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| number = ML17275B162
| number = ML17275B162
| issue date = 07/21/1981
| issue date = 07/21/1981
| title = Nonproprietary Version of Chugging Loads-Revised Definition & Application Methodology for Mark Ii Containments (Based on 4TCO Test Results).
| title = Nonproprietary Version of Chugging Loads-Revised Definition & Application Methodology for Mark II Containments (Based on 4TCO Test Results).
| author name = BEDROSIAN B, ETTOUNEY M M, VERDERBER J J
| author name = Bedrosian B, Ettouney M, Verderber J
| author affiliation = BURNS & ROE CO.
| author affiliation = BURNS & ROE CO.
| addressee name =  
| addressee name =  
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=Text=
=Text=
{{#Wiki_filter:Chugging Loads-Revised Definition and Application Methodology for Mark I I Containments (Based on 4TCO Test Results)TECHNICAL REPORT (5 (5 Q 0 flQ (5 9 (5 p 99 (5 0 p Bf 0 (5-'.'>>(5(pi>>'.'f08040527 810724 PDR ADOCK 05000397 PDR Burns and Roe, Inc.Engineers 8 Constructors Woodbury, New York  
{{#Wiki_filter:Chugging Loads Revised Definition and Application Methodology for Mark I I Containments (Based on 4TCO Test Results)
~~II LIST OF FIGURES FIGURE NO.5-4 5-5 5-6 5-7a 5-7b 5-7c 5-7d 5-7e 5-8a 5-8b 5-8c 5-8d 5-8e 5-9 DESCRIPTION Fluid-Structure Boundary-WNP-2 Suppression Pool Reactor Building Model Envelopes of Calculated Responses for WNP-2, and Measured Responses at JAERI-Containment at Vent Exit Elevation Reactor Building Response-Asymmetric Loading: Containment Vessel at Mat Reactor Building Response-Asymmetric Loading: RPV Support Reactor Building Response-Asymmetric Loading: Containment Vessel at Stabilizer Truss Level Reactor Building Response-Asymmetric Zoading: Containment Vessel at.Mid-Submergence Depth Reactor Building Response-Asymmetric Loading: Outside Building Wall Elevation 521'eactor Building Response-Nearly Symmetric Zoading: Containment Vessel at Mat Reactor Building Response-Nearly Symmetric Loading: RPV Support Reactor Building Response-Nearly Symmetric Loading: Containment Vessel at Stabilizer Truss Level Reactor Building Response-Nearly Symmetric Loading: Containment Vessel at Mid-Submergence Depth Reactor Building Response-Nearly Symmetric Zoading: Outside Building Wall Elevation 521'ibration Tolerance Observations PAGE NO.126 127 128'i 29 130 131 132.133 134 135 136 137 138 139 I
TECHNICAL REPORT flQ   (5 p
Su~arur Tests were conducted during 1975/76 by General Electric Company (GE)in their 4T test facility for the domestic Mark ZZ utilities for the purpose of evaluating the containment pool dynamic effects resulting from a postulated loss-of-coolant accident (LOCA).Based on chugging data recorded during these tests, an empirical load definition was deve-.loped This load definition was based on direct application of pressure traces measured on the boundary of the 4T test I facility to the wetted perimeter of Mark ZZ containments and, as a result, could not account for differences between the 4T test f acility and the Mark ZZ containments with respect.to vent length (vent acoustics), suppression.
9 (5
pool geometry (pool acoustics) and flexibility of suppression pool structural boundaries.
                                                                      - '.'>> (5(pi>>'.
Zn order to account for these differences, it became necessary'to develop a chugging load definition at the"source" (i.e., at vent exit).Such an improved.chugging load definition was'eveloped together with the application methodology for Mark ZZ contain-'ents for specific application to Washington PubLic Power Supply: System-Nuclear Project No.2 (WNP-2).This defini-tion was based on conclusions reached after evaluation of tests conducted to assess effects of steam-condensation pheno-mena in Mark ZZ type (over/under) pressure suppression systems.Two main conclusions from these tests were:.
99 (5 0
I I I a)chugging effects are mainly due to the sudden (impulsive) collapse of the steam-water interface which occurs near the vent exit during the chugging regime and, in view of this, chugging could be repre-sented by an impulsive load applied there;and,"b)bulk fluid motions during chugging being relatively small, a linear formulation (small displacements/
p Bf 0 (5
velocities) is adequate for predicting the dynamic pressures induced in the far field (away from vent exit)and the dynamic response of the pool boundary structures.
(5 (5
A single vent design load specification was derived to bound, statistically, the 4T test data supplied by GE as representative of Hark II conditions during LOCA.The appli-cation methodology for NNP-2 containment was also developed, properly accounting for all important plant specific parameters:
Q0 Burns and Roe, Inc.             'f08040527 Engineers 8 Constructors Woodbury, New York PDR ADOCK    810724 05000397 PDR
length of downcomer vents (vent acoustics), 3-D multi-vent suppression pool geometry with a sloped bottom (pool acoustics) and the flexibility of the suppression pool structural boundary.Two loading conditions were developed for, and considered'n the design of, the multi-vent configuration of WNP-2: a nearly symmetrical loading and an asymmetric loading.
I Additional condensation tests were performed during 1979-1980 by GE for the U.S.Mark ZZ Owners Group, in a modified configuration of the 4T test facility, known as the."4TCO" test facility.Selected and" conservatively represen-tative (most severe)4TCO chugging data supplied by GE were evaluated/analyzed with the objectives:
a)to examine in light of the 4TCO data, the adequacy of the existing improved chugging load definition; and, b)to revise, where necessary, this (improved) load definition and the application methodology for the Mark lX containment of NNP-2.Analysis of the 4TCO chugging data, as well as of the chugging data which became available from other tests during the same time period, resulted in the following main findings: a)the impulsive nature of chugging (sudden collapse of the steam-water interface) was confirmed; b)it was determined that the 4TCO data included some stronger/larger amplitude chugs which exhibited characteristics (frequency content, spatial dis-tribution) different from those of the 4T chugs;c)the random nature of chugging was confirmed; I I I d)the strength/amplitude of chugging, although random, appeared to be dependent on system conditions, i.e., stronger chugs appeared to cluster within limited time windows corresponding to specific system con-ditions.As a consequence, the following revisions to the single vent design load specification were implemented:
the"source" load was defined as an impulsive pressure gradient (acceleration) applied over the steam-water interface at vent exit;this resulted in better matching of the characteristics exhibited by the stronger 4TCO chugs;to account for the random nature of the chug strength/amplitude each strongest ("key")chug was averaged (in terms of Fourier amplitude spectrum)with the largest neighboring
("companion")
chug to obtain an"average" or"mean" chug for each time win-dow for which 4TCO chugging data were supplied.Zt is significant to note that the single vent design"source" load developed for WNP-2 in fact envelopes the 4TCO data at almost all locations of the 4TCO tank wetted boundary and throughout the frequency range of interest;it also enve-lopes the 4T data.
I I I The two loading conditions originally developed for'NP-2 were basically retained (a nearly symmetrical loading and an asymmetric loading)in a manner compatible with the revised single vent design load specification.
In ordex to account for physical realities observed during steam-condensation tests in multi-vent configuxations (JAERI, CREARE), vent-desynchronization is specified for both these loading con-ditions adopting the approach used in the Long Term Improved Generic Chugging Load Definition developed by GE for Hark II Owners Group, in a-manner compatible with the two loading con-ditions for WNP-2.To verify the adequacy of chug strength averaging and of vent desynchronization, the dynamic pressures calculated on the wetted wetwell wall of WNP-2 were compared with wall pressures recorded during large-amplitude chugs in the 7-vent full scale tests conducted by the Japan Atomic Energy Research Institute (JAERI)in a test facility representative of the Mark ZZ geometry.The calculated pressures were found to bound the JAERI data.
I I I I


==1.0 Introduction==
~ ~ II LIST  OF FIGURES FIGURE NO.          DESCRIPTION                                    PAGE NO.
and Back round The original chuggingload def inition was developed using chugging data recorded during the 4T tests conducted by General Electric Company (GE)for the domestic Mark II utili-ties in the 4T (single vent/unit cell)test facility during late 1975 and early 1976,[1].This load definition was based on direct application of pressure traces measured on the boun-dary of the 4T test facility to the wetted perimeter of Hark II containments,[2].It soon became apparent that this method of application of 4T data to Mark II containments did not account for differences between the 4T test facility and the Mark II containments with respect to vent length (vent acoustics),.
5-  4  Fluid-Structure Boundary -           WNP-2               126 Suppression  Pool 5- 5  Reactor Building Model                                    127 5- 6  Envelopes  of Calculated Responses for                   128 WNP-2, and Measured  Responses at JAERI-Containment at Vent Exit Elevation 5-7a    Reactor Building Response                                'i 29 Asymmetric Loading: Containment Vessel at Mat 5-7b    Reactor Building Response                                130 Asymmetric Loading: RPV Support 5-7c    Reactor Building Response                                131 Asymmetric Loading: Containment Vessel at Stabilizer Truss Level 5-7d    Reactor Building Response                                132.
single vent versus multi-vent suppression pool geometry and flexibility of suppression pool structural boun-daries.In order to account for these differences, it became necessary to develop a chugging load definition at the"source", i.,e., at vent exits.Because of schedule constraints, such an improved chugging load definition was developed, together with the application methodology to Hark II containments, for specific application to Washington Public Power Supply System-Nuclear Project No.design load the 4T test containment 2 (WNP2)during 1978/79, f 3, 4].A single vent specif ication was derived to bound, statistically, data supplied as being representative of Mark II conditions expected during a postulated ZOCA.
Asymmetric Zoading: Containment Vessel at. Mid-Submergence Depth 5-7e    Reactor Building Response-                                 133 Asymmetric Loading: Outside Building Wall Elevation 5-8a            Building Response 521'eactor 134 Nearly Symmetric Zoading:
I I I l I I I I The single vent design load was defined as a pressure source at the vent exit and since its definition was indepen-dent of the 4T test facility characteristics which were dif-'erent from those of WNP-2 (vent length, suppression pool geometry and flexibility of suppression pool structural boundary)it was assumed to be directly transferable to vent exits in the WNP-2 containment.
Containment Vessel at Mat 5-8b    Reactor Building Response                                135 Nearly Symmetric Loading:
Two loading conditions were developed and considered in the design of WNP 2: a nearly symmetrical loading and an asymmetric loading.The applica-tion methodology for WNP-2 containment accounted for the plant specific parameters governing the response: length of down-comer vents, 3-D multi-vent suppression pool geometry with a sloped bottom, and the flexibility of suppression pool struc-tural boundary (steel containment, the concrete pedestal and the foundation mat).Zn 1979-1980, additional condensation tests were per-formed by GE for the U.S.Nark XX Owners Group in a modified configuration of the 4T test facility, known as the"4TCO" test facility (5].The original, 4T test facility included a drywell located adjacent to the wetwell, a confi'guration which required a vent with three bends and a total length of about 90 feet.Zn the 4TCO facility, the drywell vessel was mounted
RPV Support 5-8c    Reactor Building Response                                136 Nearly Symmetric Loading:
Containment Vessel at Stabilizer Truss Level 5-8d    Reactor Building Response                                137 Nearly Symmetric Loading:
Containment Vessel at Mid-Submergence Depth 5-8e    Reactor Building Response                                138 Nearly Symmetric Zoading:
Outside Building Wall Elevation 5-9                Tolerance Observations 521'ibration 139


above the wetwell to represent'he over/under pressure suppression configuration with straight vertical vent, approximately 45'ong, representative of Mark ZZ plants.Although the 4TCO tests were planned and performed with the objective of gathering test data to be used for confirmation of the DFFR Condensation Oscillation (C.O.)load definition, the data were recorded for the entire transient including chugging, thus providing an additional data base for chugging as well.Selected chugging data obtained from regions of the 4TCO tests during which the most severe chugging effects were recorded were made available by General Electric Company as being conservatively representative for Mark lZ plants during the chugging regime.The 4TCO chugging data supplied, (6], are evaluated and results and conclusions piesented in this report.The conclusions of this evaluation together with the conclusions reached following the evaluation of multi-vent test data by GE and presented in Reference 7 report (regarding the random nature of chug strength and chug initiation time from vent-to-vent during a pool chug in a multi-vent configuration) are used in this report: (a)to examine in light of the 4TCO data, the ade-quacy of the (improved) chugging load definition developed previously, using 4T data, for applica-tion to Vii1P-2[3g 4]I and (b)to revise, where necessary, this (improved) chugging load definition and the application methodology for the Mark II containment of WNP-2.The 4TCO chugging data supplied by General Electric and the multi-vent tests evaluated by General Electric are identified in Chapter 2..The evaluation of 4TCO chugging data including the analytical studies performed in the process of data evaluation and the characteristics of single vent 4TCO chugs derived from data evaluation/analysis are described in Chapter 3.The eva-luation shows that revision in the improved chugging load definition is necessary.
I Su~arur Tests    were conducted      during 1975/76 by General Electric Company    (GE)  in their    4T  test facility for the domestic Mark ZZ   utilities for        the purpose    of evaluating the containment pool dynamic effects resulting from a postulated loss-of-coolant    accident      (LOCA). Based  on  chugging  data   recorded during these      tests,   an   empirical load definition      was  deve-.
The revised single vent load definition and the revised application methodology for the Mark II containment of WNP-2 based on theconclusions reached following the eva-luation of'TCO test data (presented in Chapter 3)and on the conclusions reached from the evaluation of multi-vent:
loped      This load      definition  was  based  on direct application of pressure traces measured on the boundary of the 4T test I
test data (presented by General Electric in Reference 7)are pre-sented in Chapter 4.The results of application of the revised chugging load definition to the WNP-2 plant (i.e., reactor building/containment structure responses) are presented in Chapter 5.  
facility to the wetted perimeter of Mark ZZ containments and, as a result, could not account for differences between the 4T test facility and the Mark ZZ containments with respect. to vent length (vent acoustics), suppression. pool geometry (pool acoustics) and flexibility of suppression pool structural boundaries.        Zn order to account for these differences,             it became    necessary 'to develop a chugging load           definition at the "source" (i.e., at vent exit) .
Such    an  improved. chugging       load   definition was'eveloped together with the application methodology for Mark ZZ contain-for specific application to Washington PubLic Power                  'ents Supply: System - Nuclear Project No. 2 (WNP-2). This defini-tion was based on conclusions reached after evaluation of tests conducted to assess effects of steam-condensation pheno-mena  in Mark ZZ type (over/under) pressure suppression systems. Two main    conclusions from these tests were:.


2.0 The New Chu in Data 2..1 The Sin le Vent 4TCO Test Data The 4TCO test facility, test variables, test matrix, test instrumentation and test results are described in detail in Reference 5.The-test facility is shown in Figure 2-1.The wetwell pressure transducer locations are shown in Figure 2 2~The pressure time histories recorded at the bottom center (channe1 28)were scanned by General Electric Company to identify significant chugs.Two hundred ninety-seven chugs were identified (See Table 4-2 of Reference 7).*Table 2-1 provides a summary of the 4TCO chug data compiled from infor-mation provided by General Electric[8]in November 1980.Table 2-1 identifies seven regions from six tests which recorded the largest chugs (based on the bottom center pressure (BCP)mean square power (msp)and peak over pressure*information from Reference 8 is provided in Tables 2-1 and 2-2 of this report for identification of chug numbers and time window numbers used in this report and to establish their correspondence with information subsequently published in Reference 7.
I I
I 1 I (POP))of all 4TCO tests.General Electric Company selected 7 key chugs (one for each of the seven regions)because the power" spectral density (PSD)envelope of these chugs closely approximated the PSD envelope of the entire sample of chugs[7, 8].Several chugs (called neighboring chugs)occurring before or after each of the seven key chugs together with the key chug define a region, or a time window making seven regions[8].The region numbers and the number of chugs in each region are also identified in Table 2-1., A total of 35 chugs in seven regions or time windows were selected by General Electric Company as the chugging data base[8].The 4TCO chugging data base identification parameters are shown in Table 2-2.The 4TCO bottom center pressure time histories for the thirty-five.chugs were recorded on magnetic tapes at.4939 millisecond interval and supplied to Burns and Roe[9].In addition, the data from all the 28 replay channels from all tests were digitized at 1 millisecond interval and supplied on magnetic tapes to the Mark II Owners Group[6].The data for the 35 chugs of the chugging data base were obtained from these tapes for the evaluation presented in Chapter 3.2.2 Multi-vent Test Data Multi-vent test data from two test programs (the CREARE subscale tests and the JAERI full scale tests)have I
I
recently become available.
General Electric Company has eva-luated these multi-vent test data for the Mark II Owners Group and has incorporated the significant findings of multi-vent effects (the random nature of chug strength and chug ini-tiation time from vent-to-vent during a pool chug in a multi-vent configuration) in the Generic Chugging Load Definition Report[7].The results of these data evaluations and conclu-sions reached will also be adopted for the chugging load defi-nition for WNP-2..


BURNS AND ROE g.lNC~PROPRZETARY 3.0 4TCO Chu in Data Evaluation and Anal tical Studies 3.,1 Xntroduction 3.2 4TCO Chu in Data Evaluation 3.2.1 Waveform Characteristics of Boundary Pressures BVRNS AND ROE I INC~PROPRXETARY BURNS AND ROE, lHC., PROPRIETARY 3.2.2 Spatial Dist:ribuhion of Boundary Pressures BURNS AND ROEI XNC.PROPRXETARY I)
a)     chugging    effects are      mainly  due  to   the               sudden (impulsive)   collapse    of the steam-water                  interface which occurs near the vent        exit during the               chugging regime and, in view of      this, chugging could be repre-sented by an impulsive load applied there; and, "b)    bulk  fluid  motions during chugging being          relatively small,   a  linear formulation (small displacements/
CHUGGING LOADS-REVISED DEFXNITION AND APPLICATION METHODOLOGY FOR MARK II CONTAINMENTS (based on 4TCO test results)TECHNICAL REPORT Prepared By BURNS AND ROE'NC.for'pplication to WASHINGTON PUBLIC POWER SUPPLY SYSTEM NUCLEAR PROJECT NO.2 Prepared By: M.M.Ettouney Senior Civil Engineer Approved By: B.Bedrosian l Assistant Chief Civil Engineer F.J Patti Chief Nuclear Engineer Submitted By: J Verderber ect Engineering Manager!Date:
velocities) is adequate for predicting the dynamic pressures induced in the far field (away from vent exit) and the dynamic response of the pool boundary structures.
I I 4'(I BURNS AND ROE g INC.DISCLAIMER OF RESPONSIBILITY Neither the Burns and Roe, Xnc.nor its affiliates or related entities nor any of the contributors to this document make any warranty or representation (expressed or implied)with respect to the accuracy, completeness, or usefullness of'he information contained in this document, or that the use of such information may not infringe privately owned rights;nor do they assume any reponsibility for liability or damage of any kind which may result from the use of any of the infor-mation contained in this document., 1-BURNS AND ROE, INC.PROPRIETARv NOTICE This document contains proprietary information of Burns and Roe, Inc.and it is not to be reproduced or furnished to third parties nor the information contained therein utilized, in whole or in part, without the prior express written per-mission of Burns and Roe, Inc.,
A single vent design load specification          was  derived to bound,   statistically,     the   4T  test data supplied                  by  GE  as representative of Hark      II conditions    during  LOCA. The              appli-cation methodology for      NNP-2  containment was also developed, properly      accounting    for   all    important plant specific parameters:      length of downcomer vents (vent acoustics), 3-D multi-vent suppression pool geometry with a sloped bottom (pool acoustics) and the flexibility of the suppression pool structural boundary.
I I GENERAL ELECTRIC COMPANY DISCLAIMER OF RESPONSIBILITY This document contains proprietary information of General Electric Company pursuant to contracts with certain utilities owning plants utilizing Mark ZI Containments.
Two  loading conditions were developed for,        and considered'n the design of, the multi-vent configuration of WNP-2:                            a nearly symmetrical loading and an asymmetric loading.
Except as otherwise provided in such contracts, the General Electric Company does not: A.Make any warranty or representation, expressed or implied, with respect to the accuracy, completeness, or usefulness of the proprietary information con-tained in this document, or that the use of any proprietary information disclosed in this document may not infringe privately owned rights;B.Assume any responsibility for liability or damage which may result from the use of any proprietary information disclosed in this document;or C.Imply that a plant designed in accordance with the proprietary information found in this document will be licensed by the United States Nuclear-Regulatory Commission or that it will comply with Federal, State or Local regulations.
I I I I I GENERAZ EZECTRXC COMPANY PROPRIETARY NOTICE This document contains proprietary information of the General Electric Company and it is not to be reproduced or furnished to third parties nor the information contained therein uti-lized, in whole.or in part, without the prior express written permission of General Electric Company.
I I TABLE OF CONTENTS Item Disclaimers Proprietary Notices Table of Contents, List-of Tables Zist;of Figures S'ummary 1.0 Introduction and Background 2.0 The New Chugging Data 2.1 The Single Vent 4TCO Test Data 2.2 Multi-vent Test Data 3.0 4TCO Chugging Data Evaluation and Analytical Studies Paca e.No.V111 10 10 11 13 3.1 Xntroduction 3.2 4TCO Chugging Data Evaluation 3.,2.1 Naveform Characteristics of Boundary Pressures 3.2.2 Spatial Distribution of Boundary Pressures 3.2.3 Summary of" Characteristics of the 4TCO Chugs 3.3 Analytical Studies and Correlation with Test Data 13 13 13 15 19 3.3.1 3.3.2 3.3.3 Finite Element Model of the 4TCO System Response Sensitivity to Source Parameters and Correlation with Test Data Response Sensitivity to System Parameters and Correlation with Test Data 21 22 l I I TABLE OF CONTENTS Item Pacae Na.3.4 Conclusions 4.0 Revised Chugging Load Definition


===4.1 Introduction===
I Additional    condensation    tests    were    performed    during 1979-1980  by  GE  for the  U.S. Mark  ZZ  Owners  Group,    in  a modified configuration of the       4T  test facility,    known as    the.
33 35 35 4.2 4.3 Summary Review of the (Improved)
"4TCO"  test facility.      Selected    and" conservatively represen-tative  (most severe)   4TCO  chugging data supplied      by  GE  were evaluated/analyzed    with the objectives:
Chugging Load Definition Based on 4T Test Data Revisions Reauired in the (Improved)
a)  to examine in   light of    the 4TCO  data, the adequacy of the existing improved chugging load        definition;  and, b)  to revise,    where    necessary,    this (improved) load definition and the application methodology for the Mark lX containment of NNP-2.
Chugging Load Definition to Account for the New Chugging Data 4.3.1 Revision Zn Source Impulse Based on 4TCO Data 36 39 39 4.3.2 Revision Zn Source Strength Based on 40 4TCO and Multi-vent Data 4.3.3 Revision Zn Application Methodology For Mark ZI Containments Based on Multi-vent Test Data 4.4 Single Vent.Design Zoad Specification 4.,4..1 Required Average Spectrum 4.,4.2 Design Impulsive Sources 4.4.3 Summary of Single Vent Design Load Specification 43 43 43 47 4.5'4~6 Application of Single Vent Load Specification 48 to Multi-vent Mark IZ Containments 4.5.1 Spatial Variation of Chug Strengths 48 4.5.2 Desynchronization of Chugs Summary of Comperative Review Between'NNP-2'1 and Mark ZI Generic Chugging Load Definitions
Analysis of the 4TCO chugging data, as well as of the chugging data which became available from other tests during the same time period, resulted in the following main findings:
a)  the impulsive nature of chugging (sudden collapse of the steam-water interface) was confirmed; b)    it  was  determined    that the    4TCO  data included      some stronger/larger    amplitude      chugs    which    exhibited characteristics    (frequency      content,    spatial    dis-tribution) different    from those of the 4T chugs; c)    the random nature of chugging was confirmed;


====4.6.1 Computational====
I I
Methodologies 51 I I TABLE OP CONTENTS Item~pa e No.4.6.2 WNP-2 Plant Unique Characteristics 4.6..3 Application Methodologies for Mark II Containments 5.0 WNP-2 Reactor Building Response to Chugging Loads 5.1 Introduction
I


===5.2 Theoretical===
d)  the strength/amplitude      of chugging, although random, appeared to be dependent on system conditions, i.e.,
stronger chugs appeared to cluster within limited time windows corresponding to specific system con-ditions.
As a  consequence,    the following revisions to the single vent design load specification were implemented:
the    "source"    load  was    defined    as  an  impulsive pressure    gradient (acceleration) applied over the steam-water interface at vent exit; this resulted in better matching of the characteristics exhibited by the stronger 4TCO chugs; to    account  for the      random    nature  of the    chug strength/amplitude      each  strongest    ("key") chug  was averaged (in terms of Fourier amplitude            spectrum) with the largest neighboring ("companion") chug to obtain an "average" or "mean" chug for each time win-dow  for which  4TCO  chugging data were supplied.
Zt is significant to note that the single vent design "source" load developed for WNP-2 in fact envelopes the 4TCO data at almost    all locations of    the  4TCO  tank wetted boundary and throughout the frequency range of interest;          it also enve-lopes the 4T data.


===Background===
I I
5.2.1 Treatment of Multiple Vents 5..3 WNP-2 Response to Chugg ing Loads 5.3.1 Containment Wall Design Pressures and Comparison with Test Data 5.3.2 Structural Response 5.4 Discussion of Calculated Structural Response to Chugging Loads 6.0 List of References 53 55 57 57 60 63 63 66 Tables Figures Appendix A-Analogy Between Acoustic and Structural Boundary Conditions Al-A6 I I jIST OF TABLES TABIE NO.DESCRIPTION PAGE NO.2-1 Summary of.4TCO Chug Data 70 2-2 4TCO Chugging Data Base Identif ication Parameters 71'-1 Identification of the Companion Chug Used for Averaging with Key Chug 72 4-2 Single Vent Design Source Definition 73 5-1 Chug Start Times for Random Phasing 7'4 5-2 Maximum Rigid Hall Pressures on WNP-2 Containment at Vent Exit Elevation (Node 15)75 5-3 4TCO Pressure Maximums and Average at Channel 20 76 5-4 JAERI Peak Positive Chugging Pressure Amplitudes 77 5-5 Maximum Computed Accelerations for NNP-2 Reactor Building 78 I
I
LIST OF FIGURES FIGURE NO.DESCRIPTION PAGE NO.2-1 Test Configuration for Nark El Condensation Oscillation (4TCO)Tests 79 2-2 4TCO Tests-Wetwell Pressure Transducer Locations 80 3-1 Comparison of Pressures and~Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No.1 81 3-2 Comparison of Pressures and Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No.2 82 3-3 Comparison of Pressures and Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time.Window No.3 83 3-4 Comparison of Pressures and Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No., 4 84 3-5 3-6 Comparison of Pressures and Fourier Amplitude Spectra of'Key Chug and A Neighboring Chug-Time Window No.5 Comparison of Pressures and Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No..6 85 86 3-7 Comparison of Pressures and Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No.7 87 3-8 Comparison of Pressures Measured at Channel 28 and Channel 26 During Time Window No.6, Chug 52 88 I
LIST OF FIGURES FIGURE NO.DESCRIPTION PAGE NO-3-9 3-10 Comparison of Pressures Measured at Channel 24 and Channel 20 During Time Window No.6, Chug 52 Phase Relationship Between Pressures Measured at Channel 20 and Channel 28 Versus Frequency-Time Window No.1 89 90 3-11 Phase Relationship Between Pressures Measured at Channel 20 and Channel 28 Versus Frequency-Time Window No.,'l 91 3-12 3-13 Ratios of Fourier Amplitudes of Pressures Measured at Channel 28/Channel 20-Vertical Distribution of Peak Pressures-Six Chugs, Time Window No.1 92 93 3-14 3-15 3-16 Vertical Distribution of Peak Fourier Amplitudes of Pressures-Two Chugs-Time Window No.1 Ratio of Fourier Amplitudes of Pressures Measured at Channel 20 and Channel 21 Comparison of 4TCO and 4T Data-Pressures Measured at Bottom Center 94 95 96 3-17a 3-17b Vent-Pool Model (Fluid Elements)Structural Finite Element Model of 4TCO Tank 97 98 3-18 3-19 Schematic Presentation of Pressure Source at Vent Exit in 4TCO System Fourier Amplitude Spectrum of Pressure Calculated at Channel 28 with Pressure Source at Vent Exit 99 100 LIST OF FIGURES FIGURE NO.3-20 3-21 DESCRIPTION Schematic Presentation of Acceleration Source at Three Locations in 4TCO System Fourier Amplitude Spectrum of Pressure Calculated at PAGE NO.101 102 3-22 Fourier Amplitude Spectrum of Pressure Calculated at Channel 28 with Acceleration Source Located 6'bove Bottom 103 3-23 Fo uri er Amp 1 i tude Spectrum o f Pressure Calculated at Channel 28 with Acceleration Souxce Located 3'bove Bottom 104 3-24 3-25 Comparison of Vertical Distxibution of Normalized Maximum Pxessure Calculated with Pressure and Acceleration Sources Vertical Distribution of Fourier Amplitudes of Pressures Calculated with Acceleration Sour'ce at Vent Exit 105 106 3-26 3-27 3-28 Fourier Amplitude Spectrum of Px'essure at Channel 28 with 1418 fps, Decreased from 1600 fps, Figure 3-21 Fourier Amplitude Spectrum of Pressure at Channel 28 with 2400 fps, Decreased from 4800 fps, Figure 3-21 Phase Relationship Between Pxessures Calculated at Channel 20 and Channel 28 Versus Frequency 107 108 109 3-29 Cw Versus Resonant Frequency'-
Analytical Curve 6 Its Applz.cation 110 4 I.I ZIST OF FIGURES FIGURE NO.DESCRIPTION PAGE NO 4-1 Comparison of Fourier Spectra of Pressures of Key Chug and Companion Chug Measured at Channel 28-Time Window No.2 4-2 Comparison of Fourier Spectra of Pressures of Key Chug and Companion Chug Measured at Channel 28-'ime Window No.3 112 4-3 4-4 4-7 4-8 4-9 Design Spectrum and Required Average Spectrum-Channel 28 Design Spectrum and Required Average Spectrum-Channel 26 Design Spectrum and Required Average Spectrum-Channel 24 Design Spectrum and Required Average Spectrum-Channel 20 Design Spectrum and Required Envelope Spectrum-Channel 28 Design Spectrum and Required Envelope Spectrum-Channel 26 Design Spectrum and Required Envelope Spectrum-Channel 24 113 114 115 116 117 118 119 4-10 Design Spectrum and Required Envelope 120 Spectrum-Channel 20 4-11 4-12 5-1 5-2 Source Strength Distribution-Asymmetric Zoading Case Source Strength Distribution-Nearly Symmetric Loading Case General Corss-Section of WNP-2 Reactor Building Wetwell Plan View at Elevation of Downcomer Exits 121 122 123 5-3 Finite Element Model of WNP-2 Suppression Pool with a Radial Row of Three Vents 124 I I BURNS AN D ROE t INC~PROPRIETARY 4 I I BURNS AND ROE, INC.PROPRIETARY BURNS AND ROE'NC.PROPRIETARY 3.2 3 Summary of Characteristics of the 4TCO Chugs Ke Chu s


BURNS AND ROE'NC.PROPRlETARY Nei hborin Chu s and the Ori inal 4T Chu s I
The two  loading conditions      originally  developed    for'NP-2 were  basically retained      (a  nearly symmetrical loading and an asymmetric loading) in        a manner compatible with the revised single vent design load specification.             In ordex to account for physical      realities    observed  during    steam-condensation tests    in multi-vent configuxations (JAERI, CREARE), vent-desynchronization is specified for both these loading con-ditions adopting the approach used in the Long Term Improved Generic Chugging Load        Definition developed    by  GE for  Hark II Owners Group,    in  a- manner compatible    with the   two loading con-ditions for    WNP-2.
BURNS AND ROE I INC~PROPRIETARY 3.3 Anal tical Studies and Correlation with Test Data 3 3 1 Finite Element'odel oC the 4TCO System-2 1.-
To  verify  the adequacy of chug strength averaging and of vent desynchronization,         the dynamic pressures      calculated on the wetted wetwell wall of WNP-2 were compared with wall pressures recorded during large-amplitude chugs in the 7-vent full scale tests conducted by the Japan Atomic Energy Research Institute    (JAERI)    in  a  test facility representative        of the Mark  ZZ  geometry.       The  calculated  pressures    were  found to bound the JAERI    data.
BURNS AND ROE, INC.PROPRIETARY 3.3.Z Response Sensitivity to Source Parameters
.and.Corelation with Test Data BURNS AND ROE, ZNC.PROPRlETARY Waveform Characteristics of Boundar Pressures Pressure Source<<23>>
BURNS AND ROE, INC.PROPRXETARY Acceleration/Pressure Gradient Source avocation of Acceleration Source I I BURNS AND ROE, INC.PROPRXETARY Saatial Distribution of Boundar Pressures and Correlation with Test Data BURNS AND ROE'NC.PROPRZETARY I I I I I BURNS AND ROE'NC.PROPRIETARY Conclusion 3.3.,3 Response.Sensitivity to System Parameters and Correlation with Test Data<<27 l I I BURNS AND ROE, INC.PROPRIETARY Sensitivity oC the Response Frequencies to C, C s w l I BURNS AND ROE~INC~PROPRI ETARY


BURNS AND ROE, IN'ROPRIETARY Sensitivity of the FSI Mode Frequency to C W
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BURNS AND ROE~INC~PROPRI ETARY
1.0      Introduction  and Back round The  original  chugging load def inition was developed using chugging data recorded during the        4T tests conducted by General  Electric  Company  (GE)  for the domestic Mark II utili-ties in the 4T (single vent/unit cell) test facility during late 1975 and early 1976, [1]. This load definition was based on direct application of pressure traces measured on the boun-dary of the 4T test facility to the wetted perimeter of Hark II containments, [2] . It soon became apparent that this method of application of 4T data to Mark II containments did not account for differences between the 4T test facility and the Mark    II  containments  with respect to vent length (vent acoustics),. single vent versus multi-vent suppression pool geometry and flexibility of suppression pool structural boun-daries. In order to account for these differences, it became necessary    to develop a chugging load definition at the "source", i.,e., at vent exits.
Because    of schedule    constraints,    such  an improved chugging    load  definition  was  developed,    together with the application methodology to Hark II containments, for specific application to Washington Public Power Supply System  Nuclear Project No. 2 (WNP2) during 1978/79, f 3, 4] . A single vent design load specif ication was derived to bound, statistically, the 4T test data supplied as being representative of Mark II containment conditions expected during a postulated ZOCA.


BURNS AND ROE, INC.PROPRIETARY Damping in the 4TCO System (D , D)s w<<32>>
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BURNS AND ROE g INC~PROPRIETARY
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===3.4 Conclusions===
The  single vent design load        was defined as  a pressure source at the vent        exit  and  since  its definition  was  indepen-dent of the    4T  test facility characteristics which were dif-from those of WNP-2 (vent length, suppression pool                  'erent geometry and flexibility of suppression                  pool structural boundary)    it was    assumed  to  be  directly transferable to vent exits in the      WNP-2    containment. Two  loading conditions were developed    and    considered    in the design of WNP 2: a nearly symmetrical loading and an asymmetric loading.               The applica-tion methodology for WNP-2 containment accounted for the plant specific parameters governing the response:              length of down-comer  vents, 3-D multi-vent suppression            pool geometry with    a sloped bottom, and the         flexibility of    suppression  pool struc-tural  boundary      (steel containment, the concrete pedestal          and the foundation mat).
<<3 3>>
Zn 1979-1980,      additional condensation tests were per-formed by GE for the U.S. Nark XX Owners Group in a modified configuration of the 4T test facility, known as the "4TCO" test facility (5]. The original, 4T test facility included a drywell located adjacent to the wetwell, a confi'guration which required a vent with three bends and a total length of about 90 feet. Zn the 4TCO facility, the drywell vessel was mounted
I I I l BURNS AND ROE'NC.PROPRIETARY I I I I BURNS AND ROE, ENC.PROPRlETARY 4.0 Revised Chu in Zoad Definition 4.1 introduction I~l I BURNS AND ROE, ENC.PROPRXETARY 4.2 Summary Review of the (Zm x'oved)Chu in Toad Definition Based on 4T Test Data l
BURNS AND ROE, XNC..PROPRXETARY
<<3 7>>


BURNS AND ROE, INC.PROP RIETARv I
above  the    wetwell    to  represent  'he  over/under      pressure suppression      configuration    with straight    vertical      vent, approximately    45'ong,      representative of  Mark  ZZ  plants.
BURNS AND ROE, INC.PROPRZETARY
Although the    4TCO tests were planned and performed with the objective of gathering test data to be used for confirmation of the DFFR Condensation Oscillation (C.O.) load definition, the data were recorded for the entire transient including chugging, thus providing an additional data base for chugging as well.
Selected  chugging data obtained    from regions of the 4TCO  tests during which the most severe chugging effects were recorded were made available by General Electric Company as being conservatively representative for Mark lZ plants during the chugging regime.        The 4TCO chugging data supplied, (6],
are evaluated and results and conclusions piesented in this report. The conclusions of this evaluation together with the conclusions reached following the evaluation of multi-vent test data by GE and presented in Reference 7 report (regarding the random nature of chug strength and chug initiation time from vent-to-vent during a pool chug in a multi-vent configuration) are used in this report:
(a) to examine    in light of the  4TCO  data,    the ade-quacy  of the (improved) chugging load definition developed previously, using 4T data, for applica-tion to Vii1P-2 [3g 4] I and


===4.3 Definition===
(b) to    revise,    where    necessary,    this  (improved) chugging    load  definition    and  the  application methodology    for the  Mark  II containment of WNP-2.
to Account for the New Chu in Data 4.3.1 Revision in Source Impulse Based on 4TCO Data
The 4TCO chugging      data supplied by General Electric and  the multi-vent tests      evaluated    by General    Electric are identified in Chapter    2..
The  evaluation of 4TCO chugging data including the analytical studies performed in the process of data evaluation and the characteristics of single vent 4TCO chugs derived from data evaluation/analysis are described in Chapter 3. The eva-luation shows that revision in the improved chugging load definition is necessary.
The  revised  single    vent  load  definition    and  the revised application methodology for the Mark II containment of WNP-2 based    on the conclusions reached following the eva-luation of'TCO test data (presented in Chapter 3) and on the conclusions reached from the evaluation of multi-vent: test data (presented by General Electric in Reference 7) are pre-sented in Chapter 4.
The  results of application of the revised chugging load    definition to the WNP-2 plant (i.e., reactor building/containment structure responses)            are presented in Chapter 5.


BURNS AND ROE'NC.PROPRIETARY 4.3 2 Revision in Source Strength Based on 4TCO and Nulti-vent Data I
2.0      The New Chu      in Data 2..1      The Sin  le Vent    4TCO  Test Data The 4TCO  test facility, test variables, test matrix, test instrumentation and test results are described in detail in Reference 5. The- test facility is shown in Figure 2-1.
BURNS AND ROE g XNC.PROPRIETARY
The  wetwell pressure    transducer    locations are    shown  in Figure 2 2~
The pressure      time histories      recorded    at the bottom center (channe1 28) were scanned by General Electric Company to identify significant chugs. Two hundred ninety-seven chugs were  identified  (See    Table 4-2 of Reference        7).*  Table 2-1 provides  a summary  of the    4TCO  chug data compiled from      infor-mation provided by General      Electric [8] in     November 1980.
Table  2-1    identifies    seven    regions    from six tests which recorded  the largest chugs        (based  on the bottom    center pressure  (BCP) mean square      power (msp) and peak over pressure
*information from Reference 8 is provided in Tables 2-1 and 2-2 of this report for identification of chug numbers and time window numbers used in this              report and to establish their correspondence with information subsequently published in Reference 7.
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BURNS AND ROE'NC.PROPRlETARY
(POP))  of all  4TCO  tests. General Electric Company selected 7 key chugs (one for each of the seven regions)                because the power" spectral density (PSD) envelope of these chugs closely approximated the PSD envelope of the entire sample of chugs
[7, 8]. Several chugs (called neighboring chugs) occurring before or after each of the seven key chugs together with the key  chug  define  a  region, or a time window making seven regions [8]. The region numbers and the number of chugs in each region are also identified in Table 2-1., A total of 35 chugs in seven regions or time windows were selected by General  Electric  Company    as  the chugging data base    [8]. The 4TCO  chugging data base    identification  parameters  are shown in Table 2-2.
The  4TCO  bottom center pressure      time histories    for the  thirty-five .chugs    were recorded on magnetic tapes at .4939 millisecond interval and supplied to Burns and Roe [9]. In addition, the data from all the 28 replay channels from all tests were digitized at millisecond interval and supplied on 1
magnetic tapes to the Mark        II Owners Group  [6]. The data  for the  35  chugs  of the chugging data base were obtained from these tapes for the evaluation presented in Chapter 3.
2.2        Multi-vent Test Data Multi-vent test data from          two  test  programs  (the CREARE  subscale tests and the JAERI          full  scale  tests)  have I
recently become available. General Electric Company has eva-luated these multi-vent test data for the Mark II Owners Group and has incorporated the significant findings of multi-vent effects (the random nature of chug strength and chug ini-tiation time from vent-to-vent during a pool chug in a multi-vent configuration) in the Generic Chugging Load Definition Report [7]. The results of these data evaluations and conclu-sions reached will also be adopted for the chugging load defi-nition for  WNP-2..


BURNS AND ROE~INC..PROPRIETARY 4.3..3 Revision in Application Methodology for Mark II Containments Based on Multi-vent Test Data 4.4'in le Vent Desi n Goad Specification 4.4.1 Required Average Spectrum I I I I BURNS AND ROE, ZHC.PROPRXETARY
BURNS AND ROE g. lNC ~ PROPRZETARY 3.0    4TCO Chu  in Data Evaluation    and Anal tical Studies 3.,1    Xntroduction 3.2  4TCO Chu  in Data Evaluation 3.2.1   Waveform  Characteristics of Boundary Pressures BVRNS AND ROE I INC ~ PROPRXETARY BURNS AND ROE, lHC., PROPRIETARY 3.2.2 Spatial Dist:ribuhion of Boundary Pressures
~44~


BURNS AND ROE'HC.PROPRXETARZ 4.4.Z Design Xmpulsive Sources I
BURNS AND ROEI  XNC. PROPRXETARY I
BURNS AND ROE, INC~PROPRIETARY BURNS, AND ROE g INC.PROPRXETARY' 4.3'ummary of Single Vent Design Koad Specification BURNS AND ROE g XNC.PROPRXETARY
)


===4.5 Application===
CHUGGING LOADS  REVISED DEFXNITION AND APPLICATION METHODOLOGY FOR MARK      II CONTAINMENTS (based on  4TCO  test results)
of Single Vent Zoad Specification to u x-vent i ar ontaxnments 4.5.1 Spatial Variation of Chug Strengths C Asymmetric foading Case Nearly Symmetric Zoading Case
TECHNICAL REPORT Prepared  By BURNS AND  ROE'NC.
for'pplication    to WASHINGTON PUBLIC POWER SUPPLY SYSTEM NUCLEAR PROJECT NO. 2 Prepared By:
M. M. Ettouney Senior  Civil Engineer Approved By:
B. Bedrosian          l Assistant Chief Civil Engineer F. J  Patti Chief Nuclear Engineer Submitted By:
J      Verderber ect Engineering Manager
                  !Date:


BURNS'ND ROE, INC.PROPRIETARY
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====4.5.2 Desynchronization====
BURNS AND ROE g INC .
of Chugs BURNS AND ROE~lNC.PROPRXETARY BURNS AND ROE g INC.PROPRIETARY 4.6 Summar of Com arative Review Between'WNP-2'nd Nark II Generic Chu in Eoad Definitzons 4 6.1 Computational Methodologies
DISCLAIMER OF RESPONSIBILITY Neither the Burns and Roe, Xnc. nor its affiliates or related entities nor any of the contributors to this document make any  warranty or representation (expressed or implied) with respect to the accuracy, completeness, or usefullness of'he information contained in this document, or that the use of such information may not infringe privately owned rights; nor do they assume  any reponsibility for liability or damage of any kind which may result from the use of any of the infor-mation contained in this document.,
'WNP-2'ethodolo The.computation methodology used for the source extraction from the 4TCO data and for its application to the multi-vent WNP-2 containment are similar to those used in Reference 3.Namely, a fully coupled model representing the vent steam/suppression pool water/4TCO tank structure was used for source extraction, thus resulting in an impulsive source free of the test facility characteristics.
1-
Similarly, the computational methodology
'for application of the"source"


design load to the multi-vent geometry of WNP-2 containment utilized a fully coupled model which directly accounted for.all important plant specific parameters:
BURNS AND ROE, INC .
length of downcomer vents (vent acoustics), 3-D multi-vent suppression pool geometry with a sloped bottom (pool acoustics) and the flexi-bility of the suppression pool structural boundaries.
PROPRIETARv NOTICE This document contains proprietary information of Burns and Roe, Inc. and it is not to be reproduced or furnished to third parties nor the information contained therein utilized, in whole or in part, without the prior express written per-mission of Burns and Roe, Inc.,
Generic Methodolo Subsequent to the development of the above methodo-logy[3J', General Electric Company presented an improved chugging methodology
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[18]and more recently the generic chugging load definition based on the 4TCO and multi-vent test data:[7].The methodology developed by GE[18,.7j is based on principles which are similar to those of, the WNP-2 methodo-logy., Zt recognizes the impulsive nature of chugging, acoustic nature of the steam response in the vent, acoustic nature of the water response in the pool, and it recognizes the need to address in the load definition the presence of vent response characteritics and of the fluid-structure interaction (PSZ)effects in the dynamic pressures measured in the test facility.However, the computational methodologies used for source extraction from test data and for its applica-tion to the multi-vent Mark ZZ containments are based on two assumptions
[181 (not required in the'WNP-2'omputation methodology):
(a)The vent is not acoustically coupled to the pool, and (b)The principal effect of the fluid-structure interaction (PSI)is to reduce the frequency of the tank ringout.With the above two assumptions, the hydrodynamic model of the test facility used for source definition is reduced to solving an acoustic.wave equation in a flat bottom axisymmetric rigid tank.To account.for the vent par-ticipation, vent harmonic (sine wave)response is added as a.forcing function to the impulsive pressure source., Prior to application of these sources to Hark II plants two modifications are required to account for the dif-ferences, if any, in the vent response characteristics and in the PSZ response characteristics between the test facility and the Hark II plant as described in References 7 and 18.The hydrodynamic model of the Mark II containment used in calculating the chugging boundary pressures due to a sour'ce consists of solution of'he acoustic wave equation in a rigid, flat bottom annular tank 4.6.2 WNP-2 Plant Unique Characteristics


There are two characteristics of the WNP-2 plant, which are, not in common with the other domestic Mark XX plants: containment shell structure built of stiffened steel plate, the sloped bottom pool geometry.The evaluation of the 4TCO data presented.in Chapter 3 shows that the boundary pressure traces from key chugs con-tain significant participation of the FSI response.-
GENERAL ELECTRIC COMPANY DISCLAIMER OF RESPONSIBILITY This document contains proprietary information of General Electric Company  pursuant to contracts with certain  utilities owning plants utilizing Mark ZI Containments. Except as otherwise provided in such contracts, the General Electric Company does not:
The magnitude of its participation vary from chug to chug and i;s dependent on the system conditions Since the WNP-2 contain-h ment shell structure is built of steel (as is the 4TCO tank wall)~its response to impulsive chugging sources will include significant participation of the FSX mode (as in the 4TCO tank)which may be axisymmetric as well as non-axisymmetric..
A. Make any  warranty or representation, expressed  or implied, with respect to the accuracy, completeness, or usefulness of the proprietary information con-tained in this document, or that the use of any proprietary information disclosed in this document may  not infringe privately owned rights; B. Assume any  responsibility for liability or damage which may result from the use of any proprietary information disclosed in this document; or C. Imply that  a plant designed in accordance with the proprietary information found in this document will be  licensed by the United States Nuclear- Regulatory Commission or that  it will comply with Federal, State or Local regulations.
To obtain realistic responses of the WNP-2 containment to chugging Loads, it is essential to use the methodology which directly accounts for the FSX.effects of the test facility in-the source extraction methodology (thus resulting in sources which are free of the test facility characteristics) and which directly accounts for the FSX'effects (axisymmetric as well as non-axisymmetric) in the containment response calculations.
<<54>>


As stated before<the generic methodology is appli-cable to a containment with a flat bottom pool geometry., Zts use for NNP-2 containment would require idealization of the sloped bottom floor to.a flat bottom floor.Such an idealiza-tion could be practically based on only one (the fundamental) pool acoustics mode.Since the Mark ZZ pool acoustic response to chugging loads involves participation of many=modes of vibrations of the coupled vent/pool/structure system, such an idealization would result in over-simplification of the problem., For the above reasons, the'WNP-2'evised chugging load definition is developed, implemented and presented in.this report.'4.6.3 Application Methodologies for Mark ZX Containments Elements of the two load application methodologies for Mark ZX containments are similar.Based on multi-vent test data both methodologies:
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recognize random variation of chug strength from vent-to-vent and use an averaging technique (although averaging is used in'WNP-2'efini-tion, it is shown that design sources bound all unaveraged 4TCO data at Channel 28),-55>>
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BURNS AND ROE p INC., PROPRlETARY recognize random variation of chug initiation times'rom vent-to-vent (the'NNP-2'ethodology conservatively assumes that the three vents in one radial.row are in-phase, see.Chapter 5).
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5..0 WNP-2 Reactor Buildin Resonse To Chu in Zoad 5.1 Zntroduction The application of the chugging load methodology of the previous chapters-is presented in this chapter.The theoreti-cal background of the structural analysis is presented.
The structural and suppression pool models are discussed.
The results of the analysis, and their comparison with JAERZ test results are presented..


===5.2 Theoretical===
GENERAZ EZECTRXC COMPANY PROPRIETARY NOTICE This document contains proprietary information of the General Electric Company and it is not to be reproduced or furnished to third parties nor the information contained therein uti-lized, in whole. or in part, without the prior express written permission of General Electric Company.
Back round The analytical.
methods that.were used.in the applica-tion of this, chugging, load methodology to the NNP-2 contain-ment is similar to that of Reference 3, Section 5.1.It was shown that the total hydrodynamic pressures, P2 (~)on the fluid-structure boundary can be expressed by PZ~Pj~+Ma (fU U (A3 (5.1)where 4)~Rigid wall pressures Ma (AJ~Hydrodynamic added mass matrix~Forcing frequency~~UP)~Accelerations of the fluid-structure interface


The structural equation of motion can then be expressed (5-2)where US (Q)=Structural displacements
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~Appropriate transformation matrix K~~Dynamic stiffness matrix~2 (Ms+.T Ma TT)+iQ Qs+Ks (5 3)Ms=Structural mass matrix~-Structural damping.matrix~Structural stiffness matrix For any specified case of loading, the rigid wall pressures Pi (JlJ can be obtained,.
equation 5.2 can then be solved to obtain the required'tructural displacements.
For more details, refer.to Reference 3.5.2.1 Treatment of Multiple Vents A cross sectional view of the WNP-2 reactor building is shown in Figure 5-1 and a plan view, of the wetwell at the I I I I elevation of vent exits is shown in Figure 5-2.There are 102 downcomers (18 downcomers of 28" diameter and 84 downcomers of 24"'iameter) located in thirty-four radial lines arranged in.an axisymmetric manner.A.three dimensional finite element model of the WNP-2 suppression pool that has a set of three vents in one radial row is shown in Figure 5-.3 and its structural boundary in Figure 5-4.The analysis is performed for any given chugging loading case using this model.and assuming the source loads at the three vent exits to be of a unit strength and occurring in-phase..
The structural and pool responses are evaluated then for, this set of three vents..Zet.the response measure of interest located.at angle 0 and time t from the reference radial vent row be represented by the vector X (&,t).lf the chugging load intensity at the vent exits corresponding to the ith radial row is assumed to be E i, the total building response, U (0,t), can be obtained as: U (<'t)-34 Li-X (e-ei, t y,)i=1 (5.4)where i~The angular position of the it radial row.measured from the reference row as shown in Figure 5-2.
I I BURNS AND ROBED ZiVC~PROPRIETARY Pi Random chug start time for the ith radial row, Table 5-1.The assumption that the chugs occur in-phase at the three vents in each row is more conservative than the case where all 102 vents are assumed desynchronized since the variance of the chug start times assigned to 34 radial rows is smaller than th'e variance of the chug start times assigned to 102 vents.5.3 WNP-2 Response to Chugging Loads The single vent load definition and the'assoc'iated multi-vent application.
methodology of Chapter 4 and the theoretical approaches of Section 5.2.are used to obtain the suppression pool boundary pressures and structural responses to chugging loads.The axisymmetric finite element model of the reactor building is shown in Figure 5-5.This model is a more refined version of the model used in Reference 3.It was shown that refined modeling techniques give more realistic results (Reference,11).
BURNS AND ROE'NC..PROPRIETARY


===5.3 T'ontainment===
TABLE OF CONTENTS Item                                                Paca e . No .
Wall Design Pressures and Comparison With Test Data, To obtain.the maximum poo1 boundary pressures for comparison with test data the source strengths at the WNP-2 vents were assumed equal and the sources along the 34 radial rows were assumed desynchronized with chug start times as given in Table 5-1'.The maximum rigid wa11 pressure value calculated at the containment wall at the vent exit elevation at 0'zimuth for each design source is shown in Table 5-2.I The maximum rigid wall pressure measured, at the vent exi;t elevat'ion in the 4TCO'ystem (Channel 20)during each of the seven time-windows (Table 2-2)and its average with maxi-mum pressure of the companion chug (Table 4..1)is shown in Table 5-3.
Disclaimers Proprietary Notices Table of Contents, List- of Tables                                            V111 Zist; of Figures S'ummary 1.0  Introduction    and Background 2.The New Chugging Data                                    10 2.The   Single Vent  4TCO   Test Data                10 2.2   Multi-vent Test Data                                11 3.0  4TCO  Chugging Data Evaluation and      Analytical      13 Studies
The maximum modified*pressures measured in different JAERI tests at the vent.exit elevation at the containment.
: 3. 1 Xntroduction                                        13 3.2  4TCO  Chugging Data Evaluation                    13 3.,2.1  Naveform Characteristics      of          13 Boundary Pressures 3.2.2    Spatial Distribution of Boundary          15 Pressures 3.2.3    Summary  of" Characteristics of the       19 4TCO Chugs 3.3  Analytical Studies      and Correlation with Test Data 3.3.1    Finite  Element Model  of the   4TCO    21 System 3.3.2   Response  Sensitivity to    Source      22 Parameters    and  Correlation with Test Data 3.3.3    Response  Sensitivity to   System Parameters    and  Correlation with Test Data
wall are shown in Table 5-4..Its comparison with the design wall pressures of Table 5-2 shows that the design wall pressures are higher than the JAERI results., To provide additional comparison with JAERI data, Fourier amplitude spectrum of the containment wall pressures at the vent exit elevation at 0'zimuth was obtained for each of the seven design sources The envelope of the seven spectra is shown in Figure 5-6 and compared with the envelope of Fourier amplitude (modified averaged)spectra of measured pressures in JAERI tests[7J.The envelope of design pressures completely envelopes.
the JAERZ data by a significant margin at all frequencies The above comparisons demonstrate that the chugging load definition including the averaging method and the desynchronization procedure used in the application methodo-logy for the Nark II containments is conservative.
The JAERI multi-vent test facility shown in Figure 3-1 of Reference 7 includes 7 vents in a 20'ector.The WNP-2 vent configuration shown in Figure 5-2 shows six vents in a 21.8'ector..
In order to account for this difference in the number of vents between the two systems, JAERI test results are divided by a factor of 1.17 based on a previous study[19], which compared peak boundary pressures resulting from in-phase equal strength source application to seven vents versus six vents in a 20'egment..


====5.3.2 Structural====
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Response Structural responses were calculated, using the axi-symmetric finite element model of the reactor building shown in Figure 5-5 subjected to the pool boundary pressures calcu-lated for each of the seven design sources Response spectra at several locations were calculated.
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The-envelope spectrum curves (with the peaks spread by+15%)corresponding to 0.58, 1%,.2%and.4S of the critical damping values are plotted'or selected locations (foundation mat.at primary containment vessel, RPV pedesta3.at vessel support.elevations, containment vessel at.stabilizer.truss level, containment vessel at mid-submergence depth'nd reactor building at elevation 521'in.Figures 5-7 and 5-8.f or the asymmetric and the nearly sym-metric loading cases,.respectively


===5.4 Discussion===
TABLE OF CONTENTS Item                                                Pacae  Na.
of the Ca3.culated Structural Res onse to Chu in'oads The calculated NNP-2 reactor building responses to chugging loads show a pattern similar to that of the cal'cu-l lated responses to SRV 3.oads, Reference 11..The reactor building can be'ivided again into three zones: The wetwell zone, including the containment struc-'ure boundary, where the hydrodynamic pressures are app3.ied, and where the structural responses are the largest.
: 3. 4    Conclusions                                          33 4.0  Revised Chugging Load        Definition                      35 4.1    Introduction                                        35 4.2    Summary Review    of the (Improved)  Chugging      36 Load    Definition Based on 4T Test  Data 4.3    Revisions Reauired in the (Improved)                39 Chugging Load Definition to Account for the New Chugging Data 4.3.1    Revision  Zn Source Impulse Based on      39 4TCO  Data 4.3.2    Revision  Zn Source Strength Based on      40 4TCO and  Multi-vent Data 4.3.3 Revision Zn Application Methodology            43 For Mark ZI Containments Based on Multi-vent Test Data 4.4    Single Vent. Design Zoad Specification              43 4.,4 ..1  Required Average Spectrum                  43 4.,4.2    Design Impulsive Sources 4.4.3    Summary of Single Vent Design Load        47 Specification 4.5    Application of Single Vent Load Specification 48 to Multi-vent Mark IZ Containments 4.5.1 Spatial Variation of Chug Strengths            48 4.5.2 Desynchronization of Chugs
ii., The drywell.zone, including the, containment struc-ture boundary, where the high responses of zone (i)have been attenuated through the RPV pedestal and the containment shell..Although smaller, they're still of a finite magnitude for the low damped steel containment structure..
    '4 ~  6  Summary of Comperative Review Between 'NNP-2'1 and Mark ZI Generic Chugging Load Definitions 4.6.1    Computational Methodologies                51
iii.The third zone consists of the biological shield and the reactor building walls and floors outside pri-mary containment The structural response accelera-tions calculated for WNP-2 are negligibly small Et is noted.here.that negligibly small responses were also calculated for NNP-2.when sub j ected to SRV loads[11I'nd this.low level of predicted response was verified by'easurements taken during Caorso and Tokai-?.SRV tests.This is due to the fact that the Load path from zone (i)where the hydrodynamic pressures are applied, to this zone is through the mat and the soil and as shown in References 12 and 13 the soil compliances reduce rapidly as the fre<<fluency of excitation increases; this explains the above mentioned large reductions in the structural responses in this zone.Table 5>>5 shows the maximum computed structural re-sponse accelerations in the three zones of the NNP-2 reactor


building.Figure 5-9 shows the vibration tolerance obser-vations as documented in References 14, 15, and 16.Examina-tion of the maximum computed structural response accelerations at locations outside the containment structure of HNP-2 reac-tor building (zone iii)indicates that they fall.consistently near the curve of Figure.5-9 labeled BEGIN TO PERCEIVE".
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These findings lead to the conclusion that evaluation of safety related piping and~equipment for chugging responses need only be carried out in zones (i)and (ii).It is noted that this conclusion is consistent with the results of WNP-2 reactor building analysis for SRV loads (Reference 11)..
6 0 LIST OF REFERENCES"Mark XX-Pressure Suppression Test Program Phase XI and XXI Tests," NEDO-13468,/NEDE-13468-P, including-Errata (1).2"Mark IX Containment Dynamic Forcing Function Information Report (DFFR),"'EDO-21061/
NEDE-21061-P, Rev.3,, June 1978, General Electric Company.3.-Chugging Loads-Improved Def inition and Application.
Methodology to Hark XI Containments,"'echnical Report (Proprietary), Prepared by Burns and Roe, Xnc , for Application to Washington Public Power Supply System, Nuclear-Pr'oject No.2, June 1'5g 1979.4.Non-proprietary Version of 3..4T Condensation Oscillation Test Program Final Test Report," NEDE-24811-P (Proprietary), Hay 1980, General Electric Company.6."Transmittal of Computer Tapes Containing 4T C.O.Test Data,"'eneral Electric Company Letter HKXX 1814-E, dated July 15, 1980 (Including the Two


Ref erenced Letters dated 1/2/80, 4/29/80)to Hark XX Consultants.
TABLE OP CONTENTS Item                                              ~pa e No.
7."Generic Chugging Load Definition Report," General Electric.Document NEDE-24302 (Proprietary), April 1981 8."4T C.O.Chugging Data Base Information," General Electric Company Letter MKXI-1970-E (including seven Attachment), dated November 18, 1980 to Burns and Roe, Inc.L'etter dated July 24, 1980 from Creare Xnc.to Burns and Roe, Inc 10."Random Data: Analysis and Measurement Procedures,.
4.6.2    WNP-2  Plant Unique Characteristics    53 4.6..Application Methodologies for           55 Mark  II Containments 5.0 WNP-2   Reactor Building Response    to Chugging Loads 5.1   Introduction                                    57 5.2   Theoretical Background                          57 5.2.1 Treatment of Multiple Vents 5 ..3  WNP-2 Response   to Chugg ing Loads             60 5.3.1   Containment Wall Design Pressures and Comparison with Test Data 5.3.2   Structural Response                    63 5.4    Discussion of Calculated Structural              63 Response  to Chugging Loads 6.0 List of    References                                  66 Tables Figures Appendix    A  Analogy  Between Acoustic and      Al-A6 Structural  Boundary Conditions
J..S Bendat.,-A..G., Piersol, Wiley-Interscience, 1971"SRV Loads-Improved Definition and Application Methodology for Hark II Cont:ainments," Technical Report (Proprietary)
Prepared by Burns and Roe, Inc.for Application to HPPSS WNP-2, July 29, 1980.1'2."Dynamic Response of Structures in Layered Soils,"'..
Chang-Liang, Department of Civil Engineering Report Number R74-10, Massachusetts, 1974.13"Dynamic Stiffness Functions of Strip and Rectangular Footings on Layered Media," G.Gazetas, Massachusetts Institute of Technology, Dept.of Civil Engineering, M.S.Thesis, 1975.
14."Data Averaged From 7 Sources," Report 1, D.E.Goldman, Naval Medical Research Znstitute, March 1948.15."Foundation Vibrations," R.E.Richart, Journal of ASCE, Vol.86, No SM-4, August 1960.16."Vibration of Zsolated Foundations for Boiler Feedpumps," H., A..Franklin, Presented at the 1979 Annual Convention, American Concrete Znstitute, Milwaukee, Wisconsin, March 1979.17."Xmproved Structural Analysis Methods For Prediction of, Containment
-Response to Suppression Poo1 Hydrodynamic Roads", Technical Report, Revis ion 2, Prepared.by Burns and Roe, Znc.for General-Electric Company, January 1981'I 8"Mark ZZ Zmproved Chugging Methodology", General Electric Document NEDE'4822 (Proprietary), May 1980'l9."Fukushima Dai-Ni: Unit 3, Containment Response to the LOCA Steam Condensation Loads" Technical Report (Proprietary), prepared by Burns and Roe, Xnc., for Toshiba Corporation April 1981..
f GENEBAG ELZCTRlC.COMPANY PBOPBZZTABZ TABZZ 2 SUMMA'P 4TCO CHUG CATA l l 1 I I I QEHEKLL, ELECTRIC COMPANY PROPRIETARY Table 2-2 4TCO CHUGGING DATA BASE IDENTIPICATION PAEQMETERS
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I BURNS AND ROE, INC.PROPRIETARY TABLE 4-1 IDENTIFICATION OF THE COMPANION CHUG USED FOR AVERAGING WITH KEY CHUG I I BURNS AND ROE~ZHC~PROP RZETARY TABLE 4-2 SXNGLE VENT DESZGN SOURCE DEFXNXTZON
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~I I I TABLE 5-3.CHUG START TINES PQR RANDOM PHASING Radial Row 2, 6 10 12 13 15 16.17 Chug Start Time (Sec)0 022826 0.021631 0.014281 0.037928 0.026944 0.025257 0.0092329 0.,035325 0.036614 0.,017459 0 030120 0.018409 0.034114 ,0.041211 0'34711 0.024805 0.031562 Radial Row 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 Chug Start Time (Sec)0.012603 0.035364 0.026404 0.039039 0.021682 0 024879 0.044889 0.024589 0.0057321 0.023880 0.033905 0.015641 0.013154 0.022173 0.026808 0.046634 0.027705 Vari.ance~0.881708 x 10 (sec.)-4 2 Note: The three vents in each radial row are assumed to chug in-phase.<<74


BURNS AND ROE, INC.PROP RIETARY TABLE 5-2 i~EMUi4 RIGID WALL PRESSURES ON WNP-2 CONTAINMENT AT VENT EXIT ELEVATION (NODE 15)
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jIST  OF TABLES TABIE NO.            DESCRIPTION            PAGE NO.
2-1    Summary  of. 4TCO Chug  Data        70 2-2    4TCO  Chugging Data Base Identif ication  Parameters          71'-1 Identification of the Companion      72 Chug Used    for Averaging with Key Chug 4-2    Single Vent Design Source            73 Definition 5-1    Chug  Start  Times  for Random      7'4 Phasing 5-2    Maximum Rigid Hall Pressures on      75 WNP-2 Containment at Vent Exit Elevation    (Node 15) 5-3    4TCO  Pressure  Maximums and        76 Average  at  Channel 20 5-4    JAERI Peak    Positive Chugging      77 Pressure Amplitudes 5-5    Maximum Computed    Accelerations    78 for NNP-2 Reactor    Building
 
I LIST OF FIGURES FIGURE NO.              DESCRIPTION                PAGE NO.
2-1      Test Configuration for Nark El          79 Condensation Oscillation (4TCO)
Tests 2-2      4TCO  Tests - Wetwell Pressure          80 Transducer Locations 3-1      Comparison  of Pressures and            81
          ~
Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No. 1 3-2      Comparison  of Pressures  and          82 Fourier Amplitude Spectra of  Key Chug and A  Neighboring Chug Time Window No. 2 3-3      Comparison  of Pressures and            83 Fourier Amplitude Spectra of  Key Chug and A  Neighboring Chug Time. Window No. 3 3-4      Comparison  of Pressures  and          84 Fourier Amplitude Spectra of  Key Chug and A Neighboring  Chug-Time Window No., 4 3-5      Comparison  of Pressures  and          85 Fourier Amplitude Spectra of 'Key Chug and A  Neighboring Chug Time Window No. 5 3-6      Comparison  of Pressures  and          86 Fourier Amplitude Spectra of  Key Chug and A Neighboring Chug Time Window No.. 6 3-7      Comparison  of Pressures  and          87 Fourier Amplitude Spectra of  Key Chug and  A  Neighboring Chug Time Window No. 7 3-8      Comparison of Pressures Measured        88 at Channel 28 and Channel 26 During Time Window No. 6, Chug 52
 
I LIST OF FIGURES FIGURE NO.              DESCRIPTION              PAGE NO-3-9      Comparison of Pressures Measured at    89 Channel 24 and Channel 20 During Time Window No. 6, Chug 52 3-10      Phase Relationship Between Pressures    90 Measured at Channel 20 and Channel 28 Versus Frequency Time Window No. 1 3-11      Phase Relationship Between Pressures    91 Measured at Channel 20 and Channel 28 Versus Frequency Time Window No., 'l 3-12      Ratios of Fourier Amplitudes of        92 Pressures Measured at Channel 28/Channel 20 3-13 Vertical Distribution of    Peak      93 Pressures    Six Chugs, Time Window No. 1 3-14      Vertical Distribution of Peak          94 Fourier Amplitudes of Pressures-Two Chugs  Time Window No.      1 3-15      Ratio of Fourier Amplitudes of          95 Pressures  Measured at Channel 20 and Channel    21 3-16      Comparison  of 4TCO and  4T  Data    96 Pressures Measured at Bottom Center 3-17a    Vent  Pool Model (Fluid Elements)      97 3-17b    Structural Finite    Element Model      98 of 4TCO Tank 3-18      Schematic Presentation of              99 Pressure Source at Vent Exit in 4TCO  System 3-19      Fourier Amplitude Spectrum of          100 Pressure  Calculated at Channel 28 with Pressure Source at Vent Exit
 
LIST    OF FIGURES FIGURE NO.            DESCRIPTION                PAGE NO.
3-20    Schematic Presentation of              101 Acceleration Source at Three Locations in 4TCO System 3-21    Fourier Amplitude Spectrum of          102 Pressure Calculated at 3-22    Fourier Amplitude Spectrum of          103 Pressure Calculated at Channel 28 with Acceleration Source Located      6'bove    Bottom 3-23    Fo uri er Amp 1 i tude  Spectrum o f    104 Pressure  Calculated at Channel 28 with Acceleration Souxce Located      3'bove    Bottom 3-24    Comparison of Vertical                  105 Distxibution of Normalized Maximum Pxessure Calculated with Pressure and Acceleration Sources 3-25    Vertical Distribution of Fourier        106 Amplitudes of Pressures Calculated with Acceleration Sour'ce at Vent Exit 3-26    Fourier Amplitude Spectrum of          107 Px'essure at Channel 28 with 1418 fps, Decreased from 1600  fps, Figure    3-21 3-27    Fourier Amplitude Spectrum of          108 Pressure at Channel 28 with 2400 fps, Decreased from 4800 fps, Figure 3-21 3-28    Phase Relationship Between Pxessures    109 Calculated at Channel 20 and Channel 28 Versus Frequency 3-29    Cw  Versus Resonant Frequency'-        110 Analytical  Curve 6 Its Applz.cation
 
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ZIST  OF FIGURES FIGURE NO.          DESCRIPTION                    PAGE NO 4-1    Comparison  of Fourier Spectra of Pressures  of Key Chug and Companion Chug  Measured at Channel 28 Time Window No. 2 4-2    Comparison  of Fourier Spectra of        112 Pressures  of Key Chug and Companion Chug  Measured at Channel 28 Window No. 3            'ime 4-3    Design Spectrum and Required Average      113 Spectrum  Channel 28 4-4    Design Spectrum and Required Average      114 Spectrum  Channel 26 Design Spectrum and Required Average      115 Spectrum  Channel 24 Design Spectrum and Required Average      116 Spectrum  Channel 20 4-7    Design Spectrum and Required Envelope      117 Spectrum  Channel 28 4-8    Design Spectrum and Required Envelope      118 Spectrum  Channel 26 4-9    Design Spectrum and Required Envelope      119 Spectrum  Channel 24 4-10    Design Spectrum and Required Envelope      120 Spectrum  Channel 20 4-11    Source Strength  Distribution-            121 Asymmetric Zoading Case 4-12    Source Strength Distribution              122 Nearly Symmetric Loading Case 5-1    General Corss-Section of WNP-2 Reactor Building 5-2    Wetwell Plan View at Elevation of          123 Downcomer  Exits 5-3    Finite Element Model of WNP-2              124 Suppression Pool with a Radial      Row of Three Vents
 
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BURNS AN D ROE t INC ~ PROPRIETARY 4
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BURNS AND ROE, INC. PROPRIETARY BURNS AND ROE'NC. PROPRIETARY 3.2 3    Summary  of Characteristics of the  4TCO Chugs Ke  Chu s
 
BURNS AND  ROE'NC. PROPRlETARY Nei hborin Chu s and  the Ori  inal 4T Chu s I
BURNS AND ROE I INC ~ PROPRIETARY 3.3  Anal tical Studies and Correlation with Test Data 3 3 1  Finite Element'odel  oC    the 4TCO System
                            -2 1.-
 
BURNS AND ROE,  INC. PROPRIETARY 3.3.Z  Response    Sensitivity to    Source  Parameters . and
      .Corelation with Test Data
 
BURNS AND ROE, ZNC. PROPRlETARY Waveform Characteristics of Boundar    Pressures Pressure  Source
                              <<23>>
 
BURNS AND ROE,  INC. PROPRXETARY Acceleration/Pressure    Gradient Source avocation of Acceleration    Source I
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BURNS AND ROE,  INC. PROPRXETARY Saatial Distribution of Boundar    Pressures  and Correlation with Test Data BURNS AND ROE'NC. PROPRZETARY I
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BURNS AND ROE'NC. PROPRIETARY Conclusion 3.3.,3  Response. Sensitivity  to  System  Parameters and Correlation with Test Data
                              <<27
 
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BURNS AND ROE,  INC. PROPRIETARY Sensitivity oC the Response Frequencies  to  C, s C w
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BURNS AND ROE ~ INC ~ PROPRI ETARY
 
BURNS AND ROE,  IN'ROPRIETARY Sensitivity of the  FSI Mode Frequency to C W
 
BURNS AND ROE ~ INC ~ PROPRI ETARY
 
BURNS AND ROE,  INC. PROPRIETARY Damping in the 4TCO System (D ,  D )
s    w
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BURNS AND ROE g  INC ~ PROPRIETARY 3.4 Conclusions
                          <<3 3>>
 
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BURNS AND ROE'NC. PROPRIETARY I
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BURNS AND ROE, ENC. PROPRlETARY 4.0 Revised Chu  in  Zoad Definition 4.1 introduction I
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BURNS AND ROE,  ENC. PROPRXETARY 4.2 Summary Review  of the (Zm x'oved) Chu in Toad Definition Based on 4T Test Data l
BURNS AND ROE,  XNC.. PROPRXETARY
              <<3 7>>
 
BURNS AND ROE, INC . PROP RIETARv I
BURNS AND ROE,  INC. PROPRZETARY 4.3 Definition to Account for the New Chu in Data 4.3.1 Revision in Source Impulse Based on 4TCO Data
 
BURNS AND ROE'NC. PROPRIETARY 4.3 2 Revision in Source Strength Based on  4TCO and Nulti-vent Data I
BURNS AND ROE g XNC. PROPRIETARY
 
BURNS AND ROE'NC. PROPRlETARY
 
BURNS AND ROE~  INC.. PROPRIETARY 4.3..3 Revision in Application Methodology for Mark Containments Based on Multi-vent Test Data II
: 4. 4'in    le Vent Desi  n Goad  Specification 4.4.1  Required Average Spectrum I
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BURNS AND ROE,  ZHC. PROPRXETARY
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BURNS AND ROE'HC. PROPRXETARZ 4.4.Z Design Xmpulsive Sources I
BURNS AND ROE,  INC ~ PROPRIETARY BURNS, AND ROE g INC. PROPRXETARY' 4.3'ummary of  Single Vent Design  Koad Specification
 
BURNS AND ROE g  XNC. PROPRXETARY 4.5  Application of Single Vent        Zoad Specification to u  x-vent i ar      ontaxnments 4.5.1 Spatial Variation of  Chug StrengthsC Asymmetric foading Case Nearly Symmetric Zoading Case
 
BURNS'ND ROE, INC. PROPRIETARY 4.5.2 Desynchronization of Chugs BURNS AND ROE ~  lNC. PROPRXETARY BURNS AND ROE  g INC. PROPRIETARY 4.6        Summar    of Com arative    Review  Between  'WNP-2'nd Nark  II Generic  Chu in      Eoad Definitzons 4  6.1    Computational Methodologies
'WNP-2'ethodolo The  .computation  methodology    used  for the  source extraction from the 4TCO data and for its application to the multi-vent WNP-2 containment are similar to those used in Reference  3. Namely, a  fully  coupled model representing  the vent steam/suppression    pool water/4TCO tank structure was used for  source extraction, thus resulting in an impulsive source free of the test      facility characteristics.        Similarly, the computational    methodology  'for application of      the  "source"
 
design  load to the multi-vent geometry of          WNP-2  containment utilized    a  fully  coupled model which    directly  accounted  for.
all  important plant specific parameters:          length of downcomer vents (vent acoustics),            3-D multi-vent suppression        pool geometry with      a sloped bottom (pool acoustics)      and the  flexi-bility of    the suppression    pool structural boundaries.
Generic Methodolo Subsequent    to the development of the above methodo-logy  [3J',    General  Electric    Company presented    an  improved chugging      methodology    [18]  and  more  recently the generic chugging load definition based on the 4TCO and multi-vent test data: [7] . The methodology developed by GE [18,.7j is based on principles which are similar to those of, the WNP-2 methodo-logy.,    Zt recognizes the impulsive nature of chugging, acoustic nature of the steam response in the vent, acoustic nature of the water response in the pool, and it recognizes the need to address in the load definition the presence of vent response        characteritics and of the fluid-structure interaction (PSZ) effects in the dynamic pressures measured in the test facility. However, the computational methodologies used for source extraction from test data and for its applica-tion to the multi-vent Mark ZZ containments are based on two assumptions      [181 (not required in the 'WNP-2'omputation methodology):
(a) The vent  is not acoustically coupled to the pool, and (b) The    principal effect of the fluid-structure interaction (PSI) is to reduce the frequency of the tank ringout.
With the above two assumptions, the hydrodynamic model of the test facility used for source definition is reduced    to solving an acoustic. wave equation in a flat bottom axisymmetric rigid tank.            To account. for the vent par-ticipation, vent harmonic (sine wave) response is added as a.
forcing function to the impulsive pressure source.,
Prior to application of these sources        to Hark  II plants two modifications are required to account for the dif-ferences,    if  any, in the vent response characteristics and in the  PSZ  response  characteristics    between the test facility and the Hark    II plant  as  described in References  7 and 18.
The hydrodynamic    model  of the  Mark  II containment used    in calculating the chugging boundary pressures due to        a sour'ce consists of solution of'he acoustic wave equation in          a rigid, flat    bottom annular tank 4.6.2        WNP-2  Plant Unique Characteristics
 
There  are  two characteristics of the WNP-2 plant, which are,    not in common with the other domestic Mark XX plants:
containment  shell structure built of stiffened steel plate, the sloped bottom pool geometry.
The  evaluation of the  4TCO  data presented .in Chapter 3  shows  that the boundary pressure    traces from key chugs con-tain significant participation of the FSI response.-            The magnitude of its participation vary from chug to chug and i;s dependent on the system conditions        Since the WNP-2 contain-h ment shell structure is built of steel (as is the 4TCO tank wall) ~ its response to impulsive chugging sources will include significant participation of the FSX mode (as in the 4TCO tank) which may be axisymmetric as well as non-axisymmetric..
To obtain realistic responses        of the WNP-2 containment to chugging Loads, it is essential to use the methodology which directly accounts for the FSX. effects of the test facility in-the source extraction methodology (thus resulting in sources which are free of the test facility characteristics) and which directly accounts for the FSX'effects (axisymmetric as well as non-axisymmetric) in the containment response calculations.
                                <<54>>
 
As  stated before< the generic methodology is appli-cable to  a containment with      a  flat  bottom pool geometry.,    Zts use  for NNP-2 containment        would require    idealization of the sloped bottom    floor to. a flat    bottom floor. Such an idealiza-tion could  be    practically based    on  only one (the fundamental) pool acoustics mode.        Since the Mark ZZ pool acoustic response to chugging      loads  involves participation of many =modes of vibrations of the coupled vent/pool/structure system, such an idealization would result in over-simplification of the problem.,
For the above reasons,          the 'WNP-2'evised        chugging load    definition is      developed,    implemented    and  presented    in.
this report.
'4.6.3    Application Methodologies for          Mark  ZX Containments Elements    of the    two load    application methodologies for  Mark ZX  containments are      similar.
Based on    multi-vent test data both methodologies:
recognize random variation of chug strength from vent-to-vent      and    use  an  averaging    technique (although averaging        is used in 'WNP-2'efini-tion,  it  is  shown  that design sources bound all unaveraged    4TCO  data at Channel 28),
                                    -55>>
 
BURNS AND ROE  p  INC., PROPRlETARY recognize  random    variation of chug initiation times'rom vent-to-vent ( the 'NNP-2'ethodology conservatively assumes that the three vents in one radial. row are in-phase,    see. Chapter 5) .
5..0    WNP-2 Reactor Buildin Resonse To  Chu    in  Zoad 5.1        Zntroduction The  application of the chugging load methodology of the previous chapters- is presented in this chapter. The theoreti-cal background of the structural analysis is presented.            The structural and suppression pool models are discussed.              The results of the analysis, and their comparison with JAERZ test results are presented..
5.2      Theoretical  Back round The  analytical. methods that. were used. in the applica-tion of this, chugging, load methodology to the NNP-2 contain-ment is similar to that of Reference 3, Section 5.1.            It was shown that the total hydrodynamic pressures,          P2 (~) on the fluid-structure    boundary can be expressed  by PZ    ~    Pj ~    + Ma (fU U (A3                      (5.1) where
: 4)  ~ Rigid wall pressures Ma (AJ    ~ Hydrodynamic added mass  matrix
              ~ Forcing frequency
    ~ ~
UP    )
              ~ Accelerations of the fluid-structure interface
 
The  structural equation of motion      can then be expressed (5-2) where US  (Q) =  Structural displacements
              ~  Appropriate transformation matrix K  ~    ~ Dynamic  stiffness matrix
                  ~2  (Ms  +. T Ma TT) +  iQ  Qs + Ks    (5 3)
Ms      =  Structural  mass  matrix
              ~- Structural  damping. matrix
              ~  Structural stiffness matrix For any specified      case    of loading,  the  rigid wall pressures    Pi (JlJ can be obtained,. equation 5.2 can then be solved to obtain the required'tructural displacements.              For more details, refer. to Reference 3.
5.2.1      Treatment of Multiple Vents A  cross sectional view of the      WNP-2 reactor building is  shown  in Figure 5-1    and a plan view,  of the wetwell at the I
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elevation of vent exits is          shown    in Figure 5-2. There are 102 downcomers    (18 downcomers    of    28" diameter and 84 downcomers      of 24"'iameter) located in thirty-four radial lines arranged in.
an  axisymmetric manner.
A. three dimensional        finite  element model of the    WNP-2 suppression    pool that has        a  set of three vents in one radial row  is  shown    in Figure    5-. 3  and  its structural    boundary    in Figure 5-4.      The  analysis is performed for any given chugging loading case using this model. and assuming the source loads at the three vent exits to be of a unit strength and occurring in-phase..      The  structural and pool responses are evaluated then for, this set of three vents.. Zet. the response measure of interest located. at angle 0 and time t from the reference radial vent row be represented by the vector X (&,t) . lf the chugging load intensity at the vent exits corresponding to the ith radial row is assumed to be E i, the total building response,    U  (0,t),  can be obtained as:
U  (<'t) -  34  Li        - X  (e-ei, t y,)            (5.4) i=1 where i~  The    angular      position of the      it    radial  row.
measured    from the        reference  row  as  shown  in Figure 5-2.
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BURNS AND    ROBED  ZiVC ~  PROPRIETARY Pi    Random  chug    start    time for the    ith radial  row, Table 5-1.
The assumption      that the chugs occur in-phase at the three vents in each      row is more conservative than the case where  all  102  vents    are    assumed      desynchronized  since  the variance of the chug start times assigned to 34 radial rows is smaller than th'e variance of the chug start times assigned to 102  vents.
5.3    WNP-2 Response    to Chugging Loads The single vent load definition and the 'assoc'iated multi-vent application. methodology of Chapter 4 and the theoretical approaches of Section 5.2. are used to obtain the suppression pool boundary pressures and structural responses to chugging loads. The axisymmetric finite element model of the reactor building is shown in Figure 5-5. This model is a more refined version of the model used in Reference 3. It was shown that refined modeling techniques give more realistic results (Reference,11).
 
BURNS AND    ROE'NC.. PROPRIETARY 5.3  T  'ontainment Wall      Design Pressures    and Comparison With Test Data, To  obtain. the    maximum  poo1  boundary    pressures  for comparison with      test data    the source strengths    at the  WNP-2 vents were assumed      equal and the sources    along the 34    radial rows were    assumed    desynchronized    with  chug  start    times  as given in Table 5-1'.        The maximum    rigid  wa11 pressure    value calculated at the containment wall at the vent exit elevation at 0'zimuth for each design source is shown in Table 5-2.
I The maximum    rigid wall  pressure measured, at the vent exi;t elevat'ion in the 4TCO'ystem (Channel 20) during each of the seven time-windows (Table 2-2) and its average with maxi-mum  pressure    of the    companion  chug  (Table 4..1)  is  shown  in Table 5-3.
 
The maximum    modified* pressures measured in different JAERI tests at the vent. exit elevation at the containment. wall are shown in Table 5-4.. Its comparison with the design wall pressures of Table 5-2 shows that the design wall pressures are higher than the JAERI results.,
To  provide additional      comparison  with JAERI data, Fourier amplitude spectrum of the containment wall pressures at the vent exit elevation at 0'zimuth was obtained for each of the    seven    design  sources      The  envelope  of the    seven spectra is shown in Figure 5-6 and compared with the envelope of Fourier amplitude (modified averaged) spectra of measured pressures      in JAERI tests [7J .          The envelope      of design pressures completely envelopes. the JAERZ data by a significant margin at all frequencies The above    comparisons  demonstrate    that the chugging load    definition including the            averaging    method  and    the desynchronization      procedure  used  in the application methodo-logy    for    the    Nark  II    containments    is conservative.
The  JAERI    multi-vent test facility shown in Figure 3-1 of    Reference    7 includes 7 vents in a 20'ector.              The WNP-2 vent configuration shown in Figure 5-2 shows six vents in a 21.8'ector..            In order to account for this difference in the number of vents between the two systems, JAERI test results are divided by a factor of 1.17 based on a previous study [19], which compared peak boundary pressures resulting from in-phase equal strength source application to seven vents versus six vents in a                  20'egment..
 
5.3.2    Structural    Response Structural responses      were calculated, using the    axi-symmetric    finite  element model    of the reactor building    shown in Figure 5-5 subjected to the pool boundary pressures calcu-lated for each of the seven design sources            Response spectra at several locations were calculated.          The- envelope spectrum curves (with the peaks spread by +15%) corresponding to 0.58, 1%,. 2% and. 4S of the critical damping values are plotted'or selected locations (foundation mat. at primary containment vessel, RPV pedesta3. at vessel support. elevations, containment vessel at. stabilizer .truss level, containment vessel at mid-submergence depth'nd reactor building at elevation 521 '              in.
Figures 5-7 and 5-8. for the asymmetric and the nearly sym-metric loading cases,. respectively 5.4    Discussion of the Ca3.culated Structural      Res onse  to Chu    in 'oads The    calculated    NNP-2  reactor  building responses to chugging loads show a pattern similar to that of the cal'cu-l lated responses to SRV 3.oads, Reference 11 ..            The reactor building can be'ivided again into three zones:
The  wetwell zone,    including the containment struc-boundary, where the hydrodynamic pressures        are
                                                                          'ure app3.ied,  and where  the  structural responses  are the largest.
 
ii., The  drywell. zone,    including the, containment struc-ture boundary, where the high responses of zone (i) have been      attenuated through the RPV pedestal and the containment shell.. Although smaller, they're still  of a finite magnitude for the low damped steel containment structure..
iii. The    third  zone  consists of the biological shield and the reactor building walls and floors outside pri-mary containment        The structural response accelera-tions calculated for WNP-2 are negligibly small Et is noted. here. that negligibly small responses were also calculated for NNP-2. when sub j ected to SRV loads [11I'nd this. low level of predicted response was verified by'easurements taken during Caorso and Tokai-?. SRV tests. This is due to the fact that the Load    path    from zone    (i)  where  the  hydrodynamic pressures    are applied,  to this zone is through the mat and the      soil  and as shown  in References 12 and 13 the soil compliances reduce rapidly as the fre<<
fluency of excitation increases; this explains the above mentioned large reductions in the structural responses in this zone.
Table    5>>5  shows    the maximum computed    structural re-sponse  accelerations      in the three  zones of the  NNP-2  reactor
 
building. Figure 5-9 shows  the vibration tolerance obser-vations  as documented in References 14, 15, and 16. Examina-tion of the maximum computed structural response accelerations at locations outside the containment structure of HNP-2 reac-tor building (zone iii) indicates that they fall. consistently near the curve of Figure. 5-9 labeled      BEGIN TO PERCEIVE".
These findings lead to the conclusion that evaluation of safety related piping and equipment for chugging responses
                            ~
need only be carried out in zones (i) and (ii) . It is noted that this conclusion is consistent with the results of WNP-2 reactor building analysis for SRV loads (Reference 11)..
6 0 LIST OF REFERENCES "Mark  XX  -  Pressure  Suppression    Test Program Phase  XI and XXI Tests," NEDO-13468,/NEDE-13468-P, including -Errata (1) .
2    "Mark    IX    Containment    Dynamic    Forcing                        Function Information Report (DFFR),"'EDO-21061/
NEDE-21061-P,    Rev. 3,, June    1978,  General                      Electric Company.
3.-    Chugging    Loads        Improved    Def inition                        and Application. Methodology to Hark XI Containments,"'echnical Report  (Proprietary), Prepared by Burns and Roe, Xnc ,    for Application to Washington Public Power  Supply System,    Nuclear- Pr'oject No. 2, June 1'5g 1979.
: 4. Non-proprietary Version of      3..
4T  Condensation    Oscillation Test Program Final Test Report," NEDE-24811-P (Proprietary), Hay 1980, General Electric Company.
: 6.    "Transmittal of Computer        Tapes  Containing                      4T C.O.
Test  Data,"'eneral Electric          Company                        Letter HKXX 1814-E,    dated  July  15,  1980  (Including the                        Two
 
Ref erenced  Letters dated 1/2/80, 4/29/80            )  to Hark XX  Consultants.
: 7.  "Generic Chugging Load Definition Report," General Electric. Document    NEDE-24302      (Proprietary), April 1981 8  . "4T C.O. Chugging Data Base          Information," General Electric    Company    Letter      MKXI-1970-E        (  including seven Attachment), dated November 18, 1980 to Burns and Roe,  Inc.
L'etter dated July 24,          1980  from Creare          Xnc. to Burns and Roe, Inc
: 10.  "Random      Data:          Analysis      and      Measurement Procedures,.      J.. S      Bendat.,-    A.. G.,    Piersol, Wiley-Interscience,      1971 "SRV Loads      Improved      Definition      and  Application Methodology    for  Hark  II  Cont:ainments,"        Technical Report    (Proprietary) Prepared by Burns and                          Roe, Inc. for Application to HPPSS WNP-2, July 29,                          1980.
1'2. "Dynamic Response      of Structures in Layered            Soils,"'..
Chang-Liang,    Department of Civil Engineering Report Number R74-10, Massachusetts,            1974.
13  "Dynamic      Stiffness      Functions      of      Strip              and Rectangular Footings on Layered Media," G. Gazetas, Massachusetts      Institute of Technology, Dept. of Civil Engineering, M.S. Thesis, 1975.
: 14.  "Data Averaged    From    7  Sources,"    Report  1,  D. E.
Goldman,  Naval Medical Research          Znstitute,    March 1948.
: 15.  "Foundation Vibrations," R. E. Richart, Journal of ASCE,  Vol. 86,  No  SM-4, August 1960.
: 16. "Vibration of      Zsolated      Foundations    for Boiler Feedpumps,"  H., A.. Franklin, Presented        at the  1979 Annual    Convention,    American      Concrete    Znstitute, Milwaukee, Wisconsin, March 1979.
: 17.  "Xmproved      Structural        Analysis      Methods    For Prediction of, Containment        Response    to Suppression Poo1    Hydrodynamic      Roads",      Technical      Report, Revis ion 2, Prepared.      by Burns and      Roe,  Znc. for General-  Electric  Company, January      1981
'I 8 "Mark  ZZ  Zmproved    Chugging    Methodology", General Electric  Document    NEDE'4822 (Proprietary), May 1980
'l9. "Fukushima Dai-Ni:      Unit 3, Containment Response to the  LOCA Steam  Condensation Loads" Technical Report (Proprietary), prepared        by Burns and Roe, Xnc.,      for Toshiba Corporation    April    1981..
f GENEBAG ELZCTRlC. COMPANY PBOPBZZTABZ TABZZ 2 SUMMA'P    4TCO CHUG CATA l
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QEHEKLL, ELECTRIC COMPANY PROPRIETARY Table 2-2 4TCO CHUGGING DATA BASE IDENTIPICATION PAEQMETERS
                  -73.-
 
I BURNS AND ROE, INC. PROPRIETARY TABLE 4-1 IDENTIFICATION OF THE COMPANION CHUG USED FOR AVERAGING WITH KEY CHUG
 
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BURNS AND ROE ~  ZHC ~ PROP RZETARY TABLE  4-2 SXNGLE VENT DESZGN SOURCE DEFXNXTZON
                <<73>>
 
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TABLE 5-3.
CHUG START    TINES PQR RANDOM PHASING Radial            Chug  Start            Radial    Chug  Start Row            Time (Sec)                Row      Time (Sec) 0  022826                18      0.012603 2,              0.021631                  19      0.035364 0.014281                  20      0.026404 0.037928                  21      0.039039 0.026944                  22      0.021682 6                0.025257                  23      0  024879 0.0092329                24      0.044889 0.,035325                25      0.024589 0.036614                  26      0.0057321 10              0.,017459                27      0.023880 0  030120                28      0.033905 12              0.018409                  29      0.015641 13              0.034114                  30      0.013154
                  ,0. 041211                31      0.022173 15              0 '34711                  32      0.026808
: 16.              0.024805                  33      0.046634 17              0.031562                  34      0.027705
                                -4          2 Vari. ance ~ 0.881708 x 10          (sec.)
Note:    The  three vents in each radial row are assumed to chug in-phase.
                                    <<74
 
BURNS AND ROE, INC . PROP RIETARY TABLE 5-2 i~EMUi4 RIGID WALL PRESSURES ON WNP-2 CONTAINMENT AT VENT EXIT ELEVATION (NODE 15)
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BUPSS hiVD ROE, Zi<C. P .OPRZETARY GENERAL ELECTRZC COMPANY PROPRZETARY TABLE 5 4 JAERZ PEAK POSZTZVZ CHUGGZ.IG P.RES SURE RMLZTUDES
                    ~77~
 
TABLE 5-5 MAXIMUM COMPUTED ACCELERATIONS FOR WNP-2 REACTOR BUILDING RESPONSE      MAXIMUM ZONE                                  DIRECTION  ACCELERATION (g)
I        510'OCATION Containment      Horizontal      1.63 Xnside and on the        Wall (Quencher boundary of the          Elevation) containment struc-ture below El.
XX Inside and on the 510'ontainment Wall El.
520'lorizontal          0.18 boundary  of the containment struc-        RPV Support      Vertical        0.060 ture above El.
Stabilizer Truss  Horizontal      0.038 IXX                Outside Building JIorizontal      0.002 Outside the con-tainment structure Wall El. 521'ertical              0.029
 
ORYWELL VACUUM
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                                              >>79-
 
C H.18&19                          CH. 17 0'0'25
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PZGURE WASHZNGTON PUBLZC POWER SUPPLY SYSTEM  4TCO Tests NUCLEAR PROJECT NO            2 Wetwell Pressure    Transducer Locations                          2~2 GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNQTON PUBLXC POWER SUPPLY SY~ COMPARISON OF PRESSURES & FOURIER    PZGUBE AMPLITUDE SPECTRA OF i<EY CHUG 6 A NUCEZAR PROJECT NO  2      NEIGHBORING CHUG - TIME WINDOW NO. 1
 
GENERAL ELECTRIC COMPANY PROPRIETARY COMPARISON OF PRESSURES & FOURIER    FIGURE WASHINGTON PUBLIC POWER SQPPXY SY~ AMPLITUDE SPECTRA OF KEY CHUG 6 A      3>>2 NUCLEAR PROJECT NO~ 2      NEIGHBORING CHUG  TIME WINDOW NO. 2 GENERAL ELECTRIC COMPANY PROPRIETARY t
t WASHZNGTON PUBLZC POWER SUPPXiY SYSTRC NU~ PROJECT    HO  2 COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A NEIGHBORING CHUG  TIME WINDOW ViO. 3 PZGURE 3 <<3
 
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GENERAL ELECTRIC COMPANY PROPRIETARY
~~~@ PmXZC ZewZz ~~zzz zz~  COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG & A PIQUE 3-5 NEIGHBORING,CHUG - TIME WINDOW NO. 5 GENERAL ELECTRIC COMPANY PROPRIETARY
%LSHZNQTON PUBLIC PowER SUPPLY SYSTzH COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A    3-6 NEIGHBORING CHUG  TIME WINDOW NO. 6 I
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GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLXC POWER SUPPLY SY~ COMPARISON OF PRESSURES & FOURIER    FIGURE AMPLITUDE SPECTRA OF KEY CHUG & A    3~7 NUCZZAR PEKL7EZT HO        NEIGHBORING CHUG  TIME WINDOW NO. 7 I
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GENERAL ELECTRIC CO%?ANY PROPRIETARY WLSHMGTON pUBLzc  pggzz gypsy gyp~  COMPARISON OF PRESSURES MEASURED AT CHZ2iNEL 28 AND C~~EL 26 RJCLEAR PRCLTEZT NO  2        DURING TIHZ WINDOW NO. 6,CHUG I
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GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM COMPARISON OF PRESSURES MEASURED AT CHANNEL 24 AND CHANNEL 20 NUCLEAR PROJECT NO  2          DURING TIME WINDOW NO. 6 I CHUG n 2 I
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BURNS AND ROE i INC ~ PROPRIETARY M7LSHZNGTON PUBLZC ~    SUPPLY SYSTM NUCLEAR PROJECT HO  2 PHASE RELATIONSHIP BETWEEN PRESS .
MEASURED AT CHANNEL 20 AND CHANNEL 28 VERSUS FREQUENCY-TIME WINDOW NO.l PZUURE 3 >0 l
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BURNS AND ROE g  ZNC ~ PROPRIETARY
~HZNGTON PUBLIC PowER sgPPLY SY~  PHASE RELATIONSHIP BETWEEN PRESS . PIGURE 3-gg MEASURED 'AT CHANNEL 20 AND CHANNEL 28 VERSUS FREQUENCY-TIME WINDOW NO.l I
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GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTZ?4 VERTICAL DISTRIBUTION OP PEAK PZGURE PRESSURES-SIX CHUGS, TIME i%JCLEAR PROJECT NOi 2          WINDOW No. 1 3-l3 I
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%LSHXNQTON'UBLIC POWER SUPPL" SYFZBC VERTICAL DISTRIBUTION OF PEAK  PIGURE FOURIER AMPLITUDES OF PRESSURES  3-14 NUCLEAR .PR03ECT NO  2 TWO CHUGS-TIME WINDOW NO. 1 5
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BURHS  ALOD  ROE I XNC ~ PROPRZETARY WASHINGTON PUGLXC PGWER SUPPLY SYSTEM%    RATIO OF FOURZER AMPLITUDES OF    FIGURE PRESSURES MEASURED AT CH.20/CH.21 NUCLEAR PROJECT NO  2                                                3-15 95>>
 
l GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLIC POWER SUPPL SYS~  COMPARISON OF 4TCO S 4T DATA FIGURE PRESSURES MEASURED AT BOTTOM NUCLEAR PBCQECT NO  2        CENTER 3-16
 
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l BURNS AND ROE,  INC . P ROP RIETARY WASHXNGTON PUBLIC POWER SUPPLY SYSTRC  SCHEMATIC PRESENTATION OF  PEGURE PRESSURE SOURCE AT VENT'XIT 3-18 NUCLZAR PROJECT NO  2            IN 4TCO SYSTEN I
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: f. REQUFHC'5  (Hl )
I- 8
 
BURNS AND ROE, INC. PROPRIETARY WASHXHGTON PUBLIC PC5KR SUPPLY, SYSTEM SCHEMATIC PRESENTATION OF ACCELERATION SOURCE AT THREE NUCLEAR PROJECT NO  2          LOCATIONS 'IN 4TCO SYSTEM
 
n CV CU=I1800/CS=1600 3& Hz n
CO n
o -& Hz
                      -24  H OgQ            CD ILI td M Q
~  Ol H      o Co Co LLJ HOR        K Q              o OH                              "40 Hz CII C6                            I QVC Cpa PS  a  CII n                        50 Hz HQO
<OS                                      I  -60  Hz
%AC g  0 I
+M  oo Q HH
: 20. OD    IIO. 00      GO. OD 00. 00  !00. 00 .'20. QO IgO. 00 ! GO. JO FREQUENCY  (t)Z)
 
      ~
~
o fV
      ~
5 u    '4                                        CtJ=~BOO/CS=i600 k
      ~
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M M
ld HQ(
R>V      K n~        n Vi C cpug        CJ w  a  cn
&OR aih) Cg Ze O
: 20. 00 tlO QQ    60 03  gQ. QD )00. OQ 120. 03 )40. OQ )GO 00 FRFQUEHCY  (HZ)
 
A n
n Ul P4 CIJ=4'000/C5=!600 CL QOQ AC+      V)    e Q.
Cd gW  4J lL M
CO R  c& C    n an<    H    n XC 0 Mg CI V) tI7 ~ N 0
OOg          a RO RbfO 0 VK R td na 0cn g      n0. 00                                  l00. DO
      \          $ 0. 00 tlO. 00    GO. QQ 00. QD          120. QO l 40. QO l GO. QO M                          FREQUENCY  (l)Z)
  "p
 
BURNS AND ROE i INC ~ PROPRIETARY m~~ ~c  ~    mme ms~
W~C PSOJEC"'O. 2    i
                        'FCOMPARISON OF VERTICAL DISTRIBUTION zZmaz NORMALIZED MAX PRESS  CALCULATED 3-24 W/PRESS . & ACCELERATION SOURCES
                              -105-
 
BURNS AND ROE,  INC. PROPRIETARY
%LSHXNGTQN PUBLXC POWER SUPPLY SYSTEM VERT. DISTR. OF FOURIER AMPLITUDES FIGURE OF PRESS. CALCULATED WITH ACCEL.
NU~~    PRGJFCT HO  2          SOURCE AT VENT EXIT 3-25
 
nn g=u800/CS=1410
                    ~35  Hz I
40 Hz I
cn 0
a CO W      7 Hz I  ~21 Hz M
V)
QJ              I K
a a
aa 2o. oo        ilo. oo    ao. 00 on. on l 00. 00  l 'c'.n. dn l 40. DD l GD. QD FREQUENCY  (HZ)
 
Ch
              +I n
n (V
C IJ.= 2 l} 00/C S.= } 6 00
/MAL          ~ ~
2$ Hz M
UWN          n nRc      IJj K
M 0lA C hf  CO gQ  LJJ K                        29 Hz Q.
n OAH          a
                    -O trz R." 8 C)
OgM          Cl thgK N    P3    CI AQ C
w II g Q  M F05
~  AQ I o        nn D. OD    20. 00      IlD. 00  60. 00 BD. 00 l00. DD      l20.00      l lO. 00 1GO. DD FREQUEHC't'H2)
 
BU RNS AND ROE I  ENC ~ P ROP R IETARY WLSHZNGTOH PUBLZC POWER SUPPLY SYSTEM PHASE RELAT1ONSHXP BETWEEN PRESSURES FZGURE CALCULATED AT CH.20 AND CH.28        3-28 NUCLEAR PROJECT HO  2        VS. FREQUENCY
                                          -109-
 
BURNS AND ROE I INC ~ PROPRIETARY WASHZNGTON PUBLZC POWER SUPPXZ SYSTEM    C. VS . RESONANT FREQUENCY NUCLEAR PBOJECT NO+ 2            ANALYTICAL CURVE  &  ITS APPL.
                                        -110-
 
oo Chug No. 2 (Key Chug}
I a
CO o
I+
          >/l 'I 0        ~1 0
oo 20 ~ QQ  'IO. QQ  60. QO    80. QC  I 00 ~ 00 I 20. 00    I 40. QQ  I 60. CQ FRCOUENCY (HZ) oo Chug No.        3 (Companion Chug)
I I2 o D
CA 0
hJ oo III VI UJ IX 0
oo ZQ. CC    40. QO    60. QQ  90. QO    I 00. 00  I 'Q. 00    I 40. CQ  I 60. QQ FREOUKNC'(    {H7.)
WASHRf~~N PUBLIC        PCSIER SUPPLY SYSTEMS        COMPARXSON OF FOURIER SPECTRA OF PRESS      OF KEY CHUG & COMPANION CHUG HUCZZAR PROJI&2 HO            2              MEASURED AT CH.2S-TIME HINDOOS NO.2
                                                        -111-
 
I I
I I
 
aa Chug No. 3 (Key Chug) cs Oa V)
            ~a 0
QJ a lZ a D
V)
Vl li!.
0 00  ZO. QQ    '40. QO  'Q. QQ    8Q.QQ  lQO. 00 !ZQ. QQ  '. !O.QD !GD. DD FREOUENC'i  (HZ)
Chug No. 4 (Companion Chug) a O
I      as O  ~
V)
Q c as
            !i! aa VE
            !Z 0
DO    ZQ.CD    CO.DQ    GO.CQ    8D.QQ  :DO.QQ  !ZQ.QO    '.AO.DQ  !GQ.QQ FRFQUE!(C"  (HZ)
WLSEKNGTCH PURL):!"      PO~  SUPPLY SYSTRt    COMPARZSON OF FOURIER SPECTRA OF                PZGURE PRESS'F KEY CHUG & COMPANZON CHUG                4-2 i&JCZZAR PRC4cX.~ HOa 2                  MEASURED AT CH.28, TZME NZNDON NO.3
                                                      -112-
 
BURNS AND ROE,  INC. PROPRIETARY I
i t WASHXNGTON PUBLIC POWER SUPPLY SYSTEM NUCZZAR PROJECT NO~ 2 ~
DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM  CHAVv. NEL'8 PZGURE 4-3  .
 
                        .BURNS AND ROE,  INC. PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM  DESIGN SPECTRUM AND REQUIRED  PZGURE AVERAGE SPECTRUM - CHANNEL 26  4-4 NUCLZAR PROJECT HO~ 2 ~
                                          -114-
 
I I
I I
 
BURNS AND ROE, INC. PROPRIETARY WASHINGTON PUBLIC POWER SUPPLY SYSTEH  DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM - CHANNEL 24 NUCLEAR PROJECT HO  2 ~
                                        -115-
 
BURNS AND ROE g  INC ~      I PROP R ETARY WASHINGTON PUBLIC POWER SUPPLY SYSTEM    DESIGN SPECTRUM AND REQUIRED    FIGURE NUCLEAR'RMECT  NO  2 ~
AVERAGE SPECTRUM  - CHANNEL 20  4-6


BUPSS hiVD ROE, Zi<C.P.OPRZETARY GENERAL ELECTRZC COMPANY PROPRZETARY TABLE 5 4 JAERZ PEAK POSZTZVZ CHUGGZ.IG P.RES SURE RMLZTUDES~77~
BURNS AND ROE, INC. PROPRIETARX i
t WASHINGTON PUBLIC POWER SUPPLY SYSTEH NUCLEAR PROJECT NO  2.
DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM  CHANNEL 28 FIGURE 4-7
                                            -3.17-


TABLE 5-5 MAXIMUM COMPUTED ACCELERATIONS FOR WNP-2 REACTOR BUILDING ZONE I Xnside and on the boundary of the containment struc-ture below El.510'OCATION Containment Wall (Quencher Elevation)
I I
RESPONSE DIRECTION Horizontal MAXIMUM ACCELERATION (g)1.63 XX Inside and on the boundary of the containment struc-ture above El.510'ontainment Wall El.520'lorizontal RPV Support Vertical Stabilizer Truss Horizontal 0.18 0.060 0.038 IXX Outside the con-tainment structure Outside Building JIorizontal Wall El.521'ertical 0.002 0.029
l


VACUUM&REAKER IIL1 It ORYWELL I I 1 2 It 52.5 ft VENT SRACE 454't 4T TANK YBIT (OCWNCOMER)
BURNS AND ROE I INC ~ PROPRIETARY PZGURE WASHZNGTON PUBLZC POWER SUPPLY SYSTEM   DESIGN SPECTRUM AND REQUIRED NUCZZAR PROJECT NO  2 ~
V E."IT aRACS Si EAM QENERATOR Il.S It I'I.OW MEASURINQ VENTI'Rl W7LSHZNGTOH PVBLXC POWER SUPPLY SYSTEM NUCLEAR PK4ECT HQ Test Configuration for Park II Conclensation Oscillation (4TCO)Tests>>79-  
ENVELOPE SPECTRUM  CHANNEL 2 6  4-8
                                          -118-


C H.18&19 0'0'25 315 CH.17~-45o 20.0'H.22&'23 I~-~, 225 315 CH.21 4'5 CH.20 12.0'H.24 C H.26&27 Oc4'25 315 CH.25~'5o 00 0.0o 6.0'.0'.0'h.
BURNS AND ROE I INC ~ PROPRIETARY WASHINGTON PUBLZC POWER SUPPLY SYSTEM   DESIGN SPECTRUM AND REQUIRED  PZGURE NUCLEAR PROJECT No  2 .
28 (Bottom Center)WASHZNGTON PUBLZC POWER SUPPLY SYSTEM NUCLEAR PROJECT NO 2 4TCO Tests Wetwell Pressure Transducer Locations PZGURE 2~2 GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNQTON PUBLXC POWER SUPPLY SY~COMPARISON OF PRESSURES&FOURIER PZGUBE AMPLITUDE SPECTRA OF i<EY CHUG 6 A NUCEZAR PROJECT NO 2 NEIGHBORING CHUG-TIME WINDOW NO.1
ENVELOPE SPECTRUM  CHANNEL 24  4-9
                                        -119-


GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLIC POWER SQPPXY SY~NUCLEAR PROJECT NO~2 COMPARISON OF PRESSURES&FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A NEIGHBORING CHUG-TIME WINDOW NO.2 FIGURE 3>>2 GENERAL ELECTRIC COMPANY PROPRIETARY t t WASHZNGTON PUBLZC POWER SUPPXiY SYSTRC NU~PROJECT HO 2 COMPARISON OF PRESSURES&FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A NEIGHBORING CHUG-TIME WINDOW ViO.3-83-PZGURE 3<<3
l I
I


GENERAL ELECTRIC COMPANY PROPRIETARY t t WASHINGTON PUBLIC POWER SUPPLY SYSTEM%NUCXZAR PROD~HO 2 COMPARISON OF PRESSURES&FOURIER AMPLITUDE SPECTRA OF KEY CHUG S(A@NEIGHBORING CHUG-TIME WINDOW NO.4-84-PIGURE 3-4 I I I I GENERAL ELECTRIC COMPANY PROPRIETARY
BURNS AND ROE, INC. PROPRIETARY wAsHINGT0N Paar'nna svpprv scrag  DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM  CHANNEL 20
~~~@PmXZC ZewZz~~zzz zz~COMPARISON OF PRESSURES&FOURIER PIQUE AMPLITUDE SPECTRA OF KEY CHUG&A 3-5 NEIGHBORING, CHUG-TIME WINDOW NO.5 GENERAL ELECTRIC COMPANY PROPRIETARY
                                  >>120-
%LSHZNQTON PUBLIC PowER SUPPLY SYSTzH COMPARISON OF PRESSURES&FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A 3-6 NEIGHBORING CHUG-TIME WINDOW NO.6 I I I l I GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLXC POWER SUPPLY SY~NUCZZAR PEKL7EZT HO COMPARISON OF PRESSURES&FOURIER AMPLITUDE SPECTRA OF KEY CHUG&A NEIGHBORING CHUG-TIME WINDOW NO.7-87-FIGURE 3~7 I I I I GENERAL ELECTRIC CO%?ANY PROPRIETARY WLSHMGTON pUBLzc pggzz gypsy gyp~COMPARISON OF PRESSURES MEASURED AT CHZ2iNEL 28 AND C~~EL 26 RJCLEAR PRCLTEZT NO 2 DURING TIHZ WINDOW NO.6,CHUG"'
I I GENERAL ELECTRICCOMPANY PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM NUCLEAR PROJECT NO 2 COMPARISON OF PRESSURES MEASURED AT CHANNEL 24 AND CHANNEL 20 DURING TIME WINDOW NO.6 I CHUG n 2 I I)
BURNS AND ROE i INC~PROPRIETARY M7LSHZNGTON PUBLZC~SUPPLY SYSTM NUCLEAR PROJECT HO 2 PHASE RELATIONSHIP BETWEEN PRESS.PZUURE MEASURED AT CHANNEL 20 AND CHANNEL 3>0 28 VERSUS FREQUENCY-TIME WINDOW NO.l l I BURNS AND ROE g ZNC~PROPRIETARY
~HZNGTON PUBLIC PowER sgPPLY SY~PHASE RELATIONSHIP BETWEEN PRESS.PIGURE MEASURED'AT CHANNEL 20 AND CHANNEL 3-gg 28 VERSUS FREQUENCY-TIME WINDOW NO.l I.I l BURNS AND ROE, INC.P ROP RIETARY~~~@~Q~$QPPT~NU~PROJE~HQ 2 RATIOS OF FOURIER AMPLITUDES OF PRESSURES MEASURED AT CHANNEL 28/CHANNEL 20 a
GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTZ?4 i%JCLEAR PROJECT NOi 2 VERTICAL DISTRIBUTION OP PEAK PRESSURES-SIX CHUGS, TIME WINDOW No.1 PZGURE 3-l3 I I GE'FERAL ELECTRIC COMPANY PROPRIETARY
%LSHXNQTON'UBLIC POWER SUPPL" SYFZBC NUCLEAR.PR03ECT NO 2 VERTICAL DISTRIBUTION OF PEAK FOURIER AMPLITUDES OF PRESSURES TWO CHUGS-TIME WINDOW NO.1-94-PIGURE 3-14 5 l 1 BURHS ALOD ROE I XNC~PROPRZETARY WASHINGTON PUGLXC PGWER SUPPLY SYSTEM%NUCLEAR PROJECT NO 2 RATIO OF FOURZER AMPLITUDES OF PRESSURES MEASURED AT CH.20/CH.21 95>>FIGURE 3-15 l
GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLIC POWER SUPPL SYS~COMPARISON OF 4TCO S 4T DATA PRESSURES MEASURED AT BOTTOM NUCLEAR PBCQECT NO 2 CENTER-96-FIGURE 3-16


588.0 54RO 543;0.505.0 466.0 424.0 Modified 4T Tank 382.0 328:0~276.0-262.0 216.0 195.0 180.0..144.0 127.0 108.0 60.0 72.0 p pll 36.0 24.0 0.0 12.0 18.0 26.'0 34.0 42.0 0.0" 12.0 MLSHZHGTON PUBLZC PC%ZR SUPPLY SYSTEM NUCLEAR PROJECT No~2-97-VENT-POOL MODEL (FLUlD ELEMENTS)PZGURE 3-3.7a
S c.CT:ON  B -B 0
0 0
I  I 0                                                                 0.
0gl Ot 2~~i~f MASHZH~iN PUBLIC PO~  SUPPLY PiaTKi        SOURCE STRENGTH D ISTRIBUTION ASYMMETRIC LOADING CASE HQ~ PMJECT    HO
                                          -121-


4~J~e~~~~~~~r~
ghkk  i  L.ii, gal.S  lk 'JAX If  j I ll SECTION B-B 0
l BURNS AND ROE, INC.P ROP RIETARY WASHXNGTON PUBLIC POWER SUPPLY SYSTRC NUCLZAR PROJECT NO 2 SCHEMATIC PRESENTATION OF PRESSURE SOURCE AT VENT'XIT IN 4TCO SYSTEN-99-PEGURE 3-18 I
0 0
ak~R n sm g ggC MNQ UI OIH C~o~9~KRC ea x a ta Q (A RAA td hJ C HQO a n Ul tO I O V)Q.II)Ul S hl IL Q.n n o n n UI 9 Hz 27 Hz~~45 Hz-63 Hz CIJ=4000/CS=-!600 hl M I-8 20.Oo IJD.QO 6D.QD 00.DQ f.REQUFHC'5 (Hl)!00.QD!20.Qo!0,00!60.QD
I 0Z I-O UJ 0        M 0                                                                Qw 0tJl (U
                                                            /
                                                    ..   /
9 ~MN SOURCE STRENGTH DISTRIBUTION  FIGURE WASHINGTON PUBLIC PONER SUPPLY SYSTEM NEARLY SYMMETRIC LOADING CASE  4 12 NUCLEAR PROJECT NO< 2 .
                                          -122-


BURNS AND ROE, INC.PROPRIETARY WASHXHGTON PUBLIC PC5KR SUPPLY, SYSTEM NUCLEAR PROJECT NO 2 SCHEMATIC PRESENTATION OF ACCELERATION SOURCE AT THREE LOCATIONS'IN 4TCO SYSTEM
I
                                                                        ~ Roa              'v le TCiN-BRlCCs        K                        CRAblK CRAAIC                                  Rl 'iiW'          QIR~aR
                                                                                                              .I SRICGK~
G!RCKR 5TCM~Kc          &#xb9;/                                                                      E    'CC-la~:
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                      ~  ~
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                                ~ e. ~
                                                                        ~-,aa Paal
                                                                            ~ ~
                                                                                ~ ~
                                                                                      -Z
                                                                                      ~  ~+i    ~
                                                                                                    ~
                                                                                                                    =1 '1  1 i l CR HEN  ~
I I  ~ia.w <=-1                      RlRCl ''
V~MSK1                                                                                              I
                                                                                                              "-  SHlc.~, Ylkl P~cl'lg B)4L M&~l                                                                                                  <al L',MNc      'l SHlP'
        'WALK                                                                                                      O'P.YYZ-i
                                                                                                                    ~g&~ Q'I        I
                                                                                                                    ='~a~
SUP..    =~  f
                        ~
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14N  baal    I':                                                                                          ~~~~~<
WA,                                                                                               I.I L -VE'
                                                                                  !                        I.I    cc cvvc~~~
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                    ~ ~
HULK~
i                                                                          COL.Uhl H 5 i4R                                                              V' PR~ws~l l                                                        ~
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                                                                        ~              ~
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                                                                                                              ~ ~
                                                                                                                ~ ~
                                                              ~  ~  ~          0        ~
FQQslC~7lOH i%As            '
                                                            ~
                                                                ~  ~
                                                                        ~      ~ ~
4    r ~
                                                                                                      ~
                                                                                                          ~
WLSHZHGXOH  PUBLIC PCWER SUPPLY             SYS~        GEaKRAL CROSS-SECTXON OP HUCLZAR PROJECT HO~ 2                             WNP-2 REACTOR BUZLDXNG
                                                          -123-


n CV 3&Hz CU=I1800/CS=1600 n CO n OgQ td M Q~Ol H HOR Q OH CII C 6 QVC Cpa PS a CII HQO<OS%AC g 0+M oo Q HH o CD ILI o Co Co LLJ K o n-&Hz-24 H I"40 Hz 50 Hz I-60 Hz I 20.OD IIO.00 GO.OD 00.00 FREQUENCY (t)Z)!00.00.'20.QO IgO.00!GO.JO
I LQ 2 GCha~CCa'- 25
~~~5 u'4 k~O(O X Ol Q M CA H td C Cd HQ(R>V n~Vi C g cpu w a cn&OR ai C h)g Ze O o fV m CL W D M M ld K n CJ 20.00 CtJ=~BOO/CS=i600 tlO QQ 60 03 gQ.QD)00.OQ 120.03)40.OQ)GO 00 FRFQUEHCY (HZ)
                                                                  =QM      5 ~C=D 90.04 I05.88o >>29 4  ~
II 47o'                    '4I2'3.534 l2 .064                                        52.94o 8
I37. 65 4                                                      42.35 48.24o                                                                    3I.76 o l58.824                                                                            2I.I 8 o l69.4I                                                                                  I0994 I800o 0.0 270.0~
~nSK J~v. PU3X    PCnZR  M      S"~     WETWELL PLAN VIEW AT ELEVATlON OF DOWNCOMER EXlTS                              5-2
                                                      >>124-


A n n Ul P4 CIJ=4'000/C5=!600 QOQ AC+Cd g W R c&C H an<XC 0 M g tI7~N OOg RO RbfO 0 V K R td 0cn g\M"p CL V)e Q.4J lL M CO n n CI V)0 a a n n 0.00$0.00 tlO.00 GO.QQ 00.QD FREQUENCY (l)Z)l00.DO 120.QO l 40.QO l GO.QO
      ~
~~uMVRY i- I
            ~ ) ~
        ~ ~~


BURNS AND ROE i INC~PROPRIETARY m~~~c~mme ms~COMPARISON OF VERTICAL DISTRIBUTION zZmaz'F NORMALIZED MAX PRESS CALCULATED 3-24 W~C PSOJEC"'O.
WASHZNGTON PUBLZC PQWER SUPPLY S~~     FLUID STRUCTURE BOUNDARY-WNP-2 SUPPRESSION POOL PZGURE 5-4 NUCLEAR PROJECT NQ  2 ~
2 i W/PRESS.&ACCELERATION SOURCES-105-  
                                  -.12 6-


BURNS AND ROE, INC.PROPRIETARY
f 605.88'67.38 547'21 500'88.8'77.6'70'63.25 456.5'49.75'43'27.75'22.25 SOIL/
%LSHXNGTQN PUBLXC POWER SUPPLY SYSTEM NU~~PRGJFCT HO 2 VERT.DISTR.OF FOURIER AMPLITUDES OF PRESS.CALCULATED WITH ACCEL.SOURCE AT VENT EXIT FIGURE 3-25
418,25                    STRUOTlBE 414 25                    I NTERFACE 410,25                        NOD'ES WASHINGTON PUBLIC POWER SUPPLY SYSTEM                                                           FIGURE REACTOR BUZLDXNG MODEL                                  5-5 NU~~   PROJECT NO>> 2 ~
                                      -127-


n n~35 Hz I g=u800/CS=1410 cn a 0 CO W M V)QJ K a 7 Hz I~21 Hz I 40 Hz I a a a 2o.oo ilo.oo ao.00 on.on FREQUENCY (HZ)l 00.00 l'c'.n.dn l 40.DD l GD.QD
BURilS AND ROE,  ZNC. PROPRIETARY GE?iEEVJ  ELECTRIC CO.'IPANY PROPRZ~TARZ WASHINGTON PUBLIC POWER SUPPLY SYSTEM ENVELOPES OF CALCULATED RESPONSES FOR FIGURE WNP-2 AND MEASURED RESPONSES AT JAERI NUCLEAR PROJECT NQ~ 2          CONTAINMENT AT VENT EXIT ELEVATION


Ch+I n n (V C IJ.=2 l}00/C S.=}6 00~~UWN nRc/MAL 0 C hf lA g Q OAH R." 8 C)OgM thgK N P3 AQ C w II g Q M~AQ F05 I o M n IJj K M CO LJJ K Q.n a Cl CI n n-O trz 2$Hz 29 Hz D.OD 20.00 IlD.00 60.00 BD.00 FREQUEHC't'H2) l00.DD l20.00 l lO.00 1GO.DD
THETA TRANSLATIOl4 O lt I
g4 Ill 4l~
Lk '0
                      ~
cga
                            . 00  IO. 04    '%0.00  40. 00    IO. 04      l00. 00   INl. 00 I 0. 00  I CO. 00 FRFOURNCT IN'L)
VERTICAL TRANSLATION DA I
g4 IC le lal ~
IJ D EJ g4
: 40. 40    W4. 00  M. 04    l4. 04      I 00. 04  I IO. 00 I%4. 00   I CO. 00 FROOUQICT      INZ)
HORIZONTAl TRANSLATICN O
Q~
I V
                    <Z4 IC lal III~
CJ ~
(g 4 b.OO    IO.<Q    'l0.04  40.00    lO.OO      104.00   l)0.04    I%0.00   ICO.OO FRE'OURNCT UI\)
Note:    Multiply all acceleration values                                            by 1.18.
REACTOR BUILDING RESPONSE-WASHTMGTCN PUBLZC PQWER SUP        LX    SZS~            ASYMMETRIC LOADING:
PZGQ3E CONTAIN),I, NT NU~ PM4ECT            HO  2                        VESSEL AT MAT                                                        5 7 a
                                                            -129-


BU RNS AND ROE I ENC~P ROP R I ETARY WLSHZNGTOH PUBLZC POWER SUPPLY SYSTEM NUCLEAR PROJECT HO 2 PHASE RELAT1ONSHXP BETWEEN PRESSURES CALCULATED AT CH.20 AND CH.28 VS.FREQUENCY-109-FZGURE 3-28
I I
I I
I I


BURNS AND ROE I INC~PROPRIETARY WASHZNGTON PUBLZC POWER SUPPXZ SYSTEM NUCLEAR PBOJECT NO+2 C.VS.RESONANT FREQUENCY ANALYTICAL CURVE&ITS APPL.-110-  
THETA TRANSLATION 2
                            ~<<
2
                        <<Og IJ
                            ~ I
                        ~0 I
                        <<4 IC
                        ~4
                        <<<<I 4 IJ EJ
                        <<0
: b. 04    to. 04    <<Io. 00  Oo. 00    Io. 00        IOO. 00  I to. 00  Ilo. 00  100.04 F Rt:OtjENCY    N2)
V.ERTICAL TRANSLATION I
                      <<04 ill l<<k
                      <<Oo
                          'b.oo    -
to.oo f RfQUEttC'f      <ltL I
                                                                                              <<  ~
HORIZONTAL TRANSLATION lh
                          <<I
                      <<0
                      <<40
                      <<<<<< ~
                    <<<<k  4 EJ EJ
                      <<0 b.04      t0.00    14.04    44.00      00.00          I04.04  IO0.04    I 0.04  IO0.00 F RCQUtttC'l    Ilt'C I Note:    multiply              all      acceleration values by 1.18.
WASEKBCZQN PUBLZC POWER SUPPXIY SYSTZA                        REACTOR BUILDING RZSPONSZ-                                        FIGURE HU~~    PRCQZCT HO~ 2 ASYK4ETRIC LOADING:                                    RPV SUPPORT S-jb
                                                                  -130-


o o Chug No.2 (Key Chug}I a CO o I+>/l'I 0~1 0 o o 20~QQ'IO.QQ 60.QO 80.QC I 00~00 I 20.00 I 40.QQ I 60.CQ FRCOUENCY (HZ)o o Chug No.3 (Companion Chug)I I2 o D CA 0 hJ o o III VI UJ IX 0 o o ZQ.CC 40.QO 60.QQ 90.QO I 00.00 I'Q.00 I 40.CQ I 60.QQ FREOUKNC'({H7.)WASHRf~~N PUBLIC PCSIER SUPPLY SYSTEMS HUCZZAR PROJI&2 HO 2 COMPARXSON OF FOURIER SPECTRA OF PRESS OF KEY CHUG&COMPANION CHUG MEASURED AT CH.2S-TIME HINDOOS NO.2-111-I I I I a a Chug No.3 (Key Chug)cs Oa V)0~a QJ a lZ a D V)Vl li!.0 00 ZO.QQ'40.QO'Q.QQ 8Q.QQ lQO.00!ZQ.QQ'.!O.QD!GD.DD FREOUENC'i (HZ)Chug No.4 (Companion Chug)a O I as O~V)Q c as VE a!i!a!Z 0 DO ZQ.CD CO.DQ GO.CQ 8D.QQ:DO.QQ!ZQ.QO'.AO.DQ!GQ.QQ FRFQUE!(C" (HZ)WLSEKNGTCH PURL):!" PO~SUPPLY SYSTRt i&JCZZAR PRC4cX.~HOa 2 COMPARZSON OF FOURIER SPECTRA OF PRESS'F KEY CHUG&COMPANZON CHUG MEASURED AT CH.28, TZME NZNDON NO.3 PZGURE 4-2-112-  
THETA TRANSLATION "1
5 ar  zo.ao  uo.oa  eo.oo    so.oo      Loo.oo  tza.ao  .uo.ao  ice.oa FRCQUKtuCY    (HZ)
HORIZONTAL TRANSLATION
              %. oa    zo. aa 'ua. aa 80. Oo  80. Oa      100. Oa L20. Qa Lua. aa boa. 00 FPEQUEtuCY <HZ>
Note:      Multiply all acceleration values by 1.18.
NASHZHQTON PUBLZC POWER  SUPP'Y~A      REACTOR BUILDING RESPONSE-ASYMMETRIC PZ GORE LOADING:         CONTAINMZNT VESSEL AT NUCLEAR  PBQZECT'O~ 2           STABILIZER TRUSS. LEVEL                            5-7 c
                                            -131-


BURNS AND ROE, INC.PROPRIETARY I i t WASHXNGTON PUBLIC POWER SUPPLY SYSTEM NUCZZAR PROJECT NO~2~DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM-CHAVv.NEL'8 PZGURE 4-3.
I I
I I


.BURNS AND ROE, INC.PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM NUCLZAR PROJECT HO~2~DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM-CHANNEL 26 PZGURE 4-4-114-I I I I BURNS AND ROE, INC.PROPRIETARY WASHINGTON PUBLIC POWER SUPPLY SYSTEH NUCLEAR PROJECT HO 2~DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM-CHANNEL 24-115-BURNS AND ROE g I NC~PROP R I ETARY WASHINGTON PUBLIC POWER SUPPLY SYSTEM NUCLEAR'RMECT NO 2~DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM-CHANNEL 20 FIGURE 4-6
THETA TRANSLAT(ON l44 4
wQ g4 I40 Ek~
EJ  ~
0 El 10.00    00.00  l0.00    IOIOO      IOO. 04  l10. 00  I10.04  IOO.OO FHE'OUQICV    IIII>
VERTICAL TRANSLATlON a
ll4
                        <ga IK 4I lal ~
ll lg4
: h. 04  10. 00  IO. 00  IO. 00  00. 00      IOO. 04  l10. 04  IlO. 04  IOO 04 FtICOUfNCT (1IZ1 HORIZONTAL TRANSLATlON I
0O 4l wQ 0't
                        'b.04      10.04    IO.OO  IO.OO    00.00      I04.04  I10.04  IIO.OO  I00.00 fREQUCIICI    NL1 Note:    Multiply all acceleration values                                        hy 3..18.
WASHINGTON ?UBLZC PCWER SUPPLY             SY~      REACTOR BUZLDZNG RESPONSE-ASYMMETRZ LOADZNG-                    CONTAZNMENT VESSEL AT PEGVRE NUCLKQt ? BOJECT HO         2                 MZD-SUBMERGENCE DEPTH 5-7 d
                                                            -132-


BURNS AND ROE, INC.PROPRIETARX i t WASHINGTON PUBLIC POWER SUPPLY SYSTEH NUCLEAR PROJECT NO 2.DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM-CHANNEL 28 FIGURE 4-7-3.17-I I l BURNS AND ROE I INC~PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM NUCZZAR PROJECT NO 2~DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM-CHANNEL 2 6 PZGURE 4-8-118-BURNS AND ROE I INC~PROPRIETARY WASHINGTON PUBLZC POWER SUPPLY SYSTEM NUCLEAR PROJECT No 2.DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM-CHANNEL 24 PZGURE 4-9-119-l I I BURNS AND ROE, INC.PROPRIETARY wAsHINGT0N Paar'nna svpprv scrag DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM-CHANNEL 20>>120-  
Theta Translation Ou
                        ~
4
                        ?
O4
                            ~
O I44 4I 4 Iu 4 IJ I?
                          'II. uo  Io. oo  co. oo  co. oo  co.uo      Ioo. oo I to. oo    i co. uo  I co. oo f RCOUEIICY  (IIII I
                          ~ \
Vertical Translation 4
Qu
                      ?
O4 gu tu lu u tu4 tu to II
                          'b.oo,  co.oo    co.uo  cu.oo    co.oo      Ioo.oo  Ico.uo    I o.uo  ccu.oo f RROUfIICY  IIQ) 4 Horizontal Translation tOu 4
O 4
O I
IC ceo 4J~
                    ~ ay 4 4
O
                          'b. uo  Io.oo    co.uo  co. oo  co. oo    duo. oo  cto. ou    cco.oo    cco. oo fRCOUCIICY UIK)
Note:    Multiply all acceleration values                                        by 1.18.
RLSEDiQTOH PQBLZC PCRER SUPPLY            SiE'8      REACTOR BUZLDZNG RESPONSE ASYHMETRXC LOADZNG:                                  OUTSXDE HU~ PBCCEZT          HO                      BUZLDZNG gALL ELEVATZON 521'133-


S c.CT:ON B-B 0 0 0 0 0 gl I I 0.Ot 2~~i~f MASHZH~iN PUBLIC PO~SUPPLY PiaTKi HQ~PMJECT HO SOURCE STRENGTH D ISTRIBUTION ASYMMETRIC LOADING CASE-121-  
THETA TRANSLATION ua
                      ?
                    ~t l
4l 4J IJa Co
                        ')I. 04  IO. 00    10. 44 IO. 00  10. 04    100. 04 IIO. 04 I IO. 00 100. 04 FRCOUKIIC) UIE) 4 l4 VERTICAL TRANSLATION ll a
4la IK 4l 4l 4lo tJ go b.00    10 00    '10.00 00.00    10.00      100.04  I 4.00 1%0.00  100.04 FRCOUCIICY    IIIL)
HORIZONTAL TRANSLATION a
Qa
                      ?.
Cl a I
ga la i@a tJ 4J  o i/4 tl. 04  )0. 04  '14. 00 44. 00  10. 00    100. 04 140. 00 I 0. 04  I <0. 04 FRCOURIICT IIIL) iVote:  Multiply all accelexation values by 1.18.
MASHISGTCN PUBLIC PGWER SUPPLY           SYS~       REACTOR BUILDING RESPONSE  KUGKY                        - ZGUBE SYMMETRIC LOADING:                          CONTAINMENT NU~ PRAT-C2        HQ    2                    VZSSEL AT MAT 5-8a'134-


If j I ll ghkk i L.ii, gal.S lk'JAX SECTION B-B 0 0 0 0 0 tJl 0 Qw (U I Z 0 I-O UJ M/../9~MN WASHINGTON PUBLIC PONER SUPPLY SYSTEM NUCLEAR PROJECT NO<2.SOURCE STRENGTH DISTRIBUTION NEARLY SYMMETRIC LOADING CASE-122-FIGURE 4 12 I
0 THETA TRANSLATION C)g IJ ce
le TCiN-BRlCCs K CRAAIC SRICGK~G!RCKR 5TCM~Kc&#xb9;/~Roa'v CRAblK Rl'iiW'QIR~aR.I E'CC-la~:~~~~~e.~~-,aa-Z Paal~R" AC i QR.=1'1 1 i l CR STEEL.PRlQAR~:.I HEN~V~MSK1 B)4L M&~l SHlP''WALK P~cl'lg~~~~~~~+i I I~ia.w<=-1 RlRCl''<al L',MNc O'P.YYZ-i'l I"-SHlc.~, Ylkl f SUP..=~~14N baal I': WA, L-VE'i p~~~g&~Q'I I='~a~SLlPPP+!I.I~~~~~<I.I cc cvvc~~~~'.'.HO.HULK~'uQ~~i COL.Uhl H 5~~i4R PR~ws~l l FQQslC~7lOH i%As~~'~V'~0 l hl&LE'R:81R>~~~~0~~~~~~~~~~4 r~~~WLSHZHGXOH PUBLIC PCWER SUPPLY SYS~HUCLZAR PROJECT HO~2 GEaKRAL CROSS-SECTXON OP WNP-2 REACTOR BUZLDXNG-123-I LQ 2 GCha~CCa'-
                        ~0 CC Wg wa CJ D
25=QM 5~C=D l2.064 I37.65 4 I05.88o>>29 II 47o'8 90.04 4~'4I2'3.534 52.94o 42.35 48.24o 3I.76 o l58.824 l69.4I 2I.I 8 o I0994 I800o 0.0 270.0~~nSK J~v.PU3X PCnZR M S"~WETWELL PLAN VIEW AT ELEVATlON OF DOWNCOMER EXlTS 5-2>>124-  
D
                            )I. 04  )O. 00  '10. 00 CO. 00  ll. 04  100,04  I CO. 04 1%4. 00 I M. 00 FRCOUFNCT IIIt)
VERTICAI TRANSLATION D
Ia D I
CC  D W
Wa CI CJ a
COD
                                    )0. 00  10,00  la. 00  IO. 00  100. 00 I)0. 00  I 0. 00 Ill.00 FRROUENCY INZ)
HORIZONTAL TRANSLATION COD D
D I
CC
                      ~a W>>
wa CJ II. 04   )0. 04  10. 44  10. 40  IO. 04  100. 04 I )0. 04 I 0. 04 104. 04 FRKOUKtlCY (NR) iVote:  Multiply aU. acceleration values by 1.18.
)t)ASKPifQTON PUBIC PCQER SUPPLY            SY~       REACTOR BUILDING RESPONSE                        - NEARLY PXGUNK NU~ PBQJE~D        No    2 SYMMETRIC LOADING:                      RPV SUPPORT      5-8 b
                                                              -135-


~~~uMVRY i-I~~~~)~
THETA TRANSLATiON R
Oe CI 44 W
ua QO
                ~>>. QQ  20. 00    'l:l. 00 .  <Q. QQ    BQ. QQ      IQO. QQ  l20 ~ JQ    l40. OQ  !OQ OJ
                                                                                                        ~
ePsOUf ICY tHZ'ORiZONTAL TRANSLATiON Cl p) gO
            ~I laJ
            ~r.~
                ~ 00  20. 00    40. 00      ""0. 00  80. 00    I QQ. 00  I 20. 00    I'40. 00  l 60. 00 FRfQUfNCY (HZ]
Note:        Multiply all acceleration values                      by 1.18.
MAKKHGTON PUBLZC PCWER SUPPLY      SYS~         REACTOR BUZLDXNG RESPONSE  NEARLY                        rzavaz iVUCXZiQL  MAC                            SYMMETRZC LOADXNG:                    CONTATNVZNT          5-8 c HO    2 VESSEL AT STABILIZER TRUSS LEVEL
                                                    -136-


WASHZNGTON PUBLZC PQWER SUPPLY S~~NUCLEAR PROJECT NQ 2~FLUID STRUCTURE BOUNDARY-WNP-2 SUPPRESSION POOL PZGURE 5-4-.12 6-f 605.88'67.38 547'21 500'88.8'77.6'70'63.25 456.5'49.75'43'27.75'22.25 SOIL/418,25 STRUOTlBE 414 25 I NTERFACE 410,25 NOD'ES WASHINGTON PUBLIC POWER SUPPLY SYSTEM NU~~PROJECT NO>>2~REACTOR BUZLDXNG MODEL-127-FIGURE 5-5
I Theta Translation O
Q4 Z
O~
gO ac
                    ~a lJ    ~
Cg D
                            . 00  t0.00    t0. 00  40. 00  40. 04      IM.00  I'CD. 00  '.10. 09 I CD. 00 FREOUENCt      (hatt Vertical Translation O
                      '?
o I
ggEh EC
                    ~a
                    ~N CJ Ef 0
                              . 04  t4,04    10,04    CCI. 05  Ql. Oo      l00. 04 'R0, 04  lWO. 00  ICl. 05 FRFOUENCT IHZI A
a'orizontal                                          Translation
                      'X tl I
gR EC
                      ~n
                      ~n EJ QA
: 0. 04  'lO. 00  lO. C4  sO. M        104. OQ I'CS,04    I%0. 00 I CO. 00 FREOUCHI:T IIIt)
Note:    Multiply all acceleration values                                            by 1.18.
WASHZHGTON PUBIC POWER'UPPLY                SY~         REACTOR BUiLDING RESPONSE                              K~LY FIGURE NUCLEAR PROJECT HO          2 SYMMETRIC LOADING:                              CONTAINMENT g-8 d VESSEL AT MID-SUBMERGENCE DEPTH
                                                              -137-


BURilS AND ROE, ZNC.PROPRIETARY GE?iEEVJ ELECTRIC CO.'IPANY PROPRZ~TARZ WASHINGTON PUBLIC POWER SUPPLY SYSTEM NUCLEAR PROJECT NQ~2 ENVELOPES OF CALCULATED RESPONSES FOR FIGURE WNP-2 AND MEASURED RESPONSES AT JAERI CONTAINMENT AT VENT EXIT ELEVATION THETA TRANSLATIOl4 O lt I g4 Ill 4l~Lk~'0 cga.00 IO.04'%0.00 40.00 IO.04 l00.00 INl.00 I 0.00 I CO.00 FRFOURNCT IN'L)VERTICAL TRANSLATION D A I g4 IC le lal~IJ D EJ g4 40.40 W4.00 M.04 l4.04 I 00.04 I IO.00 I%4.00 I CO.00 FROOUQICT INZ)HORIZONTAl TRANSLATICN O Q~V I<Z4 IC lal III~CJ~(g 4 b.OO IO.<Q'l0.04 40.00 lO.OO 104.00 l)0.04 I%0.00 ICO.OO FRE'OURNCT UI\)Note: Multiply all acceleration values by 1.18.WASHTMGTCN PUBLZC PQWER SUP LX SZS~NU~PM4ECT HO 2 REACTOR BUILDING RESPONSE-ASYMMETRIC LOADING: CONTAIN),I, NT VESSEL AT MAT PZGQ3E 5 7 a-129-I I I I I I 2~<<THETA TRANSLATION 2<<Og IJ~I~0 I<<4~4 IC<<<<I 4 IJ EJ<<0 b.04 to.04<<Io.00 Oo.00 Io.00 IOO.00 I to.00 Ilo.00 100.04 F Rt:OtjENCY N2)V.ERTICAL TRANSLATION I<<04 ill l<<k<<Oo'b.oo-to.oo<<~f Rf QUEttC'f<ltL I HORIZONTAL TRANSLATION lh<<I<<0<<40<<<<<<~<<<<k 4 EJ EJ<<0 b.04 t0.00 14.04 44.00 00.00 I04.04 IO0.04 I 0.04 IO0.00 F RCQUtttC'l Ilt'C I Note: multiply all acceleration values by 1.18.WASEKBCZQN PUBLZC POWER SUPPXIY SYSTZA HU~~PRCQZCT HO~2 REACTOR BUILDING RZSPONSZ-ASYK4ETRIC LOADING: RPV SUPPORT FIGURE S-jb-130-  
Thetal Translation O4
                          ~
4 EJ S
Eo    4 I
Ea EO l 4 E44 IJ EJ Ea 44
                            ~I
                            'b.ao    lo.oo    Ea.oo    co.ao    to.ao        too.w    toa.oa  t O.oa    too.aa FRZt)VZttCY    lllZ)
Vertical Translation EJ4 EJ  44 Ea  4 EK ill ill EJ EJ 4 ~
0,4 ta,aa. Ea. 00   40. 00   Eo. 00       taa. 00 I to. 00 IEO. 00   I to,oa FRft)VCttCY    ItlZl Horizontal Translation W
EO4 Et I
Ea Ea E4 4 l4 4 EJ EJ Eo
                          'b. oo     to. oo   Ea.ao  EO. oo    to. Oo      too.ao  t to. oo  EEO. Oo  t Eo. oa FRROVCttCY It)Z)
Note:   Multiply all acceleration values                                         by 1.18.
REACTOR BUIIEDING RESPONSE                                -
WZttsiKS~~ PQBLZC PCWER SUPPLY NU~ PROJEX.~        HO   z SYS~
SYMMETRIC LOADING:
BUILDING HALL ELEVATION OUTSIDE  S21'GVBE NEARLY 5-8e
                                                              -138-


THETA TRANSLATION "1 5 ar zo.ao uo.oa eo.oo so.oo Loo.oo tza.ao.uo.ao ice.oa FRCQUKtuCY (HZ)HORIZONTAL TRANSLATION
RQF"RKPJC-I.a i    i i    I    ~
%.oa zo.aa'ua.aa 80.Oo 80.Oa 100.Oa L20.Qa Lua.aa boa.00 FPEQUEtuCY
A<MAIN8 PCtlNQA-,ICONS AV3RAQc LIlIIT CP Hllblkt4 TCI -RkiIIC-I I I            I i
<HZ>Note: Multiply all acceleration values by 1.18.NASHZHQTON PUBLZC POWER SUPP'Y~A NUCLEAR PBQZECT'O~
CS            i I
2 REACTOR BUILDING RESPONSE-ASYMMETRIC LOADING: CONTAINMZNT VESSEL AT STABILIZER TRUSS.LEVEL PZ GORE 5-7 c-131-I I I I THETA TRANSLAT(ON l44 wQ 4 g4 I40 EJ~Ek~0 El 10.00 00.00 l0.00 IOIOO IOO.04 l10.00 I10.04 IOO.OO FHE'OUQICV IIII>VERTICAL TRANSLATlON a ll4<ga IK 4I lal~ll lg4 h.04 10.00 IO.00 IO.00 00.00 IOO.04 l10.04 IlO.04 IOO 04 FtICOUf NCT (1IZ1 HORIZONTAL TRANSLATlON O 0 I 4l wQ 0't'b.04 10.04 IO.OO IO.OO 00.00 I04.04 I10.04 IIO.OO I00.00 f REQUCIICI NL1 Note: Multiply all acceleration values hy 3..18.WASHINGTON
i I
?UBLZC PCWER SUPPLY SY~NUCLKQt?BOJECT HO 2 REACTOR BUZLDZNG RESPONSE-ASYMMETRZ LOADZNG-CONTAZNMENT VESSEL AT MZD-SUBMERGENCE DEPTH PEGVRE 5-7 d-132-  
I    i I
i I  II>>
I IIII I    i          I I
                                                                        ~
I i
I I
I
                                                                                    ~
I I  I I!
Cl C
iik I    I I
I l
I 1  lllll I
                                                                    !  I
                                                                              .i l  lllll I  I  I iii                                  !    I I I              l    . 33cIi'I  ic  38 CJ CJ Q.QI
                                          ~  i  I  I i    i    I i    I I      1  i I  I  I  I    II          I  . I  I    I  I  i I I I        I  I    I    II          i  I    I  I    I  I  III I    I  l l          ll              I  I  l    I  I  ll!
i    I  Iilil                              I    I  llii Q.CQ1 3                  IQ                  3Q              IQQ PRSCUS'ICY CP VIGRATICiV,              ~
WSBZZ~
HCC PQ3X~~
        ~I. ~c
              ~      ~~~
HQ
                            ~
                                                                -139-


Theta Translation Ou~4?~O4 O I44 4I 4 Iu 4 IJ I?'II.uo Io.oo co.oo co.oo co.uo Ioo.oo I to.oo i co.uo I co.oo f RCOUEIICY (III I I~\Vertical Translation 4 Qu?O4 gu tu lu u tu tu4 to II'b.oo, co.oo co.uo cu.oo co.oo Ioo.oo Ico.uo I o.uo ccu.oo f RROUfIICY IIQ)4 Horizontal Translation t Ou 4 O 4 O I IC ceo 4J~~ay 4 4 O'b.uo Io.oo co.uo co.oo co.oo duo.oo cto.ou cco.oo cco.oo f RCOUCIICY UIK)Note: Multiply all acceleration values by 1.18.RLSEDiQTOH PQBLZC PCRER SUPPLY SiE'8 HU~PBCCEZT HO REACTOR BUZLDZNG RESPONSE ASYHMETRXC LOADZNG: OUTSXDE BUZLDZNG gALL ELEVATZON 521'133-THETA TRANSLATION ua?~t l 4l 4J IJa Co')I.04 IO.00 10.44 IO.00 10.04 100.04 IIO.04 I IO.00 100.04 FRCOUKIIC)
APPENDIX A ANALOGY BETWEEN ACOUSTIC AND STRUCTURAL BOUNDARY CONDITIONS A.l Introduction Response  of the analytical  model of the  4T system to two types  of sources, the pressure source and the acceler-ation source applied under the vent is presented in Section It is shown that the two sources excite different modes of the 4T system. The difference in the excited modes is a result of different boundary conditions at the pool vent interface which appear in the analytical solutions of the two problems. It is important to recognize this basic difference between the two types of sources because the 4TCO  key chugs which are simulated using the acceleration source contain the response of the system which cannot be simulated using the pressure source.
UIE)4 l4 ll VERTICAL TRANSLATION a 4la IK 4l 4l tJ 4lo go b.00 10 00'10.00 00.00 10.00 100.04 I 4.00 1%0.00 100.04 FRCOUCIICY IIIL)HORIZONTAL TRANSLATION a Qa?.Cl a I ga la i@a 4J tJ o i/4 tl.04)0.04'14.00 44.00 10.00 100.04 140.00 I 0.04 I<0.04 FRCOURIICT IIIL)iVote: Multiply all accelexation values by 1.18.MASHISGTCN PUBLIC PGWER SUPPLY SYS~NU~PRAT-C2 HQ 2 REACTOR BUILDING RESPONSE-KUGKY SYMMETRIC LOADING: CONTAINMENT VZSSEL AT MAT-ZGUBE 5-8a'134-  
It is  shown in this Appendix that the acceleration/
pressure sources of vibration in acoustic fluid vibration problems are analogous to the force/displacement (or acceler-ation) sources in structural vibration problems. To emphasize the difference in the boundary conditions and their importance in changing the characteristics of the response, a simple structural vibration problem is first presented in this Appendix, then the anology    is shown between  the two problems.
                                  -Al-


0 THETA TRANSLATION C)g IJ ce~0 CC Wg wa CJ D D)I.04)O.00'10.00 CO.00 ll.04 100,04 I CO.04 1%4.00 I M.00 FRCOUFNCT IIIt)VERTICAI TRANSLATION D Ia D I CC D W Wa CJ CI a COD)0.00 10,00 la.00 IO.00 100.00 I)0.00 I 0.00 Ill.00 FRROUENCY INZ)HORIZONTAL TRANSLATION COD D D I CC~a W>>wa CJ II.04)0.04 10.44 10.40 IO.04 100.04 I)0.04 I 0.04 104.04 FRKOUKtlCY (NR)iVote: Multiply aU.acceleration values by 1.18.)t)ASKPifQTON PUBIC PCQER SUPPLY SY~NU~PBQJE~D No 2 REACTOR BUILDING RESPONSE-NEARLY SYMMETRIC LOADING: RPV SUPPORT PX GUNK 5-8 b-135-  
A.2 Forced Lon itudinal Vibrations    of  a Prasmatic Bar The equation  of motion of 'ongitudinal vibrations of a prismatic bar due to external force p(x) f(t) and the formulation of its solution is shown in Figure A-l.
The eigenmodes  and eigenvalues  (frequencies) for two cases  of boundary conditions are shown in Figure A-2. It is seen that the fundamental mode frequency for Case 1 (fixed-free) is one half of the fundamental mode frequency for Case 2 (fixed-fixed) . It is shown in Figure A-3 that vibration of the bar due to a force applied at the free end is completely defined by the eigenmodes and frequencies corresponding to the Case 1 whereas the vibration of the bar due to a displacement motion prescribed at the free end is defined by the eigenmodes and frequencies corresponding to the Case 2. In other words, the characteristics of response of the bar due to an external force is completely different from the characteristics of response of the same bar due to an imposed (displacement) motion. The imposed displacement motion requires a change in the boundary condition at the location of imposed motion which alters the response characteristics of the system.
                                  -A2-


THETA TRANSLATiON R Oe CI 44 W ua QO~>>.QQ 20.00'l:l.00.<Q.QQ BQ.QQ IQO.QQ l20~JQ l40.OQ!OQ~OJ ePsOUf ICY tHZ'ORiZONTAL TRANSLATiON Cl p)gO~I laJ~~r.~00 20.00 40.00""0.00 80.00 I QQ.00 I 20.00 I'40.00 l 60.00 FRfQUfNCY (HZ]Note: Multiply all acceleration values by 1.18.MAKKHGTON PUBLZC PCWER SUPPLY SYS~iVUCXZiQL MAC HO 2 REACTOR BUZLDXNG RESPONSE-NEARLY SYMMETRZC LOAD XNG: CONTATNVZNT VESSEL AT STABILIZER TRUSS LEVEL rzavaz 5-8 c-136-I Theta Translation O Q4 Z O~gO ac~a lJ~Cg D.00 t0.00 t0.00 40.00 40.04 IM.00 I'CD.00'.10.09 I CD.00 FREOUENCt (hatt Vertical Translation O'?o I ggEh EC~a~N CJ Ef 0.04 t4,04 10,04 CCI.05 Ql.Oo l00.04'R0, 04 lWO.00 ICl.05 FRFOUENCT IHZI A a'orizontal Translation
A.3  A'nalog    Between Acoustic      Fluid Vibrations      and Structural Vi rations The  equation of motion      for the longitudinal vibrations of a prismatic bar        is analogous to the equation of motion of acoustic fluid.
'X tl I gR EC~n EJ~n QA 0.04'lO.00 lO.C4 sO.M 104.OQ I'CS,04 I%0.00 I CO.00 FREOUCHI:T IIIt)Note: Multiply all acceleration values by 1.18.WASHZHGTON PUBIC POWER'UPPLY SY~NUCLEAR PROJECT HO 2 REACTOR BUiLDING RESPONSE-K~LY FIGURE SYMMETRIC LOADING: CONTAINMENT g-8 d VESSEL AT MID-SUBMERGENCE DEPTH-137-  
p (x  t) +
                            ~
C.
                                  ~
Bp Qt
                                        ~ 0     Bu Qx where      p = u and    Q  Q  du x    (note'. duX    6X    E  AE  )
    .'. Pressu=e  Source    in  Acous  ic  =Zmposed D'splacement m Fluid Problems          Structural Vib at on Problems ard Accelerat'on (or p ess" e g ad'ent)          =-  Appl ied. force ~~
Source in Acoustic r lu'id Problems              Structural Vibration P=oblems A.4  Conclusion From  the above analogy,      it is  evident that the response characteristics of acoustic          fluid system excited by an acceleration source (which is analogous to externally applied force in structural vibrations) will be different from those excited by pressure source (which is analogous I
to imposed motion in structural vibrations) .
Since key chugs are properlv simulated using accel-eration source, for chugging load definition to bound the key chug data, an        acceleration source must        be used.
A.5  References.
A-l "Vibration      Problems  in Engineering",      Timoshenko, S.,
D. Van    Nostrand Company, Inc.
                                      -A3-


Theta Translation l O4~4 EJ S Eo 4 I Ea l 4 EO E44 IJ EJ Ea 4 4~I'b.ao lo.oo Ea.oo co.ao to.ao too.w toa.oa t O.oa too.aa FRZt)VZttCY lllZ)Vertical Translation EJ4 4 EJ 4 Ea 4 EK ill ill EJ~EJ 4 0,4 ta,aa.Ea.00 40.00 Eo.00 taa.00 I to.00 IEO.00 I to,oa FRft)VCttCY ItlZl Horizontal Translation W EO4 Et I Ea Ea E4 4 l4 4 EJ EJ Eo'b.oo to.oo Ea.ao EO.oo to.Oo too.ao t to.oo EEO.Oo t Eo.oa FRROVCttCY It)Z)Note: Multiply all acceleration values by 1.18.WZttsiKS~~
I I
PQBLZC PCWER SUPPLY SYS~NU~PROJEX.~HO z REACTOR BUIIEDING RESPONSE-NEARLY SYMMETRIC LOADING: OUTSIDE BUILDING HALL ELEVATION S21'GVBE 5-8e-138-RQF"RKPJC-I.a i i i I~A<MAIN8 PCtlNQA-,ICONS I I I I AV3RAQc LIlIIT CP Hllblkt4 TCI-RkiIIC-CS Cl C iik iii CJ CJ i i I I I i i I I i I I II>>I~i I~I I i I I I I I I l 1 lllll!I.i l lllll!I I I l.33cIi'I ic 38 I I I I I IIII!I I I I!Q.QI~i I I i i I i I I 1 i I I I I II I.I I I I i I I I I I I II i I I I I I III I I l l ll I I l I I ll!i I Iilil I I llii Q.CQ1 3 IQ PRSCUS'ICY CP VIGRATICiV,~3Q IQQ WSBZZ~PQ3X~~~~~~~HCC~I.~c HQ-139-
I


APPENDIX A ANALOGY BETWEEN ACOUSTIC AND STRUCTURAL BOUNDARY CONDITIONS A.l Introduction Response of the analytical model of the 4T system to two types of sources, the pressure source and the acceler-ation source applied under the vent is presented in Section It is shown that the two sources excite different modes of the 4T system.The difference in the excited modes is a result of different boundary conditions at the pool vent interface which appear in the analytical solutions of the two problems.It is important to recognize this basic difference between the two types of sources because the 4TCO key chugs which are simulated using the acceleration source contain the response of the system which cannot be simulated using the pressure source.It is shown in this Appendix that the acceleration/
pA 8~uu    ec u (x,o) l u(x,t)
pressure sources of vibration in acoustic fluid vibration problems are analogous to the force/displacement (or acceler-ation)sources in structural vibration problems.To emphasize the difference in the boundary conditions and their importance in changing the characteristics of the response, a simple structural vibration problem is first presented in this Appendix, then the anology is shown between the two problems.-Al-  
I'II I.
I AE Q x 2
(3 u f (t) dx, dx FOR CE S        ACTI N G ON ELEMENT dx AT (x, (SEE SKETCH          OF f) p (x)
BAR BELOW )
So lution fzom        Refe ence A-1 may ce su~+rimed as                        oU.ows:
          "~B.
Q u(x.t)
                              +    AP~
Q  u(x, gt t)
                                                      =  p(x) z((:)      Ecuatior.        of Motion (A-1) u(x t)                    X (x)  P    (t)                      Solut'or "or Homogeneous n~l,                                              Boundary Con"'t'ons (A-2) 2 X(x) = Eicenmodes oz the eicenvalue ecuation                        .'{  (x) + Z      x (x) ~  0 wim appropriate homoce..eous boundary c8ndition9 (e.g., Case 1 and 2 in Figure A-2) p  (t)  =  Solution oz the ecuation- o mot'on p (t) +U II' wi "5 appzopz'ate initial conditions o  f (t)/Ap whe e,, a 2=- =E/p Q3    ~  recuency oz vibration               of natural    mode n "- Kna g
p      =        p(x)  X  (x) dx            X (x) o                          o n"
(  )  = A cosG3
: r.          t+
n,"  '  B    SinG3 n.
                                +  ~
                                  ~Ap t f (tl) g      1 S~zU n (t-tl)1) dtl  1.
(A-3) where con      tents A, B a e obtained rom initial cond'tions                                and aze set erual      to "ezo'- tne system at zest at. t~0.
x=O i&#xc3;.I-APPLIED  FORCE    p(x)    '  ( t)
P=    MASS DEN SITY E = MODULU S  OF,  ELASTI CITY A = AREA OF    CROSS        SECTION WASHINGTON PUBLIC POWER SUPPLY SYSTEM            LONGZTUDZNAL TRANSZENT VZBRATZONS OF                      rImRE NUCLEAR PROJECT NO~ 2 A PRZSHATZC BAR                              A-1


A.2 Forced Lon itudinal Vibrations of a Prasmatic Bar The equation of motion of'ongitudinal vibrations of a prismatic bar due to external force p(x)f(t)and the formulation of its solution is shown in Figure A-l.The eigenmodes and eigenvalues (frequencies) for two cases of boundary conditions are shown in Figure A-2.It is seen that the fundamental mode frequency for Case 1 (fixed-free) is one half of the fundamental mode frequency for Case 2 (fixed-fixed)
4 Case 1                            Case 2 Fixed                                Free      Fixed                      Fixed x=o Boundary>    Conditions:
.It is shown in Figure A-3 that vibration of the bar due to a force applied at the free end is completely defined by the eigenmodes and frequencies corresponding to the Case 1 whereas the vibration of the bar due to a displacement motion prescribed at the free end is defined by the eigenmodes and frequencies corresponding to the Case 2.In other words, the characteristics of response of the bar due to an external force is completely different from the characteristics of response of the same bar due to an imposed (displacement) motion.The imposed displacement motion requires a change in the boundary condition at the location of imposed motion which alters the response characteristics of the system.-A2-  
U(o) = o, Bu. (g) =    o                  U(o) = o, U(z) = o Qx Eigenmodes:
(x) =  Sin~
07t x xn (x) =  Sin-n = 1,3,5                                    n =  1(2(3 11 = 2 Eiaenva1ues:
K nW                                          n7l n    2g,                                   K n
WASHZNGTON PUBLZC POWER SUPPLY SYSTEN  EIGENMODES A'ND EIGENVALUES FOR TWO    FZGURE CASES OF BOUNDARY CONDITIONS        A-2 NUCLEAR PK4ECT  NO  2
                                          -A5-


A.3 A'nalog Between Acoustic Fluid Vibrations and Structural Vi rations The equation of motion for the longitudinal vibrations of a prismatic bar is analogous to the equation of motion of acoustic fluid.Bp Bu p (x t)+~~~0 C.Qt Qx where p=u and Q Q-(note'6)du.du x X X E AE.'.Pressu=e Source in Acous ic Fluid Problems=Zmposed D'splacement m Structural Vib at on Problems ard Accelerat'on (or p ess" e g ad'ent)=-Appl ied.force~~Source in Acoustic r lu'id Problems Structural Vibration P=oblems A.4 Conclusion From the above analogy, it is evident that the response characteristics of acoustic fluid system excited by an acceleration source (which is analogous to externally applied force in structural vibrations) will be different from those excited by pressure source (which is analogous I to imposed motion in structural vibrations)
Problem  l                                                            Problem    2 Applied Force at Free          L'nd                                    Imposed Displacememt        at  Free End A, L",P                                                                  Ai F(P                      o(t) e P(t)                         I x=0                                  R                                x=0 n-l K
.Since key chugs are properlv simulated using accel-eration source, for chugging load definition to bound the key chug data, an acceleration source must be used.A.5 References.
    )
A-l"Vibration Problems in Engineering", Timoshenko, S., D.Van Nostrand Company, Inc.-A3-I I I u (x,o)l 8 u pA~u ec So lution f zom Q u(x.t)"~B.u(x t)n~l, u(x,t)I 2 I'I (3 u!I AE-dx, I.Q x p (x)f (t)dx FOR CE S ACTI N G ON ELEMENT dx AT (x, f)(SEE SKETCH OF Q u(x, t)+AP~=p(x)z((:)gt X (x)P (t)Ecuatior.of Motion (A-1)Solut'or"or Homogeneous Boundary Con"'t'ons (A-2)BAR BELOW)Refe ence A-1 may ce su~+rimed as oU.ows: X(x)=Eicenmodes oz the eicenvalue ecuation.'{(x)+Z x (x)~0 2 wim appropriate homoce..eous boundary c8ndition9 (e.g., Case 1 and 2 in Figure A-2)p (t)=Solution oz the ecuation-o mot'on p (t)+U II'o f (t)/Ap wi"5 appzopz'ate initial conditions whe e,, a=E/p 2=-Q3~recuency oz vibration of natural mode n"-Kna g p=p(x)X (x)dx X (x)o o ()=A cosG3 t+B SinG3 n" r.n,"'n.+~t f (tl)S~zU (t-tl)dtl~Ap g 1 n 1)1.(A-3)where con tents A, B a e obtained rom initial cond'tions and aze set erual to"ezo'-tne system at zest at.t~0.x=O i&#xc3;.I-APPLIED FORCE p(x)'(t)P=MASS DEN SITY E=MODULU S OF, ELASTI CITY A=AREA OF CROSS SECTION WASHINGTON PUBLIC POWER SUPPLY SYSTEM NUCLEAR PROJECT NO~2 LONGZTUDZNAL TRANSZENT VZBRATZONS OF A PRZSHATZC BAR rImRE A-1 4
Pl u (x,t) =   n=l,3, pAX Z
Fixed Case 1 Free Fixed Case 2 Fixed x=o Boundary>Conditions:
S.,   G3
U(o)=o,-.(g)=o Bu Qx U(o)=o, U(z)=o Eigenmodes:
                                                    >< (u)j (t)               u (x~t)   p  ul(x, t)   + u 2 (x, t) u>(x, t) ~ ~ D(t) where, I( x H
Z (x)=Sin~07t x n=1,3,5 x (x)=Sin-n n=1(2(3 11=2 Eiaenva1ues:
xn (x) ~  sin n-2-j)-
nW K n 2g, n7l K n WASHZNGTON PUBLZC POWER SUPPLY SYSTEN EIGENMODES A'ND EIGENVALUES FOR TWO CASES OF BOUNDARY CONDITIONS NUCLEAR PK4ECT NO 2-A5-FZGURE A-2  
OO Pu (t>
0 I ri(t~> S(.uCJ n (t t>.)
l'   dtj                    where, 0> Q xn (x)     sin- n ITx g
OA H t3 OO              = 8/p lu  <t>
f 0
ri<t() SsuCJ <t-tZ> ritZ R
                                                                                  '3  n nT(a g
NH gK                                                                                  D(t)    d  D dt WO  Note that the response characteristics (x,4) ) of the same bar are different in the above two an  problems. The series solution of Problem                        l i9 based on the boundary conditions of Case A-2) . The series part of the solution (U2 (x. t) ) of Problem 2 is based on the boundary n'Figure l
conditions of      Case 2     (Figure A-2).


Problem l Applied Force at Free L'nd Problem 2 Imposed Displacememt at Free End x=0 A, L",P-e P(t)R Ai F(P I x=0 o(t)K)Pl n-l u (x,t)=-Z><(u)j (t)pAX n=l,3, S., G3 where, u (x~t)p ul(x, t)+u 2 (x, t)u>(x, t)~~D(t)H OO 0>Q OA H t3 OO R NH gK WO an x (x)~sin-2-j)-n I(x n Pu (t>I ri(t~>S(.uCJ (t t>.)dtj 0 n l'=8/p where, x (x)sin-n ITx n g lu<t>f ri<t()SsuCJ<t-tZ>ritZ 0 nT(a'3 n g D(t)d D dt Note that the response characteristics (x,4))of the same bar are dif ferent in the above two problems.The series solution of Problem l i9 based on the boundary conditions of Case l n'Figure A-2).The series part of the solution (U2 (x.t))of Problem 2 is based on the boundary conditions of Case 2 (Figure A-2).
)
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Latest revision as of 08:27, 4 February 2020

Nonproprietary Version of Chugging Loads-Revised Definition & Application Methodology for Mark II Containments (Based on 4TCO Test Results).
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Issue date: 07/21/1981
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Text

Chugging Loads Revised Definition and Application Methodology for Mark I I Containments (Based on 4TCO Test Results)

TECHNICAL REPORT flQ (5 p

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Q0 Burns and Roe, Inc. 'f08040527 Engineers 8 Constructors Woodbury, New York PDR ADOCK 810724 05000397 PDR

~ ~ II LIST OF FIGURES FIGURE NO. DESCRIPTION PAGE NO.

5- 4 Fluid-Structure Boundary - WNP-2 126 Suppression Pool 5- 5 Reactor Building Model 127 5- 6 Envelopes of Calculated Responses for 128 WNP-2, and Measured Responses at JAERI-Containment at Vent Exit Elevation 5-7a Reactor Building Response 'i 29 Asymmetric Loading: Containment Vessel at Mat 5-7b Reactor Building Response 130 Asymmetric Loading: RPV Support 5-7c Reactor Building Response 131 Asymmetric Loading: Containment Vessel at Stabilizer Truss Level 5-7d Reactor Building Response 132.

Asymmetric Zoading: Containment Vessel at. Mid-Submergence Depth 5-7e Reactor Building Response- 133 Asymmetric Loading: Outside Building Wall Elevation 5-8a Building Response 521'eactor 134 Nearly Symmetric Zoading:

Containment Vessel at Mat 5-8b Reactor Building Response 135 Nearly Symmetric Loading:

RPV Support 5-8c Reactor Building Response 136 Nearly Symmetric Loading:

Containment Vessel at Stabilizer Truss Level 5-8d Reactor Building Response 137 Nearly Symmetric Loading:

Containment Vessel at Mid-Submergence Depth 5-8e Reactor Building Response 138 Nearly Symmetric Zoading:

Outside Building Wall Elevation 5-9 Tolerance Observations 521'ibration 139

I Su~arur Tests were conducted during 1975/76 by General Electric Company (GE) in their 4T test facility for the domestic Mark ZZ utilities for the purpose of evaluating the containment pool dynamic effects resulting from a postulated loss-of-coolant accident (LOCA). Based on chugging data recorded during these tests, an empirical load definition was deve-.

loped This load definition was based on direct application of pressure traces measured on the boundary of the 4T test I

facility to the wetted perimeter of Mark ZZ containments and, as a result, could not account for differences between the 4T test facility and the Mark ZZ containments with respect. to vent length (vent acoustics), suppression. pool geometry (pool acoustics) and flexibility of suppression pool structural boundaries. Zn order to account for these differences, it became necessary 'to develop a chugging load definition at the "source" (i.e., at vent exit) .

Such an improved. chugging load definition was'eveloped together with the application methodology for Mark ZZ contain-for specific application to Washington PubLic Power 'ents Supply: System - Nuclear Project No. 2 (WNP-2). This defini-tion was based on conclusions reached after evaluation of tests conducted to assess effects of steam-condensation pheno-mena in Mark ZZ type (over/under) pressure suppression systems. Two main conclusions from these tests were:.

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a) chugging effects are mainly due to the sudden (impulsive) collapse of the steam-water interface which occurs near the vent exit during the chugging regime and, in view of this, chugging could be repre-sented by an impulsive load applied there; and, "b) bulk fluid motions during chugging being relatively small, a linear formulation (small displacements/

velocities) is adequate for predicting the dynamic pressures induced in the far field (away from vent exit) and the dynamic response of the pool boundary structures.

A single vent design load specification was derived to bound, statistically, the 4T test data supplied by GE as representative of Hark II conditions during LOCA. The appli-cation methodology for NNP-2 containment was also developed, properly accounting for all important plant specific parameters: length of downcomer vents (vent acoustics), 3-D multi-vent suppression pool geometry with a sloped bottom (pool acoustics) and the flexibility of the suppression pool structural boundary.

Two loading conditions were developed for, and considered'n the design of, the multi-vent configuration of WNP-2: a nearly symmetrical loading and an asymmetric loading.

I Additional condensation tests were performed during 1979-1980 by GE for the U.S. Mark ZZ Owners Group, in a modified configuration of the 4T test facility, known as the.

"4TCO" test facility. Selected and" conservatively represen-tative (most severe) 4TCO chugging data supplied by GE were evaluated/analyzed with the objectives:

a) to examine in light of the 4TCO data, the adequacy of the existing improved chugging load definition; and, b) to revise, where necessary, this (improved) load definition and the application methodology for the Mark lX containment of NNP-2.

Analysis of the 4TCO chugging data, as well as of the chugging data which became available from other tests during the same time period, resulted in the following main findings:

a) the impulsive nature of chugging (sudden collapse of the steam-water interface) was confirmed; b) it was determined that the 4TCO data included some stronger/larger amplitude chugs which exhibited characteristics (frequency content, spatial dis-tribution) different from those of the 4T chugs; c) the random nature of chugging was confirmed;

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d) the strength/amplitude of chugging, although random, appeared to be dependent on system conditions, i.e.,

stronger chugs appeared to cluster within limited time windows corresponding to specific system con-ditions.

As a consequence, the following revisions to the single vent design load specification were implemented:

the "source" load was defined as an impulsive pressure gradient (acceleration) applied over the steam-water interface at vent exit; this resulted in better matching of the characteristics exhibited by the stronger 4TCO chugs; to account for the random nature of the chug strength/amplitude each strongest ("key") chug was averaged (in terms of Fourier amplitude spectrum) with the largest neighboring ("companion") chug to obtain an "average" or "mean" chug for each time win-dow for which 4TCO chugging data were supplied.

Zt is significant to note that the single vent design "source" load developed for WNP-2 in fact envelopes the 4TCO data at almost all locations of the 4TCO tank wetted boundary and throughout the frequency range of interest; it also enve-lopes the 4T data.

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The two loading conditions originally developed for'NP-2 were basically retained (a nearly symmetrical loading and an asymmetric loading) in a manner compatible with the revised single vent design load specification. In ordex to account for physical realities observed during steam-condensation tests in multi-vent configuxations (JAERI, CREARE), vent-desynchronization is specified for both these loading con-ditions adopting the approach used in the Long Term Improved Generic Chugging Load Definition developed by GE for Hark II Owners Group, in a- manner compatible with the two loading con-ditions for WNP-2.

To verify the adequacy of chug strength averaging and of vent desynchronization, the dynamic pressures calculated on the wetted wetwell wall of WNP-2 were compared with wall pressures recorded during large-amplitude chugs in the 7-vent full scale tests conducted by the Japan Atomic Energy Research Institute (JAERI) in a test facility representative of the Mark ZZ geometry. The calculated pressures were found to bound the JAERI data.

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1.0 Introduction and Back round The original chugging load def inition was developed using chugging data recorded during the 4T tests conducted by General Electric Company (GE) for the domestic Mark II utili-ties in the 4T (single vent/unit cell) test facility during late 1975 and early 1976, [1]. This load definition was based on direct application of pressure traces measured on the boun-dary of the 4T test facility to the wetted perimeter of Hark II containments, [2] . It soon became apparent that this method of application of 4T data to Mark II containments did not account for differences between the 4T test facility and the Mark II containments with respect to vent length (vent acoustics),. single vent versus multi-vent suppression pool geometry and flexibility of suppression pool structural boun-daries. In order to account for these differences, it became necessary to develop a chugging load definition at the "source", i.,e., at vent exits.

Because of schedule constraints, such an improved chugging load definition was developed, together with the application methodology to Hark II containments, for specific application to Washington Public Power Supply System Nuclear Project No. 2 (WNP2) during 1978/79, f 3, 4] . A single vent design load specif ication was derived to bound, statistically, the 4T test data supplied as being representative of Mark II containment conditions expected during a postulated ZOCA.

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The single vent design load was defined as a pressure source at the vent exit and since its definition was indepen-dent of the 4T test facility characteristics which were dif-from those of WNP-2 (vent length, suppression pool 'erent geometry and flexibility of suppression pool structural boundary) it was assumed to be directly transferable to vent exits in the WNP-2 containment. Two loading conditions were developed and considered in the design of WNP 2: a nearly symmetrical loading and an asymmetric loading. The applica-tion methodology for WNP-2 containment accounted for the plant specific parameters governing the response: length of down-comer vents, 3-D multi-vent suppression pool geometry with a sloped bottom, and the flexibility of suppression pool struc-tural boundary (steel containment, the concrete pedestal and the foundation mat).

Zn 1979-1980, additional condensation tests were per-formed by GE for the U.S. Nark XX Owners Group in a modified configuration of the 4T test facility, known as the "4TCO" test facility (5]. The original, 4T test facility included a drywell located adjacent to the wetwell, a confi'guration which required a vent with three bends and a total length of about 90 feet. Zn the 4TCO facility, the drywell vessel was mounted

above the wetwell to represent 'he over/under pressure suppression configuration with straight vertical vent, approximately 45'ong, representative of Mark ZZ plants.

Although the 4TCO tests were planned and performed with the objective of gathering test data to be used for confirmation of the DFFR Condensation Oscillation (C.O.) load definition, the data were recorded for the entire transient including chugging, thus providing an additional data base for chugging as well.

Selected chugging data obtained from regions of the 4TCO tests during which the most severe chugging effects were recorded were made available by General Electric Company as being conservatively representative for Mark lZ plants during the chugging regime. The 4TCO chugging data supplied, (6],

are evaluated and results and conclusions piesented in this report. The conclusions of this evaluation together with the conclusions reached following the evaluation of multi-vent test data by GE and presented in Reference 7 report (regarding the random nature of chug strength and chug initiation time from vent-to-vent during a pool chug in a multi-vent configuration) are used in this report:

(a) to examine in light of the 4TCO data, the ade-quacy of the (improved) chugging load definition developed previously, using 4T data, for applica-tion to Vii1P-2 [3g 4] I and

(b) to revise, where necessary, this (improved) chugging load definition and the application methodology for the Mark II containment of WNP-2.

The 4TCO chugging data supplied by General Electric and the multi-vent tests evaluated by General Electric are identified in Chapter 2..

The evaluation of 4TCO chugging data including the analytical studies performed in the process of data evaluation and the characteristics of single vent 4TCO chugs derived from data evaluation/analysis are described in Chapter 3. The eva-luation shows that revision in the improved chugging load definition is necessary.

The revised single vent load definition and the revised application methodology for the Mark II containment of WNP-2 based on the conclusions reached following the eva-luation of'TCO test data (presented in Chapter 3) and on the conclusions reached from the evaluation of multi-vent: test data (presented by General Electric in Reference 7) are pre-sented in Chapter 4.

The results of application of the revised chugging load definition to the WNP-2 plant (i.e., reactor building/containment structure responses) are presented in Chapter 5.

2.0 The New Chu in Data 2..1 The Sin le Vent 4TCO Test Data The 4TCO test facility, test variables, test matrix, test instrumentation and test results are described in detail in Reference 5. The- test facility is shown in Figure 2-1.

The wetwell pressure transducer locations are shown in Figure 2 2~

The pressure time histories recorded at the bottom center (channe1 28) were scanned by General Electric Company to identify significant chugs. Two hundred ninety-seven chugs were identified (See Table 4-2 of Reference 7).* Table 2-1 provides a summary of the 4TCO chug data compiled from infor-mation provided by General Electric [8] in November 1980.

Table 2-1 identifies seven regions from six tests which recorded the largest chugs (based on the bottom center pressure (BCP) mean square power (msp) and peak over pressure

  • information from Reference 8 is provided in Tables 2-1 and 2-2 of this report for identification of chug numbers and time window numbers used in this report and to establish their correspondence with information subsequently published in Reference 7.

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(POP)) of all 4TCO tests. General Electric Company selected 7 key chugs (one for each of the seven regions) because the power" spectral density (PSD) envelope of these chugs closely approximated the PSD envelope of the entire sample of chugs

[7, 8]. Several chugs (called neighboring chugs) occurring before or after each of the seven key chugs together with the key chug define a region, or a time window making seven regions [8]. The region numbers and the number of chugs in each region are also identified in Table 2-1., A total of 35 chugs in seven regions or time windows were selected by General Electric Company as the chugging data base [8]. The 4TCO chugging data base identification parameters are shown in Table 2-2.

The 4TCO bottom center pressure time histories for the thirty-five .chugs were recorded on magnetic tapes at .4939 millisecond interval and supplied to Burns and Roe [9]. In addition, the data from all the 28 replay channels from all tests were digitized at millisecond interval and supplied on 1

magnetic tapes to the Mark II Owners Group [6]. The data for the 35 chugs of the chugging data base were obtained from these tapes for the evaluation presented in Chapter 3.

2.2 Multi-vent Test Data Multi-vent test data from two test programs (the CREARE subscale tests and the JAERI full scale tests) have I

recently become available. General Electric Company has eva-luated these multi-vent test data for the Mark II Owners Group and has incorporated the significant findings of multi-vent effects (the random nature of chug strength and chug ini-tiation time from vent-to-vent during a pool chug in a multi-vent configuration) in the Generic Chugging Load Definition Report [7]. The results of these data evaluations and conclu-sions reached will also be adopted for the chugging load defi-nition for WNP-2..

BURNS AND ROE g. lNC ~ PROPRZETARY 3.0 4TCO Chu in Data Evaluation and Anal tical Studies 3.,1 Xntroduction 3.2 4TCO Chu in Data Evaluation 3.2.1 Waveform Characteristics of Boundary Pressures BVRNS AND ROE I INC ~ PROPRXETARY BURNS AND ROE, lHC., PROPRIETARY 3.2.2 Spatial Dist:ribuhion of Boundary Pressures

BURNS AND ROEI XNC. PROPRXETARY I

)

CHUGGING LOADS REVISED DEFXNITION AND APPLICATION METHODOLOGY FOR MARK II CONTAINMENTS (based on 4TCO test results)

TECHNICAL REPORT Prepared By BURNS AND ROE'NC.

for'pplication to WASHINGTON PUBLIC POWER SUPPLY SYSTEM NUCLEAR PROJECT NO. 2 Prepared By:

M. M. Ettouney Senior Civil Engineer Approved By:

B. Bedrosian l Assistant Chief Civil Engineer F. J Patti Chief Nuclear Engineer Submitted By:

J Verderber ect Engineering Manager

!Date:

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BURNS AND ROE g INC .

DISCLAIMER OF RESPONSIBILITY Neither the Burns and Roe, Xnc. nor its affiliates or related entities nor any of the contributors to this document make any warranty or representation (expressed or implied) with respect to the accuracy, completeness, or usefullness of'he information contained in this document, or that the use of such information may not infringe privately owned rights; nor do they assume any reponsibility for liability or damage of any kind which may result from the use of any of the infor-mation contained in this document.,

1-

BURNS AND ROE, INC .

PROPRIETARv NOTICE This document contains proprietary information of Burns and Roe, Inc. and it is not to be reproduced or furnished to third parties nor the information contained therein utilized, in whole or in part, without the prior express written per-mission of Burns and Roe, Inc.,

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GENERAL ELECTRIC COMPANY DISCLAIMER OF RESPONSIBILITY This document contains proprietary information of General Electric Company pursuant to contracts with certain utilities owning plants utilizing Mark ZI Containments. Except as otherwise provided in such contracts, the General Electric Company does not:

A. Make any warranty or representation, expressed or implied, with respect to the accuracy, completeness, or usefulness of the proprietary information con-tained in this document, or that the use of any proprietary information disclosed in this document may not infringe privately owned rights; B. Assume any responsibility for liability or damage which may result from the use of any proprietary information disclosed in this document; or C. Imply that a plant designed in accordance with the proprietary information found in this document will be licensed by the United States Nuclear- Regulatory Commission or that it will comply with Federal, State or Local regulations.

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GENERAZ EZECTRXC COMPANY PROPRIETARY NOTICE This document contains proprietary information of the General Electric Company and it is not to be reproduced or furnished to third parties nor the information contained therein uti-lized, in whole. or in part, without the prior express written permission of General Electric Company.

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TABLE OF CONTENTS Item Paca e . No .

Disclaimers Proprietary Notices Table of Contents, List- of Tables V111 Zist; of Figures S'ummary 1.0 Introduction and Background 2.0 The New Chugging Data 10 2.1 The Single Vent 4TCO Test Data 10 2.2 Multi-vent Test Data 11 3.0 4TCO Chugging Data Evaluation and Analytical 13 Studies

3. 1 Xntroduction 13 3.2 4TCO Chugging Data Evaluation 13 3.,2.1 Naveform Characteristics of 13 Boundary Pressures 3.2.2 Spatial Distribution of Boundary 15 Pressures 3.2.3 Summary of" Characteristics of the 19 4TCO Chugs 3.3 Analytical Studies and Correlation with Test Data 3.3.1 Finite Element Model of the 4TCO 21 System 3.3.2 Response Sensitivity to Source 22 Parameters and Correlation with Test Data 3.3.3 Response Sensitivity to System Parameters and Correlation with Test Data

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TABLE OF CONTENTS Item Pacae Na.

3. 4 Conclusions 33 4.0 Revised Chugging Load Definition 35 4.1 Introduction 35 4.2 Summary Review of the (Improved) Chugging 36 Load Definition Based on 4T Test Data 4.3 Revisions Reauired in the (Improved) 39 Chugging Load Definition to Account for the New Chugging Data 4.3.1 Revision Zn Source Impulse Based on 39 4TCO Data 4.3.2 Revision Zn Source Strength Based on 40 4TCO and Multi-vent Data 4.3.3 Revision Zn Application Methodology 43 For Mark ZI Containments Based on Multi-vent Test Data 4.4 Single Vent. Design Zoad Specification 43 4.,4 ..1 Required Average Spectrum 43 4.,4.2 Design Impulsive Sources 4.4.3 Summary of Single Vent Design Load 47 Specification 4.5 Application of Single Vent Load Specification 48 to Multi-vent Mark IZ Containments 4.5.1 Spatial Variation of Chug Strengths 48 4.5.2 Desynchronization of Chugs

'4 ~ 6 Summary of Comperative Review Between 'NNP-2'1 and Mark ZI Generic Chugging Load Definitions 4.6.1 Computational Methodologies 51

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TABLE OP CONTENTS Item ~pa e No.

4.6.2 WNP-2 Plant Unique Characteristics 53 4.6..3 Application Methodologies for 55 Mark II Containments 5.0 WNP-2 Reactor Building Response to Chugging Loads 5.1 Introduction 57 5.2 Theoretical Background 57 5.2.1 Treatment of Multiple Vents 5 ..3 WNP-2 Response to Chugg ing Loads 60 5.3.1 Containment Wall Design Pressures and Comparison with Test Data 5.3.2 Structural Response 63 5.4 Discussion of Calculated Structural 63 Response to Chugging Loads 6.0 List of References 66 Tables Figures Appendix A Analogy Between Acoustic and Al-A6 Structural Boundary Conditions

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jIST OF TABLES TABIE NO. DESCRIPTION PAGE NO.

2-1 Summary of. 4TCO Chug Data 70 2-2 4TCO Chugging Data Base Identif ication Parameters 71'-1 Identification of the Companion 72 Chug Used for Averaging with Key Chug 4-2 Single Vent Design Source 73 Definition 5-1 Chug Start Times for Random 7'4 Phasing 5-2 Maximum Rigid Hall Pressures on 75 WNP-2 Containment at Vent Exit Elevation (Node 15) 5-3 4TCO Pressure Maximums and 76 Average at Channel 20 5-4 JAERI Peak Positive Chugging 77 Pressure Amplitudes 5-5 Maximum Computed Accelerations 78 for NNP-2 Reactor Building

I LIST OF FIGURES FIGURE NO. DESCRIPTION PAGE NO.

2-1 Test Configuration for Nark El 79 Condensation Oscillation (4TCO)

Tests 2-2 4TCO Tests - Wetwell Pressure 80 Transducer Locations 3-1 Comparison of Pressures and 81

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Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No. 1 3-2 Comparison of Pressures and 82 Fourier Amplitude Spectra of Key Chug and A Neighboring Chug Time Window No. 2 3-3 Comparison of Pressures and 83 Fourier Amplitude Spectra of Key Chug and A Neighboring Chug Time. Window No. 3 3-4 Comparison of Pressures and 84 Fourier Amplitude Spectra of Key Chug and A Neighboring Chug-Time Window No., 4 3-5 Comparison of Pressures and 85 Fourier Amplitude Spectra of 'Key Chug and A Neighboring Chug Time Window No. 5 3-6 Comparison of Pressures and 86 Fourier Amplitude Spectra of Key Chug and A Neighboring Chug Time Window No.. 6 3-7 Comparison of Pressures and 87 Fourier Amplitude Spectra of Key Chug and A Neighboring Chug Time Window No. 7 3-8 Comparison of Pressures Measured 88 at Channel 28 and Channel 26 During Time Window No. 6, Chug 52

I LIST OF FIGURES FIGURE NO. DESCRIPTION PAGE NO-3-9 Comparison of Pressures Measured at 89 Channel 24 and Channel 20 During Time Window No. 6, Chug 52 3-10 Phase Relationship Between Pressures 90 Measured at Channel 20 and Channel 28 Versus Frequency Time Window No. 1 3-11 Phase Relationship Between Pressures 91 Measured at Channel 20 and Channel 28 Versus Frequency Time Window No., 'l 3-12 Ratios of Fourier Amplitudes of 92 Pressures Measured at Channel 28/Channel 20 3-13 Vertical Distribution of Peak 93 Pressures Six Chugs, Time Window No. 1 3-14 Vertical Distribution of Peak 94 Fourier Amplitudes of Pressures-Two Chugs Time Window No. 1 3-15 Ratio of Fourier Amplitudes of 95 Pressures Measured at Channel 20 and Channel 21 3-16 Comparison of 4TCO and 4T Data 96 Pressures Measured at Bottom Center 3-17a Vent Pool Model (Fluid Elements) 97 3-17b Structural Finite Element Model 98 of 4TCO Tank 3-18 Schematic Presentation of 99 Pressure Source at Vent Exit in 4TCO System 3-19 Fourier Amplitude Spectrum of 100 Pressure Calculated at Channel 28 with Pressure Source at Vent Exit

LIST OF FIGURES FIGURE NO. DESCRIPTION PAGE NO.

3-20 Schematic Presentation of 101 Acceleration Source at Three Locations in 4TCO System 3-21 Fourier Amplitude Spectrum of 102 Pressure Calculated at 3-22 Fourier Amplitude Spectrum of 103 Pressure Calculated at Channel 28 with Acceleration Source Located 6'bove Bottom 3-23 Fo uri er Amp 1 i tude Spectrum o f 104 Pressure Calculated at Channel 28 with Acceleration Souxce Located 3'bove Bottom 3-24 Comparison of Vertical 105 Distxibution of Normalized Maximum Pxessure Calculated with Pressure and Acceleration Sources 3-25 Vertical Distribution of Fourier 106 Amplitudes of Pressures Calculated with Acceleration Sour'ce at Vent Exit 3-26 Fourier Amplitude Spectrum of 107 Px'essure at Channel 28 with 1418 fps, Decreased from 1600 fps, Figure 3-21 3-27 Fourier Amplitude Spectrum of 108 Pressure at Channel 28 with 2400 fps, Decreased from 4800 fps, Figure 3-21 3-28 Phase Relationship Between Pxessures 109 Calculated at Channel 20 and Channel 28 Versus Frequency 3-29 Cw Versus Resonant Frequency'- 110 Analytical Curve 6 Its Applz.cation

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ZIST OF FIGURES FIGURE NO. DESCRIPTION PAGE NO 4-1 Comparison of Fourier Spectra of Pressures of Key Chug and Companion Chug Measured at Channel 28 Time Window No. 2 4-2 Comparison of Fourier Spectra of 112 Pressures of Key Chug and Companion Chug Measured at Channel 28 Window No. 3 'ime 4-3 Design Spectrum and Required Average 113 Spectrum Channel 28 4-4 Design Spectrum and Required Average 114 Spectrum Channel 26 Design Spectrum and Required Average 115 Spectrum Channel 24 Design Spectrum and Required Average 116 Spectrum Channel 20 4-7 Design Spectrum and Required Envelope 117 Spectrum Channel 28 4-8 Design Spectrum and Required Envelope 118 Spectrum Channel 26 4-9 Design Spectrum and Required Envelope 119 Spectrum Channel 24 4-10 Design Spectrum and Required Envelope 120 Spectrum Channel 20 4-11 Source Strength Distribution- 121 Asymmetric Zoading Case 4-12 Source Strength Distribution 122 Nearly Symmetric Loading Case 5-1 General Corss-Section of WNP-2 Reactor Building 5-2 Wetwell Plan View at Elevation of 123 Downcomer Exits 5-3 Finite Element Model of WNP-2 124 Suppression Pool with a Radial Row of Three Vents

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BURNS AN D ROE t INC ~ PROPRIETARY 4

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BURNS AND ROE, INC. PROPRIETARY BURNS AND ROE'NC. PROPRIETARY 3.2 3 Summary of Characteristics of the 4TCO Chugs Ke Chu s

BURNS AND ROE'NC. PROPRlETARY Nei hborin Chu s and the Ori inal 4T Chu s I

BURNS AND ROE I INC ~ PROPRIETARY 3.3 Anal tical Studies and Correlation with Test Data 3 3 1 Finite Element'odel oC the 4TCO System

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BURNS AND ROE, INC. PROPRIETARY 3.3.Z Response Sensitivity to Source Parameters . and

.Corelation with Test Data

BURNS AND ROE, ZNC. PROPRlETARY Waveform Characteristics of Boundar Pressures Pressure Source

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BURNS AND ROE, INC. PROPRXETARY Acceleration/Pressure Gradient Source avocation of Acceleration Source I

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BURNS AND ROE, INC. PROPRXETARY Saatial Distribution of Boundar Pressures and Correlation with Test Data BURNS AND ROE'NC. PROPRZETARY I

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BURNS AND ROE'NC. PROPRIETARY Conclusion 3.3.,3 Response. Sensitivity to System Parameters and Correlation with Test Data

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BURNS AND ROE, INC. PROPRIETARY Sensitivity oC the Response Frequencies to C, s C w

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BURNS AND ROE ~ INC ~ PROPRI ETARY

BURNS AND ROE, IN'ROPRIETARY Sensitivity of the FSI Mode Frequency to C W

BURNS AND ROE ~ INC ~ PROPRI ETARY

BURNS AND ROE, INC. PROPRIETARY Damping in the 4TCO System (D , D )

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BURNS AND ROE g INC ~ PROPRIETARY 3.4 Conclusions

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BURNS AND ROE'NC. PROPRIETARY I

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BURNS AND ROE, ENC. PROPRlETARY 4.0 Revised Chu in Zoad Definition 4.1 introduction I

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BURNS AND ROE, ENC. PROPRXETARY 4.2 Summary Review of the (Zm x'oved) Chu in Toad Definition Based on 4T Test Data l

BURNS AND ROE, XNC.. PROPRXETARY

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BURNS AND ROE, INC . PROP RIETARv I

BURNS AND ROE, INC. PROPRZETARY 4.3 Definition to Account for the New Chu in Data 4.3.1 Revision in Source Impulse Based on 4TCO Data

BURNS AND ROE'NC. PROPRIETARY 4.3 2 Revision in Source Strength Based on 4TCO and Nulti-vent Data I

BURNS AND ROE g XNC. PROPRIETARY

BURNS AND ROE'NC. PROPRlETARY

BURNS AND ROE~ INC.. PROPRIETARY 4.3..3 Revision in Application Methodology for Mark Containments Based on Multi-vent Test Data II

4. 4'in le Vent Desi n Goad Specification 4.4.1 Required Average Spectrum I

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BURNS AND ROE, ZHC. PROPRXETARY

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BURNS AND ROE'HC. PROPRXETARZ 4.4.Z Design Xmpulsive Sources I

BURNS AND ROE, INC ~ PROPRIETARY BURNS, AND ROE g INC. PROPRXETARY' 4.3'ummary of Single Vent Design Koad Specification

BURNS AND ROE g XNC. PROPRXETARY 4.5 Application of Single Vent Zoad Specification to u x-vent i ar ontaxnments 4.5.1 Spatial Variation of Chug StrengthsC Asymmetric foading Case Nearly Symmetric Zoading Case

BURNS'ND ROE, INC. PROPRIETARY 4.5.2 Desynchronization of Chugs BURNS AND ROE ~ lNC. PROPRXETARY BURNS AND ROE g INC. PROPRIETARY 4.6 Summar of Com arative Review Between 'WNP-2'nd Nark II Generic Chu in Eoad Definitzons 4 6.1 Computational Methodologies

'WNP-2'ethodolo The .computation methodology used for the source extraction from the 4TCO data and for its application to the multi-vent WNP-2 containment are similar to those used in Reference 3. Namely, a fully coupled model representing the vent steam/suppression pool water/4TCO tank structure was used for source extraction, thus resulting in an impulsive source free of the test facility characteristics. Similarly, the computational methodology 'for application of the "source"

design load to the multi-vent geometry of WNP-2 containment utilized a fully coupled model which directly accounted for.

all important plant specific parameters: length of downcomer vents (vent acoustics), 3-D multi-vent suppression pool geometry with a sloped bottom (pool acoustics) and the flexi-bility of the suppression pool structural boundaries.

Generic Methodolo Subsequent to the development of the above methodo-logy [3J', General Electric Company presented an improved chugging methodology [18] and more recently the generic chugging load definition based on the 4TCO and multi-vent test data: [7] . The methodology developed by GE [18,.7j is based on principles which are similar to those of, the WNP-2 methodo-logy., Zt recognizes the impulsive nature of chugging, acoustic nature of the steam response in the vent, acoustic nature of the water response in the pool, and it recognizes the need to address in the load definition the presence of vent response characteritics and of the fluid-structure interaction (PSZ) effects in the dynamic pressures measured in the test facility. However, the computational methodologies used for source extraction from test data and for its applica-tion to the multi-vent Mark ZZ containments are based on two assumptions [181 (not required in the 'WNP-2'omputation methodology):

(a) The vent is not acoustically coupled to the pool, and (b) The principal effect of the fluid-structure interaction (PSI) is to reduce the frequency of the tank ringout.

With the above two assumptions, the hydrodynamic model of the test facility used for source definition is reduced to solving an acoustic. wave equation in a flat bottom axisymmetric rigid tank. To account. for the vent par-ticipation, vent harmonic (sine wave) response is added as a.

forcing function to the impulsive pressure source.,

Prior to application of these sources to Hark II plants two modifications are required to account for the dif-ferences, if any, in the vent response characteristics and in the PSZ response characteristics between the test facility and the Hark II plant as described in References 7 and 18.

The hydrodynamic model of the Mark II containment used in calculating the chugging boundary pressures due to a sour'ce consists of solution of'he acoustic wave equation in a rigid, flat bottom annular tank 4.6.2 WNP-2 Plant Unique Characteristics

There are two characteristics of the WNP-2 plant, which are, not in common with the other domestic Mark XX plants:

containment shell structure built of stiffened steel plate, the sloped bottom pool geometry.

The evaluation of the 4TCO data presented .in Chapter 3 shows that the boundary pressure traces from key chugs con-tain significant participation of the FSI response.- The magnitude of its participation vary from chug to chug and i;s dependent on the system conditions Since the WNP-2 contain-h ment shell structure is built of steel (as is the 4TCO tank wall) ~ its response to impulsive chugging sources will include significant participation of the FSX mode (as in the 4TCO tank) which may be axisymmetric as well as non-axisymmetric..

To obtain realistic responses of the WNP-2 containment to chugging Loads, it is essential to use the methodology which directly accounts for the FSX. effects of the test facility in-the source extraction methodology (thus resulting in sources which are free of the test facility characteristics) and which directly accounts for the FSX'effects (axisymmetric as well as non-axisymmetric) in the containment response calculations.

<<54>>

As stated before< the generic methodology is appli-cable to a containment with a flat bottom pool geometry., Zts use for NNP-2 containment would require idealization of the sloped bottom floor to. a flat bottom floor. Such an idealiza-tion could be practically based on only one (the fundamental) pool acoustics mode. Since the Mark ZZ pool acoustic response to chugging loads involves participation of many =modes of vibrations of the coupled vent/pool/structure system, such an idealization would result in over-simplification of the problem.,

For the above reasons, the 'WNP-2'evised chugging load definition is developed, implemented and presented in.

this report.

'4.6.3 Application Methodologies for Mark ZX Containments Elements of the two load application methodologies for Mark ZX containments are similar.

Based on multi-vent test data both methodologies:

recognize random variation of chug strength from vent-to-vent and use an averaging technique (although averaging is used in 'WNP-2'efini-tion, it is shown that design sources bound all unaveraged 4TCO data at Channel 28),

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BURNS AND ROE p INC., PROPRlETARY recognize random variation of chug initiation times'rom vent-to-vent ( the 'NNP-2'ethodology conservatively assumes that the three vents in one radial. row are in-phase, see. Chapter 5) .

5..0 WNP-2 Reactor Buildin Resonse To Chu in Zoad 5.1 Zntroduction The application of the chugging load methodology of the previous chapters- is presented in this chapter. The theoreti-cal background of the structural analysis is presented. The structural and suppression pool models are discussed. The results of the analysis, and their comparison with JAERZ test results are presented..

5.2 Theoretical Back round The analytical. methods that. were used. in the applica-tion of this, chugging, load methodology to the NNP-2 contain-ment is similar to that of Reference 3, Section 5.1. It was shown that the total hydrodynamic pressures, P2 (~) on the fluid-structure boundary can be expressed by PZ ~ Pj ~ + Ma (fU U (A3 (5.1) where

4) ~ Rigid wall pressures Ma (AJ ~ Hydrodynamic added mass matrix

~ Forcing frequency

~ ~

UP )

~ Accelerations of the fluid-structure interface

The structural equation of motion can then be expressed (5-2) where US (Q) = Structural displacements

~ Appropriate transformation matrix K ~ ~ Dynamic stiffness matrix

~2 (Ms +. T Ma TT) + iQ Qs + Ks (5 3)

Ms = Structural mass matrix

~- Structural damping. matrix

~ Structural stiffness matrix For any specified case of loading, the rigid wall pressures Pi (JlJ can be obtained,. equation 5.2 can then be solved to obtain the required'tructural displacements. For more details, refer. to Reference 3.

5.2.1 Treatment of Multiple Vents A cross sectional view of the WNP-2 reactor building is shown in Figure 5-1 and a plan view, of the wetwell at the I

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elevation of vent exits is shown in Figure 5-2. There are 102 downcomers (18 downcomers of 28" diameter and 84 downcomers of 24"'iameter) located in thirty-four radial lines arranged in.

an axisymmetric manner.

A. three dimensional finite element model of the WNP-2 suppression pool that has a set of three vents in one radial row is shown in Figure 5-. 3 and its structural boundary in Figure 5-4. The analysis is performed for any given chugging loading case using this model. and assuming the source loads at the three vent exits to be of a unit strength and occurring in-phase.. The structural and pool responses are evaluated then for, this set of three vents.. Zet. the response measure of interest located. at angle 0 and time t from the reference radial vent row be represented by the vector X (&,t) . lf the chugging load intensity at the vent exits corresponding to the ith radial row is assumed to be E i, the total building response, U (0,t), can be obtained as:

U (<'t) - 34 Li - X (e-ei, t y,) (5.4) i=1 where i~ The angular position of the it radial row.

measured from the reference row as shown in Figure 5-2.

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BURNS AND ROBED ZiVC ~ PROPRIETARY Pi Random chug start time for the ith radial row, Table 5-1.

The assumption that the chugs occur in-phase at the three vents in each row is more conservative than the case where all 102 vents are assumed desynchronized since the variance of the chug start times assigned to 34 radial rows is smaller than th'e variance of the chug start times assigned to 102 vents.

5.3 WNP-2 Response to Chugging Loads The single vent load definition and the 'assoc'iated multi-vent application. methodology of Chapter 4 and the theoretical approaches of Section 5.2. are used to obtain the suppression pool boundary pressures and structural responses to chugging loads. The axisymmetric finite element model of the reactor building is shown in Figure 5-5. This model is a more refined version of the model used in Reference 3. It was shown that refined modeling techniques give more realistic results (Reference,11).

BURNS AND ROE'NC.. PROPRIETARY 5.3 T 'ontainment Wall Design Pressures and Comparison With Test Data, To obtain. the maximum poo1 boundary pressures for comparison with test data the source strengths at the WNP-2 vents were assumed equal and the sources along the 34 radial rows were assumed desynchronized with chug start times as given in Table 5-1'. The maximum rigid wa11 pressure value calculated at the containment wall at the vent exit elevation at 0'zimuth for each design source is shown in Table 5-2.

I The maximum rigid wall pressure measured, at the vent exi;t elevat'ion in the 4TCO'ystem (Channel 20) during each of the seven time-windows (Table 2-2) and its average with maxi-mum pressure of the companion chug (Table 4..1) is shown in Table 5-3.

The maximum modified* pressures measured in different JAERI tests at the vent. exit elevation at the containment. wall are shown in Table 5-4.. Its comparison with the design wall pressures of Table 5-2 shows that the design wall pressures are higher than the JAERI results.,

To provide additional comparison with JAERI data, Fourier amplitude spectrum of the containment wall pressures at the vent exit elevation at 0'zimuth was obtained for each of the seven design sources The envelope of the seven spectra is shown in Figure 5-6 and compared with the envelope of Fourier amplitude (modified averaged) spectra of measured pressures in JAERI tests [7J . The envelope of design pressures completely envelopes. the JAERZ data by a significant margin at all frequencies The above comparisons demonstrate that the chugging load definition including the averaging method and the desynchronization procedure used in the application methodo-logy for the Nark II containments is conservative.

The JAERI multi-vent test facility shown in Figure 3-1 of Reference 7 includes 7 vents in a 20'ector. The WNP-2 vent configuration shown in Figure 5-2 shows six vents in a 21.8'ector.. In order to account for this difference in the number of vents between the two systems, JAERI test results are divided by a factor of 1.17 based on a previous study [19], which compared peak boundary pressures resulting from in-phase equal strength source application to seven vents versus six vents in a 20'egment..

5.3.2 Structural Response Structural responses were calculated, using the axi-symmetric finite element model of the reactor building shown in Figure 5-5 subjected to the pool boundary pressures calcu-lated for each of the seven design sources Response spectra at several locations were calculated. The- envelope spectrum curves (with the peaks spread by +15%) corresponding to 0.58, 1%,. 2% and. 4S of the critical damping values are plotted'or selected locations (foundation mat. at primary containment vessel, RPV pedesta3. at vessel support. elevations, containment vessel at. stabilizer .truss level, containment vessel at mid-submergence depth'nd reactor building at elevation 521 ' in.

Figures 5-7 and 5-8. for the asymmetric and the nearly sym-metric loading cases,. respectively 5.4 Discussion of the Ca3.culated Structural Res onse to Chu in 'oads The calculated NNP-2 reactor building responses to chugging loads show a pattern similar to that of the cal'cu-l lated responses to SRV 3.oads, Reference 11 .. The reactor building can be'ivided again into three zones:

The wetwell zone, including the containment struc-boundary, where the hydrodynamic pressures are

'ure app3.ied, and where the structural responses are the largest.

ii., The drywell. zone, including the, containment struc-ture boundary, where the high responses of zone (i) have been attenuated through the RPV pedestal and the containment shell.. Although smaller, they're still of a finite magnitude for the low damped steel containment structure..

iii. The third zone consists of the biological shield and the reactor building walls and floors outside pri-mary containment The structural response accelera-tions calculated for WNP-2 are negligibly small Et is noted. here. that negligibly small responses were also calculated for NNP-2. when sub j ected to SRV loads [11I'nd this. low level of predicted response was verified by'easurements taken during Caorso and Tokai-?. SRV tests. This is due to the fact that the Load path from zone (i) where the hydrodynamic pressures are applied, to this zone is through the mat and the soil and as shown in References 12 and 13 the soil compliances reduce rapidly as the fre<<

fluency of excitation increases; this explains the above mentioned large reductions in the structural responses in this zone.

Table 5>>5 shows the maximum computed structural re-sponse accelerations in the three zones of the NNP-2 reactor

building. Figure 5-9 shows the vibration tolerance obser-vations as documented in References 14, 15, and 16. Examina-tion of the maximum computed structural response accelerations at locations outside the containment structure of HNP-2 reac-tor building (zone iii) indicates that they fall. consistently near the curve of Figure. 5-9 labeled BEGIN TO PERCEIVE".

These findings lead to the conclusion that evaluation of safety related piping and equipment for chugging responses

~

need only be carried out in zones (i) and (ii) . It is noted that this conclusion is consistent with the results of WNP-2 reactor building analysis for SRV loads (Reference 11)..

6 0 LIST OF REFERENCES "Mark XX - Pressure Suppression Test Program Phase XI and XXI Tests," NEDO-13468,/NEDE-13468-P, including -Errata (1) .

2 "Mark IX Containment Dynamic Forcing Function Information Report (DFFR),"'EDO-21061/

NEDE-21061-P, Rev. 3,, June 1978, General Electric Company.

3.- Chugging Loads Improved Def inition and Application. Methodology to Hark XI Containments,"'echnical Report (Proprietary), Prepared by Burns and Roe, Xnc , for Application to Washington Public Power Supply System, Nuclear- Pr'oject No. 2, June 1'5g 1979.

4. Non-proprietary Version of 3..

4T Condensation Oscillation Test Program Final Test Report," NEDE-24811-P (Proprietary), Hay 1980, General Electric Company.

6. "Transmittal of Computer Tapes Containing 4T C.O.

Test Data,"'eneral Electric Company Letter HKXX 1814-E, dated July 15, 1980 (Including the Two

Ref erenced Letters dated 1/2/80, 4/29/80 ) to Hark XX Consultants.

7. "Generic Chugging Load Definition Report," General Electric. Document NEDE-24302 (Proprietary), April 1981 8 . "4T C.O. Chugging Data Base Information," General Electric Company Letter MKXI-1970-E ( including seven Attachment), dated November 18, 1980 to Burns and Roe, Inc.

L'etter dated July 24, 1980 from Creare Xnc. to Burns and Roe, Inc

10. "Random Data: Analysis and Measurement Procedures,. J.. S Bendat.,- A.. G., Piersol, Wiley-Interscience, 1971 "SRV Loads Improved Definition and Application Methodology for Hark II Cont:ainments," Technical Report (Proprietary) Prepared by Burns and Roe, Inc. for Application to HPPSS WNP-2, July 29, 1980.

1'2. "Dynamic Response of Structures in Layered Soils,"'..

Chang-Liang, Department of Civil Engineering Report Number R74-10, Massachusetts, 1974.

13 "Dynamic Stiffness Functions of Strip and Rectangular Footings on Layered Media," G. Gazetas, Massachusetts Institute of Technology, Dept. of Civil Engineering, M.S. Thesis, 1975.

14. "Data Averaged From 7 Sources," Report 1, D. E.

Goldman, Naval Medical Research Znstitute, March 1948.

15. "Foundation Vibrations," R. E. Richart, Journal of ASCE, Vol. 86, No SM-4, August 1960.
16. "Vibration of Zsolated Foundations for Boiler Feedpumps," H., A.. Franklin, Presented at the 1979 Annual Convention, American Concrete Znstitute, Milwaukee, Wisconsin, March 1979.
17. "Xmproved Structural Analysis Methods For Prediction of, Containment Response to Suppression Poo1 Hydrodynamic Roads", Technical Report, Revis ion 2, Prepared. by Burns and Roe, Znc. for General- Electric Company, January 1981

'I 8 "Mark ZZ Zmproved Chugging Methodology", General Electric Document NEDE'4822 (Proprietary), May 1980

'l9. "Fukushima Dai-Ni: Unit 3, Containment Response to the LOCA Steam Condensation Loads" Technical Report (Proprietary), prepared by Burns and Roe, Xnc., for Toshiba Corporation April 1981..

f GENEBAG ELZCTRlC. COMPANY PBOPBZZTABZ TABZZ 2 SUMMA'P 4TCO CHUG CATA l

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QEHEKLL, ELECTRIC COMPANY PROPRIETARY Table 2-2 4TCO CHUGGING DATA BASE IDENTIPICATION PAEQMETERS

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I BURNS AND ROE, INC. PROPRIETARY TABLE 4-1 IDENTIFICATION OF THE COMPANION CHUG USED FOR AVERAGING WITH KEY CHUG

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BURNS AND ROE ~ ZHC ~ PROP RZETARY TABLE 4-2 SXNGLE VENT DESZGN SOURCE DEFXNXTZON

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~

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TABLE 5-3.

CHUG START TINES PQR RANDOM PHASING Radial Chug Start Radial Chug Start Row Time (Sec) Row Time (Sec) 0 022826 18 0.012603 2, 0.021631 19 0.035364 0.014281 20 0.026404 0.037928 21 0.039039 0.026944 22 0.021682 6 0.025257 23 0 024879 0.0092329 24 0.044889 0.,035325 25 0.024589 0.036614 26 0.0057321 10 0.,017459 27 0.023880 0 030120 28 0.033905 12 0.018409 29 0.015641 13 0.034114 30 0.013154

,0. 041211 31 0.022173 15 0 '34711 32 0.026808

16. 0.024805 33 0.046634 17 0.031562 34 0.027705

-4 2 Vari. ance ~ 0.881708 x 10 (sec.)

Note: The three vents in each radial row are assumed to chug in-phase.

<<74

BURNS AND ROE, INC . PROP RIETARY TABLE 5-2 i~EMUi4 RIGID WALL PRESSURES ON WNP-2 CONTAINMENT AT VENT EXIT ELEVATION (NODE 15)

I, GENERAL ELECTRIC COMPANY PROPRIETARY

à i

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BUPSS hiVD ROE, Zi<C. P .OPRZETARY GENERAL ELECTRZC COMPANY PROPRZETARY TABLE 5 4 JAERZ PEAK POSZTZVZ CHUGGZ.IG P.RES SURE RMLZTUDES

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TABLE 5-5 MAXIMUM COMPUTED ACCELERATIONS FOR WNP-2 REACTOR BUILDING RESPONSE MAXIMUM ZONE DIRECTION ACCELERATION (g)

I 510'OCATION Containment Horizontal 1.63 Xnside and on the Wall (Quencher boundary of the Elevation) containment struc-ture below El.

XX Inside and on the 510'ontainment Wall El.

520'lorizontal 0.18 boundary of the containment struc- RPV Support Vertical 0.060 ture above El.

Stabilizer Truss Horizontal 0.038 IXX Outside Building JIorizontal 0.002 Outside the con-tainment structure Wall El. 521'ertical 0.029

ORYWELL VACUUM

&REAKER IIL1 It I

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2 It 52.5 ft VENT SRACE 4T TANK 454't YBIT (OCWNCOMER)

Si EAM V E."IT QENERATOR aRACS Il.S It I'I.OW MEASURINQ VENTI 'Rl W7LSHZNGTOH PVBLXC POWER SUPPLY SYSTEM Test Configuration Conclensation for Park Oscillation II NUCLEAR PK4ECT HQ (4TCO) Tests

>>79-

C H.18&19 CH. 17 0'0'25

~-

315 45o 20.0'H.

CH. 20 22&'23 CH. 21 I

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4'5 225 315 12.0'H.

24 00 C H. 26&27 CH. 25 6.0'.0'.0'h.

~

Oc4'25 315 '5o 0.0o 28 (Bottom Center)

PZGURE WASHZNGTON PUBLZC POWER SUPPLY SYSTEM 4TCO Tests NUCLEAR PROJECT NO 2 Wetwell Pressure Transducer Locations 2~2 GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNQTON PUBLXC POWER SUPPLY SY~ COMPARISON OF PRESSURES & FOURIER PZGUBE AMPLITUDE SPECTRA OF i<EY CHUG 6 A NUCEZAR PROJECT NO 2 NEIGHBORING CHUG - TIME WINDOW NO. 1

GENERAL ELECTRIC COMPANY PROPRIETARY COMPARISON OF PRESSURES & FOURIER FIGURE WASHINGTON PUBLIC POWER SQPPXY SY~ AMPLITUDE SPECTRA OF KEY CHUG 6 A 3>>2 NUCLEAR PROJECT NO~ 2 NEIGHBORING CHUG TIME WINDOW NO. 2 GENERAL ELECTRIC COMPANY PROPRIETARY t

t WASHZNGTON PUBLZC POWER SUPPXiY SYSTRC NU~ PROJECT HO 2 COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A NEIGHBORING CHUG TIME WINDOW ViO. 3 PZGURE 3 <<3

GENERAL ELECTRIC COMPANY PROPRIETARY t

t WASHINGTON PUBLIC POWER SUPPLY SYSTEM%

NUCXZAR PROD~ HO 2 COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG S( A

@NEIGHBORING CHUG TIME WINDOW NO. 4 PIGURE 3-4 I

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GENERAL ELECTRIC COMPANY PROPRIETARY

~~~@ PmXZC ZewZz ~~zzz zz~ COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG & A PIQUE 3-5 NEIGHBORING,CHUG - TIME WINDOW NO. 5 GENERAL ELECTRIC COMPANY PROPRIETARY

%LSHZNQTON PUBLIC PowER SUPPLY SYSTzH COMPARISON OF PRESSURES & FOURIER AMPLITUDE SPECTRA OF KEY CHUG 6 A 3-6 NEIGHBORING CHUG TIME WINDOW NO. 6 I

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GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLXC POWER SUPPLY SY~ COMPARISON OF PRESSURES & FOURIER FIGURE AMPLITUDE SPECTRA OF KEY CHUG & A 3~7 NUCZZAR PEKL7EZT HO NEIGHBORING CHUG TIME WINDOW NO. 7 I

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GENERAL ELECTRIC CO%?ANY PROPRIETARY WLSHMGTON pUBLzc pggzz gypsy gyp~ COMPARISON OF PRESSURES MEASURED AT CHZ2iNEL 28 AND C~~EL 26 RJCLEAR PRCLTEZT NO 2 DURING TIHZ WINDOW NO. 6,CHUG I

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GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM COMPARISON OF PRESSURES MEASURED AT CHANNEL 24 AND CHANNEL 20 NUCLEAR PROJECT NO 2 DURING TIME WINDOW NO. 6 I CHUG n 2 I

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BURNS AND ROE i INC ~ PROPRIETARY M7LSHZNGTON PUBLZC ~ SUPPLY SYSTM NUCLEAR PROJECT HO 2 PHASE RELATIONSHIP BETWEEN PRESS .

MEASURED AT CHANNEL 20 AND CHANNEL 28 VERSUS FREQUENCY-TIME WINDOW NO.l PZUURE 3 >0 l

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BURNS AND ROE g ZNC ~ PROPRIETARY

~HZNGTON PUBLIC PowER sgPPLY SY~ PHASE RELATIONSHIP BETWEEN PRESS . PIGURE 3-gg MEASURED 'AT CHANNEL 20 AND CHANNEL 28 VERSUS FREQUENCY-TIME WINDOW NO.l I

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BURNS AND ROE, INC . P ROP RIETARY

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HQ 2 RATIOS OF FOURIER AMPLITUDES OF PRESSURES MEASURED AT CHANNEL 28/

CHANNEL 20 a

GENERAL ELECTRIC COMPANY PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTZ?4 VERTICAL DISTRIBUTION OP PEAK PZGURE PRESSURES-SIX CHUGS, TIME i%JCLEAR PROJECT NOi 2 WINDOW No. 1 3-l3 I

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GE'FERAL ELECTRIC COMPANY PROPRIETARY

%LSHXNQTON'UBLIC POWER SUPPL" SYFZBC VERTICAL DISTRIBUTION OF PEAK PIGURE FOURIER AMPLITUDES OF PRESSURES 3-14 NUCLEAR .PR03ECT NO 2 TWO CHUGS-TIME WINDOW NO. 1 5

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BURHS ALOD ROE I XNC ~ PROPRZETARY WASHINGTON PUGLXC PGWER SUPPLY SYSTEM% RATIO OF FOURZER AMPLITUDES OF FIGURE PRESSURES MEASURED AT CH.20/CH.21 NUCLEAR PROJECT NO 2 3-15 95>>

l GENERAL ELECTRIC COMPANY PROPRIETARY WASHINGTON PUBLIC POWER SUPPL SYS~ COMPARISON OF 4TCO S 4T DATA FIGURE PRESSURES MEASURED AT BOTTOM NUCLEAR PBCQECT NO 2 CENTER 3-16

588.0 54RO 543;0

.505.0 466.0 424.0 Modified 4T Tank 382.0 328:0

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276.0

- 262.0 216. 0 195. 0 180.0 ..

144.0 127. 0 108. 0 60.0 72. 0 36.0 24.0 p pll 0. 0

12. 0 18. 0 26.'0 34.0 42.0 0.0" 12.0 MLSHZHGTON PUBLZC PC%ZR SUPPLY SYSTEM PZGURE VENT POOL MODEL NUCLEAR PROJECT No~ 2 (FLUlD ELEMENTS) 3-3.7a

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l BURNS AND ROE, INC . P ROP RIETARY WASHXNGTON PUBLIC POWER SUPPLY SYSTRC SCHEMATIC PRESENTATION OF PEGURE PRESSURE SOURCE AT VENT'XIT 3-18 NUCLZAR PROJECT NO 2 IN 4TCO SYSTEN I

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BURNS AND ROE, INC. PROPRIETARY WASHXHGTON PUBLIC PC5KR SUPPLY, SYSTEM SCHEMATIC PRESENTATION OF ACCELERATION SOURCE AT THREE NUCLEAR PROJECT NO 2 LOCATIONS 'IN 4TCO SYSTEM

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BURNS AND ROE i INC ~ PROPRIETARY m~~ ~c ~ mme ms~

W~C PSOJEC"'O. 2 i

'FCOMPARISON OF VERTICAL DISTRIBUTION zZmaz NORMALIZED MAX PRESS CALCULATED 3-24 W/PRESS . & ACCELERATION SOURCES

-105-

BURNS AND ROE, INC. PROPRIETARY

%LSHXNGTQN PUBLXC POWER SUPPLY SYSTEM VERT. DISTR. OF FOURIER AMPLITUDES FIGURE OF PRESS. CALCULATED WITH ACCEL.

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BU RNS AND ROE I ENC ~ P ROP R IETARY WLSHZNGTOH PUBLZC POWER SUPPLY SYSTEM PHASE RELAT1ONSHXP BETWEEN PRESSURES FZGURE CALCULATED AT CH.20 AND CH.28 3-28 NUCLEAR PROJECT HO 2 VS. FREQUENCY

-109-

BURNS AND ROE I INC ~ PROPRIETARY WASHZNGTON PUBLZC POWER SUPPXZ SYSTEM C. VS . RESONANT FREQUENCY NUCLEAR PBOJECT NO+ 2 ANALYTICAL CURVE & ITS APPL.

-110-

oo Chug No. 2 (Key Chug}

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oo ZQ. CC 40. QO 60. QQ 90. QO I 00. 00 I 'Q. 00 I 40. CQ I 60. QQ FREOUKNC'( {H7.)

WASHRf~~N PUBLIC PCSIER SUPPLY SYSTEMS COMPARXSON OF FOURIER SPECTRA OF PRESS OF KEY CHUG & COMPANION CHUG HUCZZAR PROJI&2 HO 2 MEASURED AT CH.2S-TIME HINDOOS NO.2

-111-

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WLSEKNGTCH PURL):!" PO~ SUPPLY SYSTRt COMPARZSON OF FOURIER SPECTRA OF PZGURE PRESS'F KEY CHUG & COMPANZON CHUG 4-2 i&JCZZAR PRC4cX.~ HOa 2 MEASURED AT CH.28, TZME NZNDON NO.3

-112-

BURNS AND ROE, INC. PROPRIETARY I

i t WASHXNGTON PUBLIC POWER SUPPLY SYSTEM NUCZZAR PROJECT NO~ 2 ~

DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM CHAVv. NEL'8 PZGURE 4-3 .

.BURNS AND ROE, INC. PROPRIETARY WASHZNGTON PUBLZC POWER SUPPLY SYSTEM DESIGN SPECTRUM AND REQUIRED PZGURE AVERAGE SPECTRUM - CHANNEL 26 4-4 NUCLZAR PROJECT HO~ 2 ~

-114-

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I I

BURNS AND ROE, INC. PROPRIETARY WASHINGTON PUBLIC POWER SUPPLY SYSTEH DESIGN SPECTRUM AND REQUIRED AVERAGE SPECTRUM - CHANNEL 24 NUCLEAR PROJECT HO 2 ~

-115-

BURNS AND ROE g INC ~ I PROP R ETARY WASHINGTON PUBLIC POWER SUPPLY SYSTEM DESIGN SPECTRUM AND REQUIRED FIGURE NUCLEAR'RMECT NO 2 ~

AVERAGE SPECTRUM - CHANNEL 20 4-6

BURNS AND ROE, INC. PROPRIETARX i

t WASHINGTON PUBLIC POWER SUPPLY SYSTEH NUCLEAR PROJECT NO 2.

DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM CHANNEL 28 FIGURE 4-7

-3.17-

I I

l

BURNS AND ROE I INC ~ PROPRIETARY PZGURE WASHZNGTON PUBLZC POWER SUPPLY SYSTEM DESIGN SPECTRUM AND REQUIRED NUCZZAR PROJECT NO 2 ~

ENVELOPE SPECTRUM CHANNEL 2 6 4-8

-118-

BURNS AND ROE I INC ~ PROPRIETARY WASHINGTON PUBLZC POWER SUPPLY SYSTEM DESIGN SPECTRUM AND REQUIRED PZGURE NUCLEAR PROJECT No 2 .

ENVELOPE SPECTRUM CHANNEL 24 4-9

-119-

l I

I

BURNS AND ROE, INC. PROPRIETARY wAsHINGT0N Paar'nna svpprv scrag DESIGN SPECTRUM AND REQUIRED ENVELOPE SPECTRUM CHANNEL 20

>>120-

S c.CT:ON B -B 0

0 0

I I 0 0.

0gl Ot 2~~i~f MASHZH~iN PUBLIC PO~ SUPPLY PiaTKi SOURCE STRENGTH D ISTRIBUTION ASYMMETRIC LOADING CASE HQ~ PMJECT HO

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ghkk i L.ii, gal.S lk 'JAX If j I ll SECTION B-B 0

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/

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9 ~MN SOURCE STRENGTH DISTRIBUTION FIGURE WASHINGTON PUBLIC PONER SUPPLY SYSTEM NEARLY SYMMETRIC LOADING CASE 4 12 NUCLEAR PROJECT NO< 2 .

-122-

I

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I LQ 2 GCha~CCa'- 25

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~nSK J~v. PU3X PCnZR M S"~ WETWELL PLAN VIEW AT ELEVATlON OF DOWNCOMER EXlTS 5-2

>>124-

~

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WASHZNGTON PUBLZC PQWER SUPPLY S~~ FLUID STRUCTURE BOUNDARY-WNP-2 SUPPRESSION POOL PZGURE 5-4 NUCLEAR PROJECT NQ 2 ~

-.12 6-

f 605.88'67.38 547'21 500'88.8'77.6'70'63.25 456.5'49.75'43'27.75'22.25 SOIL/

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-127-

BURilS AND ROE, ZNC. PROPRIETARY GE?iEEVJ ELECTRIC CO.'IPANY PROPRZ~TARZ WASHINGTON PUBLIC POWER SUPPLY SYSTEM ENVELOPES OF CALCULATED RESPONSES FOR FIGURE WNP-2 AND MEASURED RESPONSES AT JAERI NUCLEAR PROJECT NQ~ 2 CONTAINMENT AT VENT EXIT ELEVATION

THETA TRANSLATIOl4 O lt I

g4 Ill 4l~

Lk '0

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cga

. 00 IO. 04 '%0.00 40. 00 IO. 04 l00. 00 INl. 00 I 0. 00 I CO. 00 FRFOURNCT IN'L)

VERTICAL TRANSLATION DA I

g4 IC le lal ~

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HORIZONTAl TRANSLATICN O

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Note: Multiply all acceleration values by 1.18.

REACTOR BUILDING RESPONSE-WASHTMGTCN PUBLZC PQWER SUP LX SZS~ ASYMMETRIC LOADING:

PZGQ3E CONTAIN),I, NT NU~ PM4ECT HO 2 VESSEL AT MAT 5 7 a

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I I

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THETA TRANSLATION 2

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2

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V.ERTICAL TRANSLATION I

<<04 ill l<<k

<<Oo

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to.oo f RfQUEttC'f <ltL I

<< ~

HORIZONTAL TRANSLATION lh

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WASEKBCZQN PUBLZC POWER SUPPXIY SYSTZA REACTOR BUILDING RZSPONSZ- FIGURE HU~~ PRCQZCT HO~ 2 ASYK4ETRIC LOADING: RPV SUPPORT S-jb

-130-

THETA TRANSLATION "1

5 ar zo.ao uo.oa eo.oo so.oo Loo.oo tza.ao .uo.ao ice.oa FRCQUKtuCY (HZ)

HORIZONTAL TRANSLATION

%. oa zo. aa 'ua. aa 80. Oo 80. Oa 100. Oa L20. Qa Lua. aa boa. 00 FPEQUEtuCY <HZ>

Note: Multiply all acceleration values by 1.18.

NASHZHQTON PUBLZC POWER SUPP'Y~A REACTOR BUILDING RESPONSE-ASYMMETRIC PZ GORE LOADING: CONTAINMZNT VESSEL AT NUCLEAR PBQZECT'O~ 2 STABILIZER TRUSS. LEVEL 5-7 c

-131-

I I

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wQ g4 I40 Ek~

EJ ~

0 El 10.00 00.00 l0.00 IOIOO IOO. 04 l10. 00 I10.04 IOO.OO FHE'OUQICV IIII>

VERTICAL TRANSLATlON a

ll4

<ga IK 4I lal ~

ll lg4

h. 04 10. 00 IO. 00 IO. 00 00. 00 IOO. 04 l10. 04 IlO. 04 IOO 04 FtICOUfNCT (1IZ1 HORIZONTAL TRANSLATlON I

0O 4l wQ 0't

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WASHINGTON ?UBLZC PCWER SUPPLY SY~ REACTOR BUZLDZNG RESPONSE-ASYMMETRZ LOADZNG- CONTAZNMENT VESSEL AT PEGVRE NUCLKQt ? BOJECT HO 2 MZD-SUBMERGENCE DEPTH 5-7 d

-132-

Theta Translation Ou

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O4

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Vertical Translation 4

Qu

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O

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Note: Multiply all acceleration values by 1.18.

RLSEDiQTOH PQBLZC PCRER SUPPLY SiE'8 REACTOR BUZLDZNG RESPONSE ASYHMETRXC LOADZNG: OUTSXDE HU~ PBCCEZT HO BUZLDZNG gALL ELEVATZON 521'133-

THETA TRANSLATION ua

?

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4l 4J IJa Co

')I. 04 IO. 00 10. 44 IO. 00 10. 04 100. 04 IIO. 04 I IO. 00 100. 04 FRCOUKIIC) UIE) 4 l4 VERTICAL TRANSLATION ll a

4la IK 4l 4l 4lo tJ go b.00 10 00 '10.00 00.00 10.00 100.04 I 4.00 1%0.00 100.04 FRCOUCIICY IIIL)

HORIZONTAL TRANSLATION a

Qa

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Cl a I

ga la i@a tJ 4J o i/4 tl. 04 )0. 04 '14. 00 44. 00 10. 00 100. 04 140. 00 I 0. 04 I <0. 04 FRCOURIICT IIIL) iVote: Multiply all accelexation values by 1.18.

MASHISGTCN PUBLIC PGWER SUPPLY SYS~ REACTOR BUILDING RESPONSE KUGKY - ZGUBE SYMMETRIC LOADING: CONTAINMENT NU~ PRAT-C2 HQ 2 VZSSEL AT MAT 5-8a'134-

0 THETA TRANSLATION C)g IJ ce

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D

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VERTICAI TRANSLATION D

Ia D I

CC D W

Wa CI CJ a

COD

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HORIZONTAL TRANSLATION COD D

D I

CC

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)t)ASKPifQTON PUBIC PCQER SUPPLY SY~ REACTOR BUILDING RESPONSE - NEARLY PXGUNK NU~ PBQJE~D No 2 SYMMETRIC LOADING: RPV SUPPORT 5-8 b

-135-

THETA TRANSLATiON R

Oe CI 44 W

ua QO

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~I laJ

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Note: Multiply all acceleration values by 1.18.

MAKKHGTON PUBLZC PCWER SUPPLY SYS~ REACTOR BUZLDXNG RESPONSE NEARLY rzavaz iVUCXZiQL MAC SYMMETRZC LOADXNG: CONTATNVZNT 5-8 c HO 2 VESSEL AT STABILIZER TRUSS LEVEL

-136-

I Theta Translation O

Q4 Z

O~

gO ac

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Cg D

. 00 t0.00 t0. 00 40. 00 40. 04 IM.00 I'CD. 00 '.10. 09 I CD. 00 FREOUENCt (hatt Vertical Translation O

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a'orizontal Translation

'X tl I

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~n

~n EJ QA

0. 04 'lO. 00 lO. C4 sO. M 104. OQ I'CS,04 I%0. 00 I CO. 00 FREOUCHI:T IIIt)

Note: Multiply all acceleration values by 1.18.

WASHZHGTON PUBIC POWER'UPPLY SY~ REACTOR BUiLDING RESPONSE K~LY FIGURE NUCLEAR PROJECT HO 2 SYMMETRIC LOADING: CONTAINMENT g-8 d VESSEL AT MID-SUBMERGENCE DEPTH

-137-

Thetal Translation O4

~

4 EJ S

Eo 4 I

Ea EO l 4 E44 IJ EJ Ea 44

~I

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Vertical Translation EJ4 EJ 44 Ea 4 EK ill ill EJ EJ 4 ~

0,4 ta,aa. Ea. 00 40. 00 Eo. 00 taa. 00 I to. 00 IEO. 00 I to,oa FRft)VCttCY ItlZl Horizontal Translation W

EO4 Et I

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Note: Multiply all acceleration values by 1.18.

REACTOR BUIIEDING RESPONSE -

WZttsiKS~~ PQBLZC PCWER SUPPLY NU~ PROJEX.~ HO z SYS~

SYMMETRIC LOADING:

BUILDING HALL ELEVATION OUTSIDE S21'GVBE NEARLY 5-8e

-138-

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-139-

APPENDIX A ANALOGY BETWEEN ACOUSTIC AND STRUCTURAL BOUNDARY CONDITIONS A.l Introduction Response of the analytical model of the 4T system to two types of sources, the pressure source and the acceler-ation source applied under the vent is presented in Section It is shown that the two sources excite different modes of the 4T system. The difference in the excited modes is a result of different boundary conditions at the pool vent interface which appear in the analytical solutions of the two problems. It is important to recognize this basic difference between the two types of sources because the 4TCO key chugs which are simulated using the acceleration source contain the response of the system which cannot be simulated using the pressure source.

It is shown in this Appendix that the acceleration/

pressure sources of vibration in acoustic fluid vibration problems are analogous to the force/displacement (or acceler-ation) sources in structural vibration problems. To emphasize the difference in the boundary conditions and their importance in changing the characteristics of the response, a simple structural vibration problem is first presented in this Appendix, then the anology is shown between the two problems.

-Al-

A.2 Forced Lon itudinal Vibrations of a Prasmatic Bar The equation of motion of 'ongitudinal vibrations of a prismatic bar due to external force p(x) f(t) and the formulation of its solution is shown in Figure A-l.

The eigenmodes and eigenvalues (frequencies) for two cases of boundary conditions are shown in Figure A-2. It is seen that the fundamental mode frequency for Case 1 (fixed-free) is one half of the fundamental mode frequency for Case 2 (fixed-fixed) . It is shown in Figure A-3 that vibration of the bar due to a force applied at the free end is completely defined by the eigenmodes and frequencies corresponding to the Case 1 whereas the vibration of the bar due to a displacement motion prescribed at the free end is defined by the eigenmodes and frequencies corresponding to the Case 2. In other words, the characteristics of response of the bar due to an external force is completely different from the characteristics of response of the same bar due to an imposed (displacement) motion. The imposed displacement motion requires a change in the boundary condition at the location of imposed motion which alters the response characteristics of the system.

-A2-

A.3 A'nalog Between Acoustic Fluid Vibrations and Structural Vi rations The equation of motion for the longitudinal vibrations of a prismatic bar is analogous to the equation of motion of acoustic fluid.

p (x t) +

~

C.

~

Bp Qt

~ 0 Bu Qx where p = u and Q Q du x (note'. duX 6X E AE )

.'. Pressu=e Source in Acous ic =Zmposed D'splacement m Fluid Problems Structural Vib at on Problems ard Accelerat'on (or p ess" e g ad'ent) =- Appl ied. force ~~

Source in Acoustic r lu'id Problems Structural Vibration P=oblems A.4 Conclusion From the above analogy, it is evident that the response characteristics of acoustic fluid system excited by an acceleration source (which is analogous to externally applied force in structural vibrations) will be different from those excited by pressure source (which is analogous I

to imposed motion in structural vibrations) .

Since key chugs are properlv simulated using accel-eration source, for chugging load definition to bound the key chug data, an acceleration source must be used.

A.5 References.

A-l "Vibration Problems in Engineering", Timoshenko, S.,

D. Van Nostrand Company, Inc.

-A3-

I I

I

pA 8~uu ec u (x,o) l u(x,t)

I'II I.

I AE Q x 2

(3 u f (t) dx, dx FOR CE S ACTI N G ON ELEMENT dx AT (x, (SEE SKETCH OF f) p (x)

BAR BELOW )

So lution fzom Refe ence A-1 may ce su~+rimed as oU.ows:

"~B.

Q u(x.t)

+ AP~

Q u(x, gt t)

= p(x) z((:) Ecuatior. of Motion (A-1) u(x t) X (x) P (t) Solut'or "or Homogeneous n~l, Boundary Con"'t'ons (A-2) 2 X(x) = Eicenmodes oz the eicenvalue ecuation .'{ (x) + Z x (x) ~ 0 wim appropriate homoce..eous boundary c8ndition9 (e.g., Case 1 and 2 in Figure A-2) p (t) = Solution oz the ecuation- o mot'on p (t) +U II' wi "5 appzopz'ate initial conditions o f (t)/Ap whe e,, a 2=- =E/p Q3 ~ recuency oz vibration of natural mode n "- Kna g

p = p(x) X (x) dx X (x) o o n"

( ) = A cosG3

r. t+

n," ' B SinG3 n.

+ ~

~Ap t f (tl) g 1 S~zU n (t-tl)1) dtl 1.

(A-3) where con tents A, B a e obtained rom initial cond'tions and aze set erual to "ezo'- tne system at zest at. t~0.

x=O iÃ.I-APPLIED FORCE p(x) ' ( t)

P= MASS DEN SITY E = MODULU S OF, ELASTI CITY A = AREA OF CROSS SECTION WASHINGTON PUBLIC POWER SUPPLY SYSTEM LONGZTUDZNAL TRANSZENT VZBRATZONS OF rImRE NUCLEAR PROJECT NO~ 2 A PRZSHATZC BAR A-1

4 Case 1 Case 2 Fixed Free Fixed Fixed x=o Boundary> Conditions:

U(o) = o, Bu. (g) = o U(o) = o, U(z) = o Qx Eigenmodes:

Z (x) = Sin~

07t x xn (x) = Sin-n = 1,3,5 n = 1(2(3 11 = 2 Eiaenva1ues:

K nW n7l n 2g, K n

WASHZNGTON PUBLZC POWER SUPPLY SYSTEN EIGENMODES A'ND EIGENVALUES FOR TWO FZGURE CASES OF BOUNDARY CONDITIONS A-2 NUCLEAR PK4ECT NO 2

-A5-

Problem l Problem 2 Applied Force at Free L'nd Imposed Displacememt at Free End A, L",P Ai F(P o(t) e P(t) I x=0 R x=0 n-l K

)

Pl u (x,t) = n=l,3, pAX Z

S., G3

>< (u)j (t) u (x~t) p ul(x, t) + u 2 (x, t) u>(x, t) ~ ~ D(t) where, I( x H

xn (x) ~ sin n-2-j)-

OO Pu (t>

0 I ri(t~> S(.uCJ n (t t>.)

l' dtj where, 0> Q xn (x) sin- n ITx g

OA H t3 OO = 8/p lu <t>

f 0

ri<t() SsuCJ <t-tZ> ritZ R

'3 n nT(a g

NH gK D(t) d D dt WO Note that the response characteristics (x,4) ) of the same bar are different in the above two an problems. The series solution of Problem l i9 based on the boundary conditions of Case A-2) . The series part of the solution (U2 (x. t) ) of Problem 2 is based on the boundary n'Figure l

conditions of Case 2 (Figure A-2).

)

I I

I I

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