such as open hooks on suspended lights. In the interaction
review, the SRT should look for (1) unusual impact situations, and (2) lack of properanchorage or bracing of adjacent equipment.
L
L
24046PR0.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 20
L7.0 REQUIRED DOCUMENTATION
The walkdown shall be documented by notes and observations recorded on theSEWS sheets from Attachment C. The SEWS sheets shall be signed and dated byall members of the SRT.
The qualification and training of the individual seismic review team members shallbe documented on Attachments A and B.
24046PRO.doc
Procedure 240046-P-001Revision 0April 30, 1998Page 21
1:- 8.0 QUALITY ASSURANCE
This walkdown shall be performed in accordance with the latest revision of the EQE
Quality Assurance Manual (Reference 4).
24046PROAd0o
Procedure 240046-P-001Revision 0April 30,1998Page22
9.0 REFERENCES
1. USNRC. February 1987. "Generic Letter 87-02, Verification of Seismic Adequacyof Mechanical and Electrical Equipment in Operating Reactors, Unresolved SafetyIssue (USI) A-46."
2. SSRAP Report, OUse of Seismic Experience Data to Show Ruggedness ofEquipment in Nuclear Power Plants," Senior Seismic Review and Advisory Panel,Revision 4.0, February 28, 1991.
3. Bishop, Cook, Purcell, and Reynolds; EQE Incorporated; MPR Associates, Inc.;L Stevenson and Associates; URS Corporation/John A. Blume and Associates:December 1988." Generic Implementation Procedure (GIP) for Seismic Verificationof Nuclear Plant Equipment," Revision 2 corrected 2/28/91
4. EQE Engineering. November 15, 1991. "Quality Assurance Manual," Revision 2.
L 5. EPRI Report NP-5228, Revision 1, "Seismic Verification of Nuclear Plant EquipmentAnchorage," Electric Power Research Institute, Palo Alto, CA, prepared by URSCorporation/John A. Blume & Associates, Engineers, June 1991.
L 6. EPRI Report NP-7149, "Summary of the Seismic Adequacy of Twenty Classes ofEquipment Required for Safe Shutdown of Nuclear Plants," Electric PowerResearch Institute, Palo Alto, CA, prepared by EQE, Inc., March 1991
- 7. EQE Incorporated, "Piping Seismic Adequacy Criteria Recommendation Based onPerformance during and after Earthquakes", 2 Volumes. Prepared for the Electric
U Power Research Institute, RP-2635-1, February 1987.
8. EPRI NP-6041, Revision 1, "A Methodology for Assessment of Nuclear Power PlantSeismic Margin," Electric Power Research Institute, Palo Alto, CA, prepared by NTSEngineering, Long Beach, California, and RPK Consulting, Yorba Unda, CA, July1991.
9. EQE Incorporated. 1986. "Power Piping During and After Earthquakes." Vol. 1.Prepared for the Electric Power Research Institute. San Francisco, CA.
LL
24046PRO.doc
Procedure 240046-P-001Revision 0April 29, 1998Page Al of 2L
ATTACHMENT A:
TRAINING VERIFICATION SHEET
Procedure 240046-P-001Revision 0April 29, 1998Page A2 of 2
l EXHIBIT 1L TRAINING SESSION RECORDS
Description of Session Topic(s): _
LInstructor:-
Designated Attendees:
Print or Tvne Name Initial Sinaturel at
!
*My signatumreinitials attest to mypresenice during the prescribed training session and generalunderstanding of the subject matter. As of now, anry questions I might have had regarding sessionL subject matter have been answered to my satisfaction.
L
Procedure 240046-P-001Revision 0April 29, 1998Page BI of 2
ATTACHMENT B:
SEISMIC REVIEW TEAM MEMBERS
QUALIFICATION SHEET
LI U
LI :I
L
L
LUl
i
"I
Procedure 240046-P-001Revision 0April 29, 1998Page B2 of 2
SEISMIC REVIEW TEAM QUALIFICATION SHEET
1.0 Name:
2.0 Company:
3.0 Position:
4.0 Education:
5.0 Professional engineers registration:
6.0 Engineering discipline:
7.0 Areas of expertise_
L-,-
L 7.1
1 7.2L
+ .7.3
7.4
L
L7.5
!
L 8.0
L 9.0
LSign
L
Experience
Knowledge of failure modes
Knowledge of nuclear design STDs & nuclearseismic design practice
Seismic capability evaluations
Knowledge of equipment- Nuclear- Heavy industrial process plants- Fossil fuel power plants
Conduit/Cable tray evaluations
Training Courses
Other qualifications
Years Experience
-
ature nave-&LOua__ _
Procedure 240046-P-001Revision 0April 29, 1998Page C1 of 4
ATTACHMENT C
SCREENING AND EVALUATION WORKSHEETS
IiIL7� 11--7�1�
1 iIL�
Procedure 240046-P-001Revision 0April 29, 1998Page C2 of 4
SCREENING AND EVALUATION WORKSHEET (SEWS)System Name
Equip. ID No.
Une Identifier
Equip. Class 23-Pining System Without Dynamic Analysis
Bldg. Floor Elevation(s)_
Drawing No.
Drawing Spec. No.
Operating Pressure/remperature _ __ PSIG
Pining System Boundary'
Description
, or sketch (attach sheets as necessary)
Functionality Recuirement
1. During Seismic Event
2. After Seismic EventY N UY N U
Evaluation by Date
*The piping system boundary Includes the piping configuration from component to component (or other anchor points)L Other Interconnections to the subject piping are Included from the connection to the first anchor point or componentanchor is defined as a point at which the pipe Is restrained In 3 directions and 3 rotations or through a series of supporwhich provide equivalent restraint of the pipe.
Caveats - Piping
L1. Does the piping configuration appear to have adequate flexAbi-lity to accommodate the therTnal loading?
2. No visible damage?3. No significant visible rust/corrosion deterioration?4. Are afl fittings standard?5. No potentially brittle connections (threaded joints, cast Ion
fittings, etc.)?6. Does the piping configuration appear to have adequate flexibil-
L7 lity to accommodate differential movement of vibrating components?\ -~7. Do the support spans appear to follow ANSI 831.1 requirements?
8. No unreinforced main/branch connections?9. No unusual pipe attachments?
Y N U N/A
Y N U N/AY N U N/AY N U N/AY N U NIA
Y N U N/A
Y N U N/AY N U N/AY N U N/A
Procedure 240046-P-001Revision 0April 29, 1998Page C3 of 4
SCREENING AND EVALUATION WORKSHEET (SEWS)
Equip. ID No. Equip. Class -2-Pl-ino System Without Dynamic Analysis
10. No heavy valves supported by small bore vent andlor drain pipesL t1. Does the piping configuration at building joints appear to haveadequate flexibility to accommodate seismic Induced differentialmovement?
12. No in-line components which can be subject to Impact due to seismicInduced movements?
L 13. No fittings (bellow, flexible hoses, etc.) which can be adverselyaffected by seismic Induced differential movernerits?L 14. Free of piping attached to poorly anchored equipment?
15. No stiff piping attached to flexible equipment?16. No stiff branch piping attached to the main line with potentially
significant movements?17. No other concerns (if no, comment on separate sheets and attach)?LAre the caveats met?
Evaluation by
; aveats - SuPDoils
1. No visible damage?2. No visible rust/corrosion deterioration?3. No unusual design?4. No customized parts used in place of catalog parts, which
appear Inadequate?L0 5. Are the support settings (spring hangers, etc.) adequate?L 6. Free of any sliding surfaces which appear not to be performingtheir intended function?
7. No one-way guide support with the potential for the piping toslide off during a seismic event
8. Free of support details which appear to have been altered toaccommodate Interferences or other problems?
9. Do nuts have full thread engagement?L 10. No friction beam clamps?
11. Do concrete expansion bolts appear to have adequateS Bolt centerline to plate edge distance
L Bolt centerline to bolt distanceBolt centerline to concrete edge distanceBolt centerline to empty hole
12. Does the anchorage appear adequate (attach SEWS 25A through25.F, as required)?
13. No additional concerns (If no, document comments on separate
L sheet and attach).K Are the above caveats met?
Y N UY N U
Y N U
Y N U
Y N UY N UY N U
N/ANIA
N/A
NWA
NIANfANfA
Y N U
Y N U
Date
Y N UY N UY N UY N U
Y N UY N U
Y N U
Y N U
Y N UY N U
N/AN/AN/AN/A
N/AN/A
N/A
N/A
NIAN/A
Y N U N/AY N U NA.
Y N N/A
Y N U
Evaluation by Date
Procedure 240046-P-001Revision 0April 29, 1998Page C4 of 4
SCREENING AND EVALUATION WORKSHEET (SEWS)
Equip. ID No. Equip. Class 23-Pipinc, System Without Dynamic Analysis
Interaction Effects
L 1. Soft targets free from Impact by nearby equipment or structures?2. Distribution branch lines have adequate fleibilty?3. No collapse of overhead equipment, distribution systems, or
masonry walls?L 4. No other concerns?
| Is equipment free of Interaction effects?
Evaluation by _
Y N U N/AY N U N/AY N U N/A
Y N U N/A
Y N U
Date
Is the piping system seismically adequate? Y N U
Comments
L All aspects of the equipment's seismic adequacy have been addressed.Li Evaluated by Date:
(AM team members)
LIIL
L
A,
240048-R-001Revision IJune 5, 1998Page C 1
ATTACHMENT C:
TRAINING AND QUALIFICATIONS
j,
LLK-
46R1 revl .doc
I-
-L
L
*l
L.,1
I
-I1
Procedure 240046-P-00tRevision 0April 29, 1998Page B2 of 2
SEISMIC REVIEW TEAM QUALIFICATION SHEET
1.0 Name: t49AS L W/7.
2.0 Company:
3.0 Position: G odV1p/ C4WjL/scTJ7Wi.-
4.0 Education:
5.0 Professional engineers registration: A4(SS/ 5A4'e/. Flour
6.0 Engineering discipline: C0 V/L. Sfnl1 C7Ly
7.0 Areas of expertise: C-V1 C S7VIC,- 7J7dL M&VAL f 6'127N4VWCA f
Lu~1 7.1
7.2
7.3
L 7.4
_
.L 7.5
L 8.0
L 9.0
L signatu.
Experience
Knowledge of failure modes
Knowledge of nuclear design STDs & nuclearseismic design practice
Seismic capability evaluations
Knowledge of equipment- Nuclear- Heavy industrial process plants- Fossil fuel power plants
Years Experience
/0 Usabl- Slap
20*e
Conduit/Cable tray evaluations 20
Training Courses 6Q(C A4LXOICW /i'gC . ao sJ nzc
Other qualifications AMIWC /Atl em0 57XS.S AMAC JV#APOJ-reC /9044 L D ate±6z
rW, D /Gate 'j-s
Procedure 240046-P-001Revision 0April 29, 1998L Page A2 of 2
EXHIBIT I
TRAINING SESSION RECORDS
Description of Session Topic(s): "DZi LIV1L" VA/I 0Vo IV1A5 ZVO4'7W-,--001A4V~, 0, -f0ag os #V SC.C.A oG -1tfV1(-141zs
P4=Zq/1&- 47r Mrz/ &.56b M4r-r- Ag 0 NVor- Wfr 51f.Ajk OFpeL
L Instructor: A 0, 0e 0)CA8lL Dsnated6+ yfesDesiqnated Attendees:
L Print or Tvoe Name Initial Sianature* Da
L A e1. X9dvMAd ._ _ __ _ _ _ _ _ 'f/71
i_ £ C. WN(? . 24/ - 94716
LL-
L *My signatureirnitials attest to my presence during the prescribed training session and generalunderstanding of the subject matter. As of now, ary questions I might have had regarding session
| subject matter have been answered to my satisfaction.
A
f
L
1.0
2.0
iL" 3.0
L 4.0
L-
5.0
. 6.0
7.0
Procedure 240046-P-OltRevision 0April 29, 1998Page 82 of 2
SEISMIC REVIEW TEAM QUALIFICATION SHEET
Name: PAVL b Z.AfJ
Company:
Position: 54. J~LcfTJ4
Education: BscE, s
Professional engineers registration: 5 tJ /
Engineering discipline: 6 IViiLf 57ZverueC?-L
Areas of expertise: 61/VIL. 377ZUsRA-. "&CtM*Jj/CAL. •i le-5- /
Experience
L 7.1 Knowledge of failure mode
7.2 Knowledge of nuclear desi!L seismic design practice
7.3 Seismic capability evaluatih
7.4 Knowledge of equipment- Nuclear- Heavy industrial process
- - Fossil fuel power plants
L 7.5 Conduit/Cable tray evaluati
8.0 Training Courses..$ U
9.0 Other qualifications Stp'JZ
L Signature
L
es
gn STDs & nuclear
ins
plants
Years Experience
2-5-4-
_25T4(Ioi US SJ4J 30U
/0 i-
ions - /0 f,-
WDky&AIMJF /IEf A&2A-oaJ
-A0 5?1E, I~~t MAf"1fj!
-DateSZS5
240046-R-01Revision IJune 5, 1998Page D I
ATTACHMENT D:
ANALYSIS RESULTS - EQE CALCULATION 240046C-"O1
46R1 rov .doc
lI
IUI
Calculation No.
Project
Calculation Title
References
Attachments
240046-C-001
TMJ-1 Auxiliary Steam Piping
TMI-1 Auxiliary Steam Pininn Evaunaionn…- -. . p - *
As Noted
As Noted
,
Total Number of Pages (including Cover Sheet): I/z 3,-51 a-0 2 4 5 7,
R evion Apprval Description of Revision Originator Checker Approver
0 4-30 - fX Initial Issue
l £/7tt. ke dC RSi By
LLI-I
K>;
EQE INTERNATIONAL-MNO. 240046 JOB TMI-1 Auxliary Steam Piping BY
mLC. NO. C-001 SUBJECT TMI-1 Auxiliary Steam Pipina Evaluation Cl
TABLE OF REVISIONS
SHEET NO. -.
P: DATE: 4-7049HK D: /.2DATE: 4 0 -fC'
ApprovedDate )Revision Description of Revision
0
i
Initial Issue
6'o Jf.fo-4. e"44L ,A/..t5, 7, A, bP 3S,40 hvortor4t . ZAL *vv
4 - Sxo- 9 is
L
2448001.DOC Pae 2
i EQE INTERNATIONAL
' 0XJ . 240046 JOB TMI-1 Auxiliary Steam Pining E.NO. C-001 SUBJECT TMI-1 Auxiliary Steam Piping Evaluation
TABLE OF CONTENTS
SECTION
L Table of Revisions.
L 1.0 Purpose.
2.0 M ethodology ............................................................................
3.0 Calculations.
4.0 Conclusions.
5.0 References.
ATTACHMENTS
A. Walkdown Sketches.
B. AutoPIPE Computer Output.
L C. TMI-1 5% Damped Response Spectra.
D. Checking Criteria Checklist.
SHEET NO. 3BYKD:.1ZDATE: 4-jo 4e,CHICD: eJ DATE:.- 4)0 f I
PAGE
..........................2
.........................4
..........................4
...........................4 ,.
.......................... /
.......................... / /
No. Paaes
......................... . 4........................ ss
.........................3 2
.............................. 3
L
L-I -, )
L 244DC-O1 DC Page 3
EQE INTERNATIONAL
SHEET NO.7NO. 240046 JOB TMI-1 Auxiliary Steam Pining BY: DATE- '/4'/V |
NO. C-001 SUBJECT TMI-1 Auxiliary Steam Pipina Evaluation CHICD: .g DATE |
1.0 PURPOSE
The purpose of this calculation Is to provide a seismic verification review of the TMI-1 AuxiliarySteam Piping in certain areas of the plant. There is equipment located In these areas thatcould be adversely affected by a steam line break.
The system is not safety related and was not designed to plant seismic design basisrequirements. This seismic verification review uses the results of research into the effects ofpast strong motion earthquakes on similar piping to assess if the TMI-1 Auxiliary Steam Pipingwill maintain pressure boundary integrity during and following an earthquake equal to the TMI-1SSE. The review technique is similar to that used to verify seismic adequacy of equipmentusing earthquake experience data.
2.0 METHODOLOGY
The piping was walked down in the field to determine actual piping and support configuration.The walkdown was performed per the guIdelines of Reference 3.
L: Using the walkdown information, the piping is analyzed using the REBIS AutoPIPE computerprogram (Reference 4). This program has been certified for use on QA projects (Reference 5).
This calculation is a seismic margin analysis using the conservative deterministic failure margin(CDFM) approach as described in Reference 6. This approach is summarized in Table 1. Forthis project the seismic margin earthquake (SME) was taken as the TMI-1 safe shutdownearthquake (SSE). Broadened USI A-46 floor response spectra was used rather than the lessconservative unbroadened, median-centered floor response spectra with frequency shiftingcalled for in Reference 6. The piping was linearly analyzed using 5% damping per Reference-6. Resulting stresses were compared to ANSI B31.1 allowables equivalent to ASME ServiceLevel D (comparing Equation 12 stresse to 3.OSh.)The 0.8 factor to account for inelastic energyabsoption was conservatively not applied.
L The response spectra used will be the 5% damped SSE values for Elevation 305' of the TMI-iAuxiliary Building as found in Reference 2. The Auxiliary Building spectra envelopes the FuelHandling Building spectra over the entire frequency range. The N-S and the E-W spectra are
* 244&COt1.(DOC Page 4
EQE INTERNATIONAL
SHEET NO._ _t JNO. 240046 JOB TMI-1 Auxiliary Steam Piping BY: DATE: 41Yt
;'u C. NO. C-001 SUBJECT TMI-1 Auxiliary Steam Piping Evaluation CHICD: -dk' DATE: 4J3t4L A(z6/h
used in the X and Z directions. The vertical spectra is defined as 213 the maximum of the N-L S or E-W spectra and is input in the Y direction.
L
-7hLiEL
SUMMARY OF CONSERVATIVE DETERMINISTIC FAILURE MARGIN APPROACH
Load Combination:
Ground Response Spectrum:
Damping:
Structural Model:
Soil-Structure-Interaction:
Normal + SME
- Conservatively specifiedability)
(84% Non-Exceedance Prob-
Conservative estimate of median damping
Best Estimate (Median) + Uncertainty Variation in* Frequency .
Best Estimate (Median) + Parameter Variation
III
I
Material Strength: Code specified minimum strength or 95% exceedanceactual strength if test data are available.
Static Capacity Equations: Code ultimate strength (ACI), maximum strength(AISC), Service Level 0 (ASME), or functionallimits. If test data are available to demonstrateexcessive conservatism of code equations, then use84% exceedance of test data for capacity equation.
Inelastic Energy Absorption: For non-brittle failure modes and linear analysis,use 80% of computed seismic stress in capacityevaluation to account for ductility benefits, orperform nonlinear analysis and go to 95% ex-ceedance ductility levels
In-Structure (Floor) Spectra Use frequency shiftitn'rather than peak broadeningGeneration: to account for uncertainty plus use median damp-
I ng.
IA
2446C-O1.DOC Pa9p 5
EQE INTERNATIONAL
SHEET NO. L9
,BNO. _ JOB_______________________ BY___ DATE ______
CALC. NO. O1) I SUBJECT PIEPid4 / FVlr4(-LiuS7iJA CHK'DVW DATE -O4
L. o " C)-1j
dcc jcn 4c4,&. A AC.9-4 ccc..
* - _________s
P PiL -A-il p4pi'-yps A s/ O Ao.kI - Spci c. fsr~vJyo! ccs - a ° 74s 1
l_ -/0a..z 4t I^ 15 ce4I4u, s^Cv ,/,c~e. Js+/e
L - 3/D/" p';p; r~z s ftire, a ,1e / M/Vser spe-ciApee Sf2, ,
- -/Jpe. Sspor jklls am i n R4e 7.-\-2. p wpi^ k/^s Ae4' 740 L Ce Iev, '42) 1 e 7e4r #4k.
I 3 Pro_-' 7g ,q 6 4 5 zy (Itt~17LI drss sI/rZ 5;f'5 vc 5;n ss 1 P/,P 3fj
I - 71VI a f 3 c z5' 6eoe F- 3 i
L - 7%yp /p " 3fhss5 725ft I k L le-I Tre'Ss /4v bf i= 4c -or- P4L'
e / Ar p 5 k4, tv- 4- a4 S/ I 0
1l
to-
EQE INTERNATONAL
i L%1U%ATVAL
NO. 2*04o JOB T4X- I Aix, w rqa 1, p&iQ
j CALC. NO. .00QL SUBJECT PI/ PJA1? PVA(,4 77-6J
L _ _ _ _ _ _ _ _ _
SHEET NO. 7BY DATE 4- _-
CHK'D1 DATE 4! 37-ff
7 pot> (0-4-19
*i rao 1, ;!.9z psCti A,4,wP's~r e 4~I-c(
fs 133%&e 4, eewvo;e- oSl, - 4 z9 3 ' se -
7-4 w,4417 / £(/x exc!- ca #4 i 4 4k n0 1~is,~ /4&IS ~ ~ ect A,-sws 7'wsc r4~sae rid hcprf, 4irko.s4e f-stp. As s nA 'vre noJ cefzLL of IL tH
J2p/E'd ,i4-OecC6Ie bL*pJE7HD 'sM~.+j ,esi\g~t
3 q3es g3't r7 /336 Qg 4none o/44<J<2,5 hva se<Me 0,-- r Sp-Ss{ vfq
J~r-e'ew&v 4 e c4ArL/4s) +Y4 V'f /1 6 V4 bLf'-7
15 ce- pw'de, ( An ckpiq4 ,t S62Th o r 4 sVt vr s A>p ,go-:S q An4 csse
Cs o D ,v eetPO4/s
1A
COMPwv7CE LoAb..&4- t7r+ sca Ak.
L-oAb ad41MUC 1iil
WDSF - , - 'i -,- - - - - .1 , �- -i
L 4o3Ao4
L AllAlz
L- A15
IA I qL--- 1f 05
I Ie soeAj c q.
5757
7&C "1O5 ofs
5,13i
T/3s .j4.9(.BIC-'J oo
4liM
A$-13 i
4.s-iu-iAs-144
ks- J40AS-147A's'-14 1
II coD
q9o4-
99N4-7-04+
I.,,
0.771. 1+
1.. I i
I1fA1
~, I~t~r1% 95e.
_ EQE INTERNATIONAL
I
yJ NO. 404b JOB -77A>5- / ,4 pW-PP)
j CALC. NO. 00) SUBJECT __P_____ ev____ _A__Vi
SHEET NO. -_5
BY DATE______
CHK'D 1 tft/ DATE _____
pit 6 1t -1
L
L
ttQ Svfpor+ Ufl'SB vtirmel CLlelaeLic- lu"Ls ;2 hs rS S.Ry imsgec~b7-5 4e- Weock lbk pI all A_ eppOrk +'s
I e r- c (S01-11 c v r i iY% S 9c, &W-. . -
�31
1 _ .:3 VA
L
L
A5 a-it cW -A it4er-,c~vs are- kss " '/3 -55 4~'As +s aJezr4ep 4-7t sets Ars 7L4 1 <g IQ flihs z4 6 .v- J/~
L
7 5p s a. pp4 er 4. 7Z+t litqz 4y pi, el J(oQ) re2 SOppor At oe'P'/t}s q -C 4
,( AZ 1 Cf/0 ') +Z 4e r' iecs, HA/csmzo ll'w 5; w+,7 1 +L. vet por4 a4 .A h0g t; S-_190 cfplW 11 ',
•fRA W A 66
L *(Do
Li -416
re -fram Lo A-qL+ TT SSE
3,i2 4f
5 ZTU5ZoI
A S-142.A s-I4 3AS-) +S
LoCMf oJS~fMV_-7v"A
5i9 4DII o All IupF O
-0j .L. TkLor-l awmtL -5ruf" o^Ax f-1 svftO atrwles , & d-roJ W @t fi {<Kt' s 4%
EQEINERAONAL
084NO._24__ JOB-I CALC. NO. OnL SUBJECT.
kY't7-/ SL/ •174P,P,g4Pr PJ A Li 1
SHEET NO.
BY DATE __-__CHKD t1l DATE _-___
t VA b-4-fIL' Lt,6 5 PPoR7
There.. I' !~-: 5die L'pv4 1 c44 aJnt J3Le314- 11 ov 3ite- -,5-ueap or4 u -m- nodez Co3 -- <,4Pip' ^S
,& p S, F3SA S SUM I 4 r4
4-Ad 4-o -hs 5011 qy 97 0-a
&- 67"1 "
t t - 4 .71 (; ) -_g 2 51IF t
t 4pvn.:L2+ - N Z e l 4 12 /2z
4 2s4 114
6ros . 4- u.e- ""L )uE.
A6 0I !AJtS a /
t?
L TZ !5Lrfp~+ is sb 4 Q4. L.A1 II (2V) 4 5"sL41
WA-LAL-
Th ecLr ' ppac4s e p,4_5 hje Jeed 4I 4Lj 7 4! K
4, ry 4orJt^-la p.t irSoee-Ve d
L T 5 i TA se4 3 34 k IE
EQE INTERNATIONAL
SHEET NO. / °NO. 240046 JOB TMI-1 Auxiliary Steam Piping BY: PQnf D
i uC. NO. C-001 SUBJECT TMI-1 Auxiliary Steam Piding Evaluation CHK'D:- DATE :J-g
4.0 CONCLUSIONS
The TMI-1 Auxiliary Steam Piping from anchor MK-AS-155 in the Fuel Handling Building toanchor MK-AS-156 in the Auxiliary Building has been evaluated in accordance with the CDFMmethodology as detailed in Reference 6. The piping and supports have been found adequateto ensure there will not be a breach of the piping pressure boundary during and/or following aL- SSEeventatTMI. in e 4oy ID CL +5 I rd V164-ev* ii peo- 5 aWI Sts ga^l se, Cves I14cufs 5 X
LL pipi 4 do-SAd 4Wfi 5iT- 3/-? A's Sr
t o?>g5aJSo aoe- 4Vule.
2C4481DOC Pages
EQE INTERNATIONAL
SHEET NO. /1a- NO. 240046 JOB TMI-1 Auxiliary Steam Pipina BY:._._DATE _-30-f! C. NO. C-001 SUBJECT TMI-1 Auxiliary Steam Piping Evaluation CHICD: _DATE: 2ad
5.0 REFERENCES
L 1. aGeneric Implementation Procedure (GIP) for Seismic Verification of Nuclear PlantEquipment', Prepared for the Seismic Qualification Utility Group (SQUG), Revision 2 dated6-28-91.
2. EQE Report No. 42105-R-001, "Summary of Conservative, Design In-Structure ResponseL Spectra for Resolution of Unresolved Safety Issue A-46 for the Three Mile Island Nuclear
Generating Station, Unit 1-. Revision 0 dated July 1993.
3. EQE Procedure 240046-P-001, Revision 0.
4. AutoPIPE User Reference Manual D/N QA26API-4.7, Volume 1, Revision 0, C/N 104
L 5. Memorandum from J.L. White, "Certification of AutoPIPE*, February 12, 1996, File3.19.5Q, Log No. 004.
L 6. EPRI NP-6041, "A Methodology for Assessment of Nuclear Power Plant Seismic Margin*,Prepared for the Electric Power Research Institute (EPRI), , Final Report dated October1988.
L 7. Basic Engineers Support Drawings:
Support No.AS-120AS-121AS-122AS-123AS-124AS-125AS-126AS-127AS-128AS-129AS-130AS-131AS-132AS-133AS-134AS-135AS-136AS-137AS-138AS139
S.O.8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS
Sheet No.GA-1 663 and 1664GA-1665GA-1666GA-1667GA-1668GA-1669GA-1670GA-1671GA-1672GA-1673GA-1674GA-1675GA-1676GA-1677GA-1679GA-1680GA-1681GA-1682GA-1684GA-1686
2448C-O1.O Page 7
M EQE INTERNATIONAL
0Y. 240046 JOB TMI-1 Auxliary Steam PiPina BYI C. NO. C-001 SUBJECT TMI-1 Auxiliary Steam Piping Evaluation Cl
B/! 7. Basic EngineersSupport Drawings:
SHEET NO. / Z
-IKD: -J*DATE: 430f
TL M4 & _'d-I ISUDDOrt No.AS-140AS-141AS-142AS-143AS-144AS-145AS-146AS-147AS-148AS-149AS-154AS-155AS-156AS-157
S.O.8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS8563-AS
Sheet No.GA-1687GA-1688GA-1689GA-1690 and 1691GA-1692GA-1693GA-1694 and 1694-AGA-1695 and 1696GA-1697 and 1698GA-1699GA-1706 and 1707GA-1708GA-1709GA-1710
8. T Power Piping, ASME Code for Pressure Piping, B31*,ASMEB31.1-1995 Edition
q9 67iLSEAT ASS0C-,*7.Cs Tb~*WI14XZ-54-Sg. " pi D .- #1
3 3 ~ 'I- ~-
VtC)
/0 G I oTE7 65Cv-iA'7r_5 'Lb .,#4e - 4--7 5Z2 LP. " D,_
by ScPAzLti a 5 A-I-/ ~l~Jk e ~ t,7 T-em, A cowe -Fc I .C- to
11, I.5;c £,e-orr Le.'t1-e-r 4o 6(' sod'o 0*1 , 5
Wit v5 a{ -,rto' f, Irb, 11,Po 'i
I Praof f.ett Ft( (,I/Q, to 00/.5-/- V/sg,2yodet
2440.1.MC Pap$S
JOB Trf, £'/r / JOB NO.
-- SUBJECT -VW /CAl~y smw zov Fimt '64, CLC NO.
DATE 4 !'LCHKD E SHE NO. OF__
o-4.
Ii d
No A.2
VI
* X\;v......................... . ss<.___
)7A-4r E a-. =-FA, T A -At t~~~~~ Len Brow}{!Ao/{
JOB 7Xyl vlrT / JOB NO. Z Voa I/
SUBJECT 4VXILA-MY Sg -/- 4&'x/wzO At-' - CALC NO. I
DATA # 1' o HKD_ AE SHEE NO. - OF___
i
.12*i4 C
'I-,-o -P
4.,
1LO)
4~ V-
L
Li ALI 1 X r/pe.y1
i
I t
A -1A: Cj/f4A17 A,JOB 7r7 13v T~- -
SUBJECT* i MV'J441A ;72-t 1% IA/
\DATE _______ c. ,c A.- DATE ______
--- . N<>- _ _ S A
,_ , *.-
>-, -4o~ -
L-k--- - - - 6 AQ - __ O-
-~~- - . - tt:-- - - -.- --- ----
_ --- . . .... . ... - .. _ .. _ .
= 6_ \ - .%- . -\. _
$A/7 4 3_JOB NO. c=4c{_CALC NO. ° C.>
SHEET NO. . OF___
'. - -4.
*~-,--;g-O------
i_-- _.... _.2 ... __ .....__ :
i - _ -
'- ,.. ...
,~- , -. 1 I- , - - - ~,! ~ : , _,- -- . 4 :4
'S. .'-- . .. - . '*4. " . .x xS x. , .**
<xo- - --- - -- ; ~. --.- < <-----.-
- -- -o s -. -. _ s . . -
L .------ :------ - -. -- s ---- - - --
.4- -'.zl t 44. S "4. . 6 a o -
h4ff2.r 1$ .. I~tS. inAy A{~ ~~~~~~~~'d7~Ji ; ei 9.D~§ :Sev t.J5+Sk
IL-rr7L,- I PAsAz;I/--r -A A W/I 7f1 r r 'W /7 -5//7'7 I~t 94
JOB J77 z r ..7 JOB NO.,>4x4v
SUBJECT A.JwL-IAiy 5-r~r-tl Pj e/A//p CALC NO._____
rLDATE ii'~ CHICD ~ DATE_.L FL_ 9SHEET NO. -OF I- -. r-- r----~----r--- .,
..... l8 * __
__ I ~7 - 7 -- 4. .c
N.0
-- - - - *.A
YJ . -. 4
-r -Z
fl- .,L N.-- 7
H - _IJ
ALCULATION 240046-C-001 ATTACHMENT B PAGE BE…__ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ - - _ _ _ _ _ _ _ _ _ _ _
AUXSTM1 240046 EQE International! 04/30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 1_- - - -_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
*
** **
** **
** **
** **
****1
**
'***** ** *******
** ** ** **
** ** ** **.***** ** ********* ** ** ***** **i
** ** ** ** ** .**
** ** ** ** ** **
***** ** ***** **
**
**
**
**
**
**
**
**
r**
**
Pipe Stress Analysis and Design Program
Version: 4.70.06
Edition: Plus-DOS
Developed and Maintained by
REBIS Industrial Workgroup Software1600 Riviera Ave., Suite 300
Walnut Creek, CA 94596
A
ALCULATION 240046-C-001 ATTACHMENT B PAGE B2
________________________________________________________________________________
!ATTKSTM1 240046 EQE International_ '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 2
F ** ~AUTOPIPE SYSTEM DATA LISTING .*
Ii
in
i .
ji j,6\-
SYSTEM NAME : AUXSTM1
PROJECT ID :
PREPARED BY :
CHECKED BY :
240046TMI-1 AUX STEAM LINE-
Je 4- In a e
%e- pulpit lysWA> "a t+ re-65ee,04
CPaw Atk L
PIPING CODE : B31.1
AMBIENT TEMP. ( deg F )
COMPONENT LIBRARY
MATERIAL LIBRARY
MODEL REVISION NUMBER
:70.0
: AUTOPIPE
: AUTOB311
:33
(JLCULATION 240046-C-001 ATTACHMENT B PAGE B3
…_-__-___________________________________-____-________-___-___________________| UXSTM1 240046 EQE International' 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 3
…-- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
O I N T D A T A
i'OINT ----- OFFSETS (ft )…_AME TYPE X Y Z PIP]
…____ - - - - ____ __ - - - - -- - - - --** SEGMENT A.00 Run 0 0 0 8"-I
XA01 Run 0 0 8.000,ao2 Bend 0 0 1.500
L I S T I N G
3 ID DESCRIPTION…_________________________________
AS
00
Long Elbow, RadiusBend angle change -SIF 2.44Flex - 7.360
- 12.000 inch90.00 deg
i 3A04
, i
1
Run 10.750Bend 11.500
00 Long Elbow, Radius - 12.000 inch
Bend angle change = 90.00 degMid point at 50.00 percentSIF - 2.44Flex - 7.360
Bend 0 -10.000 0 Long Elbow, RadiusBend angle change -SIF - 2.44Flex - 7.360
= 12.000 inch90.00 deg
L~JA06
I.io7
A.09-
_ 10
Alli 12_13
RunBend
RunBend
Bend
RunRunBend
3.9171.500
00
00
00 Long Elbow, Radius = 12.000 inch
Bend angle change - 90.00 degSIF = 2.44Flex - 7.360
0 -8.2500 -1.500
0 -2.000 0
Long Elbow, RadiusBend angle change -SIF = 2.44Flex - 7.360
Long Elbow, RadiusBend angle change =SIF = 2.44Flex = 7.360
Long Elbow, RadiusBend angle change -SIF - 2.44Flex - 7.360
- 12.000 inch90.00 deg
= 12.000 inch90.00 deg
= 12.000 inch45.00 deg
000
0 -16.4170 -11.0830 -1.250
Bend 13.000 0 -13.000 Long Elbow, Radius = 12.000 inchBend angle change - 45.00 degMid point at 50.00 percentSIF - 2.44Flex = 7.360
EJLCULATION 240046-C-001 ATTACHMENT B PAGE B4
______________________________________________________ -------------------------
'iUXSTM1 240046 EQE International. '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 4
-------- __________f
P O I N T D A T A L I S T I N G
! ?OINT*%AME TYPE
I1 U5 Runi t16 RunA17 Tee,18 Bend
.1.
----- OFFSETS (ft )-----X Y Z PIPE ID
…______ ------- ------- --------13.500 0 017.417 0 05.917 0 0
0 5.365 0
~'A1 9A2 0
DESCRIPTION…____________________-____________
Long Elbow, Radius - 12.000 inchBend angle change = 90.00 degSIF = 2.44Flex = 7.360
Long Elbow, Radius = 12.000 inchBend angle change = 45.00 degSIF = 2.44Flex = 7.360
Long Elbow, Radius = 12.000 inchBend angle change = 45.00 degSIF = 2.44Flex = 7.360
RunBend 0
2.083
0 -3.0000 -1.000
0 -2.083Bend
Run 0 0 -9.417
I k**
"A17B01302
* 303
SEGMENTTeeReduRunBend
B77.501
000
-12.000-1.250-0.500-1.250
-42.000 8"-AS0.0 2"-AS0
Cone angle = 27.51 deg, SIF = 2.00
Long Elbow, Radius - 3.000 inchBend angle change = 45.00 degSIF - 1.73Flex = 4.404
B04 Bend 0 -0.500
0 -1.000
0.500 Long Elbow, Radius = 3.000 inchBend angle change = 45.00 degSIF = 1.73Flex = 4.404
305
i 305C 17Co1
Tee 0
SEGMENT CTee 77.501 -16.500 -41.500 3/4"-ASTee 0 -0.833 0Valv 0 -0.667 0 Weight - 5 lb
Surface factor - 1.00Non-standard joint, SIF = 1.00
RunI v RunII I Bend
0 -0.2500 -0.2500 -0.500
00
Long Elbow, Radius - 1.125 inchBend angle change - 90.00 degSIF = 1.30
PkLCULATION 240046-C-001 ATTACHMENT B PAGE BS
kUXSTM1 240046 EQE International- 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 5
LP O I N T D A T A L I S T I N G
' ?OINT'-AME
C05
TYPE_end
Bend
----- OFFSETS (ft )-----X Y Z PIPE ID
…__ _ _ _ _ - - - - - - - - - - - - - - - - - - - - - -DESCRIPTION
…__ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _Flex - 2.849
-1.500 0
Bend 0 -1. 000
0
0
0
Long Elbow, RadiusBend angle change -SIF = 1.30Flex - 2.849
Long Elbow, RadiusBend angle change =SIF - 1.30Flex - 2.849
Long Elbow, RadiusBend angle change =SIF - 1.30Flex - 2.849
= 1.125 inch90.00 deg
= 1.125 inch90.00 deg
= 1.125 inch90.00 deg
Bend -0.500 0
- Valv 0 1.750 0 Weight - 5 lbSurface factorSocket welded,
' 1.00SIF = 2.10
I O09WsZ18C10
I 4** 4
C17; G011 71 8
RunTeeJunc
0 0.2500 0.6670 0.833
G77.501 -17.333-1.500 0-0.500 0
000
1 "-AS
SEGMENTTeeRunTee
-41.500 3/4"-AS00
I :10_ 01
SEGMENTJuncBend
H75.501
0-16.500 -41.500 1"-AS
2.000 0 Long Elbow, RadiusBend angle change =SIF - 1.31Flex - 2.889
= 1.500 inch45.00 deg
H02 Bend 0 0.750 0.750 Long Elbow, RadiusBend angle change =SIF = 1.31Flex - 2.889
= 1.500 inch45.00 deg
Bend 0 1.000 0 Long Elbow, RadiusBend angle change =SIF = 1.31Flex = 2.889
= 1.500 inch45.00 deg
I J--H-0H04 Bend 0 0.500 0.500 Long Elbow, Radius = 1.500 inch
Bend angle change = 90.00 deg
; ALCULATION 240046-C-001 ATTACHMENT B PAGE B6
_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
; AUXSTM1 240046s 30/98 TMI-1 AUX STEAM LINE
…-- - - - - - - - - - - - - - - - - - - - - - - --
._____________________________________________EQE International
: AutoPIPE+4.70 MODEL PAGE 6._________________________________________________
~ P O I N T D A
| POINT ----- OFFSETS (ft )-----,-NAME TYPE X Y Z
.T A L I S T I N G
PIPE ID DESCRIPTION_ _ _ _ _ _ _ _ - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
__________________________________
SIF =1.31Flex - 2.889
H05 Run -0.500H06 Run -8.000
0 00
I, B05
I02
SEGMENT ITee 77.501 -16.500 -41.500 1"-ASRun -0.-667 0 0Bend -0.500 0 0 Long Elbow, Radius
Bend angle change-SIF = 1.31Flex -2.889
- 1.500 inch90.00 deg
! 103 Bend 0 0.500 0.500 Long Elbow, RadiusBend angle change-SIF = 1.31Flex -2.889
. tut Bend
- 1. 500 inch45.00 deg
= 1.500 inch90.00 deg
0 0. 667 0 Long Elbow, RadiusBend angle change -SIF - 1.31Flex - 2.889
II05IL
Run -4.000 0 0
,Total weight of empty pipes : 5617 lb
AALCULATION 240046-C-001 ATTACHMENT B PAGE B7
1 AUXSTM1 240046_. 0/98 TMI-1 AUX STEAM LINE
---------------------------
EQE InternationalAutoPIPE+4.70 MODEL PAGE 7
._________________________________________________
C O M P O N E N T D A T A L
|POINT --- COORDINATE(ft )--- DATA--NAME X Y Z TYPE DESCRIPTION
…____ - - - - - - - - - -- - - - -- - -- - - - -- - - - _ _ _ _ _ _ _ _ _ _ _
I S T I N G
,_______________________________-
A#** SEGMENT AA00 0.000 0.000 0.000 ANCHOR Rigid
Thermal movements : None
! o01A02 NA02
I &02 Fjk03
P .04 N
L-A04 MA04 F
, P05 N'A05-AOS F
.I
I 07 NLA07A07 F
, 08
|09 NLsosA09 Fi110 N
,10A10 F~1 1
-A12A13 N
Lkl3 FA14 N\14e 14 MLA14 FI I
Ls;>
0.0000.0000.0001.000
10.750
21.25022.25021.95722.25022.25022.25023.25026.167
26. 66727.66727. 66727.667
27. 66727.66727. 66727.66727.66727.66727.667
27.66727.66727.66727.96040.37440.66740.69941.08154.167
0.0000.0000.0000.0000.000
0.0000.000
-0.293-1.000-9.000
-10.000-10.000-10.000
-10.000-10. 000-10.000-10.000
-10. 000-10.000-11.000-11.002-12.000-12.000-12.000
-12.000-12.000-12.000
4 mass point(s)9.5009.5009.5009.5009.5009.5009.5009.500
TIY-STOP ID : AS-141, Connected to Ground
3 mass point(s)
TI1 mass point(s)
SPRING ID : AS-142, Connected to Ground1 hanger(s)Stiffness = 91 lb/inPreload - 288 lb
3 mass point(s)8.000 Y-STOP ID : AS-139, Connected to Ground8.5009.500 TI - -9.500 4 mass point(s)9.500 Y-STOP ID : AS-140, Connected to Ground
9.5009.500 TI8.5001.250 SPRING
-0.750-0.250 TI-0.250-0.250-0.250. TI-1.250
-16.667 Y-STOP
-27.750 Y-STOP-28.586-29.000 TI
3 mass point(s)ID : AS-143, Connected to Ground1 hanger(s)Stiffness - 107 lb/inPreload = 496 lb
6 mass point(s)ID : AS-144, Connected to Ground4 mass point(s)ID : AS-145, Connected to Ground
7 mass point(s)
ID : AS-146, Connected to Ground5 mass point(s)ID : AS-147, Connected to Ground7 mass point(s)ID : AS-148, Connected to Ground1 hanger(s)Stiffness - 107 lb/in
-12.000 -29.293-12.000 -41.707-12.000 -42.000 TI-12.000 -41.924 Y-STOP-12.000 -42.000-12.000 -42.000 Y-STOP
71.584 -12.000 -42.000 SPRING
I.LLCULATION 240046-C-001 ATTACHMENT B PAGE B8
! tt e ¶, t - A e% n A _UAJA% LCML
'0/98 TMI-1 AUX STEAM LINEEQE InternationalAutoPIPE+4.70 MODEL PAGE 8
--------------------------------------------------------------------- PAGE-8
C 0 M P 0 N E N T D A T A L I S T I N G
I?OINT ---COO]IX-_4AME X
_ _ _ _ _ - - - - - - -
RDINATE(ftY
)--- DATAZ TYPE DESCRIPTION
…____ ------ ------------------------------------------
Preload = 505 lb
77.501 -12.000 -42.000 TEE2 mass point(s)Welded-on fittingSIF - In - 2.23, Out - 2.231 mass point(s)
A18I 8 F
A20 N\20
1 i20 Fhi21 NA21
I 2l FLi22
77. 50177.50177.50177.50177.50177.50177.79479.29179.58479.58479.584
-7.635-6.635-6.635-6.635-6.635-6.635-6. 635-6.635-6.635-6.635-6.635
-42.000-42.000-43.000-45.000-45.586-46.000-46.293-47.790-48.083-48.497-57.500
TI
Y-STOP ID : AS-149, Connected to Ground
TI
TI4 mass point(s)
ANCHOR RigidThermal movements : None
TEE Welded-on fittingSIF - In = 2.23, Out - 2.23
t EGMENT B<S 77.501 -12.000 -42.000
301UJ02
1503
1'-031303-
LS04
t404__04
N
F
77.501 -13.250 -42.00077.501 -13.750 -42.000
77.501 -14.896 -42.000
USRFLX In = 2.10, Out = 2.10, FlexOverride all other values =
USRFLX In = 2.10, Out = 2.10, Flex
77.50177.501
-15.000 -42.000 TI-15.073 -41.927 USRFLX
Override all other values =
In - 2.10, Out = 2.10, FlexOverride all other values =In - 2.10, Out - 2.10, FlexOverride all other values -
- AutomaticYes= AutomaticYes
= AutomaticYes= AutomaticYes
N 77.501 -15.427 -41.573
77.501 -15.500 -41.500F 77.501 -15.604 -41.500
77.501 -16.500 -41.500
USRFLX
TIUSRFLX In = 2.10, Out - 2.10, Flex = A
Override all other values = YesTEE Welded-on fitting
SIF - In = 1.52, Out - 1.52USRFLX In - 2.10, Out = 2.10, Flex = A
Override all other values = Yes
utomatic
utomatic
k **
B05SEGMENT C
77.501 -16.500 -41.500
77.501 -17.333 -41.500
77.501 -18.000 -41.500
TEE Welded-on fittingSIF - In - 1.52, Out - 1.52
USRFLX In - 2.30, Out - 2.30, FlexOverride all other values -
TEE B16.9 welding teeSIF - In - 1.00, Out = 1.00
USRFLX In - 2.30, Out = 2.30, FlexOverride all other values
USRFLX In - 2.30, Out - 2.30, Flex
- AutomaticYes
- AutomaticYes,Automatic
t LCULATION 240046-C-001 ATTACHMENT B PAGE B9
: DXSTM11/98
_L ,_ _
240046TMI-1 AUX STEAM LINE
EQE InternationalAutoPIPE+4.70 MODEL PAGE 9
._______________________________________________________________________
C O M P O N E N T D A T A L I S T I N G
I _ _- _! 'OINT --- COORDINATE(ft )--- DATA%.EAME X Y Z TYPE
i 02 77.501 -18.250 -41.500 USRFLX
,r03 77.501 -18.500 -41.500 GUIDE
Y04 N 77.501 -18.906 -41.500 USRFLX
i04 77.501 -19.000 -41.500 TI&04 F 77.407 -19.000 -41.500 USRFLX
:-05 N 76.095 -19.000 -41.500 WEIGHT
DESCRIPTION____________________________________-____
Override all other values = YesIn = 2.30, Out = 2.30, Flex - AutomaticOverride all other values = YesID : C03 1, Connected to GroundStiffness = RIGIDIn = 2.30, Out = 2.30, FlexOverride all other values -
- AutomaticYes
In - 2.30, Out - 2.30, Flex - AiOverride all other values = Yes50 lb , No offsetsIn - 2.30, Out = 2.30, Flex = AiOverride all other values = Yes
automatic
I ,
C05j 05 F
C06 N
i'
I '07 N
C07. 07 F
t08
L09C18
L
USRFLX atomatic
76.001 -19.00076.001 -19.094
76.001 -19.906
76.001 -20.00075.907 -20.000
75.595 -20.000
-41.500 TI-41.500 USRFLX In = 2.30, Out = 2.30, Flex
Override all other values --41.500 USRFLX In - 2.30, Out - 2.30, Flex
Override all other values =-41.500-41.500
-41.500
75.501 -20.000 -41.50075.501 -19.906 -41.500
75.501 -18.250 -41.500
75.501 -18.000 -41.500
75.501 -17.333 -41.500
75.501 -16.500 -41.500
TIUSRFLX In - 2.30, Out = 2.30, Flex
Override all other values =USRFLX In = 2.30, Out - 2.30, Flex
Override all other values =TIUSRFLX In = 2.30, Out = 2.30, Flex
Override all other values =USRFLX In - 2.30, Out = 2.30, Flex
Override all other values =USRFLX In - 2.30, Out = 2.30, Flex
Override all other values -TEE B16.9 welding tee
SIF - In - 1.00, Out = 1.00USRFLX In = 2.30, Out = 2.30, Flex
Override all other values =
= AutomaticYes= AutomaticYes -
= AutomaticYes= AutomaticYes
= AutomaticYes= AutomaticYes= AutomaticYes
= AutomaticYes
SEGMENT G77.501 -17.333 -41.500
76.001 -17.333 -41.500
75.501 -17.333 -41.500
TEE B16.9 welding teeSIF - In - 1.00, Out - 1.00
USRFLX In = 2.30, Out - 2.30, Flex IOverride all other values = No
WEIGHT 5 lb , No offsetsUSRFLX In = 2.30, Out = 2.30, Flex =I
Override all other values = NoTEE B16.9 welding tee
SIF - In = 1.00, Out = 1.00
Automatic
kutomatic
SEGMENT H75.501 -16.500 -41.500
LCULATION 240046-C-001 ATTACHMEN
-_______________________________________
1,UXSTM1 2400460/98 TMI-1 AUX STEAM LINE
-------- --------------------------
[T B PAGE B10
________________- ---------------------- _
EQE InternationalAutoPIPE+4.70 MODEL PAGE 10
…_______________________________________
C O M P O N E N T D A T A L I S T I N G
I'OI]. oil
i 01
H01901
hdi02
t02L102
*1 03
'i03H03
.S04
H05
L06
E05
I .
LIO
102
102'02
0 3
I03I 0 3
'I04
ET --- COORDINATE (ftX Y
N 75.501
75.501F 75.501
N 75.501
75.501F 75.501
N 75.501
75.501F 75.501
N 75.501
75.50175.376
75.001
67.001
SEGMENT I77.501
76.834
N 76.459
76.334F 76.334
N 76.334
76.334F 76.334
N 76.334
/ 76.334F 76.209
-14.552
-14.500-14.463
-13.787
-13.750-13. 698
-12.802
-12.750-12.713
-12.338
-12.250-12.250
-12.250
-12.250
-41
-41-41
-40
-40-40
-40
-40-40
-40
-40-40
-40
-40
)--- DATAZ TYPEI---- ------
_.500 USRFLX
L.500 TI.463 USRFLX
.787 USRFLX
.750 TI
.750 USRFLX
.750 USRFLX
.750 TI
.713 USRFLX
.338 USRFLX
.250 TI
.250 USRFLX
.250 Y-STOP
.250 ANCHOR
DESCRIPTION…-----------------------------------------
In = 2.10, Out = 2.10, Flex - AutomaticOverride all other values - Yes
In = 2.10, Out - 2.10, Flex = AutomaticOverride all other values - YesIn = 2.10, Out - 2.10, Flex = AutomaticOverride all other values Yes
In - 2.10, Out - 2.10, Flex = AutomaticOverride all other values = YesIn = 2.10, Out = 2.10, Flex = AutomaticOverride all other values = Yes
In - 2.10, Out - 2.10, Flex - AutomaticOverride all other values = YesIn - 2.10, Out - 2.10, Flex AutomaticOverride all other values = Yes
In - 2.10, Out = 2.10, Flex - AutomaticOverride all other values = YesID : H05 1, Connected to Ground3 mass point(s)RigidThermal movements : None
-16.500 -41.500
-16.500 -41.500
-16.500
-16.500-16.412
-16.037
-16.000-15. 948
-15.458
-15.333-15.333
-41.500
-41.500-41.412
-41.037
-41.000-41.000
-41.000
-41.000-41.000
TEE
USRFLX
WEIGHTUSRFLX
USRFLX
TIUSRFLX
USRFLX
TIUSRFLX
USRFLX
TI
USRFLX
Welded-on fittingSIF - In = 1.52, Out - 1.52In - 2.10, Out = 2.10, FlexOverride all other values -5 lb , No offsetsIn - 2.10, Out - 2.10, FlexOverride all other values -In - 2.10, Out - 2.10, FlexOverride all other values -
In - 2.10, Out = 2.10, FlexOverride all other values =In - 2.10, Out - 2.10, FlexOverride all other values -
In - 2.10, Out 2.10, FlexOverride all other values =In - 2.10, Out = 2.10, FlexOverride all other values =
1 mass point(s)In - 2.10, Out - 2.10, FlexOverride all other values =
- AutomaticYes
= AutomaticYes= AutomaticYes
= AutomaticYes= AutomaticYes
= AutomaticYes= AutomaticYes
= AutomaticYes
C LCULATION 240046-C-001 ATTACHMENT B PAGE BlI
1 JXSTM1 240046 EQE International.1/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 11
-L ----.- . m .- - m - - _ A m - --C I rLU N lE4 N T D A T A L I S T I N G
i OINT.AME
05
Lm
f 'ume
--- COORDINATE(ft )---x Y z
72.334 -15.333 -41.000
DATATYPE DESCRIPTION
…_____ ------------------------------------------
ANCHOR RigidThermal movements : None
of points in the system : 166
I ALCULATION 240046-C-001 ATTACHMENT B PAGE B12
________________________________________________________________________________
AXUXSTMl 240046 EQE International' 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 12
LP I P E D AT A L I S T I N G
i Pipe ID/Lj4aterial
____________
ISm-ASI -S
Nom/ O.D.Sch inch____ -----
8 8.625STD
-----Thickness(inch)-----W.Th.
0.322
Corr Mill Insu0___ 0.04 2-00
0 0.04 2.00
Ling____
0
SpecGrav
0
Weight(lb/ft )Pipe Other Total
…____ ----- -----28.52 5.10 33.62
ZL/zC
1.001.00
2 "-ASI 'S
3/4"-AS
, "-ASi C
2.000STD
0.750STD
1.000STD
2.375 0.154
1.050 0.113
1.315 0.133
0 0.02 2.00
0 0.01 2.00
0 0.02 2.00
0 0 3.65 2.10 5.75 1.001.00
0 0 1.13 1.46 2.59 1.001.00
0 0 1.68 1.59 3.27 1.001.00
LLCULATION 240046-C-001 ATTACHMENT B PAGE B13
i UXSTM1 240046 EQE Internationall '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 MODEL PAGE 13
LM A T E R I A L D A T A L I S T I N G
1 Material. Name Pipe ID
8"-AS
Density Pois.lb/cu.ft Ratio
489.0___ 0.30-
489.0 0.30
Temper.deg F_______
70.0300.0
ModulusE6 psi____.50_
29.50
Expans. Allow.in/lOOft psi
14100.01.8200 14100.0
CS
Cs
CS
2"-AS
3/4 "-AS
489.0 0.30 70.0300.0
489.0 0.30 70.0300.0
489.0 0.30 70.0300.0
29.50
29.50
29.50
14100.01.8200 14100.0
14100.01.8200 14100.0
14100.01.8200 14100.0
1" -AS
Lu'-II 7
i
L
L
L -
L_LL_
JALCULATION 240046-C-001 ATTACHMENT B PAGE B14
_______________________________.
AUXSTM1 240046, ' 0/98 TMI-1 AUX STEAM LINE
.______________________-__________________________
EQE InternationalAutoPIPE+4.70 MODEL PAGE 14
I- -- - --- -- - -- - -- - -- ---- ----- ------ --- -- ---- ---
| POINTIIAME
----- CPRESS.psi______
A S ETEMPERdeg F______
TEMPERATURE AND PRESSURE DATA1------ -----C A S E 2------EXPAN. PRESS. TEMPER EXPAN.
in/lOOft psi deg F in/lO.Oft-_______ ------ ---- -- --------
-----C A S EPRESS. TEMPERpsi deg F_ _ _ _ _ _ - - - - - -
3…--___EXPAN.
in/lOOft________
,I j
i k** SEGMENT ALAOO 25.00A22 25.00
300 1.820300 1.820
A17, 302305
SEGMENT B25.0025.0025.00
300300300
1.8201.8201.820
SEGMENT C25.0025.00
300 1.820300 1.820
i ***
L:17
C18
SEGMENT G25.0025.00
LI 'EGMENT H25.00
H06 25.00
300 1.820300 1.820
300 1.820300 1.820
300 1.820300 1.820
Ilkt**L.B
B05* 105
SEGMENT I25.0025.00
:ALCULATION 240046-C-001 ATTACHMENT B PAGE B15
_-_____________________________ ________-_______________________________________
l AUXSTM1 240046 EQE International1 30/98 TMI-1 AUX STEAM LINE AutoPIPE14.70 RESULT PAGE
----------------------------------------------------------------------
A N A L Y S I S SUMMARY
Current model revision number : 33
Static - Date and Time of analysis .............Model Revision Number.Number of load cases ..................Load cases analyzed ...................Gaps/Friction/Yielding considered ....Hanger design run .....................Cut short included ....................Weight of contents included ...........Number of mass points per span ........Pressure stiffening case ..............Water elevation for buoyancy loads ....
April 30, 1998333GR T1 P1NoNoNoYesAutomatic0Not considered
10:18 AM
Modal - Date and Time of analysis .Model Revision Number .Number of modes .Cutoff frequency (Hz).Weight of contents included .Number of mass points per span ..Pressure stiffening case .Water elevation for buoyancy loads ....
April 30, 1998333033.0YesAutomatic0Not considered
10:18 AM
Response Date and Time of analysis ............. A]Model Revision Number ................. 3Number of load cases ........... 3Load cases analyzed .... .............. RDate and time of modal analysis ....... ANumber of modes .................. 3Cutoff frequency (Hz) ... .............. 3Model revision of modal analysis -.... 3:Weight of contents included ........... YeNumber of mass points per span ........ AlPressure stiffening case ............. . 0Water elevation for buoyancy loads .... Ni
pril 30, 19983
1 R2 R3pril 30,03.03esatomatic
10:19 AM
10:18 AM1998
ot considered
NkLCULATION 240046-C-001 ATTACHMENT B PAGE B16
________________________________________________________________________________-
I UXSTM1 240046 EQE Internationalg '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 2
CODE COMPLIANCE COMBINATIONS
i Combination Category Method Load-
Factor M/S Allowable Remarks
GR + Max P Sustain Sum GravityMax Long
1.001.00
Automatic Default
Cold to Ti
Sus. + Ri
Sus. + R2
Sus. + R3
Expansion
Occasion
Occasion
Occasion
Sum Thermal 1
Abs sum Response 1Max Sus
Abs sum Response 2Max Sus
Abs sum Response 3Max Sus
1.00
1.001.00
1.001.00
1.001.00
Automatic
Automatic
Automatic
Automatic
Default
Default
Default
Default
Max P
L* SSE-SEISMC
IL-..+P+SSE
Hoop Max Hoop
Occasion
Occasion
SRSS Response 1Response 2Response 3
1.00
1.001.001.00
1.00 M1.00 M
Automatic
Automatic
Default
User
UserAbs sum GR + Max PSSE-SEISMC
Automatic
6 XLCULATION 240046-C-001 ATTACHMENT B PAGE B17
________________________________________________________________________________
.UXSTM1 240046 EQE InternationalL 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 3
L OTHER USER COMBINATIONS
Combination___________
GR
Method Load
Sum Gravity
Factor1.00__
1.00
RemarksDefault
Default
Ti Sum Thermal 1
Press 1
1.00 Default
1.00 DefaultP1 Sum
RI Sum
R2
R3
Sum
Sum
Response 1 1.00
Response 2 1.00
Response 3 1.00
Default
Default
Default
SSE-SEISMC SRSS Response 1Response 2Response 3
1.001.001.00
User
l-
ALLCULATION 240046-C-001 ATTACHMENT B PAGE B18
…_______________________________________________________________________________AUXSTM1 240046 EQE International
'0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 4
CODE COMPLIANCE
-Y - Factor ..................... 0.40Weld efficiency factor ................ 1.00Range reduction factor ........ * ....... 1.00Design Pressure Factor ...... .......... 1.00Minimum stress ratio used in reports.... 0.00
| Include corrosion in stress calcs. YInclude axial force in code stress .... NSet sustained SIF to 1.00 .... ......... NLongitudinal pressure calculation ..... PD/4t
L Include rigorous pressure .... ......... N
i
U-
I ALCULATION 240046-C-001 ATTACHMENT E PAGE B19
___________ ___________________.
IAUXSTM1 240046L' '0/98 TMI-1 AUX STEAM LINE
___-
REPNESETRMLA AE
._________________________________________________
EQE InternationalAutoPIPE+4.70 RESULT PAGE 5s
-_________________________________________________
RESPONSE SPECTRUM LOAD CASES :-
Number of load cases analysed : 3
Load case 1 - R1
Missing mass : YesZPA : Yes
Combination method : SRSS
X- Spectrum : 305NSMultiplier : 1.00
305NS
Freq (Hz)
U. 0.1500.300
t 0.450g p.600
1.1002.500L 4.1008.600
i 15.000L 27.000
Grav(-___________
0.010.050.080.130.160.200.310.370.430.360.17
Freq (Hz)
0.2000.3500.5000.6500.9001.3003.0005.000
10.00020.00033.000
Grav(_____________
0.030.050.090.150.170.250.340.400.480.200.15
Freq (Hz)________
0.2500.4000.5500.7001.0002.0003.6006.900
11.00021.000
Grav(_____________
0.040.060.100.150.180.280.370.410.480.17
i.i-
T, ALCULATION 240046-C-001 ATTACHMENT B PAGE B20
| 'UXSTM1 240046 EQE International0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 6
r
Load case 2 - R2
Missing mass : YesZPA : Yes
Combination method : SRSS
Y- Spectrum : 305NSMultiplier : 0.67
305NS
L Freq(Hz)________
L 0.150L 0.3000.4500.600
I' 0.800L 1.100
2.500
1 4.100.600
L-A5 . 00027.000
Grav(_____________
0.010.050.080.130.160.200.310.370.430.360.17
Freq(Hz)________
0.2000.3500.5000.6500.9001.3003.0005.000
10.00020.00033.000
Grav(_____________
0.030.050.090.150.170.250.340.400.480.200.15
Freq (Hz)________
0.2500.4000.5500.7001.0002.0003.6006.900
11.00021.000
Grav( )
0.040.060.100.150.180.280.370.410.480.17
iLCULATION 240046-C-001 ATTACHMENT B PAGE B21
________________________________________________________________________________
1 LUXSTM1 240046 EQE Internationalt- l)/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 7
Load case 3 - R3
Missing mass : YesZPA : Yes
Combination method : SRSS
Z- Spectrum : 305EW- Multiplier : 1.00
305EW
l- Freq(Hz)________
I 1 0.1500.320
a 0.5601.0501.950
L 4.7007.1003.000
A, .000
Grav(_____________
0.020.050.110.190.290.410.460.360.14
Freq(Hz) Grav(
0.210 0.030.420 0.070.620 0.141.070 0.222.950 0.355.100 0.449.000 0.37
20.500 0.25
Freq(Hz) Grav(
0.280 0.030.510 0.110.810 0.171.100 0.263.700 0.386.050 0.46
11.500 0.3827.000 0.15
C JCULATION 240046-C-001 ATTACHMENT B PAGE B22
…
L.UXSTM1 240046 EQE International* 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 8
~F R E Q U E N C I E S
lode Frequency Frequency Period Participation factorsLumber (Rads/sec) (Hertz) (Sec) X Y Z
…_____ ----------- ---------- ------ --- ----- ---- - --- - -------
1
2
3
4
S
! 6C-
7
l_ 8
1 11
12
13
, 14
15
t 16
17
18
19
L 20
21
L 22
24
4.0612
13.3305
17.9294
22.5992
28. 6141
29.6625
31.5866
39.0302
48.0421
52.2803
61.3152
69.8966
73.3366
86.4064
96.1673
103.5508
110.9562
114.5139
120.1983
128.7373
131.5620
138.4425
141.9278
146.8770
0.6464
2.1216
2.8535
3.5968
4.5541
4.7209
5.0272
6.2119
7.6461
8.3207
9.7586
11.1244
11.6719
13.7520
15.3055
16.4806
17.6592
18.2255
19.1301
20.4892
20. 9387
22.0338
22.5885
23.3762
1.547
0.471
0.350
0.278
0.220
0.212
0.199
0.161
0.131
0.120
0.102
0.090
0.086
0.073
0.065
0.061
0.057
0.055
0.052
0.049
0.048
0.045
0.044
0.043
-0.380
2.329
2.115
-0.085
-0.066
-0.462
-0.161
1.061
1.024
-0.122
-0.768
-0.251
0.054
-0.196
-0.062
0.054
-0.010
-0.182
0.064
-0.139
-0.139
-0.245
-0.172
-0.037
-0.003
0.134
0.047
-0.262
0.025
0.319
-0.646
0.061
-0.826
0.929
-0.339
-0.461
-0.511
-0.831
-0.217
-0.074
0.206
-0.599
-0.698
-0.223
0.372
0.632
-0.111
0.104
-3.020
-0.746
0.338
-0.398
-0.535
0.329
-0.571
-0.495
0.510
0.381
0.236
-0.346
* -0.111
0.209
-0.080
-0.160
-0.033
-0.139
0.160
-0.325
-0'.387
-0.240
-0.065
-0.040
ALCULATION 240046-C-001 ATTACHMENT B PAGE B23
…-------------------------------------------------------------------------------AUXSTM1 240046 EQE International
L" 10/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 9------------------------------------------------------------------ ____________
9 F R E Q U E N C I E S
~,Mode Frequency Frequency Period Participation factors,1u ber (Rads/sec) (Hertz) (Sec) X Y Z
25 159.3507 25.3615 0.039 0.016 0.115 -0.101
26 171.1813 27.2444 0.037 -0.115 0.122 -0.009
27 176.0196 28.0144 0.036 0.199 0.143 -0.135A-
28 186.5147 29.6847 0.034 -0.117 -0.270 0.180
29 200.5212 31.9139 0.031 -0.049 -0.080 -0.026
30 203.3268 32.3605 0.031 -0.17-AQ n ion- - - - - - -
L-J
U
L
I'
-.,
I .,
6.-
L-
, LCULATION 240046-C-001, X T 1 2 0 4 ATTACHMENT B PAGE B24
_______________________________.
, UXSTM1 240046'I- '0/98 TMI-1 AUX STEAM LINE_ - -S_ -__-__-__-__-__-__-__-__-__-__-__-.
r
~D I'S I
.____________________________________-____________
EQE .InternationalAutoPIPE+4.70 RESULT PAGE 10
._________________________________________________
P L A C E M E N T S
'oint Load1-?am'e combination
i'~tr** Segment A begin
TRANSLATIONS (in )
_ _ _ _Y Z
_ _ _ _ _ _ - - - - - -
ROTATIONS (deg ). X Y Z_ _ _ _ _ _ - - - - - - - - - - - -
GRT1P1SSE-SEISMC
GR -T1P1SSE-SEISMC
GRT1P1SSE-SEISMC
O .000O. 000O. 000O .000
O .001-0.034
O .0000.175
O .001-0.038
O .0000.197
O .000O .000O. 000O .000
O. 000O .000O. 000O. 000
O. 000O .000O .000O .001
A02 N
!
A0
1 t
U,,
.1 GRT1P1SSE-SEISMC
>3 GRT1P1SSE-SEISMC
14 N GRT1 -PiSSE-SEISMC
4 M GRT1P1SSE-SEISMC
4 F GRT1P1SSE-SEISMC
O .001-0.030
O .0000.262
O .0010.147O .0000.262
O .0010.338O .0000.262
O .0010.351O .0000.262
0.0020.354O .0000.264
-O.001O .001O .0000.008
O .000: . 000O .000O .000
-O.0010.006O .0000.008
O .000O .000O .000O .000
0.000,-0.014
O 0.0000.007
O .000O .000O .000O. 000
O. 0000.146O .000O. 000
O .0000.155O . 000O .000
O .0000.186O. 0000.082
-0.0030.350O .0001.260
-0.0070.518O0.0012.739
-0.0070.527O. 0012.849
-0.0070.532O .0012. 919
O. 000O. 000O .000O .000
O .000--O.001
O .000O .011
O .000-O .001
O .0000.014
0 . 000 . 000 . 000.000
O .001-0.037
O .0000.203
O .001-0.038
O .0000.215
O .000O .000O .000O. 000
-0.002-0.002
O .000O .010
-0.003-0.002
O .000O. 011
O .001-O .005
O . 0000.048
O. 000-0.014
O .0000.118
-0.002-0.024
O .0000.192
-0.003-0.019
O .0000.197
-0. 003-0.016
O .0000.214
O. 001-0.072
O. 0000.487
0.002-0. 084, O .0000.645
0.002-0.063
O. 0000.677
-0.002-O.001
O .0000.004
O .0000.002O .0000.012
0.004-O.001
O .0000.028
'A0 0.001 0.004-0.047 -0.008
O.000, 0.0000. 665 0.089
IL~O .001
-0.040O .0000.664
0.005-0.016
O .000O .150
ALCULATION 240046-C-001 ATTACHMENT B PAGE B25
_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
I AUXSTM1 240046> 30/98 TMI-1 AUX STEAM LINE
% J ,
EQE InternationalAutoPIPE+4.70 RESULT PAGE 11
…______________________________________________
D I S P L A C E M E N T S
, Pointname______
-A05 N
bI-.
1l0N F
i
,A06
|A07 N
Loadcombination___________
GRTIP1SSE-SEISMC
GRTiP1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
TRANSLATIONS (in' )x y
0.012 0.0000.324 -0.1590.000 0.0000.414 0.007
0.0140.3400.0000.444
0.0140.3930.0010.444
0.0140.4020.0010.444
.0.002-0.179
0.0000.047
0.008-0.1790.0000.162
0.009-0.1800.0000.182
z______
0.0000.5560.0013.268
0.0010.5520.0013.428
0.0000.5280.0013.765
0.0000.5230.0013.822
-0.0060.0170.0000.163
-0.0070.0260.0000.141
-0.0070.0280.0000.138
-C-cCC
ROTATIONS (deg )X Y Z
.005 0.001 0.0071.009 -0.001 -0.016.000 0.000 0.0001.211 0.618 0.190
0.0000.0330.0000.570
0.0000.0470.0000.551
0.0000.0490.0000.547
0.0'09-0.0020.0000.190
0.008-0.0010.0000.188
0.008-0.0010.0000.188
A07 F
L
A09 N
L
l k09 F
. >
A-10 N
L
GRT1P1SSE-SEISMC
GRTiP1SSE-SEISMC
GRTiP1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
0.0140.4020.001.0.446
0.0150.2110.0000.841
0.0150.1960.0000.875
0.0140.1640.0000.967
0.0140.1640.0000. 967
0.008-0.1720.0000.204
-0.005-0.1010.0000.137
-0.006-0.0960.0000.135
-0.009-0.1040.0000.132
-0.009-0.1040.0000.132
0.0010.4900.0013.926
0.0010.3580.0003.926
0.0010.3490.0003.926
0.0040.3210.0003.934
0.0040.3210.0003.934
-0.0090.0420.0000.105
-0.0100.0490.0000.080
-0.0110.0490.0000.078
-0.0150.0460.0000.053
-0.0150.0460.0000.053-
0.0000.1100.0000.447
-0.0010.1390.0000.374
-0.0010.1410.0000.369
0.0010.1600.0000.288
0.0010.1600.0000.288
0.0020.0050.0000.190
-0.0030.0010.0000.182
-0.0040.0010.0000.181
-0.007-0.008
0.0000.146
-0.007-0.0080.0000.146
.ILCULATION 240046-C-001 ATTACHMENT B PAGE B26
11UXSTM1 240046 EQE International_ '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 12
-D I S P L A C E M E N T S
i?oint Load TRANSLATIONS (in ) ROTATIONS (deg )&,ame combination X Y Z X Y Z
…_____ - --- - - ----- - --- -- - ----- _ ____ - --- -- - -- - - -,110 F GR 0.012 -0.012 0.007 -0.012 0.003 -0.011* T1 0.126 -0.112 0.293 0.045 0.175 -0.015
P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 1.037 0.126 3.937 0.043 0.205 0.109
;11 GR 0.004 0.000 0.007 0.008 0.003 -0.023Ti -0.456 0.000 0.013 0.014 0.173 -0.010P1 -0.001 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 1.307 0.000 3.937 0.019 0.071 0.067
A12 GR -0.003 0.000 0.007 -0.005 0.003 -0.031T1 -0.812 0.000 -0.189 -0.006 0.127 -0.007P1 -0.001 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 1.105 0.000 3.938 0.007 0.176 0.037
)13 N GR -0.003 -0.001 0.007 -0.006 0.003 -0.032Ti -0.834 -0.001 -0.204 -0.005 0.122 -0.007P1 -0.001 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 1.078 0.001 3.938 0.007 0.184 0.035
A13 F GR -0.004 -0.004 0.006 -0.007 0.003 -0.033T1 -0.844 -0.002 -0.223 -0.002 0.087 -0.006
L P1 -0.001 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 1.051 0.002 3.928 0.011 0.241 0.030
1,14 N GR -0.014 -0.002 -0.003 0.039 0.004 0.001T1 -0.703 -0.001 -0.534 0.010 -0.022 0.001P1 -0.001 0.000 -0.001 0.000 0.000 0.000SSE-SEISMC 0.410 0.001 3.286 0.021 0.361 0.007
A14 M GR -0.014 0.000 -0.004 0.038 0.004 -0.001T1 -0.696 0.000 -0.536 0.012 -0.039 0.003P1 -0.001 0.000 -0.001 0.000 0.000 0.000SSE-SEISMC 0.402 0.000 3.263 0.023 0.373 0.005
,.14 F GR -0.014 0.000 -0.004 0.038 0.004 -0.003T1 -0.688 0.001 -0.533 0.012 -0.057 0.005P1 -0.001 0.000 -0.001 0.000 0.000 0.000
F SSE-SEISMC 0.399 0.000 3.235 0.024 0.388 0.004
\I15 GR -0.014 0.000 -0.016 0.036 0.005 -0.003T1 -0.450 0.000 -0.292 0.026 -0.110 -0.013.P1 -0.001 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.399 0.000 2.154 0.043 0.439 0.008
; ALCULATION 240046-C-001 ATTACHMENT B PAGE B27
.______________________________________________________________________
I PUXSTM1_i-r 0/98
x---.240046TMI-1 AUX STEAM LINE
EQE InternationalAutoPIPE+4.70 RESULT PAGE 13
,_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ - _ _ _ _ _ _ _ _ - _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
D I S P L A C E M E N T S
i PointB1ame
, 1
Loadcombination___________
GRT1P1SSE-SEISMC
-TRANSLATIONS (in )x y z
…__ _ _ _ - - - - - - - - - - - -
ROTATIONS (des
-0.014-0.1330.0000.399
-0.010-0.0920.0000.038
-0.0320.1210.0000.616
x______
0.0330.0440.0000.073
0.004-0.1010.0000.408
g )z
-0.002-0.0220.0000.009
A18 N
Lj18 F
A19
j _
i20NLi~
A20 F
tiL
f 21 N
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRTIP1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRTiP1SSE-SEISMC
-0.014-0.0260.0000.399
-0.004-0.0270.0000.397
-0.001-0.0210.0000.345
-0.001-0.0140.0000.253
-0.001-0.0130.0000.227
-0.001-0.0070 . 0000.199
-0.0010.0190.0000.147
-0.0010.0230.0000.127
-0.019-0. 1090.0000.027
-0.019-0.0290.0000.027
-0.012-0.0060.0000.015
0.0000.0000.0000.000
0.0030.0010.0000.004
0.0040.0030.0000.008
0.0000.0060.0000.016
-0.0010.0060.0000.017
-0.0360.2320.0000.158
-0.0070.2760.0000.087
0.0000.2650.0000.076
0.0000.2290.0000.076
0.0000.2180.0000.076
0.0000.2050.0000.064
0.0000.1770.0000.009
0.0000.1640.0000.000
0.0320.0500. 0000.083
0.0320.0450.0000.081
0.0300.0160.0000.040
0.0260.0120.0000.032
0.0230.0110.0000.030
0.0090.0040.0000.014
0.0040.0010.0000.009
0.001-0.0030.0000.011
0.003-0.0760.0000.354
0.002-0.0490. 0000.296
0.000-0.0200.0000.242
0. 000-0.0130.0000.227
0.000.-0. 0120.0000.223
0.0000.0010.0000.182
0. 0000.0050.0000.166
-0.0010.0150.0000.117
-0.010-0.0030.0000.029
-0.0120.0030.0000.035
-0.0140.0140.0000.056
-0.0150.0120.0000.048
-0.0150.0110.0000.046
-0.0200.0070.0000.040
-0.0180.0060.0000.033
-0.0170.0040.0000.029
kLCIUT.ArThn 9dnnDsz-r,-nn1 ,I7 W MMtxy -
PAGE B28
__-_____________________________________________________________________________
i kUXSTM1 240046 EQE InternationalI *. 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 14
-KJ-
D I S P L A C E M E N T S
Doint Load TRANSLATIONS (in ) ROTATIONS (deg_iame combination X Y Z X Y Z
…__ _ _ _ - - - - - -- - - -- - -- - -- -- - - -- - - - - - - - - - - - - - - - - - - - - - - - -122 GR 0.000 0.000 0.000 0.000 0.000 0.000
Ti 0.000 0.000 0.000 0.000 0.000 0.000P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.000 0.000 0.000 0.000 0.000 0.000
2** Segment A end ***
;** Segment B begin ***
A17 GR -0.014 -0.019 -0.036 0.032 0.003 -0.010Ti -0.026 -0.109 0.232 0.050 -0.076 -0.003
, P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.399 0.027 0.158 0.083 0.354 0.029
,301 GR -0.017 -0.019 -0.045 0.032 0.003 -0.011T1 -0.026 -0.131 0.219 0.051 -0.076 -0.001P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.397 0.027 0.178 0.083 0.353 0.030
GR -0.018 -0.019 -0.048 0.032 0.004 -0.011T1 -0.026 -0.141 0.213 0.053 -0.076 0.001P1 0.000 0.000 0.000 0.000 0.000 0.000
L SSE-SEISMC 0.396 0.027 0.187 0.081 0.350 0.033
.03 N GR -0.021 -0.019 -0.055 0.030 0.014 -0.015Ti -0.017 -0.161 0.193 0.108 -0.052 0.064P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.357 0.027 0.199 0.042 0.242 0.276
j03 F GR -0.021 -0.020 -0.056 0.032 0.017 -0.014T1 -0.015 -0.167 0.190 0.137 -0.042 0.087P1 0.000 0.000 0.000 0.000 0.000 0.000
i SSE-SEISMC 0.346 0.027 0.200 0.048 0.217 0.400
B04 N GR -0.021 -0.022 -0.059 0.029 0.021 -0.015Ti -0.011 -0.184 0.186 0.153 -0.040 0.095P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.315 0.027 0.199 0.056 0.204 0.454
L04 F GR -0.021 -0.022 -0.059 0.016 0.025 -0.013Ti -0.008 -0.189 0.181 0.176 -0.041 0.098P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.297 0.026 0.198 0.072 0.200 0.514
'ALCULATION 240046-C-001 ATTACHMENT B- PAGE B29
AUXSTM1 240046 EQE International30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 15
-- - - - - - - - - -- - - - - - - - - - -- - - - - - - - - - --------------- _! - -
D I S PLA CE ME NTS
i Points..,,name
B05
Loadcombination___________
GRTiP1SSE-SEISMC
TRANSLATIONS (in )x y z
… _____ ------ _____-0.023 -0.022 -0.0610.010 -0.206 0.1460.000 -0.000 0.0000.199 0.026 0.187
ROTATIONS (deg )x y z
0.005 0.035 -0.0100.190 -0.047 0.0820.000 0.000 0.0000.092 0.194 0.512
**Segment B end
1 *** Segment C begin ***
B05 GR -0T1 0P1 0SSE-SEISMC 0
l C17 GR -0Ti 0P1 0SSE-SEISMC 0
.023
.010
.000
.199
.019
.014
.000
.112
-0.022-0.2060.0000.026
-0.022-0.2210.0000.026
-0.0610.1460.0000.187
-0.0470.0970.0000.139
(<C 02
L
_ 03
I
, C04 N
l
,_704 -F
GRTiP1SSE-SEISMC
GRTiP1SSE-SEISMC
GRT1P1SSE-SEISMC
GRTiP1SSE-SEISMC
GRT1P1SSE-SEISMC
-0.0080.0070.0000.047
-0.0050.0040.0000.023
0.0000.0000.0000.000
0.012-0.0090.0000.035
0.015-0.0130.0000.043
-0.022-0.2330.0000.026
-0.022-0.2380.0000.026
-0.022-0.2420.0000.026
-0.022-0.2500.0000.026
-0.027-0.2490.0000.033
-0.0220.0430.0000.063
-0.0110.0210.0000.032
0.0000.0000.0000.000
0.018-0.0330.0000.052.
0.026-0.0390.0000.069
0.0050.1900.0000.092
-0.1520.3450.0000.452
-0.2070.4110.0010.602
-0.2070.4110.0010.603
-0.2140.4010.0010.613
-0.2190.3780.0000.615
-0.2240.3610.0000.620
0.1500.0130.0000.614
0.1500.0130.0000.615
0.1600.0320.0000.668
0.1750.0640.0000.756
0.1850.0840.0000.809
0.035-0.0470.0000.194
0.123-0.0380.0000.480
-0.0100.0820.0000.512
0.091-0.0480.0000.472
0.073-0.0630.0000.451
0.073-0.0630.0000.451
0.106-0.0840.0000.431
0.169-0.1160.0000.408
0.231-0.1420.0000.400
f
i-.�
; ALCULATION 240046-C-001 ATTACHMENT B PAGE B30
AUXSTM1 240046 EQE International_ '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 16
V-----------------------------------------------i-------------__-----
~D I S e L A C E M E N T S
I Point-ame
Z C05 N
X05 F
Loadcombination___________
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
TRANSLATIONS (in )x
______
0.015-0.0370.0000.043
0.020-0.0420.0000.050
y
-0.100-0.2020.0000.134
-0.104-0.2000.0000.141
z
0.081-0.0100.0000.286
0.090-0.0130.0000.311
ROTATIONS (deg )X y z
-0.237 0.209 0.2460.291 0.114 -0.1920.000 0.000 0.0000.632 0.865 0.371
-0.2400.2800.0000.637
0.2120.1130.0000.847
0.208-0.1980.0000.355
-C06 N
I 06 F
LJC07 N
_
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
GRT1P1SSE-SEISMC
0.049-0.0760.0000.108
0.051-0.0810.0000.115
0.051-0.0860.0000.115
0.050-0.0860.0000.107
0.011-0.0490.0000.050
-0.104-0.2140.0000.141
-0.106-0.2130.0000.148
-0.112-0.2020.0000.172
-0.114-0.1980.0000.180
-0.114-0.1680.0000.180
0.131-0.0590.0000.401
0.140-0.0620.0000.426
0.154-0.0560.0000.473
0.154-0.0490.0000.475
0.0730.0380.0000.277
-0.2400.2660.0000.661
-0.2380.2690.0000.669
-0.2350.2720.0000.685
-0.2330.2710.0000.699
-0.2440.2090.0000.725
0.2190.0990.0000.778
0.2200.0940.0000.763
0.2210.0850.0000.746
0.2210.0750.0000.728
0.218-0.0070.0000.638
0.134-0.1850.0000,354
0.097-0.1660.0000.371
0.085-0.1490.0000.390
0.090-0.1240.0000.419
0.140-0.1190.0000.385
F
; I
C08j :
GRT1P1SSE-SEISMC
0.003-0.0420.0000.068
-0.114-0.1630.0000.180
-0.114-0.1510.0000.180
0.0600.0490.0000.255
0.0240.0730.0000.223
-0.2440.2090.0000.725
-0.2640.1380.0000.709
0.218-0.0070.0000.638
0.141-0.1190.0000.385
GRT1P1SSE-SEISMC
-0.019-0.0220.0000.112
0.216-0.0400.0000.607
0.171-0.1780.0000.279
I t2l�
LLCULATION 240046-C-001 ATTACHMENT B PAGE B31
________________________________________________________________________________
jUXSTM1 240046 EQE InternationalL- 0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 17-------- - - - - - - - - - - - - --
D I S P L A C E M E N T S
Point Loade-~ame combination
10 GRTiP1
,~ SSE-SEISMC
tk** Segment C end
TRANSLATIONS (in )X Y z
-0.044 -0.113 -0.0240.009 -0.136 0.0910.000 0.000 0.0000.147 0.180 0.249
ROTATIONS (deg ). X y z______
-0.2940.0670.0000.739
0.235_0.235
-0.0350.0000.580
0.122-0.1810.0000.175
*** Segment G begin ***
C17 GR -0.019Ti 0.014
: P1 0.000SSE-SEISMC 0.112
-0.022-0.2210.0000.026
-0.0470.0970.0000.139
-0.1520.3450.0000.452
0.123-0.0380.0000.480
0.091-0.0480.0000.472
L�-�
GRTiP1SSE-SEISMC
GRTiP1SSE-SEISMC
-0.019-0.0130.0000.112
-0.019-0.0220.0000.112
-0.091-0.1710.0000.147
-0.114-0.1510.0000.180
0.0030.0790.0000.175
0.0240.0730.0000.223
-0.236 0.1950.190 -0.0590.000 0.0000.622 0.616
0.245-0.2050.0000.353
0.171-0.1780.0000.279
-0.2640.1380. 0000.709
0.216-0.0400.0000.607
Segment G end ***
Segment H begin ***
:
H01 N
L- F
H0d1 F
GRTiP1SSE-SEISMC
GRTiP1SSE-SEISMC
GRTiP1SSE-SEISMC
-0.0440.0090.0000.147
-0.0760.0830.0000.176
-0.0740.0860.0000.172
-0.113-0.1360.0000.180
-0.113-0.1000.0000.180
-0.110-0.0980.0000.175
-0.0240.0910.0000.249
-0.1630.0850.0000.475
-0.1700.0840.0000.486
-0.2940.0670.0000.739
-0.390-0.0970.0000.730
-0.406-0.121
0..0000.722
0.235-0.0350.0000.580
0.277-0.0240.0000.565
0.281-0.0230.0000.568
0.122-0.181
O.'0000.175
0.041-0.1770.0000.058
0.033-0.1750.0000.063
L2ALCULATION 240046-C-001 ATTACHMENT B PAGE B32
____________________.
1,AUXSTM1 240046L 30/98 TMt-1 AUX
.____________________________________________________________
STEAM LINEEQE InternationalAutoPIPE+4.70 RESULT PAGE 18
r----------------------------- ------------------- --------------------------
D I S P L A C E M E N T S
X Point'~name
______
i H02 NI'
Loadcombination___________
GRTiP1SSE-SEISMC
TRANSLATIONS (in )x
______
-0.0360.1070.0000.090
y
-0.050-0.0640.0000.076
H02 F GR -0.034Ti 0.110P1 0.000SSE-SEISMC 0.085
,IH03 N GR -0.033Ti 0.140P1 0.000SSE-SEISMC 0.069
t H03 F GR -0.031Ti 0.142P1 0.000SSE-SEISMC 0.063
H04 N GR -0.006Ti 0.152P1 0.000SSE-SEISMC 0.012
LH04 F GR 0.000T1 0.152P1 0.000SSE-SEISMC 0.000
H05 GR 0.000Ti 0.146Pi 0.000SSE-SEISMC 0.000
H06 GR 0.000L Ti 0.000
P1 0.000SSE-SEISMC 0.000
Segment H end ***
L~ **Segment I begin ***
-0.047-0.0610.0000.070
-0.047-0.0450.0000.070
-0.043-0.0420.0000.066
-0.009-0.0190.0000.019
0.000-0.0100.0000.008
0.0000.0000.0000.000
0.0000.0000.0000.000
z
-0.2300.0740.0000.577
-0.2380.0720.0000.588
-0.3200.0360.0000.703
-0.3280.0330.0000.714
-0.3630.0240.0000.759
-0.3630.0210.0000.755
-0.3390.0200.0000.711
0.0000.0000.0000.000
ROTATIONS (deg )x y z
…_____ ------ -------0.435 0.291 0.008-0.172 -0.019 -0.1660.000 0.000 0.0000.690 0.567 0.088
-0.435-0.1790.0000.679
-0.440-0.199-0.0010.641
-0.442-0.205-0.0010.627
-0.436-0.207-0.0010.600
-0.421-0.2000.0000.577
-0.403-0.1910.0000.552
0.000*0. 0000.0000.000
0.293-0.0190.0000.568
0.302-0.0170.0000.571
0.304-0.0180.0000.572
0.306-0.0160.0000.575
0.310-0.0170.0000.576
0.309-0.0170.0000.576
0.0000.0000.0000.000
0.003-0.1630.0000.096
-0.009-0.1530.0000. 110
-0.011-0.1490.0000.112
-0.014-0.1400.0000.111
-0.010-0.1290.0000.105
0.003-0.1130.0000.095
0.0000.0000.0000.000
'ALCULATION 240046-C-001 ATTACHMENT B PAGE B33
-AUXSTM1 240046 EQE International. 10/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 19
D I S P L A C E M E N T S
Point Load TRANSLATIONS (in ) ROTATIONS (deg ),-name combination X Y Z X Y Z
…___ _ _ - -- - - - - - - - - - - - - - - - -- -- - - - - - -- - - - - - - - - - - - - -- - - - -iB05 GR -0.023 -0.022 -0.061 0.005 0.035 -0.010
Ti 0.010 -0.206 0.146 0.190 -0.047 0.082P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.199 0.026 0.187 0.092 0.194 0.512
GR -0.020 -0.021 -0.055 0.019 0.055 -0.014TI -0.002 -0.206 0.138 0.121 -0.062 -0.075P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.199 0.068 0.176 0.060 0.266 0.159
,02 N GR -0.023 -0.019 -0.050 0.028 0.065 -0.027Ti -0.009 -0.197 0.133 0.083 -0.057 -0.160P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.199 0.071 0.162 0.051 0.351 0.085
t I02 F GR -0.021 -0.019 -0.048 0.033 0.081 -0.047Ti -0.008 -0.191 0.135 0.038 -0.034 -0.274P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.185 0.066 0.155 0.056 0.514 0.393
103 N GR -0.010 -0.022 -0.045 0.036 0.083 -0.063T1 0.014 -0.186 0.143 0.007 -0.069 -0.371P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.103 0.065 0.154 0.058 0.506 0.634
LI03 F GR -0.008 -0.022 -0.044 0.036 0.083 -0.066Ti 0.021 -0.184 0.144 -0.004 -0.078 -0.392P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.086 0.065 0.154 0.062 0.495 0.677
I04 N GR -0.002 -0.022 -0.041 0.034 0.079 -0.063T1 0.062 -0.175 0.143 -0.014 -0.137 -0.403P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.016 0.065 0.153 0.062 0.408 0.646
I04 F GR 0.000 -0.021 -0.038 0.031 0.076 -0.050Ti 0.070 -0.163 0.138 -0.023 -0.173 -0.370P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.001 0.052 0.144 0.070 0.357 0.450
I05 GR 0.000 0.000 0.000 0.000 0.000 0.000Ti 0.000 0.000 0.000 0.000 0.000 0.000
L P1 0.000 0.000 0.000 0.000 0.000 0.000SSE-SEISMC 0.000 0.000 0.000 0.000 0.000 0.000
J Segment I end ***
PALCULATION 240046-C-O01 ATTACHMENT B PAGE B34
_________.
I AUXSTM1L' '0/98
1
._ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _240046TMI-1 AUX STEAM LINE
EQE InternationalAutoPIPE+4.70 RESULT PAGE 20
._ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ - - -
R E S T R A I N T R E A-C T I O N S
1 Point-name
______
Loadcombination X
FORCES (lb ) MiY Z Result X
…__ _ _ _ -- - - - - - - - - - - - - - - - - -
DMENTS (ft-lbY Z
---- ----- ___
)Result
…-- - -
AnchorGRTiP1SSE-SEISMC
1-78
0454
-133-26
0259
-i79
0442
133114
0684
175690
669
22-1505
-27277
-59-51
0259
1861508
27312
A03
4I M
L.
I A06
Y - StopGRT1P1SSE-SEISMC
Y - StopGRTiP1SSE-SEISMC
Y - StopGRT1P1SSE-SEISMC
SpringGRT1P1SSE-SEISMC
SpringGRT1P1SSE-SEISMC
Y - StopGR .T1P1SSE-SEISMC
0 -3120 3o 00 260
0 -45331-,70 76 ' 70 00 401
0 -436 '0 400 00 370
0 -2870 -160 00 15
O -497O -110 00. 15
*0 -557O -1690 00 299
0 3120 30 00 260
5750
0000~
0000
0 4530 760 0o 401 V
-9** 7 7,M1
0 4360 400 00 370
76*
0 2870 160 00 15
5/b 4
0 4970 110 00 -'
0 5570 1690 00 299
/0 z
0000
0000
0000
0000
0000
0000
0000
0
00
0
000
0
000O
0000
0
00in0
00
0
00
0
000
° 10000
0000
0000
0000
0000
0000
0000
C LCULATION 240046-C-001 ATTACHMENT B PAGE B35
s^.UVSTM1 240046 EQE International1 /98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 21
R E S T R A I N T R E A C T I O N S
I 'oint-name
; 12L
A14 M
L _
Loadcombination
FORCES (lb ) MOMENTS (ft-lb )X y Z Result X Y Z Result
…__ _ - - - - - - - - - - - -- - - - - - - - - - - - - - - - - - - - - -Y - StopGRTiP1SSE-SEISMC
Y - StopGRTiP1SSE-SEISMC
Y - StopGRT1P1SSE-SEISMC
SpringGRT1P1SSE-SEISMC
Y - StopGRTiP1SSE-SEISMC
o -490O-3/o 97 430 00 190
0 -4951 -10 780 00 98
0 -5650 -1520 \ 00 151
0 4900 970 00 190
0 4950 780 00 98 V
sis 515
0000
0000
0000
0000
0000
5651520151
0000
0000
0000
0000
0000
0000
0000
0000
00.
00
-372960
639
0K0
0 &
0006
00000t0
4541281
15039
0000
-506-10
04
0 5060 100 00 4
51i0
0 -7070 590 00 188
0000
A2',
i
707590
188 -
45f+ 83 C.
0000
0000
2 AnchorGRTiP1SSE-SEISMC
-9178
0449
-154590
154
14-132
0375
1552290
605
254-357
0930
-591227
14911
'U03 GuideGRTiP1SSE-SEISMC
31-19
047
91 *
0 -80 320 00 47
g7I
32380
67i
I1V1
0000
0000
0000
0000
ALCULATION 240046-C-001 ATTACHMENT B PAGE B36
.^AUXSTM1 240046 EQE International'% '30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 22
- ---
,-Point Load| name combination X
H05 Y - StopGRT-P1
-_ SSE-SEISMC
-H06 AnchorGRT1P1SSE-SEISMC
105 Anchor- GR
Tl
SSE-SEISMC 2
R E S T R A I
FORCES (lby z
0 -480 -280 00 34
N T
Res
0000
R E A C T I O N S
MOMENTS (ft-lb )cult X Y Z
…__ _ -- -- -- - - - - - -- - - - - -- - -
48 0 0 028 0 0 0
0 0 0 034 0 0 0
-13304
-6-40
42
/r4
-3 14-0 40 0
13 18
-2 2021 820 019 282
-12-60
17
2-104
23-10
62
10-540O40
-18909
-8-37
046
Result_______
0000
32110
65
1366061
PLCULATION 240046-C-001 ATTACHMENT B PAGE B37
…_______________________________________________________________________________-AWXSTM1 240046 EQE International
0 '30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 23
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
, Point Load Ma-lame combination (Sus.)
1 -- - - - - - - - - - - - - - - - - - - - - - -
B31.1 (1992) CODE COMPL3mients in ft-lb )
Mb Mc(Occ.) (Exp.) S.I.F
-_ _ _ _ _ _ - - - - - - - -
(Stress in psi )Eq. Load Code Codeno. type Stress Allow.
…_ _ - - - - - - - - - - - - - - - -
Segment A begin ***
AOO Max PGR + Max P 186L Cold to TiSSE-SEISMC 0 7312GR+P+SSE 0 7355
L,01 Max PGR + Max P 198Cold to TiSSE-SEISMC 0 6507GR+P+SSE 0 6569
1.001508 1.00
1.001.00
1.00891 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372300
107652205251
372309636
46454690
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
t 02 N- Max PGR + Max PCold to T1SSE-SEISMC
J GR+P+SSE
121
0 65140 6556
1.00854 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372254610 -
46504680
A02
LI 2i
N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
F- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
F+ Max P.GR + Max PCold to T1SSE-SEISMCGR+P+SSE
121
0 65140 6556
77
0 62190 6244
77
0 62190 6244
2.44854 2.44
2.442.44
2.44705 2.44
2.442.44
1.00705 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372325
148785058560
372268122881208153
372223503
44404458
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
Lj02 ( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
495
0 31190 3295
1.00286 1.00
1.00'1.00
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
372521204
22272352
1410014100211504230042300
iALCULATION 240046-C-001U-
ATTACHMENT B PAGE B38
m-AUXSTM1 240046 EQE International'1P"'30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 24
_ ---------------------------------------------------- _I---------------------__
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
,,Point Load! name combination
------ -----------
A04 N- Max P1 GR + Max P
L Cold to TiSSE-SEISMC
1 * GR+P+SSE
Ma Mb Mc(Sus.) (Occ.) (Exp.) S.I.F
-_____ ---- --- -------
-A04 N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
88
0 33410 3423
88
0 33410 3423
40
D 34620 3492
1.00989 1.00
1.001.00
2.44,989 2.44
2.442,44
2.441041 2.44
2.442.44
Eq.no.
( 3)(11)(13)(12)(12)
(Stress in psiLoad Codetype Stress
HOOP 372SUST 230DISP 706OCC 2385OCC 2444
L )
\ A04 M
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372282
172143634470
372219
181245204560
CodeAllow.14100_
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
F- Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
76
0 32530 3322
2.441046 2.44
2.442.44
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372267182242484337
1410014100211504230042300
A04
Li ;z-A05
F+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
N- Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
76
0 32530 3322
* 76
0 22370 2288
1.001046 1.00
1.001.00
1.001162 1.00
1.001.00
( 3) HOOP(11) SUST(13) DISP(12) oCC(12) OCC
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
372222747
23232371
372222829
15971633
14100141002115042300.42300
1410014100211504230042300
N+ Max PGR + Max PCold to TISSE-SEISMCGR+P+SSE
76
0 22370 2288
2.441162 2.44
2. 442. 44
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
372266
202229202988
1410014100211504230042300
PkLCULATION 240046-C-001 ATTACHMENT B PAGE B39
…__ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _,-AUXSTM1 240046 EQE International
0s" 1'0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 25
…---------------------------------------------------_ I- ------------------ __
L ASME B31.1 (1992) CODE COMPLIANCE
,?oint Load! iame combination
A05 F- Max PGR + Max P
L Cold to TiSSE-SEISMC
I GR+P+SSE
(Moments in ft-lb )Ma Mb Mc Eq. I
(Sus.) (Occ.) (Exp.) S.I.F no. I…__ _ _ _ _ - - - - - - - - - - - - - - - - - - - - - _ _ _ _
50
0 25410 2580
2.441262 2.44
2.442.44
( 3)(11)(13)(12)(12)
I
I
(Stress in psiLoad Codetype Stress A____ ------ -
HOOP 372SUST 233)ISP 2197OCC 3317OCC 3369
Codeilow.
1410014100211504230042300
F+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
50
0 25410 2580
1.001262 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372203901
18141842
1410014100211504230042300
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
ST- Max PGR + Max PCold to T1SSE-SETSMC
306
0 29530 3032
247
0 30430 3108
247
0 30430 3108
1.001433 1.00
1.001.00
-1.001468 1.00
1.001.00
2.441468 2.44
2.442.44
GR+P+SSE
A07 N+ Max PGR + Max P
L Cold to TiSSE-SEISMCGR+P+SSE
kr7 F- Max PGR + Max P
; Cold to TiL SSE-SEISMC
GR+P+SSE
07 F+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372386
102321082165
372344
104821722219
372490
255639734058
372368
251040894145
372277
102922362266
141001A4100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
154 2.441442 2.44
0 3132 2.440 3175 2.44
154
0 31320 3175
1.001442 1.00
1.001.00
I I
!LLCULATION 240046-C-001 ATTACHMENT B PAGE B40
________________________________________________________________________________
ttUXSTM1 240046 EQE Internationalje '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 26
W J ---------------------------------------------------- --------------- -------
ASME B31.1 (1992) CODE COMPLIANC:(Moments in ft-lb )
I'oint! tame
A08
I!
Loadcombination___________
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
Ma(Sus.)
_ _ _ _ _ _
Mb Mc(Occ.) (Exp.)
_ _ _ _ _ _ _ - - - - - - -
Eq.S.I.F no.
_ _ _ _ _ _ _ - - - -
E(Stress in psiLoad Codetype Stress J
HOOP 372SUST 490DISP 553OCC 2195OCC 2310
sA09Il
452
0 30750 3236
313
0 31070 3209
N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
1.00775 1.00
1.001.00
1.00737 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
oCCOCC
CodeAllow.
1410014100211504230042300
1410014100211504230042300
372391526
22182291
09 N+ Max PGR + Max PCold to Ti
t: SSE-SEISMCL GR+P+SSE
313
0 31070 3209
2.44-737 2.44
2.442.44
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372576
128440574191
1410014100211504230042300
I
L-
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
151
0* O
2.44652 2.44
2.442.44
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372364
113542124249
1410014100211504230042300
32263254
A09
LF+ Max P
GR + Max PCold to TiSSE-SEISMCGR+P+SSE
151
0 32260 3254
1.00652 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372275466
23032323
1410014100211504230042300
N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
151
0 32260 3254
151
0 32260 3254
1.00652 1.00
1.001.00
2.44652 2.44
2.442.44
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCoCC
372275466
23032323
372364
1135.42134249
1410014100211504230042300
1410014100211504230042300
PILCULATION 240046-C-001 ATTACHMENT B PAGE B41I
, WUXSTM1 240046 EQE International'C 0'"0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 27L I- - - -- - -- - -- - -- -- -- ---- - ------ ----- --- --- ---- -- --- ---- ---.- --- - -- -- - -- --- ---
'Point Loadi name combination
A10 F- Max P
|; GR + Max PCold to TiSSE-SEISMC
, - GR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCI(Moments in ft-lb )
Ma Mb Mc Eq.(Sus.) (Occ.) (Exp.) S.I.F no.
…______ - - -- - -- - - - - - -- - -- -- - - -- - -
256
0 33500 3445
256
0 33500 3445
( 3)2.44 (11)
576 2.44 (13)2.44 (12)2.44 (12)
( 3)1.00 (11)
576 1.00 (13)1.00 (12)1.00 (12)
(Stress in psi )Load Code Codetype Stress Allow.
…___ - -- --- _____HOOP 372 14100SUST 502 14100DISP 1003 21150OCC 4374 42300OCC 4499 42300
HOOP. 372 14100SUST 351 14100DISP 411 21150OCC 2391 42300OCC 2460 42300
'-10 F+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
887
0 40150 4424
1.001215 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372801867
28663158
1410014100211504230042300
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
A13 N- Max PGR + Max PL Cold to TiSSE-SEISMCGR+P+SSE
'A13 N+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
441
0 31320 3247
205
0 30780 3139
205
0 30780 3139
1.001512 1.00
1.001.00
1.001578 1.00
1.001.00
2.441578 2.44
2.442.44
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372483
107922362318
372314
112621972241
372435
274640194099
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
I 13 F- Max PGR + Max PCold to T1
. SSE-SEISMCLGR+P+SSE
101
00
30233047
2.441610 2.44
2.442.44
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372300
280339483979
1410014100211504230042300
v-I
, LCULATION 240046-C-001 ATTACHMENT B PAGE B42
…
,AUXSTM1 240046 EQE InternationalLt '00/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 28--
?oint Loadiame combination
----- -----------
A13 F+ Max PGR + Max P
L Cold to TiSSE-SEISMCGR+P+SSE
"'A14 N- Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq. 3(Sus.) (Occ.) (Exp.) S.I.F no. I
…____ ______ ------- -------… ---- -
( 3) 1101 1.00 rll * c
(Stress in psiLoad Codetype Stress ;____ ------ -lOOP 372SUST 240)ISP 1150OCC 2158OCC 2175
1610 1.000 3023 1.000 3047 1.00
' ~,(13)(12)(12)
I
CodeAllow.
1410014100211504230042300
1410014100211504230042300
124
0 30290 3057
1.001621 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372256115821622182
1i 4 N+ Max PGR + Max P
I 1 Cold to TiSSE-SEISMCGR+P+SSE
T Max PI, > GR + Max P
Cold to Tif, SSE-SEISMCi GR+P+SSE
124
0 30290 3057
2.441621 2.44
2.442.44
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372329
282339543992
1410014100211504230042300
227 2.441613 2.44
0 3049 2.440 3096 2.44
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372464
280939824043
1410014100211504230042300
A14 F- Max P! , GR + Max P
L Cold to TiSSE-SEISMC
i .GR+P+SSE
k
,14 F+ Max PGR + Max PCold to TiL SSE-SEISMCGR+P+SSE
159
0 30430 3072
159
0 30430 3072
2.441587 2.44
2.442.44
1.001587 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372375
27623974.4012
372281
113321732193
1410014100211504230042300
1410014100211504230042300
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
833
00
1.001005 1.00
2466 1.002783 1.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372762717
17611987
1410014100211504230042300
ALCULATION 240046-C-001 ATTACHMENT B PAGE B43
________________________________________________________________________________
;AUXSTM1 240046 EQE InternationalIr '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 29K1-
ASME B31.1 (1992) CC(Moments in ft-lb )
iPoint Loadi iame combination
.A16 Max P1. GR + Max PL_ Cold to TI
Ma(Sus.)
_______
Mb(Occ.)
_ _ _ _ _ _
Mc(Exp.)
_______
)DE COMPLIANCE(Stress in psi
Eq. Load CodeS.I.Fr no. type Stress i
…__ _ _ _ _ - - - - - - - - - - - - - - -
SSE-SEISMCGR+P+SSE
'I,
AJ17. i;
- Max PGR + Max. PCold to TiSSE-SEISMCGR+P+SSE
819
0 26430 3026
147
0 37500 3827
1.001026 1.00
1.001.00
2.231710 2.23
2.232.23
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
oCCoCC
HOOPSUSTDISP
oCCoCC
372752732
18872160
372343
272544824575
)CodeAllow.
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
122
0 37550 3841
2.231458 2.23
2.232.23
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
372313
232344894591
KJ7 Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Al8 N+ Max PLI GR + Max PL Cold to Ti
SSE-SEISMCGR+P+SSE
LA18 F- Max PGR + Max PCold to Ti
L SSE-SEISMCGR+P+SSE
L18 F+ Max PGR + Max PCold to Ti
- SSE-SEISMCGR+P+SSE
108
0 35350 3602
108
0 35350 3602
263
0 33640 3499
263
0 33640 3499
1.001398 1.00
1.001.00
2.441398 2.44
2.442.44
2.441265 2.44
2.442.44
1.001265 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
372244998
25232571
372308
243446154703
372511
220343934568
372355903
24022498
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
I ALCULATION 240046-C-001 ATTACHMENT 3 PAGE B44
________________________________________________________________________________
AUXSTM1 240046r/130/98 TMI-1 AUX STEAM LINE
EQE InternationalAutoPIPE+4.70 RESULT PAGE 30
I- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Point Loadname combination~____ ----- _---------
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb ) (Stress in psi
-Ma Mb Mc Eq. Load Code(Sus.) (Occ.) (Exp.) S.I.F no. type Stress J
…__ _ _ _ _ - - - - - - - - - - - - - - - - - - - - - - - - - - - - - _ _ _ _ _ _
CodeAllow.______
Al 9L 1
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
1016
0 28400 3366
851
0 27020 3122
1.00849 1.00
1.001.00
1.00745 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISPoCcOCC
HOOPSUSTDISP
OCCOCC
372893606
20282403
372775532
19292229
1410014100211504230042300
14100* 14100211504230042300
LA20 N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
F- Max PLx GR + Max P
Cold to TiSSE-SEISMCGR+P+SSE
A20 F+ Max PGR + Max P
L Cold to TiSSE-SEISMC
851
0 27020 3122
664
0 26200 2973
664
0 26200 2973
475
0 27840 2950
475
0 27840 2950
2.44745 2.44
2.442.44
2.44647 2.44
- 2.44
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISPoCc
2.44 (12) OCC
A
'A21
GR+P+SSE
N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
1.00647 1.00
1.001.00
1.00525 1.00
1.001.00
2.44525 2.44
2.442.44
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
oCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
3721278129735284076
372* 103411273421* 3881
372641462
18712122
37250737519872106
372788914
36353852
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
LA21 N+ Max PGR + Max P
I Cold to TiL SSE-SEISMC~GR+P+SSE
LL
L
kLCULATION 240046-C-001 ATTACHMENT B PAGE B45
KAUXSTM1 240046 EQE International'0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 31
------------ ----- ---- ---- ---- --- ---- ---- ---- ----------------------
i-oint Loadiame combination
-A21 F- Max P'i GR + Max P
Cold to TiSSE-SEISMC
- GR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq.(Sus.) (Occ.) (Exp.) S.I.F no.
…__ _ _ _ _ - - - - - - - - - - - - - - - - - - - - - - - - -
439
0 28130 2985
2.44427 2.44
2.442.44
( 3)(11)(13)(12)(12)
(Stress in psi )Load Code Codetype Stress Allow.
…__ ------ ------HOOP 372 14100SUST 741 14100DISP 743 21150OCC 3673 42300OCC 3898 42300
*.22
F+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
439
0 28130 2985
454
0 50390 5208
*
46
0 12910 1325
1.00427 1.00
1.001.00
1.001281 1.00
1.001.00
2.23435 2.23
2.232.23
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
k jegment A end
*** Segment B begin
I k17 Max PL GR + Max P.Cold to T1
I SSE-SEISMCL GR+P+SSE
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
372481305
20082131
372492915
35973718
372222693
15431584
372198
422985
1010
210884
107912600626650
210709
52871513415594
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
.1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
p301 Max PGR + Max PCold to T1
- SSE-SEISMC| GR+P+SSELB02 Max P
GR + Max P1 Cold to'T1
SSE-SEISMC- GR+P+SSE
403 N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
29
0 9200 943
23
0 7710 791
18
0 4490 463
2.00295 2.00
2.002.00
2 2.10240 .2.10
2.102.10
2.10118 2.10
2.102.10
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
ALCULATION 240046-C-001 ATTACHMENT B PAGE B46
AUXSTM1 240046 EQE Internationalt 30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 32
-- --,_ _ _ _ - - -- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Point Load, name combination
B03 N+ Max P| GR + Max PL Cold to T1
SSE-SEISMC! GR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq. ](Sus.) (Occ.) (Exp.) S.I.F no. I
…__ _ _ _ _ _ _ _ _ _ _ _ - - - - - - - - - - - - - - - -- - -
(Stress in psi )Loadtype
18
0 4490 463
2.10118 2.10
2.102.10
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
CodeStress______
210709
528715134-15594
CodeAllow.14100_
1410014100211504230042300
! B03
F- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
F+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
18
0 3910 405
18
0 3910 405
2.10100 2.10
2.102.10
2.10100 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
oCCOCC
HOOPSUSTDISP
oCCOCC
210694
44741319313638.
210694
44741319313638
1410014100211504230042300
1410014100211504230042300
L -Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
5 B04
L:
LB0 4
N+ Max PGR + Max PCold to T1iSSE-SEISMCGR+P+SSE
F- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
37
0 2450 274
37
0 2450 274
42
0 1910 222
42
0 1910 222
2.1072 2.10
2.102.10
2.1072 2.10
2.102.10
2.1063 2.10
2.102.10
2.1063 2.10
2.102.10
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
( 3) HOOP'(11) SUST(13) DISP(12) OCC(12) OCC
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
2101353322182559250
2101353322182559250
2101508281464387477
2101508281464387477
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
I
LB04 F+ Max PGR + Max PCold to Ti
II SSE-SEISMCL- - GR+P+SSE
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
.ALCULATION 240046-C-001 ATTACHMENT B PAGE B47
,AUXSTM1 240046 EQE International'30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 33K - -------------------------------
L~ ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
I Point Load Ma Mb Mc Eq. :_name combination (Sus.) (Occ.) (Exp.) S.I.F no. 1
B05 Max P ( 3) IGR + Max P 33 2.10 (11) '
L. Cold to Ti 8A ' in ,i i
(Stress in psiLoad Codetype Stress A
HOOP 210SUST 1220DISP 3987OCC 6343OCC 7265
Codehlow.
1410014100211504230042300
SSE-SEISMC
L GR+P+SSE
*** Segment B end ***
' *** Segment C begin ***
0 1880 215
. 1w
2.102.10
1J2 I
(12)(12)
LC17
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
32
0 880 119
36
2.3040 2.30
2.302.30
2.3031 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
1239405
156752571234911
12310521122732285532648
1410014100211504230042300
1410014100211504230042300
00
78* 111
+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
20
00
4967
lC02
II
10
0 330 43
15
0 340 47
2.3023 2.30
2.302.30
2.3011 2.30
2.302.30
2.3012 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
12359549001
1448219776
123313943799738
12570
123445248839968
13709
1410014100211504230042300
14100-14100211504230042300
1410014100211504230042300
5 IJ
Max PGR + Max PCold to TISSE-SEISMCGR+P+SSE
21 1.00* 17 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
oCCOCC
1233708287464659529
1410014100211504230042300
00
3856
PILCULATION 240046-C-001 ATTACHMENT B PAGE B48
________________________________________________________________________________
! UXSTM1 240046 EQE International,' '0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 34
ILASME, B31.1 (1992) CODE COMPLITANCEr
1?oint LoadIlame combination
_ _ _ _ _ _ - - - - - - - - - - -
(Moments in ft-lb ) (StriMa Mb Mc Eq. Load
(Sus.) (0cc.) (Exp.) S.I.F no. type…__ _ _ _ _,_ _ _ _ _ _ _ - -- - - -- - - - - - - - - -- - - - --
C04
C04
0
L 0 4
N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
N+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
F- Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
00
3047
21
21
00
2.3013 2.30
2.302.30
2.3013 2.30
2.302.30
2.3012 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
3047
ess in psiCode
Stress______
1236166.5168891113863
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
123616651688911
13863
12354134621787412216
i )Code
Allow.14100_
1410014100211504230042300
1410014100.211504230042300
1410014100211504230042300
18
00
2742
'+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
C05 N- Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
tO5 N+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
18
00
2742
14
00
1425
2.3012 2.30
2.302.30
2.306 2.30
2.302.30
2.306 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
oCCOCC
HOOPSUSTDISP
OCCOCC
123541346217874
12216
1234155239842307399
1234155239842307399
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
14
00
1425
F- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
11
0 130 21
2.305 2.30
2.302.30
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
1233428209439076264
1410014100211504230042300
,tALCULATION 240046-C-001 ATTACHMENT B PAGE B49
eAUXSTM1 240046P '30/98 TMI-1 AUX STEAM LINE
EQE InternationalAutoPIPE+4.70 RESULT PAGE 35
r…_________________ _-
-Point LoadIname combination
C05 F+ Max PGR + Max PL Cold to T1SSE-SEISMCL GR+P+SSE
C06 N- Max PGR + Max P
I ~ Cold to T1L SSE-SEISMC
GR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq. I(Sus.) (Occ.) (Exp.) S.I.F no. I
…______ ------- ------- ------- ---- -
11
00
1321
13
0 180 28
13
2.305 2.30
2.302.30
2.306 2.30
2.302.30
2.306 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
I
(Stress in psiLoad Codetype Stress____ ------
HOOP 123SUST 3428DISP 2094OCC 3907OCC 6264
i
LC06 N+
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
1233771228452418314
1233771228452418314
)Code
Allow.
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
00
1828
i F-
LCO- F
C06 F+
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
10
0 190 28
10
2.307 2.30
2.302.30
2.307 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
1232983281255998086
1232983281255998086
1410014100211504230042300
1410014100211504230042300
00
1928
-C07 N- Max PGR + Max PCold to Ti
* SSE-SEISMCGR+P+SSE
' z07 N+ Max PGR + Max PCold to T1
|i SSE-SEISMCLGR+P+SSE
1
00
1920
2.309 2.30
2.302.30
2.309 2.30
2.302.30
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
123372
356456465862
123372
356456465862
1410014100211504230042300
1410014100211504230042300
1
00
1920
ELCULATION 240046-C-001 ATTACHMENT E PAGE B50
, UXSTM1 240046 EQE InternationalL' "0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 36L r------------------------------------------------------------------------
ASME B31.1 11992) CODE COMPLITANCE(Moments in ft-lb )
?oint Load Ma Mb Mc Eq. ]Iame combination (Sus.) (Occ.) (Exp.) S.I.F no. I
______ ----------- --------------- ------- ------- ---- -
C07 F- Max P ( 3) 1L GR + Max P 3 2.30 (11) 'Co-l d to T1l a i an r1w %
(Stress in psi )Load Code Codetype Stress Allow.____ ------ ------
ROOPSUSTDISP
OCCOCC
SSE-SEISMCGR+P+SSE
00L-
C07
L
1821
F+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
2.30
2.302.30
2.309 2.30
2.302.30
( 1 2
(12)(12)
A
123923
352552606031
123923
352552606031
1410014100211504230042300
1410014100211504230042300
3( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
00
1821
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to TiSS&-SEISMCGR+P+SSE
6
00
2127
6
00
2632
8
2.3013 2.30
2.302.30
2.3016 2.30
2.302.30
2.3022 2.30
2.302.30
2.3027 2.30
2.302.30
1.0027 1.00
1.001.00
( 3)(11)(13)(12)(12)
( 3). (11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)'(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
oCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCoCC
1231774517861587781
1231940610875219338
12323998716
11470137-74
132364855739028
12554
1322011240442936159
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
00
3947L
.Cie23
00
5881
22
00
4868
Ir** Segment C end
, Segment G begin
L,~
C LCULATION 240046-C-001 ATTACHMENT B PAGE B51
_____________-__________________________________________________________________
.UXSTM1 240046 EQE InternationalL/ 1/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 37_ - I , _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
L oint LoadLame combination
.,17 Max PII GR + Max P
Cold to T1SSE-SEISMC
I GR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq. ](Sus.) (Occ.) (Exp.) S.I.F no. 1
…______ ------- ------- ------- ---- -
(Stress in psi )Loadtype____
42
00
5998
2.3032 2.30
2.302.30
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
Code CodeStress Allow.
123___ 14100-
123 1410012278 1410012692 2115017246 4230028623 42300
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
15 2.3011 2.30
2.302.30
( 3)(11)(13)(12)(12)
HOOP*SUSTDISP
OCCOCC
123443843859060
13152
1410014100211504230042300
00
3145
L18 Max PGR + Max PCold to Ti
I1 SSE-SEISMCL- GR+P+SSE
28
00
18
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
123475330187377
11627
14100- 141002115042300
423004368
i egment G end ***
*** Segment H begin ***
L10 Max PGR + Max PCold to TiSSE-SEISMC
L GR+P+SSE
01 N- Max PL GR + Max P
Cold to TiSSE-SEISMCL GR+P+SSE
H01 N+ Max PI GR + Max PL Cold to T1
SSE-SEISMCj GR+P+SSE
..
'D -,->e~l~( 3) HOOP
r 1 09 11)SUST27 1.00 (13)DISP
1.00 (12) OCC1.00 (12) OCC
1162.7 (z. I)S zd4,07ts
Z*41'7 , O. sf & I.4?W132 14100
2011 141002404 211504293 423006159 42300
22
00
21
00
4868
3958
2.1026 2.10
2.102.10
2.1026 2.10
2.102.10
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
1323037498755308305
1323037498755308305
1410014100211504230042300
1410014100211504230042300
21
0 390 58
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
'101 F- Max PGR + Max P
I Cold to T1SSE-SEISMC
I > GR+P+SSE
I-
20
00
3857
2.1025 2.10
2.102.10
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
1322928481154398143
1410014100211504230042300
* :ALCULATION 240046-C-001 ATTACHMENT.B PAGE B52
AUXSTM1 240046 EQE International_' 30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 38
L -.<
I Point LoadL-name combination
: HO1 F+ Max PI GR + Max P
Cold to TiSSE-SEISMC
| GR+P+SSE
* ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq.(Sus.) (Occ.) (Exp.) S.I.F no.
…______ ------- ------- ------- ----
20
00
3857
2.1025 2.10
2.102.10
( 3)(11)(13)(12)(12)
(Stress in psi )Load Code Codetype Stress Allow.
…___ -- --- - ---- --HOOP 132 14100SUST 2928 14100DISP 4811 21150OCC 5439 42300OCC 8143 42300
H02 N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
7 2.109 2.10
2.102.10
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
1321036163938924771
1410014100211504230042300
00
2734
-H02 N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
7
00
2734
2.109 2.10
2.102.10
( 3) HOOP(11) SUST(13) DISP(12) OCC(12) OCC
1321036163938924771
1410014100211504230042300
_ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
6
0 270 32
2.108 2.10
2.102.10
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
132972
148238374493
1410014100211504230042300
IH02 F+ Max PL - GR + Max P
Cold to TiSSE-SEISMC
| GR+P+SSE
6
00
2732
H03 N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
4
2.108 2.10
2.102.10
2.108 2.10
2.102.10
2.108 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
132972
148238374493
132694
155941274714
132694
155941274714
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
00
2933
N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
4
00
2933
t LCULATION 240046-C-001 ATTACHMENT B- PAGE B53
________________________________________________________________________________
IkUXSTM1 240046 EQE International'0/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 39
--- - - - - - - - - - - - - - - - - - - - - - - -__
|oint_L3ame
______
'103 F-I '
, _t
Loadcombination
JuAmr, Z).)1.1 k z C COLIk uukeLANCE(Moments in ft-lb )
Ma Mb Mc Eq. 3(Sus.) (Occ.) (Exp.) S.I.F no. I
…______ ------- ------- ------- ---- -Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
4
00
H03
i :
2932
F+ Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
2.108 2.10
2.102.10
2.108 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
I
I
(Stress in psiLoad Codetype Stress
iOOP 1323UST 579)ISP 1424OCC 4102OCC 4498
4
0 290 32
CodeAPllow.
1410014100211504230042300
1410014100211504230042300
HOOPSUSTDISP
OCCOCC
132579142441024498
L.-04 N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
9
00
2734
k 1+ Max PGR + Max PCold to T1SSE-SEISMC
L GR+P+SSE
9
00
2734
2w04
:i~
H04t.VF- Max P
GR + Max PCold to TiSSE-SEISMCGR+P+SSE
F+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
13
( 3)2.10 (11)
6 2.10 (13)2.10 (12)2.10 (12)
( 3)2.10 (11)
6 2.10 (13)2.10 (12)2.10 (12)
( 3)2.10 (11)
10 2.10 (13)2.10 (12)2.10 (12)
( 3)2.10 (11)
10 2.10 (13)2.10 (12)2.10 (12)
3)1.00 (11)
19 1.00 (13)1.00 (12)1.00 (12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP- OCC
OCC
HOOPSUSTDISP
oCCoCC
1321399115138504842
1321399115138504842
1321869190338165409
1321869190338165224
1321946167725974202
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
14100141002115042300.42300
00
13
00
2738
2737
21
00
2947
.LCULATION 240046-C-001 ATTACHMENT B PAGE B54
_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
I ;tUXSTM1 2400461 )''10/98 TMI-1 AUX STEAM LINE- I_>--------------------------
EQE InternationalAutoPIPE+4.70 RESULT PAGE 40
…________________________________________________
I- ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
! ?oint Load Ma Mb Mc Eq. :Laame combination (Sus.) (Occ.) (Exp.) S.I.F no. I
…____ ----------- ------- ------- ------- ------- ---- -H06 Max P
I 1 ~GR + Max PL- Cold to T1
SSE-SEISMCGR+P+SSE
*** Segment H end
32
00
1.0011 1.00
1.001.00
( 3)(11)(13)(12)(12)
IIII
(Stress in psiLoad Codetype Stress____ ------
HOOP 132SUST 2913DISP 959OCC 5865OCC 8482
CodeAllow.
.1410014100211504230042300
6594
i;:** Segment I begin ***
B05I
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
12
0 1760 185
13
0 2030 214
2.1080 2.10
2.102.10
2.1076 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
1321811151722504626387
1321907
144752881730447
1410014100211504230042300
1410014100211504230042300
[:02 N- Max PGR + Max P
, I Cold to TiIi SSE-SEISMC%. GR+P+SSE
At02 N+ Max P
L GR + Max PCold to T1
;1 SSE-SEISMCI GR+P+SSE
16
0 2180 233
16
0 2170 232
2.1075 2.10
2.102.10
2.1075 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
1322285
142903096733093
1322285
142903084632966
1410014100211504230042300
1410014100211504230042300
I02 F- Max Pj' GR + Max Pj- Cold to Ti
SSE-SEISMC
1 GR+P+SSE
9I02 F+ Max P-GR + Max P
PI Cold to T1L- SSE-SEISMC
GR+P+SSEK,
14
0 1900 204
14
0 1900 204
2.1067 2.10
2.102.10
2.1067 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
1322064
127582706229000
1322064127582706229000
1410014100211504230042300
1410014100211504230042300
ALCULATION 240046-C-001 ATTACHMENT B PAGE BSS
AUXSTM1 240046r' '0/98 TMI-1 AUX STEAM LINEt r---------------------------------___________
EQE InternationalAutoPIPE+4.70 RESULT PAGE 41
…_____________________________
PointL -ame
Loadcombination (S
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb )
Ma Mb Mc Eq. ];us.) (Occ.) (Exp.) S.I.F no. I
…___ ------- ------- ------- ---- -
(Stress in psi )Loadtype
103 N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
5
00
8893
45
( 3). HOOP2.10 (11) SUST2.10 (13) DISP2.10 (12) OCC2.10 (12) OCC
N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
5 2.1045 2.10
2.102.10
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
00
-8893
"Zo3 F- Max PGR + Max PCold to T1SSE-SEISMCGR+P+SSE
j + Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
!T04 N- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
4
00
7477
4
0 740 77
7
0 1040 110
2.1041 2.10
2.102.10
2.1041 2.10
2.102.10
2.1031 2.10
2.102.10
( 3)(11)(13)(12)(12)
( 3)(11)(13)(12)(12)
3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
oCCOCC
CodeStress______
132767
84661248113174
132767
84661248113174
132587
77761049910999
132587
77761049910999
132101859361475715659
1410014100211504230042300
1410014100211504230042300
1410014100211504230042300
CodeAllow.14100_
1410014100211504230042300
1410014100211504230042300
Lo04
N+ Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
F- Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
7
0 1040 110
8
0 1290 137
2.1031 2.10
2.102.10
2.1034 2.10
2.10
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
HOOPSUSTDISP
OCC
13210185936
1475715659
13212476541
1834019489
1410014100211504230042300
1410014100211504230042300
( 3)(11)(13)(12)
2.10 (12) OCC
, kLCULATION 240046-C-001 ATTACHMENT B PAGE B56
________________________________________________________________________________
,XSTM1 240046 EQE International1'30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 42
t y__- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -_
PointIiame
______
104 F+
I05
Loadcombination___________
Max PGR + Max PCold to T1SSE-SE ISMCGR+P+SSE
Max PGR + Max PCold to TiSSE-SEISMCGR+P+SSE
ASME B31.1 (1992) CODE COMPLIANCE(Moments in ft-lb ) (Stress in psi
Ma Mb Mc Eq. Load Code(Sus.) (Occ.) (Exp.) S.I.F no. type Stress J
_______ ------- ------- ------- ---- ---- ------ -
( 3) HOOP 1328 2.10 (11) SUST 1247
34 2.10 (13) DISP 65410 129 2.10 (12) OCC 183400 137 2.10 (12) OCC 19489
CodeAllow.
1410014100211504230042300
1410014100211504230042300
13 1.0066 1.00
1.001.00
( 3)(11)(13)(12)(12)
HOOPSUSTDISP
OCCOCC
1321266595355146702.
00
6174
1
L.*** Segment I end
( LCULATION 240046-C-001_k
ATTACHMENT B PAGE B57
________________________________________________________________________________
!.UXSTM1 240046 EQE International_ii'10/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 43
S Y S T E M S U M M A R Y
aximum displacements (in)I-._______________________
Maximum X :Maximum Y :Maximum Z :Max. total:
"Maximum rotations (deg)_______________________
L- ~ - Maximum X :Maximum Y :Maximum Z :
I Max. total:
1.307-0.2503.9384.149
0.7390.8650.6771.134
PointPointPointPoint
PointPointPointPoint
: All: C04 N: A13 N: All
: C10: C05 N:I03 F: C05 N
Load Comb.: SSE-SEISMCLoad Comb.: T1Load Comb.: SSE-SEISMCLoad Comb.: SSE-SEISMC
Load Comb.: SSE-SEISMCLoad Comb.: SSE-SEISMCLoad Comb.: SSE-SEISMCLoad Comb.: SSE-SEISMC
L jumrestraint forces (lb)_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
Maximum X :Maximum Y :Maximum Z :Max. total:
454-707442707
Maximum restraint moments (ft-lb)
I - - - --- --- --- - ---------------- ____
Point : ADOPoint : A19Point : AOOPoint : A19
Point : A22Point : AOOPoint : A22Point : AOO
Load Comb.:Load Comb.:Load Comb.:Load Comb.:
Load Comb.:Load Comb.:Load Comb.,:Load Comb.:
SSE-SEISMCGRSSE-SEISMCGR
SSE-SEISMCSSE-SEISMCSSE-SEISMCSSE-SEISMC
Maximum X :Maximum Y :Maximum Z :Max. total:
9307277639
7312
L-
ALCULATION 240046-C-001 ATTACHMENT B PAGE B58
________________-_______________________________________________________________
1,AUXSTM1 240046 EQE International; '30/98 TMI-1 AUX STEAM LINE AutoPIPE+4.70 RESULT PAGE 44
S Y S T E M S U M M A R Y
Maximum sustained stress
PointStress psiAllowable psiRatioLoad combination
: C17: 12278: 14100: 0.87: GR + Max P
Maximum displacement stress
PointStress psiAllowable psiRatioLoad combination-:
B0515675211500.74Cold to T1
Maximum occasional stress
PointStress psiAllowable psiRatioLoad combination
: B05: 34911: 42300: 0.83: GR+P+SSE
Maximum hoop stress
PointStress psiAllowable psiRatioLoad combination
: AQO: 372: 14100: 0.03: Max P
!-.
ikLCULATION 240046-C-001 ATTACHMENT B PAGE B59
_________-______________________________________________________________________
WUXSTM1 2400465'',X 0/98 TMI-1 AUX STEAM LINE
tK __ …
EQE InternationalAutoPIPE+4.70 RESULT PAGE 45
._______________________________________________-
S Y S T E M SUMMARY
Maximum sustained stress ratio
PointStress psiAllowable psiRatioLoad combination
: C17: 12278: 14100: 0.87: GR + Max P
Maximum displacement stress ratio
PointStress psiAllowable psiRatioLoad combination :
B0515675211500.74Cold to T1
Maximum occasional stress ratioIL-,--� Point
Stress psiAllowable psiRatioLoad combination :
B0534911423000.83GR+P+SSE
Maximum hoop stress ratio
PointStress psiAllowable psiRatioLoad combination
: AOO: 372: 14100: 0.03: Max P
l1 * * * The system satisfies ASME B31.1 code requirements * * ** * ** for the selected options * * *
-"I. / - t- . ( -~ [-;
a
UM
: "I,
IX,i
Frequency (Hz)
\ILegend:
Envelope of LB, BEUB Spectra1.5 x SQUG BoundingSpectrum
C'7
v
Notes:
Enveloped In-Structure ResponsLB & UB Broadened 10%BE Broadened 15%5.0 % Spectral DampingAccelerations in gos
_ _ _- _-
.__ II - I
Ii
(I
I tI
I 2 2I0
0
C)i
l
.o
4.II0
NI
IFrequency (Hz)
.
I
Ii|- -.?
1 ? i ! E
%S1
Legend:
Envelope of LB, BEUB Spectra .
1.5 x SQUG BoundingSpectrum
, . .
Notes:
Enveloped In-StructureLB & UB Broadened 10%BE Broadened 15%5.0 % Spectral DampingAccelerations in g's
_ _- -_-
a _ I
A4 77Adr ",I; J7 <,*7 r> )
1.
L
Li
L
L
L
LI
L
CHECKING CRITERIA CHECKLIST
Client (ZPd/ Project A In P/F^S
Job No. 2 4 o4 Calc. No. 0 /
Revision No.
Criteria Yes No N/A Comment No.
1. Originator followed defined procedures.
2. Title, purpose and function of the workchecked are adequately described.
3. Work method clearly stated and appropriate.
4. Assumptions identified. Open items flaggedfor subsequent verification where necessary..
5. Technical bases and references current,correctly selected, and incorporated.
6. Technical input properly selected andadequately identified. Any specific input tobe excluded are adequately identified.
7. Applicable codes, standards and regulatoryrequirements identified and properly used.
8. Analytical steps can be verified withoutrecourse to originator.
9. Each page of the work identified and trace-able to originator, date and job or equivalent 3control number.
1 O.All markings legible and identifiable.
Page bi of 3
PD6)"2KLW
A- 7A'14A>,J-y7 >)
4-
4.-
I.
L
i
k--
l'1
LI
CHECKING CRITERIA CHECKLIST
_ __
Client
Job No.
61-11) PUIA./
2-4V O 4 &Project
Calc. No.
Revision No.
Avy--572*m P Pl
A3�A, 4 P, Pdd,
t0
0
Criteria Yes No N/A Comment No.
11.Work clearly references any final supportingcomputer runs.
1 2. Final computer runs include input listing andoutput.
13.Final computer runs contain unique numberidentifier.
14.Results consistent with inputs, technicalprocedures, and other project criteria.
1 5.Results are reasonable.
1 6.Revisions are clearly documented. _
1 7.Technical interface requirements in theProject Plan have been satisfied.
1 8.AII documentation available to checker.
19.Computer program version identified.
20.Computer program version certified andapplication valid.
I.
Checked by: IA k7 A.
4 30-fmDate:
' #4-f6Page P2- of .3
#"MWe2Lw
A AriA . Pi>-I-_~~ 7 , *A frg-c 11R.
CHECKING CRITERIA CHECKLIST
Client 67pL1 Project 57-CAM P,16
Job No. ___ _ _ _ _ _ Calc. No.
Revision No.
CHECKING CRITERIA CHECKLIST
Comment No. Comment Resolved by:
Date:
l_ . /h 4-?o-
___ A/rt ____v ? 1;-
.. I
Page t3 of 3'
N4�
II
ii Ii
240046-R-001Revision 1June 5, 1998Page E I
_
LNJI I
L-LII
ATTACHMENT E:
WALKDOWN PHOTOGRAPHS
I.
L
240046-R-001Revision 0April 30, 1998Page E 2
Photo 1: Auxiliary Steam Piping from header. Turbine Bldg. El. 355'.
Photo 2: Auxiliary Steam Piping from header. Turbine Bldg. El. 355'.
III...
240046-R-001Revision 0April 30, 1998Page E 3
Photo 3: Auxiliary Steam piping at Control Building Penetration #1 847. ControlBldg. El. 355'.
Photo 4: Auxiliary Steam Piping support no. MK-AS-1 29. Control Bldg. El. 355'.This support is located approx. 5'-0 south of penetration 1847. Thepenetration will limit E-W (lateral) deflection of the pipe. The short rodhanger is judged acceptable based on deflection being limited by thepenetration.
240046-R-001Revision 0April 30,1998Page E 4
Photo 5: Auxiliary Steam Piping support no. MK-AS-1 30. This photo is lookingup at rod penetrating cutout in grating. Above grating is flexible plateand carpeting for an office area. The SRT judged the rod will not bedamaged by movement of piping and the resulting interaction with theplate and carpet.
Photo 6: Auxiliary Steam Piping in wall penetration near support no. MK-AS-134.
L
240046-R-001Revision 0April 30, 1998Page E 5
Photo 7: Auxiliary SteamPiping Truck Bay-Fuel Building pipepenetration andsupport no. MK-AS-1 35.
Photo 8: 2" branch line off 85 diameter Auxiliary Steam Pipe header in theTruck Bay.
240046-R-001Revision 0April 30, 1998Page E 6
Photo 9: Anchor support no. MK-AS-1 55 for the Auxiliary Steam Piping in theTruck Say.
L
Photo 10: Typical wall mounted U-bolt support for the 2 diameter AuxiliarySteam Piping going to the Decontamination Pit.
240046-R-001Revision 0April 30, 1998Page E 7
Photo 1 1: Auxiliary Steam Piping support no. MK-AS-1 42.
Photo 1 2: Auxiliary Steam Piping support no. MK-AS-1 46.
240046-R-001Revision 0April 30, 1998Page E 8
Photo 13: Auxiliary Steam Piping support no. MK-AS-147.
Photo 14: Looking east at steam trap AS-ST-31.
240046-R-001Revision 0April 30, 1998Page E 9
Photo 15: Wall mounted support near steam trap AS-ST-31. Calculations showsupport is acceptable.
Photo 16: Close-up of wall mounted support near steam trap AS-ST-31.
240046-R-001Revision 0April 30, 1998Page E 10LL
L
LLLLI>
Photo 17: 1" diameter branch piping from valve AS-V-102 running to decant andslurry pump and make up tank room.
Photo 1 8: Auxiliary Steam Condensate Return piping.; \_-/8
240046-R-001Revision 0April 30, 1998Page E 11
i I1
Photo 19: Auxiliary Steam Conde Lte Return piping.
I
Photo 20: 1 " diameter condensate return to condensate return tank/pumps AS-P2A/B.
V
240046-R-001Revision 0April 30, 1998Page E 12
Photo 21: 1 diameter condensate return to condensate return tank/pumps AS-P2A/B.
LL.