4.0 Comments

5.0 Test Results 6.0 Test Procedure 7.0 Drawings 8.0 9.0 Diagram'I Acton Environmental Testing Corporation Laboratory Test Report Page 1 Page 2 Page 3 Page 4 Page 5 Page 9 Pages 10 thru 15 Page 16 Page 17'N Y

1.0 Test Items 1.1 Manufacturer: FOXBORO CO.Model Page 1 Serial Mo.'a~b.C.d.-f.g, h.1.J~k.l.m.M/62HF-5E-OH-L, Style C, Controller M/62H8-4E-OH, Style C, Batch Controller M/6420HF-O, Style A, Recorder M/63U-AC-OHAA, Style B, Alarm-M/66DC-OH-4, Style 8, Multiplier/Divider M/66, Special Low Selector M/66AC-OH-XP, Style E, Sq.Rt.Converter M/693AT-OA-6, Style C, Converter M/610AC-OH, Style C, Power Supply N0140AB, Power Supply N0140MA, Distribution Panel EH4-D, Consotrol Shelf 2075-E, Thermocouple Assembly 2532962 2423454 2462637 2532963 2533089 2407569 2532960 2532961 2533160 1.2 Manufacturer: WESTINGHOUSE Model a.VX-252, Vertical Indicator 1.3 Manufacturer: GENERAL ELECTRIC Model a.SBM Type Switch

~~2.0~T<<Ob'age 2 To determine the ability of the instrumentation specified within to function during and after subjection to the following Seismic environ-ments: Tests were conducted in the vertical and two orthogonal horizontal planes at frequencies from 1 to 30 Hz with accelerations of lg at 1 Hz, ramped to 2g's at 1.5 Hz and constant at 2g's to 30 Hz.Sweep rate was 1 octave/min. Refer to Diagram No.l. ~~~3.0 Conclusions Page 3 The outputs of all electronic rack or shelf mounted instruments, with the exception of the M/6420HF-0 Recorder and VX-252 Vertical Indicator, changed less than O.l percent during vibration tests in all three planes.See Section 5-N and 5-L for results on the recorder and indi-cator.With the exception of the M/6420H Recorder, M/66D-OH-4 Multi-plier/Divider and VX-252 Vertical Indicator the maximum calibration changes noted on all other electronic instruments after tests were com-pleted were less than 0.1 percent.The maximum calibration changes noted on those instruments were-Od90,-0.45, and+1.7 percent, re-spectively.. tIo permanent electrical or physical damage was noted on any of the instrumentation after tests were completed. Where the function of the unit under test provided analog inputs and/or output signals which could be monitored continuously, these were moni-tored by oscillographic recorders with span settings of+5/of full signal span.Due to the length of these recorder charts, they are not included in this report.Rather, the data are summarized under Section 5.0 Test Results.Copies of the recordings are on file in Dept.383 d~f

4.0 Comments

Page 4 4.1 The shelf-mounted units (62HF Contro'Iler, 62H8 Controller, 6420 Recorder)were restrained at their front faces by a special retain-ing bar used on other seismic applications.(See Drawing No.1.)The use of this retaining method along with another hold-down assembly at the rear of the units is recommended. 5.0 Test Results Page 5 a.M/62HF-5E-OHL Controller The controller was tested per Drawing No.2.The local set point, remote set point (derived from a d/p transmitter powered from the controller's Force Balance Power Supply)and controller output were set at 100/, 50/and 50/respectively. These signals were monitored on strip chart recorders during all tests and were calibrated for spans of 10%(i.e.100+5%, 50+5%and 50+5%for the three signals).All monitored signals changed less than O.l/during seismic tests in any of the three planes.The maximum calibration change of the local set point and controller outputs after testing was less than 0.1/.b.c~M/62HB-4E-OH Controller The controller was tested per Drawing No.2.The local set point, remote set (derived from a d/p transmitter powered from the control-ler's Force Balance Power Supply)and controller output were set at 100%, 50/and 50%respectively. These signals were monitored on strip chart recorders during all tests and were calibrated for spans of+5/(i.e.100+5%, 50+5%and 50+5/for the three signals).All monitored signals changed less than 0.1/during tests in any of the three planes.The maximum calibration change of the local set point and controller outputs after testing was less than 0.1%.H M/66D-OH-4 Multi lier/Divider d.The multiplier/divider was tested per Drawing No.3.Both inputs (one input was derived from a d/p transmitter powered from the'ultiplier/divider 's Force Balance Power Supply)and the output were set at 80%, 25/and 50%respectively, These signals were moni-tored on strip chart recorders calibrated for spans of 10/.All monitored signals changed less than O.l/during seismic test in any of the three planes.The maximum calibration change noted after testing was completed was-0.45%.M/66 Low Selector The low selector was tested per.Drawing No.3.Input Nos.1 and 2 and the output were set at 52/, 50%and 50/respectively. All three signals were monitored on strip chart recorder's with spans of 10/.The output of the selector changed less than 0.1%during seismic tests in any of the three planes.The maximum calibration change not'ed'after completion of all'tests was less than 0.1/.---- 5.0 Tes t Res ul ts (Con t.)Page 6 e.H 66A-OH-XP S.Rt.Converter The sq.rt.converter was tested per Drawing No.4.The input (derived from a d/p transmitter powered from the converter's internal Force Balance Power Supply)and the output was set at 55%and 75%respectively. Both signals were monitored on a strip chart recorder calibrated for spans of 10%.Neither signal changed more than 0.1%during any seismic test in any of the three planes.The maximum calibration change noted after testing was completed was less than 0.1%.h.H/693AT-OH-6 Converter The converter was tested per Drawing No.4.The input and output were both set at 50/.The input was supplied by an Electronic Development Corporation Millivolt Standard and the output was moni-tored on a strip chart recorder calibrated to 50+5%of span.The output changed less than 0.1%during seismic tests in any of the three planes.The maximum calibration change noted after all tests were completed was less than 0.1%~H/63U-AC-OHAA Alarm The alarm was tested per Drawing No.5.The set point and input were set at 50%and 48%respectively, and the alarm was deenergized. The input and output were monitored on strip chart recorders. The input recorder was calibrated to 48+5%while the output recorder monitored any alarm firing.The alarm did not fire during any seismic test in any of the three planes.The maximum firing point calibration change noted after testing was completed was less than 0.1%.H 610AC-OH Power Su 1 The Power Supply was tested per Drawing No.5.During tests, the power supply was loaded with one d/p transmitter. The transmitter output current was monitored on a strip chart recorder calibrated for 50+5/of span.The output current changed less than O.l percent during vibration test in any of the three planes.The unit functioned properly after all tests were completed. N0140AB Multi le Power Sun 1 The Power Supply was tested per Drawing No.6.During tests, the power supply was'oaded with'ne" d/p transmitter. The-transmitter '=..output current changed less than 0.1 percent during vibration test in any of the three planes.The unit functioned properly after all tests were completed. 5.0 Test Results (Cont.)Page 7 j.N0140i~Q Distribution Panel The distribution panel functioned properly before and after vibration tests in all three planes.The panel was not monitored during tests.k.2075-E Thermocou le Assembl The thermocouple assembly functioned properly before and after vi-bration tests in all three planes.The thermocouple was not monitored during tests.l.VS-252 Vertical Indicator Calibrations were made before and after vibration tests in all three planes.The results are as indi cated below: Zero Error,%Span Error, X Maximum Error,'A m.G.E.T e SBM Switch Before Tests+0.2-0.9-0.9 After Tests+0.8-0.5+0.8 Contacts 1, 3, 5, 5 6 were wired in series and monitored in the closed position during testing.The contacts did not break during vibration tests in any of the three planes.n.N/6420HF Recorder 1.Vertical Plane During vibration in this plane the following happened: a)The pen lifter and bracket assembly lifted causing the whole chart drive assembly to vibrate against the front face plate.I b)The retaining clip on the right side plate assembly (P/N G103TK)released the chart guide bar causing the chart paper to lift off the sprocket assembly.The pens there-fore inked in only one spot leaving large blotches.One=pen, the red, actually wore a hole in the paper.c)The red and green pens shifted a maximum of+4.2 and-3.2 percent, respecti vely during vibrati on tests.d)After testing was completed in this plane the chart drive assembly was opened for inspection. Numerous screws were found loose, notably those on the right side plate.No visual physical damage was noted.The screws were tight-ened and tests were resumed. ~~5.0 Test Results (Cont.)Page 8 n.M/6420HF Recorder (Cont.)2.Horizontal Plane (Motion Parallel to Instrument Face)The red and green pens oscillated during vibration in this plane.The maximum oscillation bandwidths were+3.2 per-cent for the red pen and+2.8 percent for the green pen.The maximum pen shift for either pen was less than 0.5 per-cent during the vibration tests.3.Horizontal Plane (Motion Perpendicular to the Instrument Face)The red and green pens oscillated during vibration in this plane.The maximum oscillation bandwidths were+2.6 percent for the red pen and+2.8 percent for the green pen.The maxi-mum pen shift for either pen was less than 0.5 percent during the vibration tests.4.After Tests The maximum calibration changes noted after tests were com-pleted were-0.9 percent on the green pen and less than 0.1 percent on the red pen.

~~C'i 6.0 Test Procedure Page 9 Calibration or function of the test Gems were checked prior to start of vibration tests and repeated at the completion of testing in all planes.Inputs and outputs were monitored per enclosed drawings during the vibration tests in each plane.All the test items were subjected to the following tests in the vertical and two orthogonal horizontal planes: Frequency Range: 1 to 30 Hz Sweep Rate: 1 octave/min. Acceleration: lg at 1 Hz ramped to 2g's at 1.5 Hz and constant at 2g's to 30 Hz The H/62HF Controller, H/62HB Contr'oiler and M/6420HF Recorder were mounted in a EH4-D Consotrol Shelf which was placed in a fixture made by Acton Environmental Testing Corporation. The fixture had a trans-missibility ratio of 1.All other instruments were mounted in test fixtures made by Acton Environmental Testing Corporation such that the fixture had a transmissibility of l. ~'I N I r DRAHIC NQ.t Page 10 4 RETAINING BAR'-'N iN N N ri 0 B SHELF I.PLATE A (Attached to Shelf and Panel Face)(Attached to Plate A and Panel Face)RETAINING BAR O 4 O 0~g'l NN PLATE B PANEL FACE'PLATE A~N~~'.---SHELF J NN 1 TEST SETUR FOR, li/52&IF J)PAwlNt 8 2 Page ll M/&2.HF l oo s2.ioo A LOCAL M'7 PD(H1 looA QiHOTE 5'b>Hl too~CELL Cu CH RccoRbaR, 2 TED se'tvp mod 0/S2 H 5>o0 sl.100~V 4 LOCLI.SA.PolHT laos'oo~,Wcx SET RN HT 9/p

~~j)RAwiNc N.3-feSV,<l.~~For.Y.t',&9 Page l2 I I!'/p CELL I f lOOX?.Lf~g I M/&S D y'v C I C IOO A<educ,wt I I I I~l ICH~CH!!Ci)l;2]RKc ORBS ig i I l-ci.uP v-oR~l&&='a>>" LC:.CVOf>>. I"r t'0" 8 T~.hips/luPeg Ply~~H/ga l.aW S I i (-~-~vpA<o z,'v R.g,cHT~F00 Q.gevRCK VI'{'QR.'(LCO~'HPOT 4.3"4T~1 tt Pg~~.i~,-I cq)>cd l 2 r I cH, XP.b.H i u 6 Page 13 ot'c'w, 5 (a&4 t Jl'cuaz~r-:- <00 M>SddRCG~~1 g/&4>A Sce n Vlf~A~i 00$l I~I I I'-I Cll i I Lc~l RecoADC a.--~.l KENT~~t" TOP 7:Ok N~69@t'IG CTA GK'Nt'4'i yllH j693 poc Q.W:-"vl+~<l's'-lOO~L~~[cuGCoA.DQQ.

~i'giver Iw G Wo 5 Page 14~s Sr 6v.Tv V FoP t/6~~U l I GG~<I~i'~+iC~I I00%P CI'iL L Page 15 f QW (Q~5 x o i'a%INcx d6 08ez 7 X 10 INCHCS ssDC Is v.S.l.~KCUFFCI.5 CSSCR CO, 1 I JUNE 97 L I Test Report No 9154 No.of Pogos Report ol Test on SE I SMI C V I BRAT IOH of SELECTED FOXBORO COMPAHY COMPOHEHTS for FOXBORO COMPANY.under PURCHASE ORDER HO.681841A.J ENVIRONMENTAL '.I,.YiiC'iE Qi.!" COQPORATION Februar 23 1972 Dot Signed Dote Prepo red R.Gi1foy MLT:RG/hfdf Checked A.G roux ARP"QVod iM.L.To1f Ig,/;)0.7'Q AGP1lAl~.f'BI,)YO 9813 gualification Seismic Vibration of selected Foxboro Company instruments. F FOXBGRO COf1PAHY FOXBORO, MASS.r Mo l N~See list in paragraph 2.0 below.~~Foxboro Co.Test Procedure for Seismic Vibration Testing of specific Foxboro instruments for Gulf General Atomic Co.Test Ho.T1-1070, dated Oec.1971.See list in paragraph 2.0 below.NONE February 4, 1972 A.Giroux/R.Gilfoy Returned to Foxboro Company.There was no evidence of damage or deteriora: .-'.;tion to any of the Foxboro Company components as a resul: of the'Se'.smic Vibration Test specified in paragraph 2.0 below, Report No.9154 Page 1 ENVIRONMENTAI TESTING CORPORATION

1.0 TEST REOUIR"-~'E"'TS The Foxboro Company instruments specified in para.2.0 below are required to pass the Seismic Vibration Test specified in paragraph 2.0 below without evidence of damage or deter iorat'.on. The Foxboro Comoany instruments must be capable of operating within their specified parameters before and after the specified vibration test.2.0 TEST PROCEDURES For the purpose of the subsequent Se'.smic Vibration Test, the Foxboro Company instruments were separated into the following groups.Each group was tested as a single unit on special vibration test fixtures manu-factured by Acton Environmental Testing Corporation under this purchase order.GROUP 1 l10DEL HUil'3ER SERIAL NUMBER a)t</62HF-5E-OH-L,Style C,Controller 2532962 b)H/62HB-4E-OH,Style C,Sa+ch Control'.er 2423<54 c)b1/6420HF-O,Style A,Recorder 2462657 d)EH4-G,Consotrol Shelf e)2075-El"QVO,Thermo Couple Assemblv Report No.9154 pago 2 GROUP 1 (continued) NOD EL NUt".BE R f)!1/57SRG2-H,Style B,Consotrol Suboanel a)t1/58P4-FMC-SCC,Style F,Controller h)VX-252,Vertical Indicator SERIAL NUMBER 2533161 GROUP 2 a)H/13HAl-HK2,Style C,d/p Transmitter 2532964 GROUP 3 a)E11GH GROUP 4 a)H/63U-AC-OHAA,Style B,Alarm b)i'/66,Special Low Selector c)N/693AT-OA-6,S.yle C,Converter d)H/610AC-OH,Style C,Power Supply e)N0140YA,Distribut'on Panel 2532963 2407569 2532961 2533160*GROUP 5 a)-H/66DC-OH-4, Style B,Multiplier/Divider b)tl/66AC-OH-XP,Style E,Sq.Rt.Converter c)N)14CAB,Power Supply d)General lee.ric SBi~Type Swi ten 2533089 2532960 GPOUP 6 a)8114YL",Selector Relay Report No.9l54 KNVl AOH M CNTAL g hCTQM CQR BOA ATlOH Pago 3 Each test group was individually mounted to its specific test fixture and the test fixture/test item assembly was moun ed on the moving element of the AETC ivTS Yodel 294-63 Hydraulic Actuator.Prior to 8e start of the vibration test,'he test items were operated by Foxboro Company personnel present at the time of test.Following the initial operation, the following test was performed: FREOUENCY TEST LEYEL 1 to 1,5 Hz 1.5 Hz to 30 Hz 20" DA 2g's peak One (1)acc lerometer was mounted on the test fix-ture and monitored the applied vibration. The above specified test was performed in each of three (3)mutually perpendicular axes.All the vibration or,.all units was completed in one axis before switching to the next axis.Following completion of the vibration test in'each Report No.91 54 i,~~J~axis, the test items were operated by Foxboro Company personnel present at the time of test.3.0 TEST RESULTS There was no ev'.dence of damage or deterioration to any of the Foxboro Company instruments as a resul t of the vibration test specified in paragraph 2.0 above.During the course of Group 4 testinq in the first axis, a catastrophic failure of a hydraulic coupling occurred.The test was aborted at this point while the area was cleaned up and the line was repaired.Following completion of the clean-up and repair, the first run on Group 4 test items was re-performed. All operational data on the Foxboro Company instru-ments subjected to+he above speci;i d test were mon.'tored by Foxboro Company personnel on Foxboro Company instrumentation. /~/'~j Report Na.9154 ENVIRONMENTAL. Pago l)AHE))FGR.TEST EgUIPHENT LIST MODEL SER.NO.RANGE CAL.ACCURACY INV.II FRE(}.Accelerometer Sweep Oscillator Oscilloscope Amplifier Charge l)ydraulic Actuator HTS 204.63 BS.K 4335 Spec.Dynamics SD104-5 I I Tektronix'64 Unh-Dickie 011HGSV 1.35036 21 9027 1-12 2 Hz to 6 KHz.005 Hz to 50 KHz DC to 10)1C Hz 1-1000g 2 Hz-20 KH" DC to 300 Hz 25,000 force pounds 25" DA max.+25 2X+2'5+55 2X Freq.SX Ampl.AC326 SG315 OS311 AH333 1 yr 3 mont 6 mofl t~Vick ers 443.115 PVA120 ITVH Bal 1 intine 310A Hydraulic Actuator Controller HTS Hydraulic Power Supply i 5580 DC to 2000 Hz 120 GPH to 170 GPH Max.3000 to 5000 psi max.250 HP 1.0 Hz to 2 HHz 0-100 volts N/A HY305 3 month The Fo:<bon R,;.beany Test Report ho.Tf-1030 26 AUG 75 Seismic Ltibration Test OT Specific"Hu Line Tnstrurrent'tion Fo:<boro r;ortpany S 0 Ho 73"-55013-Tes.ed at-e Acton Environmental Te" ing Corporation, Acton, Hass.s~~>>e>>>>~~F': H 7 C.{SArt F({..r rt.co ilL(.QQt{{'(p't (t(rll{{']I ACCSPT.t~, t f~ill J,.ctur(ng tnny Oroccc'~(2 Q ACCePT.P'c:c!recut,ming c{(ff<c cd{t u(cr'tot 0'l].4nu: 'cturir.-(n..'y procccd.g g NOT flCC~CPtAOLE-Sc'on>(ncnts. g Q Betll('tlttts: .C.Childs, Staff Engineer N clear Power Products Approved by:((K.G.MCCaslan , Supervisor Test and Evaluation Laboratory Test Conduct.by: I L.1<ewey C~j-.Seni or Te.t{t Evaluation Engineer Tes t ar d Eva 1 ua ti on Labo>a tory and'.Prior Tes.TecItnician Test and Evaluation Laboratory OCT]]o7g ~\e The Fo."bo!a".~..pany Test Report ho.TI1-1030 26 AUG 75 Seismic Yi bb, a ti on Tes t, OT Specific"H" Line lns trull ent'i on Fo:<boro r'oripany S 0 No 73'I-55013 rested at-Ac ton Environmental Te" ti ng Corporation, Acton, tlass.Akeeeoeee~teee.e r$~SEC HYPE V'('G~le.l;QQ(Q, f t S~I/el)f$e(er.y.rCCSPT.;.d r., f~~>u..ctursng rtlni P.OCCC 2 Q ACCisPT.Pec:~r. rceeue yg/E" Q AC t".PT'V/t tg O;"-"T~~,, corrtc cd u~~i cr4teoz t.l nu: cturinsnuy t,rocccd.NOT/(CCFPl ROLE.St.c:luncnts. 5 Q RCt)'AttKS: rau~tJ J sle1:<~/~on!C:rO)gl)L~Ol@cart'e eelce g.C.Ch>lds, Staff Engineer N clear Power Products Test Conduct , by:>-)I L.Hewey C~/f Senior Te t 3 Evaluation Engineer Test and Evaluation Laboratory Approved by: I/~n~K.G.McCaslan , Supervisor Test and Evaluation Laboratory I'Prior Tes.Techni ci an Test and Evaluation Laboratory OCT 1 Lo7ge e s%e 1 l p C1 INDEX 1.0 Test Items 2.0 Test Objective 3.0 Observations &Conclusions

4.0 Summary

of Test Results 5.0 Test Procedures 6.0 Test Equipment 7.0 Test Sequence 8.0 Test Report from Acton Environmental Testing Corporation Page 1 Page 2 Page 3 Page 4 Page 17 Page 19 Page 2".Attached LIST OF ILLUSTRATIONS Photographs of Test Instruments and Test Fixture Sei smi c Acce1 e rati on Test Levels Instrument Test Setups Photographs 1&2 Figure No.1 Drawing Nos.1 thru 7 ' ~I~yves 1.0 Test Items The test items were as follows:.2 3 Instrument M/62H-4E-OJ M/67HTG-OJ l1/610AT-OI ~St le C C C Serial No.2943024 2943031 3086130 Controller Auxiliary Station Power Supply Weieht 10 lbs.9 lbs.6 lbs.Note: This was a specially modified unit, manufactured per ECEP 8262 p 4 5 6 7 8 M/66AT-OJ M/63U-BT-OJER M/66BT-2J M/EH4-0 E B D NA M/6403HF-OJ Note: This was a specially 3091846 modified unit, 2943008 3103851 3005446 NA Recorder manufactured per ECEP 8847 Sq.Root Converter Alarm Current Repeater.Shel f 30 lbs.9 lbs.8 lbs.3 lbs.1.1 Instrument Wei ht 8 Center of Gravit Center of Gravi t In.)Item 1 2 3 5 6 7 8 Wei ht lbs.10 9 6 30 9 8 3 NA~Hei ht 2 5/8" 3 1/8" 2 5/8" 2 1/8" 2 1/2" 2 3/4" 2 5/8" Width 1 1/8" 1 1/4" 1 1/4" 2 3/4" 1" 1 1/8" 1" Len<eth 1 2 II)2 II 5 1/2" 10 7/8" 10 5/8" 7 5/8" 8 I I Note: Height measured from base of instrument, Width measured from left side when facing front of instrument and Length measured from front plate.er~" r t~r s re r\~I~h, ly~~ e ~~~~~~~(2)~M)2.0~T<<Ob'o determine if the instruments listed under Test Items perform per Acceptance Criteria of Bechtel Specification 0000-J820, Rev.0, dated 9/74 when tested in accordance with Foxboro Test Pro ram for a Seismic Vibration ualification Test of S ecific"H" Line Instrumentation, Rev.2, dated Apri 7, l975 and approved by Bechtel Corporation under No.6600 tl 2204-AC-027-5C.~k~~v'A 4"'~, r I~8 I ll e,~~~lir>'S,~e sq~~'~~.~4 I~~ I~~s~)3.0 Cbservations 5 Conclusions With th exception of M/6403H-f-OJ, Style C, Recorder, all of the instru-m nts listed in S ction 1.0 1'est Items operated within their rated accuracy both duriing and ai'ter all rcson nce search and random tests and performed within the cceptance criteria stated in Test Obiectiv=. The largest calibration shifts after each test or output shift during each test for the M/668 Current Repeat"r, M/67HTG Auxiliary Station arid M/62H Controller were less than 0.2%.Also, the output current of d/p trans-mitter supplied by the M/610 Power Supply changed<0.2%during any tesi.Th M/66A'q.Root Convert r and M/63U Alarm calibration shifts after each test were less than 1.04.The output shifts during each test also were less than 1.0%.The M/6ifH Recorder had calibration shifts after each test of greater than its rated accuracy nf'-0.6",.with maximum shifts of 2.8%, 2.5%and 1.Q/for the green, red and blue pens, respectively during any one test.Howev"r, the majority of the calibration shifts were less than 0.5/(see Section S.7).The pen tension on all three pens changed during each test causing the pe..s to lift from the paper.The tension was readjusted after each test before calibration data could be taken.Two screws (P/N X0115CM)which hold the chart drive motor assembly to th=motor mounting plate were found loose during the tests.This caused the chart drive to become inop rative, Neither screw had locking hardware.~, i~~~,'I.i Q1'I~

I~I, I>>>>a a~~(4)4.0 Summar of Test Results Note: All calibration shifts after each particular test are referenced to data taken before each test and all data are listed in order of testing.4.1 H/62H-4E-OJ Controller Bated Accuracy: 0.5%4.1.1 Resonance Search Plane 50%Point Shift>>>>i>>T I 100%50'e 0 Calibration Shi fts After Test,%Verti cal Si de-to-Side Front-to-Back <0.1<0.1<0.1+0.1-0.1+0.1<0.1<0.1-0.2<0.1<0.1+0.1 4.1.2 Random Tests Plane 50%Point Shift Durin Test Calibration Shifts After Test,%0%50%100%Five 1/2 SSE's Vertical/Horizontal (Back-to-Front) Five 1/2 SSE's Vertical/Horizontal (Front-to-Back) Five 1/2 SSE's Vertical/Horizontal (Right-to-Left) Five 1/2 SSE's Verti.cal/Hori zontal-(Le f t-to-Ri ght)One SSE Vertical/Horizontal (Back-to-Front) -0.2+0.1<0.1<0.1<0.1-0.2<0.1<0.1<0.1<0.1-0.2<0.1<0.1<0.1<0.1-0.2<0.1<0.1<0.1<0.1 r>>I>>>>t~I>>>>0>>~~a~a a>>~I>>1~~~>>>>' lg e~'p~~~(5)4.0 Summar of Test Results (Cont.)4.I H/62H-4E-OJ Controller (Cont.)4.1.2 Random Tests (Cont.)Plane 50%Point Shift Durin Test,%100%0'0%Calibration"Shifts After Tests,%One SSE Vertical/Horizontal (Front-to-Back) One SSE Vertical/Horizontal (Right-to-Left) One SSE Vertical/Horizontal (Left-to-Right) +0.1+0.1-0.1+0.1<0.1<0.1<0.1<O.1+0.1<0.1<0.1<0.1 4.1.3 Comment During all resonant search and random tests the internal force balance power supply of the N/62H Controller was supplying a E13 d/p transmitter. The transmitter current changed less than 0.1%during any one test.0<4.2 H 66AT-OJ S.Root Converter Rated Accuracy: aboue 50%output 25 to 50%output ZO t'o 25%output helot Z0%output+0.5%+0.75%+l.0%o+3'%4.2.1 Resonance Search Plane 70%-Point-Shift-T Calibration Shifts-After-Tests; -%0%50%00Verti cal Side-to-Side Front-to-Back <0.1<0.1<0.1+0.5-0.2-1.0<0.1<0.1<0.1-0.1+0.2<0.1~f~S~'I'a a~~s~e"".i,~.~'r~I~e Il ,~ 1 a a~C 4.0 Summar of Test Results (Cont.)oL 4.2 tl 66AT-OJ S.Root Converter (Cont.)4.2.2 Random Tests Plane 70%Point Shiftl<<,K Calibration Shifts After Test 00%100" Five 1/2 SSE's Verti cal/Hori zonta1 (Back-to-Front) Five 1/2 SSE's Ver ti cal/Hori zontal (Front-to-Back) Five 1/2 SSE's Verti cal/Hori zontal (Right-to-Left) Five 1/2 SSE's Ver ti ca 1/Hori zonta1 (Le f t-to-Ri ght)<0.1<0.1<0.1<0.1+0.5-0.3-0.3+0.5<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1 One SSE Vertical/Horizontal (Back-to-Front) <0.1+0 3'0 1<0.1 One SSE Vertical/Hori zontal (Front-to-Back) <0.1-0.8<0.1,'<0.1 One SSE Vertical/Horizontal (Right-to-Left) One SSE Vertical/Morizontal (Left-to-Right) <0.1<0.1+0.7-0.7<0.1<0.1<0.1<0.1 (g~, a~II~e~e a~~I f (7)4.0 Summar of Test Resul ts (Cont.)4.3 H/66BT-2J Current Re eater Bafed ACCT aCy: 0.5/e 4.3.1 Resonance Search Plane 50/Point Shift~tl i T,C 50%0%Calibration Shift After Test,%100~Vertical Side-to-Side Front-to-Back <0.1<0.1<0.1<0.1<0.1<0~1<0.1<0.1<0.1<0.1<0,1<0.1 4.3.2.Random Tests Plane 50%Point Shift Doiot 0%50/100/Calibration Shift After Test Fi ve 1/2 SSE'Vertical/Horizontal (Back-to-Front) <0.1<0.1+0.1<0.1 Five 1/2 SSE's.Vertical/Horizontal (Front-to-Back) Fi ve 1/2 SSE'Verti cal/Hori zontal (Ri ght-to-Le f t)Five 1/2 SSE's Verti cal/Hori zonta1 (Left-to-Right )One SSE Vertical/Horizontal (Back:to-Front) One SSE Vertical/Horizontal (Front-to-Back) <0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0~1<0.1<0.1<0.1 ff.~"~I~~N,~~I

4.0 Summmar

of Test Results (Cont.)4.3 t1/66BT-2J Current Re eater (Cont.)4.3.2 Random Tests (Cont.)Plane 50%Point Shrift Durin Test,%50%l00" 0%Calibration Shifts After Test One SSE Vertical/Horizontal (Right-to-Left) One SSE Vertical/Horizontal (Left-to-Right) <0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1 4.4 t1 67HTG-OJ Auxi1 1 ar Station Rated Accuracy: 0.Si".4.4.1 Resonance Search Plane 50/Point Shift~ri r,l 50%0'e Cal i bra ti on Shifts After Test 100%Vertical Side-to-Side Front-to-Back <0.1<0.1<0.1<0.1<0.1+0.2<0.1<0.1<0.1<0.1<0.1<0.1 4.4.2 Random Tests Pl ane 50/Point Shift~ri<<.r Calibration Shifts After Test 50%'l00%0'jra~r five 1/2 SSE's Vertical/Horizontal (Back-to-Front) Five 1/2 SSE's Vertical/Horizontal (front-to-Back) )~r+0.1+0.1<0.1<0.1<0.1<0.1<0.1 1 II rr 1 r I~

~&~y a 0'e 4.0 Suomar of Test Results Cont.4.4 M/67HTG-OJ Auxi liar Station (Cont.)4.4.2 Random Tests (Cont.)P'I ane 501 Point Shift~0i T 50 100%0%Calibration Shifts After Test,%Five 1/2 SSE's Verti cal/Hori zontal (Right-to-Left) Five 1/2 SSE's Vertical/Horizontal (Left-to-Right) .One SSE Vertical/Horizontal (Back-to-Front) One SSE Vertical/Horizontal (Front-io-Back) One SSE Vertical/Horizontal (Right-to-Left) One SSE Verti cal/Horizontal.(Left-to-Right) P7-GHAT 4.5 M 63U-BT-OJER Alarm Rated Accuracy: 2$4.5.1 Resonance Search"<0.1+0.2+0.1+0.1+0.1+O.1<0.1<0.1<O.1<0.1<0.1<O.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1<0.1 Calibration Shift After Test Plane Low Alarm Green 0~505~100 High Alarm (Red)05 Vertical Side-to-Side Front-to-Back +0.6<0.1-O.1<0.1-0.2+0,5<0.1<0.1<0.1<0:1-0.3+0.4<0.1-0.3+0.2<0.1-0.8<0.1 5~~~~ ~~~e I'(10)4.5 M63U-BT-OJER Alarm (Cont.)4.5.1 Resonance Search (Cont.)4.5.2 Random Tests Calibration Shift After Test Hi h Alarm ow arm 50ll 1005 505 Ole 100~Plane 0%Five 1/2 SSE's Vertical/Horizontal (Back-to-Front) ~five 1/2 SSE's Verti cal/Hori zontal (Front-to-Back) +0.3+0.3-0.3-0.6+0.1+0.3<0.1-0.3-0.2,+0,5-0.4-0.3 Five 1/2 SSE's Verti cal/Horizontal (Right-to-Left) <O.1 I+0.4+0.1<0.1-0.2+0.4 Five 1/2 SSE's Vertical/Horizontal (Left-to-Right) +0.2 One SSE Vertical/Horizontal (Back-to-Front) <O.l-0.1+0.4+0.5<0.1<0.1+0+0.2-0.3-0.3-0.1 One SSE Vertical/Horizontal (Front-to-Back) +0.2-0.3-0.4+0.3-0.3+0.2 One SSE Vertical/Hori zonta 1 (Right-to-Left) One SSE Vertical/Horizontal (Left-to-Right) -0.6<0.1+0.6-0.1<0.1-0.3+0,4+0.3-0.6+0.3<0.1<0.1~~s~\~%~s~~t, p r~~e Ouring all tests the low and high set points were set at 49 and 51%, rspectively. The input was at 50/and both outputs were monitored with equipment capable of detecting 100 us openings or closures.No closure, opening or chattering of ei ther alarm occurred during any resonance search test. ~4 e~~~~4 I 4 4.0 Summar of Test Results (Cont.)I.I~II I-I-IIII AI (I I.i 4.5.2 Random Tests (Cont.)During all tests the low and high set points were set at 49 and 51%, respectively. The input was at 50%and both outputs were monitored with equipment capable of detecting 100 us openings or closures.No closure, opening or chattering either alarm occurred during any random test.Q 4 6 M/610AT-OI Power Suool.v Rated Accuracy: Not AppHcable Note: The M/610 was supplying a d/p transmitter (to simulate normal use)during a>>tests.The current output was moni tored throughout all tests.(See Figure No.4)4.6.1 Resonance Search Plane Verti cal Side-to-Side Front-to-Back

4.6.2 Random

Tests 12 mA Output Shift Durin Test,/<0.2<0.2<0.2 Plane Fi ve 1/2 SSE'Vertical/Horizontal (Back-to-Front) 12 mA Output Shift Durin Test,%<0.2 Five 1/2 SSE's Vertical/Horizontal (Front-to-Back) Five 1/2 SSE's Verti cal/Hori zontal (Ri ght-to-Le f t)Five 1/2 SSE's Vertical/Horizontal (Left-to-Right) <0.2<0.2<0.2 I'4~4 4 4 II ad

~e~~~~e 4.0 Summar of Test Results (Cont.)o 4.6 M 610AT-OI Power Su 1 (Cont.)4.6.2 Random Tests (Cont.)One SSE Vertical/Horizontal (Back-to-Front) One SSE Vertical/Horizontal (Front-to-Back) One SSE Vertical/Horizontal (Right-to-Left) One SSE Vertical/Horizontal (Left-to-Right) 12 mA Output Shift Durin Test<0.2<0.2<0.2<0.2.4.7 M/6403H-F-OJ Recorder Rabed Accuracy: 0.5R 4.7.1 Resonance Search 4.7.1.1 Green Pen Calibration Shifts After Test, A Plane Verti ca 1 Side-to-Si de , Front-to-Back 0/o+0.3-0.2<0.1 50%+0.1-0.5<0.1 100K-0.9+0.7<0.1 4.7.l.2 Red Pen Verti cal Si de-to-Si de Front-to-Back -1.0+0.7+0.1-0,4-0.2<0.1-1.0+0.7-0.5~~r r~~r 4~~l 4 g~~~e~~

I~~~~C~~I (13)4.0 Summar of Test Results (Cont.)4.7 M/6403H-F-OJ Recorder (Cont.)4.7.1 Resonance Search (Cont.)Calibration Shift After Test,%4.7.1.3 Blue Pen Vertical Side-to-Side Front-to-Back 0%-0.2+0.1-0.2 lo fr-0.3-0.9<O.l+0.4<0.1-0.3 4.7.2 Random Tests 4.7.2.1 Green Pen Plane Five 1/2 SSE's Vertical/Horizontal (Back-to-Front) Five 1/2 SSE's Vertical/Horizontal (Front-to-Back) Five 1/2 SSE'Ver ti cal/Hori zonta1 r(Right-to-Left) Five 1/2 SSE's Verti ca 1/Ho ri zon ta 1 (Left-to-Right) One SSE Vertical/Horizontal (Back-to-Front) 0'/+2.7-2.8<0.1<0.1-0.1 Calibration Shifts After Test%%d 50/o+0.3+0.2 l 00%+2.0-1.2+0.2+0.4-0.2 ry~r 1 Aw One SSE Vertical/Horizontal (Front-to-Back) One SSE Vertical/Horizontal Right-to-Left) One SSE Vertical/Horizontal (Left-to-Right) +0.2-0.2-0.3+0.2+0.1-0.4~r r-0.1+0.1-0.2 r r r~a~~

~~I~\I%~'~~I S (14)4.0 Summar of Test Results (Cont.)4.7 N 6403H-F-OJ Recorder (Cont.)4.7.2 Random Tests (Cont.)4.7.2.2 Red Pen~: Plane Five 1/2 SSE's Vertical/Horizontal (Back-to-Front) Five 1/2 SSE's Vertical/Horizontal (Front-to-Back) Five 1/2 SSE's Verti cal/Hori zontal (Right-to-Left) Five 1/2 SSE's Vertical/Horizontal (Left-to-Right) -0.1+1.6+l.9+0.4 Calibration Shifts After Test, A 50%+0.2+1.2+2,1+1.0 100%+1,0 0.1+2.1+0.5 One SSE Vertical/Horizontal .~,=';, (Back-to-Front) One SSE Vertical/Horizontal {Front-to-Back) One SSE Vertical/Horizontal (Ri ght-to-Le f t)One SSE Vertical/Hori zonta1{Left-to-Right) +0.1+0.5+2.2+0.2+0.6+0.2+2.5+0.4+0.3+0.1'2.5-0.1 J II I~,,~I'K~'K~~II I~J~r', I~J I I K r I J uc4

l a~<~4.0 Summar of Test Results (Cont.)..e J 4.7 H 6403H-F-OJ Recorder (Cont.)4.7.2 Random Tests (Cont.)4.7.2.3 Blue Pen Plane Olo Calibration Shifts After Test,%50I 1001 F ive 1/2 SSE's Vertical/Horizontal (Back-to-Front) Five 1/2 SSE's Vertical/Horizontal (Front-to-Back) Five 1/2 SSE'Verti cal/Hori zontal (Right-to-Left) Five 1/2 SSE's~Vertical/Horizontal (Left-to-Right) One SSE Vertical/Horizontal (Back-to-Front) One SSE Vertical/Horizontal (Front-to-Back) One SSE Vertical/<<i:.Horizontal (Right-to-Left) One SSE Vertical/Horizontal (Left-to-Right) +1.5+O.1-0.3+0.2-0.2+0.5-0.3-0.1+1,3 I<0.1-0.2+0.2-0.3+0.3+0.1-Of2+1.8<0.1<0.1+0.1-0.1+0.3+0.2-0.1~, l~)~~~~'~'ar ff'rl al, f Il*~~l I~r~f~I l l~I ll e~~=~~t f%I%Vl:, e c~f~ h~tt~~(16)Summar of Test Results (Cont.)4.7 tl/6403H-F-OJ Recorder (Cont.)4.7.3 Comments 1.After each random test it was necessary to readjust the pen tension on all three pens.2.After Test No.4 (five 1/2 SSE's in the horizontal back-to-front plane)two screws (P/N X0116CM)which hold the chart drive motor assembly to the motor mounting plate were found loose and rattling near the front door and caused the chart drive to become inoperative. ~t~I~I I~I~r (,~I~t I~I"r'I I'h~r 4~~1~~>e~'g~5.0 Test Procedure 5.1.1 Rack-Mounted Units The units were mounted in a test fixture which simulates normal rack installation (see Photograph Ho.1).The front terminal plates of the units were secured to the test fixture by screws through the holes provided.At a point approximately three quarters of the distance from the front terminal plate to the rear of each instrument, supports above and below the units were installed to limit vertical movement.This rear retention simulates the use of Unistrut in present rack installation. 5.1.2 Shelf-Mounted Units The four-unit shelf was mounted in a test fixture secured front and rear by normal installation means.Three additional seismic modifications were made to the standard EH shelf for this test.The first modifi cation was the addition of a retention bar with spring loaded clips mounted towards the rear of the shelf to minimize verti-cal movement of the installed units (see Photograph Nos.1&2).The second modification was the addition of spring loaded clips to the primary top horizontal member of the shelf, again to limit the vertical motion of the instruments. The third modification was the addition of pawl mechanisms (see Photograph No.2)which are actuated by screws below the front plate of each instrument. Each screw rotates a pawl which engages a slot in the bottom of each instrument housing to assure that the instruments will remain in the shelf during a seismic event, 5.2 Test Monitorin'he instruments were operational during all tests.Calibrations were made before and after each test and each output was monitor>..d during all tests.'he test setups were as in Drawing Nos.1 through 7.I 5.3 Resonance Surve A resonance search at one octave per minute using a sinusoidal input of 0.3g at frequencies of 1 through 40 Hz was run in each of the three major, perpendicular axes.1 5.4 Random Test The random input was simultaneous biaxial, performed in the horizontal A and vertical directions and in the horizontal 8 and vertical directions. The test fixture was then rotated 180'rom the original direction and'.-both horizontal/vertical components were equal and resulted in a TRS which'enveloped the curves of Figure Ho.l. ~~5.4 Random Test (Cont.)The test duration was 30 seconds for each biaxial test.The frequency range was from 1 to 40 Hz.Five 1/2 SSE tests in each of.the four planes preceeded one SSE in each of the four planes.t I~I>>I~~(I~h ,~~'I I r~>>y r (t%'~~~((>>(1 a(a'\~~~q',$(l(",

i'~a'a ie e~e~~~a (19)6.il i~i 1 to de 1 Seri al No.Date Ca 1 i bra ted Next Ca 1>bra ti on Date"--'-=-EDC Current Source CR-100 t7777 2/21/78-8/21/78 Brush Recorder Hark 280 15-6327-10 779 7/26/74 7/26/75 Brush Recorder Hark EE Hewlett Packard 4 Channel Recorder RD-2521-00 110 7754A 1135A00104 6,'l5/75 2/17/75 3/76 8/17/75 Fairchild Digital Hultimeter EDC Voltage Source EDC Voltage Source 7000A HV-105 HV-105 1122 5118 4785."/75 5)/c'.3/75 4/7/75 8/75 12/23/75 4/7/76~)~a I a~~II 1~a~~i~;r~s ~~~~(2O)y4;>0~hh Test Ho 1 2 3 5 6 7 8 9 10 ll Resonance Search Resonance Search Resonance Search Random Test (Five 1/2 Random Test (Five 1/2 Random Test Five 1/2 Random Test Five 1/2 Random Test (One Full Random Test (One Full Random Test{One Full Random Test One Full SSE's)SSE's)SSE's)SSE's)SSE)SSE)SSE)SSE)Plane Vertical Side-to-Side Front-to-Back Horizontal, Back-to-Front Horizontal, Front-to-Back Horizontal, Right-to-Left Horizontal, Left-to-Right Horizontal, Back-to-Front-Horizontal, Front-to-Back Horizontal, Right-to-Left Horizontal, Left-to-Right w~y~~h=~h~I 4~g~~w h~~y~~I q"~l>>w*y'I h.wf~y~~h h.I,~I,~~h I'I I ,~w'h.-y I lhy~4.wyy!ay,

I~~~~II'~I~Drawing No.1 EDC CURRENT SOURCE INPUT 4-20 mA H/66BT-2J STYLE D CURRENT 250A REPEATER OUTPUT RECORDER~~I I~I y'~~W'll, I~I~I II~I~I'~S~I"~.I~~

a~~Drawing No.2 EDC CURRENT SOURCE 4-20 mA INPUT ALARM ALARM 2 63U-BT-PgER ALARM 1 STYLE B l 100 us RELAY CHATTERING MONITOR~~'I~~~'~~~~8 g+'f', 5j ~~~t I Drawing No.3 67HTG-OJ STYLE C SST POINT~AUX.STATION 250l.RECORDER I>>,I E>>>>I I It>>I~~'t t t r)>>~~h ll 1 ett 1 A t I I I I~r I~~~<>s'~~~i I r" 5~~,~4~I~Ir>~~y 4~~Drawing No.6 INPUT BLUE PEN N/6430H-F-OJ ~$EDGE CURRENT SOURCE 4-20 NA RED PEN GREEN PEH STYLE A 3-PEN RECORDER~i'7'b~~,1l,g (~I 4~I j1 gt ia\1%~I1 h I~~~~1$~~'~'~I,~~.

~I Dra>zing No.7 d/p RECORDER<, 2500 LOCAL S.P.62H-4E-OJ Style C CONTROLLER 250@I RECORDER 4~K~~f~r J~~ t i<<I"5 I~I O I I~2 I~e~<<~e;'.1~'~I I 1!I~I~1~I"II~II~~I I~~I I~'Lt I~I s I I tT'g: ate~f I" It!I Ig'l rg I~~l,le'I Iis I':11 as.ii~I~~I.'~I'I I~Ii I peg!.I ,,~1 i~~er~!l~l I I II a I I I'~a\'I'e III j'el I 1~tla~1 I':~a I~sit tt i sl I I ia~i a~1'i.a aa~a gsa oa v ooe~le~g ,i,i~a~lei Ie I~<<II~!.I I~<<4~'ii a~I~'ili~.I~~I I~I~'a~al I a!.11 e J s s it!~'I I~s I~e~1 a I~~I I i~I l I-'}-!~g I l 4'~I I I I.I!lt 11~!1~,I el Is a l I e I~~'~I g~I I~1~I'1.0'e A v Ce~IiIii'1 I.s!11~I~~I Figure Ho.1\-<<4'~-~I Acceleration Response Spectrum Taken from Hechtel Specification 6600-C-2102 Figure 10 Damping-2%Elevation-386'ate 7/22/75 I I~~~I i~I'.i Ii~a'1'I'!1!l!j~I'I nir.~\~I I~I~I",;I I~~I'l IIg~tJ I.I~'g il a~t~.'.I'I.1 I l:, ti ilis'I" I~ie ii ,'i a Iel l I;~~t I~I ji I, I'I'!'i, Il gsa~t t I t~l Full SSE (Fig.10x1.5).'L.st!~gila~I il'I e 1~eel~\T I~t~I'I~'il e li 1 T.g~I'i I e I I t a I I~~"~~s~I!I~'I l I t I a'I is!a I~I,!t Ij.", I j I~aa t I~I I~I~j.I tst~~la.~i I~I I.~il I~~t!~is I I.Ij',.'}1!:I~ef,'I'i a~1 li',a 1/2 SE l~e a<<1 al a 1!I~I e I~e I!I is~I+--T~j~e I e l~tss I~a 1~~!e 1<<I~<<t'ia eat, ,1st'it'ill"I~e I~a I~!",}~~'Its~a~I~~-~I'~!<<,~I I I e.'ll;I I I'~!~t'it IT e!a!I'~I;I I s!~'I e~sg g I~~!I~I~I~i II'!<<~I~I~a 10 Freauency (ft~'4 V~eat+V yy+()~Ie II I~,t g~I~14~I~J I.I I~I~~~I~~~~i~~'I ii;I I'al~i~~I I~Ieg~i Iia I,~l.ie'le: I~i Ji'1', Ii I ja i I~J~J'A"rt-~!~I"'1'I e e 1~I<<~1~~igl I 1'ai I.~e ,I'~~~I'~I~I~~~i,li~~~~I e'I, ,I'll ai g~,~~e g~~;I~~~I~~~'~I 100

~~~~Photograph No.1 Front View of Test Fixture and Instruments Tested 4*r I'E~~t 5:j 4>p'i4'b)-j-,):,"-. 0 QO>~I I;I~I~C>lT~~pic+I~<<1>444>~~i1~I'4 44 w 4 t I>'.14 0 I t.t'>44" J~,p,.)t>l Rear View of'est fixture and Instruments Tested~I~I~CI C EP ,t S e"~~>-Stt+0 V~~y, t'~>t 4., 44 np,"-~4MMtfk~~'t'I: "RA u'~t'~i;4'-~4'.>~~'t t 4 I 4.4 I 4 4 4~~4>, t 4~H>t>.~I*~'4~) 0~I I~l~~Photograph No.2 1>>~Corner View of"H" Line Shelf Vertical Restraint Bracket~ll>>j:.'l'I I I~~II ll.qadi I ll II I~~I~.I>>I f" g'LII n.'.'.'th.q.~QP AA I Front View Showing Latch Locking Mechanism for"H" Lin>>Display Instruments P ri>j*~VIP lf jig~I I\I I I I P~~~~"~I P I l I I j I I~>>l P~~PP

g~~,~~n~The Foxboro Company Addendum to Test Report Ho.T4-1030 9 SEPT 75 Sei smi c Vi brat i on Tes t of.M/64H R rder an d~/63U Alarm 87-Tested at-Acton Environmental Testing Corporation, Acton, Mass.\eviewed by: J.C.Childs Staff Engineer Huclear Power Products Apoed y:-K.G.McCasland, Supervisor Test 5 Evaluation Laboratory Test Co cted b: L.W.e Senior Test E=Evaluation Engineer=---Test 5 Evaluation Laboratory OCT g tg7g~K~a I'a~"*I>>'-a~ 1.0 Test Items 2.0 Test Objective 3.0 Test Results and Conclusions 4.0 Test Procedure 5.0 Test Equipment 6.0 Test Level Page 1 Page 2 Page 3 Page 4 Page 5 Fiqure No.1 I IJ 1~~ ~5 I~~1.0 Test Items Instrument H/6430HF-OJ N/6420)IF-OJ H/63U-BT-OJER ~St le Style A Style B Style B Recorder Recorder Recorder Serial No.3091846 2943033 3103851-S 1 e~I~rl, LI<i'AE~j~p <<4v~'0 2.0~0b'ective Determine if the modified tl/64 Recorder chart drive functions properly and remains attached to the motor mounting plate during four full SSE's as noted on Figure No.l.Initial tests T4-1030, dated 26 AUG 75, indi cated that the chart drive assembly became inoperative because two screws holding the motor assembly to the motor mounti ng plate became loose.t1odifications to the chart drive assemblies of the two th/64H Recorders were as follows: l.Unit Serial Numbered 3091846 had Loctite@242 applied to the two screws attaching the chart drive assembly to the motor mounting plate.2.Unit Serial Numbered 2943033 had lockwashers added to the two screws attaching the chart drive assembly to the motor mounting plate.Also, step the input of the N/63U Alarm and monitor the outputs to assure proper operation during seismic tests.1 h~I~'~~e ,~~>~~ee i~h~4 1~~iitb r',~~' s f I c,~~I'l-3-3.0 Test Results and Conclusions The chart drives of both N/64H Recorders remained operational during all tests.The H/63U Alarm operated properly when stepped during all tests.Both the N.O.and N.C.contacts of each alarm output were monitored and operated properly during each test.~'I~~,'>~~'I I'~'6~t gfsgl ~I, g~~V 4 4.0 Test Procedures 4.1 M/64H Recorders The two recorders were mounted in a four-unit shelf which, in turr;, was mounted in a test fixture secured front and rear by normal installation means.Three additional seismic modifications were made to the standard EH shelf for this test.The fi rst modification was the addition of a retention bar with spring-loaded clips mounted towards the rear of the shelf to mini-mize vertical movement of the installed units.The second modi-fication was the addition of spring-loaded clips to the primary top horizontal member of the shelf, again to limit the vertical motion of the instruments. The third modification was the addition of pawl mechanisms which are actuated by screws below ihe front plate of each instrument. Each screw rotates a pawl which engages a slot in the bottom of each instrument housing to assure that the instruments will remain in the shelf during a seismic event.4.2 M 63U Alarm 4,3 This unit was mounted in a test fixture which simulates normal rack installation. The front terminal plate of the unit was secured to the test fixture by screws through the holes provided.At a point approximately three quarters of the distance from the front terminal plate to the rear of each instrument, supports'above and below the units were installed to limit vertical movement.This rear retention simulates the use of UnistruP in present rack installation. Test Monitorin 4,4'P.~~I I The M/64H Recorder chart drive was operational during all tests.Checks were made to determine if the chart drive was operational before, during and after each test, The M/63U Alarm was stepped during all tests.The output was moni-tored with equipment capable of detecting 100 us openings or closings.Random Test The random input was simultaneous biaxial, performed in the horizontal A and vertical directions and in the horizontal B and vertical directions. The test fixture was then rotated 180'rom the original direction and both horizontal/vertical directions run again.The magnitude of the horizontal and vertical components were equal and resu'ited in a TRS which enveloped the full SSE curve of Figure No.1.The test duration was 30 seconds for each biaxial test.The frequency range was from 1 to 40 Hz.One SSE in each of the four planes was tested.t I I q k 5.4~TE Descriotion EDC Current Hewlett Packard 4-Channel Recorder l~iodel CR100 7754A Serial Number 4717 1135A00104 Date Cal ibra ted 8/19/75 8/75 Ca 1 i',';i on Hatri x, False Contact monitor 202D 310 Cal.Interval 6 r.'.o.;.'5 5 4 I(I e 5~~5 4~a~(5P ya Ee

P r"e f{ger.I<it~~t ta'P.J ei r e i fit~'<.I)i~-,-5 I I," 0 r 2'at ti e'Ia.ss 1'a ga 0'-, 0.1 i e I i-~~~g~I I<g I s t~1 i I r!~I 1~~~~at t~~~f a~'I~'s<~~." t~~1 I't!~,~k1 I f~I~ts-~I'.i e~~~~I I~I}I~tii 1 t~tit)e aJ\i Ig.';,I Jl;'I;ri I jti~1~t e~e".I e'li II'i la i"I',~'~a'I'i li;, I!'I:ll.1 v~'I ,ia ei Pb'4 CO Cl ia~I aaj~I~g I f1"-.)J~l~I r!'-L;,."~t~l~q a I I r~i I eai~s~f~~1 I~i a s I~i~~~i I I~e~;~ii.;>>~Ili I'~I-'+.'+~~i'l i ,t~I.ti~i tl'li 4a r ie i'fit~i t'aii iT)., as'i~!i i IL'I I:,-<it<If!ifff:~'ie)I ti'1'ijj J<l:.I!'.Ii"e 1.0 e e a tas gr<Jgf I P!gift L".~: LL"'i{l~~<: 'I:i~~~e~e iii: I~,""r'igure Ho.Accelerati on Response Spectrum t'aken from Bechtel Specification 6600-C-2102 Figure 10 Damping-2X Elevation-386'ate 7/22/75~~i t)I~'r 4!g~.I-I I'tt'~<<r~')I s~<II I~~t~~,tl~~I~~I~i t~ar I I t~~~'.l"ii Ii:ii:~Ia<Ji;'i ii.i t'i~g j~~'I l t~t~I" a~i~I 1 i~~~i~Ii!I~~I:~It tsii 4i t i ,Is'ew , I e~t Sg's Aa;r<'.i i~','i I,'!1-t~~I i I I~,I~ii~Full SSE (Fig.10x1.5)>!~~<I'~la I I'g t~I , a.)~si 1'~t I'lt~t'<I~II~~i'.)r'if!~its ti sl~!I'I~~I'e~i~~I'itl t~i<~i:Af il~I~I'~~~e~~'I~~.I ej~f~~I t I's~asti ii,~~e~..'t'<i'i II','.)-.,'~i, sir I i I~~i s i i~~I I i I~~I~je~ff" rs see I.'~~t)~I!~~4 i t'e.'j);'si r.'~~'i i g 1/2 SSE~~I~I I Ili.f!i~~.:fi~e~~i't tet~i s ji l'ff LI{!ii!ilii,.I+jt ei~I g l:"'d jfLI i~t'l'i;If I I i et'i s I.{t g e e I!~.Il<'lJ i 1 I st)~'<I~I'~ai Its I',Lf s.a I 1 if{it/i{t'at',il!~'i'I e~<<)~fei'f Lt;.:1:.z!L'I!fd'.'I I.Ii it{i)I'l,!,IJ ji IIi;~~I~et s I ,if~~~tj{~....~~~~I~~,......l La{{i)'t 10 I~~i,etc@~r'K;I I')i'I'ls~, a1 lil.'I'i 4s'I s.I l I:~t i~'.I')I sii ,ej;ta s I!)!!l','i'i i"'4 a<'~t~i'~'1 t~a I~~t~+I f~I~,s~Il<~I t a I I j I~t~~I i I I s s I'I~~~~t)~~.l!i:,"~tl I~'~I:l'L 1 I tl..~~~I t~~I;~~.'~a~'il~<I a.<I!t i)e~~!i~I!I~:~l~is a~e~~~tlt I pa~e iLf'.;I i Qlt t.'+a I~s~~I~~l:!i We!I's'TI sl I I!~s~iii I~I I S I!I e'04'i Il's~1'~i I e,e f t I!'I'gl lif:~g s!II~tt~'ti~~'e H ii ,!f Ts II ,!4 i~~'i~i asa gta et J.<~a~~~t~t" ,l I~ii ,Il!~'i)il;, t't'~t ii!.ti.e}i e~~"~a tt)I!.I'4 l<'..~t~', I I'tef~tt~)!t1 i.I~,'i~i e s I I: Ia s 1)'Ii i~4a ie~)~iiif~~I i t~~I'I!I il ,~~~t!!l!i ai)'ltt ftl.a e'i ii~tIf i.s~ttf t,"1 ,ii is<i t~ea<lli i~ja Iae.i i V <<(<<~r'g'Vl, Q li-(2 ('.Oti 3:?.'Q1.+:: 'n Ii)a.r,C')C)Ih. (.L'(t (C i<<'f.c'a a~r~~ao<<J~}CI (c}N'j'1 1~3 l>3.'cc'nc.h r..a<<r<<)i aa'aa I (v r'<<~1 nc'<<a I Jr'ac~q air'4<<>>'c'ra h r'~glar l..-a<<'I r>ana a'ra>>a nr 1'Cbrit.'V O, 3,'!IO"O 3'Q;1 V.,":-r":.J.397 a~~~<<,~~~~J.ar~m C c L~~c': 'r>>~a', r'c~a~'~~~~C~a~'.~~~~'GTa33.3 Cf;;.., gt".'J." tC.':..., 3)",,'$Ott nr..: Jl(C"r((cnQ Q), I',~~'I,\I'>>j C j.'C]ac..<<pr<<) nl,r!nn)1 n a'l,l~I~>-na<<:t li?rn nc;(a33 ca<<3 Z n n O~,-l-p, (ancta c na-~a~.~a nra (133'tr.t ('O-c'(I ll" ca.'3.'t'0'~':Vpi'c'a'Q Q"'..L)"Q'"(3 c."~:3-t':-P C'!YC".V.tja'l~n~~<<~rc\r c~'5'?3.liC33 c J lo'l-2 a".J".'.r 7:." fjl?JtC}3 I c,".3'lc c.',Tr.l't-2 a'O.t a'"..: "r's.'l3','tl ~<Jaji3c ((lite I rgn<<ic c<<Q$<<<<l~Q(<arj c O c t'ter+>t(0.$q'rr 3t, t<<ra<t>r31 yra>'3+r 3>>.,Ja',(ta 1>a~~a.a<<>>a7 J,~a..~~c ar I.w a cr ,<<<<~D~,~~a~'a~<<4'I<<r<<1}to).'..'ri(?:a'cc"3. c".$a: t.'33(.G:3 c tl nt.o v"~03.cD;" VQ t" CQ).Qtp (<<1 I~(I3<<j aq+nn Cng+(>>pj'et i a q>>c~3}3+,<<n jrag l ip 3.'c.'CO'U. a.',I'rC t.act?.'337rU':Q 'O.'.1:n c CC(!'?a.c~'-.('aa 3 Q$llo 3$<<'3"v"v.c'$J Ga".-:"ai'Icc:j~~~~~~~~~~~'r a~a~u<<.J\<<C~ar<<a Cr'<<3~I~<<rc~r cra~"n--I a-4'r'a$t(3tr$IQ;)2$;r'a c,Cjic<<$4;t.'a'I3 c U,)1QCtn(crp (,'Clan-Q).gpI liag a n J tll'-.;;... ~-,3'j C~'O'" (j'JO'.it-tp- ',"J.C!(-~.g(I a';.3.3}t.", Si(1C-Ja'O-5i (co-2.C".f J.'Zt VQZ",.3.C(.l. J..2+yG mal)}17<<(.'0'it>~'On"'}3ui'Q Co rŽ3""A"'C.'""3'3" 6333 3 3..J t (3'Q$'U$(, J C Qc.C(Q'3'Q Of Cg"'C<" (a+.$a'tJ3'a,c,'tl Q".:: a<<3.t"'aa (', a a.'3~~into Cocle'cno a S VQ~Q".3 tP.~Ctr'I;3.(:Q(c O'8-.0':aQI'paiV3.'i~J'. C.'.CL!'I c'!'(a.p~I<<~~~'33 3(tcrJ+3$O'rfcQ t?3'\Jtr JO a'rQ aj$p t a A(~7rat)Cc ft'g C 03'3'I3 i.t V.a T r ra i<<<<nn I~J (tc>I n,c n~nn>~r~~n"~~<<<<lttC AnnvC I w lrlaC r.tto rntt>COT rcCCO".O Or O'A, OOWttt(n rttO".%VX~It CIIOVCC Lt.CCl rtC COIII<<ott*'trot .1 C'I r.rr"Art'ra<<r-<~~a l'p.r.'J~TI>~~I rgltai-trjq a<<'C i~r~.t C'<tnac f'<<<<,+fa/I r,~I~ n Bak Unk ut't)IS'oave 0vIOI P.PUACHASKR Westinghouse'AT K WKSTINGHOUSC GENERAI ORDER NO PARATU5~"-2 St'r i t;ch Node l BATING sHoP oRDER No, DeveloPm'i'esi;.i>~) ~of':,'-2."~rt.hach was done on l)evelopkk)ont; mode..".n)0 t;I.r)a.Col)f act I<<)sistrinco -i'lang readu))ps o'rop were a<en, acro'" flokyl3 l)r..T)):i.s result;s:i.n approx~ma e y.o llkls con ac rests ance.DlclecL;rlc' The svvi.ca~st.x" ac orx y.vz.".ooo bel i."een ooen contacL;s be vveen~clgacen con ac s, anc con ac t;erminals and LI,round.Contact Interrup v.o.n-vese e" o vverc con uc.ov con';unoaro voltage con acts no lav np e w ee s on eac enc o ro er cont'act;. R suIIII-ary o e resu.s ave as o.ows: D-C o af;e I)U)V bO V 2gV 2$U OOV 30A 1.5A Hot;Tested 25A r)R Hot;'i.'est;ed D-C Usin 2'cont;acts irk series 2" OV.xCoil A k)rox..2 henry'i'heŽe tests were macle with o"clllorra >h to dot;ormi.nc loni,t;h>>~made.H.i.;her rabin..s coul.d i)e used if.ad;acen.contact's Irere noi;used.1>>terrunt;ion l..i.fe varies vr i.t;h t;ho cur)'ont: anti voltak;c t'e rector thc currant anvl~vole;n"e L'ho"ho>'tcr t)vc 1.LL'o;'Lt 1VL lip vI)l t: A-0 i;ho l..i.fc i;e."t;cd 2 Ikki3.3.ion. 'ct;ai;2A ll')V A-C t'e l:i.fc c;)n b>>e:;-Ikect,e>.Vikcci)'lnica3. 0 crai;i.I)n: The si;arwilec.l. rk)ecl)al):i.: m Pro.: silt'.i.s fact;vrll t;csi;ed f'r i In:i.].l.i.or) o)erat;:i.o>)s. lrcar on t:oz'i.n);i)col reduced'na)action but;sC:i.ll retained)os:i.t;ion act;ion.t l;)ss o3.vest;er molded)art;s sl)owed>)o.reat;wear after mi3.1).ons of o erat;fons and a ear,ood for ion, life.I'HC ABOVE IS A TRUE AND CORRECT BCCORO OF DATA OBTAINED FROM TESTS AT THE WCSTINGHOUSE EI.CCTRIC CORPORATION. vAGC l OF l I*GLS SICNCD 7 i-.,a t;Picots'our h't.P..'.i,1 v.i.u" WORIk5 OF CHGIHECR

a~<vrr I Vl ICOSI iI roirrr 640I F,~1 t r FVACHhSEA WCStU IghauSC VIESTINOHOUSE OEHEAAI OAOEA NO, AFPhAATVS SHOP OAOEA NO.OAI-'lan 5 ART IHO I (1 r"n~d-Q LLhcQLLa~"~ULQ QSL~m~>~m~ 1 h 4i'i~~ood condibion s n.ont;t;.h~-r h w r u N r i F I.">>r i s i,i f..Earlier test:s shouted s'in breaica e but wit;h~dIii t;ion of t;ef ion tubin-und'er s rin mechanical life was r-at;l.e>: anded I,:i.fe of 0 million.o>erat;ions ivas comoleted on a heav load s rin t;hat;is'uch st;ron ier Chan used in nres<<en'oduct;ion. I vc I rn~0021 ohms nd t;I:I'i>w s 00 0 ohr." c'.o-~t-}i s';-: C',.ct;r""sf;inc of stand rd ont'4 roland.r" lIlosocl O'I<<II~T.i~<: 0'ra mi'vo~it'"'i:(as foun 1 h t cont', c-s f h no"n rru 8 on o curr nt for 6 mr'i's'i.nc ud s t;he o ratio of II>dtum si si nj't;hout; cont;act;Irheels~I)r mi>>~i1O Ii.M I I'I':!gl ii~~i~t sv'v': g~~Z"I'O~I Q E hII E IS h TAVE hNO COAAECT AECOAD OF OhTh OQThINEO FROM TESTS AT THE WESTINGHOUSE EI.ECTAIC COAFOAhTION. ~'I)I WOAKS OF 5K~OI'~I'ACES'ICNEO r'I~P.a'>i.1 V I u G ENCINEEA P i t 1.L'.-.-'~:.'L"":stinghouse Relay Instrument Division IQ...I sL%~.>>.v V/ESTINGHOUSE RELAY-INSTRUMEN I DIVISION PROTECTIVE RELAY SEISMIC EVALUATION TEST PROGRAM--.I (,(,pt.5~ihe Westinghouse Relay-Instrument Division Protective I<clay Seismic Evaluation Test Program, follows for the most part, thc guidclincs set forth in the IEEE STD-344,"Guide for Seismic Qualification ol'Class I Electrical Equipmcnt for Nuclear Power Generating Stations." Each test is basically conducted in two parts.Part A of the test consists of a resonance search of the test relay and Part II, the determination of its maximum seismic operating fragility level under seismic vibration. Thc rcsonancc search of a relay under test is accomplished by a onc octave pcr minute sinusoidal wave swccp ol'not less than 0.2g input lcvcl over a frcqucncy span of I.5 to 35 hertz.Any observed resonance of thc test relay is noted by olT frequency stroboscopic inspection. The maximum seismic operating acceleration level test consists of applying sine beat inputs at discrete frcqucncics in three mu(ual)y pcrpcndicular axes simultaneously (east-west, north-south, and vertical). These discrete frequencies are dctcrmincd by computer analysis such that any relay test sample resonance is excited to at least I/2 peak amplitude. For a sine beat excitation of IO cycles/beat thc discrete frcqucncies of'1.25, l.7, 2.25, 3.2, 4.25, 5.9, 8.0.I I.I, I5.4, 2I.25, 294, and 35 arc applied for assurance that any natural resonance of the test specimen which would alfcct its functional capability vvould bc dctccted.At each frequency thc sine heat input level in acceleration (g)is increased until there is a change in state of any ol'thc monitored relay contacts.Thc test consists of a minimum of 5 sine beats each of l0 cycles/beat with at least a 2-second interval bchveen beats as shown in Exhibit I.The input acceleration is applied at a 45-dcgrec angle to the relay major horizontal axis and at a 56.3 degree angle to thc vertical axis.This provides a vertical force xvhich is 2/3 of the horizontal forces.A vector diagram of thc resultant lorces is shown on thc seismic capability curve I'or each type relay.After thc testing of the specimen has bccn completed with thc above orientation, the relay is rotated I80'n the horizontal plane and the fragility tests arc repeated.This additional parameter is based on thc I EEE STD.344-l 973 which recommends that if thc test inputs in the two axes are identical and in phase that the test be rcpcatcd with the inputs I80'ut of phase.The purpose of this new test is to insure that all modes of coupling will bc cxcitcd since relays arc assymetrical due to their structural characteristics. Thc resultant vectors will thus excite any test relay rcsonancc in thc I.O to 35 Ilz.range in any of the 3 test planes.A tninimum nf 3 relays of each pat ticular type mechanism selected at random frown calibrated production rchys is used to establish thc scisntic withstand capability curve of thc protcctivc relay.Thc capability curve for each type relay is established by the lowest ((g)Icvcl points of any o('he relays tested.A Iinal test rcport capability curve is made at a slightly lower Icvcl than thc'bove cstablishcd curve to allow for thc norntal manufacturing contingcncics. The state of the protective relay under test is in accordance with its normal application. For a normally cncrgizcd relay, thc current circuits arc energized at 75%of their rating and potential circuits are encrgizcd at l00%.As an example.a type CO-8 ovcrcurrcnt relay with a tap setting of 8 amps will be cnergizcd with 6 amps AC in its current circuit.All critical contacts including auxiliary elements nortnally furnished in the test relay (ICS, IIT)arc monitored by a timing circuit to dctcct and measure changes in status of such contacts. Thc loss of function criterion for thc relay test program is a ch'ange of status ol'any critical relay contact for a duration of two milliseconds or greater and IO milliseconds or grcatcr.In order to establish positive documentation as (o thc capability of each relay type under scisrnic vibration tcs(ing.it is necessary to test the relay under at least two of the following three modes of operation: (I)its normal non-operating mode energized at a current and or voltage level which docs not cause its operation (quiescent) (2)thc relay functional change to an operate mode during the sine beat test whcrc thc cu'rrcnt, voltage or difcrcntial change is applied, depcndcnt on the relay under test, for ascer(jinment of the proper functional operation of thc relay in a seismic cnvironmcnt and (3)the operate mode, if applicable, such as a latching auxiliary relay.Exhibit II is a comprchcnsive list of thc test equipment used in thc protective relay seismic test program.Figure I is a closeup viciv of thc relay mounting test fixture attached to thc Unholtz-Dickie Model 6"Shaker.The horizontal and vertical accelcromcters arc shoivn rigidly mounted to the test fixture adjacent to thc test relay so as to accurately dctcrmine and record thc type and amplitude of the vibration applied to the relay mounting surface.Figurc 2 shows the test control and monitoring cquipmcnt. A special lightweight, yet rugged relay mounting fixture was designed to obtain the minimum distortion of any vibration sequence applied by thc shaker shal't and to accommodate testing of the many sizes and types of.relay cases.Thc relay mounting fixture ivill permit, with the use of adapter plates, the application of vibration in at least (7)directions with rcspcct to the test relay.The sine beat method lends itself to thc seismic fragility testing of protective relays.Thc protective relay is a relatively small coinplex mechanical assembly whcrc there arc no apparent marked peak resonances so that thc loss of function is a morc critical design problem than an obvious strength failure.lt should be apparent from'the above test procedure that each type of relay mechanism is subjected to a great many tests in order to document its capability under all modes of operation over the critical frequency range.The sine beat method limits thc quasi.resonance build-up and avoids excessive fatigue in the cquipmcnt. This test program, therefore, should bc accurate and adequate for the satisfaction of the rcquircment for seisinic capability documentation. This program is particularly significant bccausc thc tested relays simulate the actual electrical conditions for its nor(nal cnvironmcnt including all complemcn(ary devices such as indicating contactor switch and'ndicating instantaneous trip units over the complete frequency span of I to 35 Hz.Thc testing of individual relay basic mechanisms without their normal complements ivould present inconclusive evidcncc of the scisrnic capability of a protcctivc relay.Exhibit IV is'a copy of Dr.E.G.Fisher's treatise on the Sine'Beat Method for seismic qualification of clcctrical test equipmcnt. This rcport should clarify any questions which may arise r'cgarding our.sine beat method of testing.Tliis test program description Part I, covers that portion of.the test program which is common to all relay seismic testing.Separate capability curves, Part II attached, are'issued for each type of relay., TIME BETWEEN BEATS IO CYCLES PER BEAT PEAK ACCELERATION ONE BEAT 5 BEATS TOTAL EXHIBIT I-SINE BEAT INPUT FOR TESTING

Relay-Instrument Division Seismic Program EXHIBIT II TEST EQUIPMENT A.Shaker: Unholtz-Dickie Model 6 capable of generating 1000 pounds of force from D.C.to 1000 Hz.AVith a 6-inch.peak-to.peak stroke.II.Function Generator: Wavctck Model 114 and Model 136 which generate all standard waveshapes as well as sine beat.C.IsIotion Sensing: Thrcc Unholtz-Dickie accelerometcrs and amplifiers D.Motion I<ccording: Three Endevco ivIodel 2954A Peal'eading Meters.E.Mounting Fixture: IIVcstinghousc-designed fixture to permit testing'of relays in one, two or three directions 'imultaneously and in phase.F.Time ttlonitoring: IIVcstinghousc tirnc monitoring fixture for detection of contact or circuit status change.'.l,,~'4!W Ctl jte.,ij P r Ti,>>t L~ti~8'fq, I-.'(11.*.PII;.I I Art T S SI'"1"tf Y',I 1 ij,-ACCELEROMFTERS .i r'r'Y 1 SIIAKER~li>1 pe@IS',,~o RELAY*">>.t"TYPICAL RELAY~~'.,-g>>j."'t'Y FIXTURE SKISMIC TESTIHG s>)p>r>>I,','EIIER>>,j(,YI,.I'ti>>IS CHAL TORS>>A Il Y I i PEAK RKA I'I.1~.1".AMP L IF Q..I , N Sl Iii~0~t l MXYXOaeC 4.~,>>OIHG"I ACCELERATIOH METERS*P ACCELEROMETER AMPI.IF IERS SIIAKER Ezt.t.I J~I~t>>S>>I~'I 1 r'zx I~>>TY>>III,A Y Ck>>>>-'-'-T~':~~I 1", L'iSIGHAL GKHKRATOR COHTACT GAIN COHTRGLS oISCOHTINUITY TIYYKR tir>>J<~A.~L-,-~~>>St Jt T T~, ES"4'>>>>C~~jsP+j+ggttrt.>>,giVpl+ <<g'I;.';>"~'-"-S~Afg~':)sjYP%4)t

MAXIMUM SEISMIC.OPERATING ACCELERATION t r~10 9 6 I-5 h3 O: 3 0=Relay fragility exceeds, the test equipment limit.NG-6 Relay 6"NO" 5."NC".nontacts G 2 Prea.at which.contacts which are normally (Closed)with the coil'energized), change state for'(lo)mill'seconds.. 0 2 4 6 8.10 12 14-16 18 20.22 FORCE APPLIED AT'REQUENCY-HERTZ 45'O RELAY MAJOR HORIZ.AXES AND AT 56.3~TO THE MAJOR VERTICAL AXIS.24 26 28 30 32 34'WESTINGHOUSE REI.AY INSTRUMENT DIVISION ENG.~+-'ATE: MAXIMUM SEISMIC OPERATING ACCELERATION 10 7 I z 0 I-UJ O 0 3 t4G-6 Relay 4."HO" 5 2"HC" contacts 0 5 Preq.at i~hich contac'ts i-hich are.normally (Closed)arith the coil (Energized) change state for (2)milliseconds'. =Relay fragility exceeds=the test equipment limit.0 0 2 4 6.8 10 12 14 16 18 20 22 FORCE APPLIED AT FREQUENCY-HERTZ 45'O RELAY MAJOR HORIZ.AXES AND AT 56.3~TO THE MAJOR VERTICAL AXIS.24 26 28 30 32 34 WESTINGHOUSE R LAY INSTRUMENT DIVISION ENG.~DATE: /UP//'v 6/arA)r"~tC/ay//,8//g e FULL SEISMIC CERTIFICATION FOR THE GINNA STATION.MOTOR CONTROL CENTERS DESIGNATED 1L and'lM'NTRODUCTION A%)SUIQfARY*P A computer-aided analysis has been made of a Type"<4" motor , control center'which was originally tested at Hyle Laboratories, Huntsville ~AL, in October-1972 to meet the se'ismic requirements recommended by IEEE Std 344-1971.These calculations determined the acceleration g-levels and type of motion response that was excited ,, in the equipment by a simultaneous horizontal and vertical sine beat\t e o yp f motion input (5 cycibeat, 4%%d damping).\Subsequently, a similar dynamic analysis was made of the~equipment as modified for the Ginna Station, with attention'focused on the, new panelboard and distribution transformers."Hence, a comparison .can be made of the original test response spectrum and the required response spectrum (4%damping).for this new equipment application. The well-known"normal mode" method was used to evaluate both P I'.multi-direction and multi-frequency effects as recommended by the latest (1975)revision of IEEE Std 344..The comparison of input response.spectra, as well as corresponding g-levels sustained in the equipment,~shows that the original fragility-level tests pexformed at Wyle 1 Laboratories were quite'severe (1.49g rms)and can now be used to fully qualify the Ginna Station equipment for the specified seismic environment. COMPUTER MODEL OF MOTOR CONTROL CENTER Figure 1 shows a cutaway photograph of the type of motor control center that was tested with a variety of typical control devices according to'he 1971 seismic standard.The computer model was based upon simple static load and"snap-back",vibration tests of a single cabinet 1, 0.C e unit, which was built up out of-,actual structural members (channel and angle beams, flat plates)using the finite element method,.The'inal four-cabinet model, as tested, was assembled using 4 single-cabinet substructures (so called"super elements").The base spring atta'chment was subsequently ad)usted so that th'e computer model had natural frequencies in agreement i~ith the 1972 prototype test values.Figure 2 shows a schematic diagram of the original Type W equipment as modified for the Ginna Station.Special attention was paid to the modeling of the pa'nelboard and the three(75 lb each}distribution transformers. In general, the new assembly, was.made up of a combination of different substructures based upon the original single cabinet as follows: The base remained Original cabinet, except increased to 20 in, deep.Original cabinet, except reduced to 14.5 in.wide.(Use twice)Original cabinet, except added weight for top panelboard and for transformers in the bottom three drawers.spring attachments for both the original and the new assemblies the same, and were not part of the.substructuring. The natural frequencies and modal effective weights determined from the normal mode analysis are shown in Table I,.'The original equipment assembly as modified for, the Ginna Station had similar modal P frequencies and modal effective weights so that the seismic test results on the original Type W motor control center can safely be applied to'the modified equipment by means of the computer-aided dynamic analysis.In general, only the first three normal modes were in the seismic frequency range (1 to 33 Hz)and in addition could be effectively excited by the base motion input.The vertical (14th)normal mode of vibration was introduced by the base spring attachment in the computer model, but is well-above the seismic frequency range and has little influence on the final seismic response of the equipment. ~~~~~~~~~~'I~~~~~~~~I~~~~~I~~~~~~~~~~~~~~1~~I.~~~~~~~~~~~~~~~~~~~ O.X.-dir (front to rear)=.707 (.56)0,4pg Y-.dir (side to side)=.707 (.56)~p, 4pg Z-dir (vertical) =1'.ppp (.56)=p.568 2 ZPA (rms)=.56 (.707)+(.707)+(l.p)'~p.'79g In the 3-dimensional computer-aided analysis, in each coordinate direction, except, that'the'portioned as shown above.the SSE spectrum is applied ordinate values are pro-Figure 3'also shows the response spectrum for the 5 cyc/beat horizontal direction input at Hyle Lab during tne quasi-resonance sine beat test at the 8.5 Hz measured natural frequency in the equipment assembly.In addition, the simultaneous ver'tical direction input was C equal to two-thirds of the single horizontal component giving a total vector input as follows: '!'X-dir (front to rear}=,.'707 (1.35)~0,95g Y-dir (side to.side)~";707 (1.35)=0.95g~II Z-dir (vertical) '.667 (0.95)=0.64g ZPA (rms)=0.95 (1)+(1)+(2/3)"~1.49g*'t" The resonance search specified by IEEE Std 344-1971 indicated a major resonance at 8.5 Hz and,as much as 5-10%damping measured in the equipment at the maximum 1.49g sine beat acceleration input.However, r the subsequent couiparison of equipment response values-has been made at a only 4/damping, the largest value appearing in the required response spectra supplied for the'Ginna Station.1 In addition to the test at 8.5 Hz, similar quasi-resonance dwell-tests (5 beats at 5 cyc/beat}were performed at the six most signi-,.ficant resonant frequencies in the seismic range from 1 to 33 Hz.E Corresponding g-level input and SDF (single degree of freedom)response are shown in Table II'

4 Table II-RfS Input and SDF Response Frequency Horizontal Vertica3.'-Level Input RHS g-Level Response ax 2 5 8.5 17 20 33 0.72 1.35 1.35 0.82 0.68 0.45 0.34 ,0.64 0'4" 0.40 0.37 0.21 0.80 1.49~1.49'.91 0.77 0.50-6.9 12.9 12..9 7'.9 6.7 4.3 4.9 9.1 9.1 5.6 4.7 3.1 In general, the calculated SDF g-level test response values are well-above