ML18031A299
| ML18031A299 | |
| Person / Time | |
|---|---|
| Site: | Susquehanna  |
| Issue date: | 10/25/1979 |
| From: | Curtis N PENNSYLVANIA POWER & LIGHT CO. |
| To: | Parr O Office of Nuclear Reactor Regulation |
| Shared Package | |
| ML18031A300 | List: |
| References | |
| 840-2, NUDOCS 7910300106 | |
| Download: ML18031A299 (36) | |
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~JO usauehanna Steam Electric Stations Uni> 1i Pennsylva Jsnuenanna Steam Electric Station>
1!nit 2, Pennsvlva A!3TH(JR AFFTL TA7[6N Pennsylvania oo~er R l.ioht Co, RECIPIENT AFF ILI AT TO,'J Light '!Jater Reactors Branch 3
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Forwards "GKJ". IIM Tests~Test Philosophy JJ Matrix" F
"GK'~
II'ondensation Tests~Description of Measurement Cnnceot
~
Repts submitted in response to NRC Comment 2 issued on 790323 meeting.
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TWO NORTH NINTH STREET, ALLENTOWN, PA. 18101 PHONEs t215) 821-5151 October 25, 1979 Docket No. 50-387 50-388 Mr. Olan D. Parr, Chief Light Water Reactors Branch No.
3 Director *of Nuclear Reactor Regulation U. S. Nuclear Regulatory Commission Washington, DC 20555 SUSQUEHANNA STEAM ELECTRIC STATION GKM-IIM CONDENSATION OSCILLATION TEST PROGRAM ER 100450 PILE 840-2, 172
Dear Mr. Parr:
Enclosed please find forty (40) copies each of two reports dealing with the GKM-IIM condensation oscillation tests being performed by Kraftwerk Union at the GKM facility in Mannheim, Pederal Republic of Germany.
They are:
1.
"GIGA-IIMTests, Test Philosophy and Matrix" October 10, 1979, Adapted from KWU Working Report R 141/136/79 2.
"GKM-IIMCondensation Tests, Description of the Measurement, Concept" KWU Working Report R 541/10/79.
These reports are submitted in response to staff comment number 2 issued on the March 23, 1979 meeting held with PPGL to discuss the GKM-IIMtests.
Very truly yours, 4u3 N.
W. Curtis Vice President - Engineering S Construction DPR:dah P 8NN SYLVAN I A POWER 8
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O ct 6Kfl II-N CoNDENsATIoN TEsTs DESCRIPTION OF THE MEASUREMENT CONCEPT astranslatedfrom G
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6Kf'1 II-l'l CONDENSATION TESTS BESCHREIBUNG DES NESSKONZEPTES
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& LIGHT COMPANY ALlENTOWN, PENNSYLVANIA 7
Joy 3220 ALPINE ROAO, PORTOLA VALLEY CALIFORNIA84025 (415) 854-6732 4
as translated I'rito
.E. N.G. L.I. S.H........
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I Title Working Report R 541 10 79 er ep o.
ear GKM-II-MCondensation Tests Description of the measurement concept Karlstein 11 A ril 7
- ace, a
e Schmid R541 328 Kem f R522 543 Author Dept.
Tel.
Reference (e.g., Project, RGD Project):
- PPGL, SSES Units 1 and 2, CCOP Tests 2
/s/ ll Ma 79 Class Signature / Classifier R 541-Sd/0000-876291 Summary Pages:
6
( Attachments:
i eno.,
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. no.
Under contract to the Pennsylvania Power 6 Light Company (PPGL), the KWU is preparing transient condensation tests of the pressure suppression system in the Grosskraftwerk Mannheim (GKM).
These tests will be per-formed in the modified GKM II test stand (single cell with proportionate drywell and suppression chamber at actual scale).
The purpose of the tests's to verify the design of the pressure suppression systems of the Susquehanna l and 2 nuclear power plants.
The test stand is extensively instrumented.
Two instrumentation systems are installed: operating instrumentation and test instrumentation.
The purpose of the operating instrumentation is to controle the test sequence and ensure-safe monitoring of the test stand.
A process control computer is used for data acquisition.
The purpose of the test instrumentation is to collect all relevant data needed to evaluate the various phenomena.
The measurement signals from the individual transducers are recorded on magnetic tape, light-spot line recorders and to some extent by the process control computer.
A survey of the instrumentation and its arrangement is g'iven in Zigures and Tables.
ID@3 'I K@I>>@~~
illI.5 ca egor no For disposition by or for information/
Time limits Authors'ignatures Schmid Kem f For ext. release Dr. Becker, R141
- Sack, RF 32 16 May 7!
Dr. Schweickert R5 Dr. Schad R54 Mr. Stolben R522 Mr. Lohr R141 Distribution list (Add "z.K." if only Summary for information):
Standard distribution list 2 of 15 May 79 Mr. Witt R541 Mr. Brunswick R522
'Hoffmann R541 PPGL 3x via RF 132 Flittner R541 Ehrnsperger R541
. Spengler R523 For info. only Storb R522 Zz'a fork Union COMPANY CONFIDENTIAL
Page 2
- l. Introduction KWU is preparing in the GKM a test program for the performance of transient.
condensa-tion tests on the pressure suppression systems of the Susquehanna l and 2
BWR plants.
A detailed description of the instrumentation, test set-up and test execution will be included in the Test Procedure which is being prepared for those tests.
The tests are performed in a rebuilt condensate accumulator.
It conservatively simulates the smallest single cell of the pressure suppression system of the Susquehanna l and 2 plants.
The volume of the proportionate upper annulus (drywell) is simulated by a mounted accumulator.
A replaceable standard orifice installed in the blowdown line simulates the postulated break cross-section of a main-steam line'r feedwater line.
The "break cross-section" is released by means of a rupture disk combination.
This report gives a first survey of the instrumentation of the test stand, which is subdivided into operating and test instrumentation.
The purpose of the operating instrumentation is to control the test sequence and monitor the test stand.
The test instrumentation ensures the recording of all data of significance for evaluation of the phenomena which occur during air-poor condensation.
- 2. Identification s stem for the instrumentation The measurement transducers are identified by a system of letters and numbers.
Each identification starts with a letter or letters describing the type of transducer:
P for Pressure Transducer T
for Temperature Sensor (Thermocouple)
L for Water Level Measurement DG for Displacement Gage SG for Strain Gage I
for Electrical Impulse Signal LP for Level Probe LC for Load Cell AF for Air Fraction OR for Oxygen Rate
~
Page 3
Following these letters is a number which characterizes the mounting location or measurement location in 'the test stand.
For that purpose, the test stand is divided imaginarily into different System Groups as follows (see Fig. 1):
System Group 1
contains transducers on the steam lines to the accumulator S6 and to the feedwater tank B 202 and in the feedwater tank B 203 System Group 2
contains the feedwater tank B 202 System Group 3
characterizes the steam accumulator S6 System Group 4 contains the steam supply'o the test stand System Group 5
contains the instrumentation of the proportionate drywell with the vent pipe System Group 6
characterizes the suppression chamber The System Groups 1-4 contain the operating instrumentation, while groups 5 and 6
characterize the test instrumentation.
After this identification number there is a decimal point which separates this number from the running numbers of the transducers.
3.
eratin instrumentation The purpose of the operating instrumentation (see Tables 1 and 2, Figures 1,
3 and 4) is to monitor the steam accumulator, feedwater tank and steam lines.
The signals from the measurement transducers are interrogated by a process control computer and recorded.
This computer is a part of the operating instrumentation.
All data are stored on magnetic tape and can be printed out or plotted after each test.
Before test start>
the process control computer compares the recorded measurement signals with prescribed setpoint values and prints them out. lf the measurement value differs from the setpoint value by a prescribed percentage, that measured value is identified in the printout.
The operating instrumentation concentrates on the measurement of pressures, temperatures and water levels in the steam accumulator, steam lines and feedwater tanks.
Page 4
- 4. Test instrumentation The test instrumentation (see Tables 3-7 and Figures 3-6) records all the data needed to evaluate the phenomena occurring during air-poor steam condensation and the resulting loads in the pool, and also the data needed to'etermine the steam flow rate in the piping.
The dynamic pressure loads are measured at several points in the pool.
The forces occurring at the vent pipe bracing and at internals in the suppression chamber and at its structure are recorded by strain gages or load cells.
The pressure build-up in the vent pipe is measured at several points.
In addition, Level Probes are installed at the vent pipe so as to be able to record the dynamic behavior of the water surface.
Pressure and temperature measuring
,points in the air space of the suppression chamber and in the proportionate accumu-lator provide information about the variation of pressure and temperatuxe during the tests.
Two differential-pressure measuring points in the water region of the suppression chamber record the air bubble fraction in the pool.
At the upper end of the vent pipe there are two measuring points for determination of the air content of the steam, one measuring point fox continuous
- sampling, and one other measuring point for discontinuous sampling.
The measurement system for continuous sampling is provided by SRI..
- is also providing assistance in the design of the second system.
The data is recorded on magnetic tape in analog form by means of carrier-frequency amplifiers and dc amplifiers.
This ensures that high-frequency measurement signals axe recorded with proper frequency and amplitude.
The data is reduced latex by a computer.
Simultaneously with the recording on magnetic tape, most of the measure-ment points are also recorded on light-spot line recorders.
That type of recording makes it possible to get a quick look at important measurement.
variables shortly after each test.
At the same time, a few selected transducer channels of the test.
instrumentation are recorded additionally at the process control computer.
This procedure makes it possible to perform a quick and simple summary evaluation of that data after each test.
All the measurement channels run together at a measurement place which is located in an air-conditioned measurement container.
Each measurement chains consists of a transducer, connection cable, amplifier (carrier-frequency or dc amplifier), balancing unit and recording unit (see Fig. 7).
- Stanford Research Institute International
Page 5
The utilized pressure transducers have a measuring diaphragm and a foil strain gage system which'is directly connected to the diaphragm.
All pressure transducers in the water region of the suppression chamber have an exposed measuring diaphragm with direct contact to the surrounding water.
Earlier studies by KWU have shown that this type of transducer is best suited for recording higher-frequency pressure oscillations with correct frequency and amplitude.
For the pressure measurement in the lines which carry steam, the measuring diaphragm has to be protected from the hot steam.
That is accomplished by means of a short water-filled pipe which connects the transducer to the measurement site.
The transducers are connected to the measuring amplifiers by shielded cables.
Carrier-frequency amplifiers providing a frequency resolution of up to 1 kHz are used for the strain gages, displacement transducers and pressure transducers.
DC amplifiers with a 10 Hz low-pass filter are used for the temperature measurement.
- 5. Filmin of the rocesses in the ool The processes in the water region of the suppression chamber are recorded optically on film by a high-speed camera and on video tape by a television camera.
The cameras are mounted outside the tank and observe the processes by means of bull's eyes.
Several underwater searchlights are installed in order to ensure satisfactory lighting of the end of the vent pipe.
A uniform electrical reference signal ensures time correlation between all the data acquisition systems.
Page 6
- 6. Note The following additional abbreviations are used in Tables 1-7.
DPS CTC DCA HT-SG PG RTD Data Processing
~S stem Coated Thermocouple Direct Current Amplifier Carrier Frequency Amplifier High Temperature Strain Gage Pressure Gage Resistor Temperature Detector
1
~
Tr. note:
The column headed "Transducer Dates" should read "Transducer Data".
This is an incorrect translation by KWU of the German word nDaten", which can mean either "dates" or "data" in Englisht KWU R 541 GKM H-M- Condensation Tests
-Operating Instrurnentation Date 4/11/79 Transducer Measuring - Point Marking Measuring - Locution Transducer Dates Type Measuring Stock-No.
Measuring Ran e
Am tifier Recording Ploce DPS Control Test Channel Station Facilil Figure P
1 ~ 1 Pressure in tho superheated stoam line steam line to thc steam accumulator PG with romoto sensor 25 bar 20 mA P
1 ~ 2 main steam line P
1 ~)
Pressure in the feodwatcr tank feedwater tank B 20$
P 2,1 fcedwater tank B 202 50 bar CFA P 3el Pressure in thc stoam accumulator, stcam zone L 3 ~ 1 Water lovel in tho stcam accumulator Barton cell 2 bar 20 mA L A+2 0.2 bar 20 mA L 3.3 Water Qago P
4 ~ 1 Pressure.in the blowdown line before throttlo nozzle Pressure in tho blowdown line before the rupture discs SG complete bridQc PG with remote sensor 50 bar 25 bar CFA 20 mA P A.5 Pressure bctvccn the two rupture cKecs T
1 ~ 1 Temperature in the superheated stcam line steam linc to the steam accumulator CTC 550 C
DC A T
1' main steam line C T C 400 c
1
~ w\\
KWU R 541 GKMII-M-Condensation Tests
-Operating
.Instrumentation-Date 4/11/79 Transducer Measuring - Point Marking Measuring - Location Transducer Dates TYpe Measuring Stock-No.
Measuring Ran e
Am lifier Recording Place OPS Control Test Channel Station Facilit Figure T
1 ~ 3 Tenporature in the fcodvatcr tank feeduater tank 9 203 CTC 300 C
DCA T 2ot fooduator tank 9 202 T F 1 Tonporature in tho stean accunulator, stean zona T 3 ~ 2 Toaporatur o in the stean accunulator, vator zone u
T 3 ~ 3 T 4.1 Touporaturo for tho correction of the water lovel noasurouont in the stean accuaulator Teuporaturo in the blovdown line before tho throttle nozzle I
00 I
T 5' Toaperaturo in tho dryuoll,at the wall 1 ~ 3 ~ 4
- l. 6.1 llator level in tho suppression pool Barton cell 2 bar Oo ~ ~ 20aA X
3,4 b 6.2 Vator level in the annulus gap 3,4
l
KWU R 541 GKM II-M-Condensation Tests Test Instrumentation Date 4/11/79 Transducer Measuring-Point Marking Measuring Location Level Angle H (mm) ock-No.
easuring Range Ne Tr'ansducer Dates T
M St Measuring Amplifier DPS Visi-corder Magnetic Tope Channel Data Recording Figure SG 6' Strain in the. tank wall, outside,vertical 265o 90 SG semi bridge 6000/iu/n CFA Sc 6.4 Strain in the tank wall, outside,horirontal 265o 90 sc 6.5 Strain in tho,tank wall, ou tsi do, vert Ical 265o sc 6.6 Strain in the tank wall, outside,horizontal 2650 sc 6.7 Vertical bending strain at the quencher dunay 1100 270 SG 6 ~ 8 llorizontal bending strain nt tho quencher douay 1100 270 Sc 6'
Vertical handing strain at the legs of the test vessol sc 6.1o Vertical bending strain at the legs of the test vessel 90 PG 6.1 OG 6,2 oG 6,4 0G 6,3 oc 6.5 Displncenent of the bottou of the inner cylindor Displacenent of the inner cylinder at the crossing place Displacencnt of the inner cylinder at the crossing place 10000 10000 center 270 90 0
180 inductive semi brldgo Dc 6.4 Displacenent at the stiffening ring 6o9o 90 T 6.1 Tenperaturo in the suppression pool, water xone b
6800 180 CTC 300 c DC A T 6.2 5200 180
)
KWU R 541 GKM Ij:-M-Condensation Tests
-Test Instrumentation Date 4/11/75 Transducer Measuring-Point Marking Measuring Location Level Angle H tmm) ock-No M
St Vpe easuring Range Transducer Dates T
Measuring Amplifier Data Recording g
iC Tape Channel corder DPS Visi-Ma net Figure T 6' Temperature in the suppression pool,vater xone 3650 180 CTC 300 C
DC A T 6A 265o 180 T 6.7 1100 180 T 6.8 center T 6.g Tcnperaturo in the suppression pool,air xonoytop 14100 270 u
T 6.1o Tesperature in the supprossion pool,air xone,bolov 8oio 270 i>5 P 4.1 hP 4 ~ 2 Prcssure in the blovdovn line before throttle noxxle Difforential prossure at tho throttle noxxlo SG complete bridge 50 bar 35 bar CFA hp 4.3 Darton coll 20 nA T 4.1 Tcnperature in the blovdovn line before throttle noxxle C T C 300 C
D C A P
3 ~ 2 P 5+1 Dynaeic pressure in the stean accunulator,vater zono Pressure in tho dryvoll Piezo-electric transducer SG complete bridge 20 bar 20 bar Charge amplifier CFA P
5 ~ 2 Pressure in the dovncoser pipe,top 15550 270 10 bar P
5' Pressure in the dovnconor pipe,middle '1058070
KWU
. R541 GKM H-M-Condensation Tests Test Instrumentation Date 4/11/79 Transducer Measuring -Point Marking Measuring Location Level Angle H (mm) ock-Na
'/pe easunng Range Transducer Dates T
M 'l Measuring Amplifier Data Recording g
IC Tape Channel corder DPS Visi-Ma net Figure P
5' Pressure in the downconer pipe, below 7300 270 SG coaplote bridge 10 bar C F A
P 5'
Pressure in the downcoacr plpo,oxlt 3750 270 ap 5.6 Prcssure dlffcrcntial bctwccn dry-woll and suppression chanbcr 3,5 bar on 5.1 oxigene rata in the downcoaer pipe 15550 270 OA 5+2 15550 270 0G 5 ~ 1 Indication of the swing chock valve betwoen drywall and suppression chaaber CF A
DG 5 ~ 2 T 5+i Toaperature in the drywall,top CTC 300 C
DC A T 5 ~ 2 Tcaperature in the drywall,below 5+3 Tcnpcraturo in tho drywell,sunp T 5+5 Tcnpcrature in thc downconcr pipe,middle 10500 270 T 5.6 Tcnpcrature in thc downcoser,exit 3750 270 P 6.1 Prcssure at tho suppression pool wall,water xone 6150 I80 SG cooplcte br idge 10 bar CFA P 6'
.4 I50 180
KWU R 541 GKM II-M-Condensation Tests
-Test Instrumentation
.Date 4/11/79 Transducer Measuring -Point Marking Measuring Location Level Angle H (mm) ock-No T
M St Vpe eas wing Range Transducer Dates Measuring Amplifier DPS Channel ViSI-corder Magnehc Tape Data Recording Figure P 6.3 Prcssure at the suppression pool wall,water xono 3650 180 SG couplote bridge 10 bar C
P A
p 6.4 265o 180 p 6.5 265o p 6.6 265o 90 P 6.7 1100 IBO p 6.8 center P 6.9 Pressure in,the suppression chanber,air xone 14100 270 20 bar AF 6 ~ 1 Air fraction in the suppression chaober,water xone 4150/6150 180 3,5 bar AF 6' 26 50/6150 180 LP 5 ~ 1 Vatcr lovel in the downconer pipo 3750 90 spark plug D CA LP 5' 4o5o 90 Lp 5' 445o 90 Lp 5 ~ 4 615o 90 LP 5 ~ 5 7950 90
KWU R 541 GKM H-M-Condensation Tests Test Instrumentation Date 4/11/79 Transducer Measuring-Point Marking I-I (mm)
(0)
Measuring Location Level Angle ock-No Vpe easuring Range Transducer Dates T
Measuring Amplifier DPS Channel Visi-corder Magnetic Tape Data Recording Figure SD 6.1 Longitudinal strain,gracing 1
6090 0
Sg complete bridge C F A 5,6 SG 6' Longitudinal strain, gracing 2
6090 90 9,6 LC 6 ~ 1 Loads duo to the notion of the water surface 6300 270 piano olectric transducer Charge asplifier LC 6' 6300 270 I
I XI C)
Legend:
F-Remote steam 20 bar, 800aC H-Heating steam 20 baz, 400aC D-Process
- steam, saturated steam V-Vater, toom water K-condensate Remote steam Ferndam f 20bar 300 C DN 250 P
.1 T41 ON 300 0
r'5 O
Q tQ Q
l 0
CL Q
(A0 0
- stoll DNtoN'2 DNIO P4.5 E1 DNcop D
Cp
~Entspanner ZLa h tank DN20 T 5.3 ON Cppo EA L4 T5.1 A cumuE ipeicher S3 T5.2 L2 ON20 T 6.9 P 6.9 o
zO E2 E3 E5 T6.10 T5.6 YYY T6.8 g-ON 6S ON 65 P 4.4 Nitr'ogen D4 St ick ON20 g 05 ONr 00 06 ON 300 Cl Vl A6 zO o
PlzO D3 F1 I-F6 E9 ap4.2 E10
>>iY wi Y
50 uJ DN 25 I
DN25 o
0 v(
o lV 0
z0 C1o zO F2
~ P2.1 Ee tez tank Speisewasser-behi3ller ~
8 202 Ci Cl PlRO oo T 2.1 eedbfater tank Speisewasser-behaller ~
8203 T 1.3 o
rVz DNZO DNSO ON20 DN250 S2 D1 S4 ci 07 BN Coo S6 S
DN 350 S9 E7 YYYY T3,1 Speiche S6 Accumu-SQtor'2 P3.1 DN250 RO T 3.3 Ci zO Ci rVzO S 0 DNloo Condensate l<1 Kondensat 20 bar tpP'C DN250 DN250 L6 DN20 e et riebsdruck tult E 21 Oper'ating sur'ised E22Dppaiz 0
lpp N
ttf UJ L3.1/2/3 Heipdam f 20 bar CotPC n
uper ea e
s earn DN 20 T 3.2 DN 80 E18 P
3 E19 P11 T1.1
~ DN 400.
H1 t.egende:
F--- Ferndnmpl H -- - Heizdompl cn o
I 20bnr, 300'C 20 bar r C004C 0
A1 A2 A3 F7 A4 P1g Abwassersammetschiene Paste-bloater common header E20 DN to 0-- -prozep-
. Sottdompf N
Y W--- ttlosscr, Stodtwosser K--- Kondensal
O CD 15 4 3600 Kraftwerk Union R 541 R 541/10/79 lA P)
CV CD CD QD 43000 CD CD U3 Rohr 609,6x10 CD.
4 2160 CD CV C) lA (V
CV CD LA CO P)
I 4 3780 GKMII-M-Condensation Tests Tesf Tank Fi
.2
T 5.4 T 5.1I-P,5.1 KraffwerkUnion R 541 R 54i/iO/79 T 5.2 T5.3 B PS.6 OR OR 5.
S.1 T6.9 P5.2 P6.9 I
T5.5/P5.3
.P S.L L6.2 L6.1 T 5.6/PS.S Dummy Quencher
+Om Legend: P Pressure transducer T
Temperature transducer L
Water Level OR Oxygen Rate 2700 90o Bull's eye 180o GKM II-M Condensation Tests Coordinate System and Test Instrumentation Fig. 3
Legend: P Pressure transducer T
Temperature transducer L
Water Level OR Oxygen Rate T 5.4 T 5.1I-P 5.1 Kraffwerk Unson R 541 a 54</Zo/79 OOO OO CV T5.3 T 5.2 a DP5.6 OOO OO O
P OR OR S.
5.1 T6.9 P5.2r P6.9 O
IQ CA IA T5.5 /PS.3 P 5.4 L6.2 O
CO O
O 0
L61 a T56/PS.S
+ SG6.9 S G 6.10 GKM II-M-Condensation Tests Test Instrumentation
Legend: P Pressure transducer T
Thermocovple DG Displacement Gage LP Level Probe LC Load Cell SG Strain Gage AF Air Fraction
>> 18-Kraftwerk Union R 5l1 R 54i/i0/79 LP 55 OO T6.1 0 DG 6.2 DG 6.3 DG6.4 DG6.5 LP Si5 O
lO C3 P 5.5 LP 5.4 LP 5.3 LP52 o
Oo 1
OO Ol OO CO OOOO LC 6.1/2 LP5.4 I
T6.1 DG6.4 G6.1/SG6.2 O
TO co O
O0 O
O ln ln N
LP5.3 LP52 P5.1 T5.6 SG 6.7 SG 6.8 SG6.7 DG6.1
~TT 6.2 P6.2
- P6.3/TK3 G 6.3/SG6.4
cSG6.5/SG65
~P 6.4/P65/P6.6 T6,4 P 6.7 T6.7 oO Oln O
O oo o OO C)lo Section A-B 00 I
P66 horizontal,S G6.
vertical,SG6.6 I-Beam 270O P 6.8 T 6.8 GKM II-M-Condensatipn SG 6.3, horizontal TpgtS 90~
'66 Test Instrumentation AF61/AF62 P 6.1... P 6.4, P 6.7 i 160o T6.1...T64.T 6.7 Fig. 5
Kraftwerk Union R 541 R S4</aO/Ve 00 SG 6.1 Bracing 1
~ 4 ~
270o 90 Bracing 2 GKMII-M-Condensation Tests Bracing Configuration Fig.6
Sensor Tape Recor der 1
2 3 4 5 6 7
8 9 1011 1213 14 2
3 4
5 6
1 2
3 4
5 6
L0 Cl CS 2
3 4
5 6
1 2
3 4
5 6
1 2
3 4
5 6
Correlation Si nal Reference Si nal 1
2 3
4 5
6 13 14 Data Recording:
Schematic Block Diagram'
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-2i-R 54 LEGAL NOTICE This document was prepared as a result of work sponsored by Pennsylvania Power 5 Light Company (PPM.)
and performed by Kraftwerk Union Aktiengesellschaft (KWU).
Neither PPM nor KWU, nor any person or firm acting on behalf of either:
ao Makes any warranty or representation, express or implied, with respect to the accuracy, com-pleteness, or usefulness of the information contained in this report, or that the use of any information, apparatus, method, or process disclosed in this document may not infringe privately owned rights; or b.
Assumes any liabilitywith respect to the use of, or for damages resulting from the use of, any information, apparatus, method or process dis-closed in this document.
o II R
3 Kraftw'erk Union
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