ML17229A097
| ML17229A097 | |
| Person / Time | |
|---|---|
| Site: | Saint Lucie  |
| Issue date: | 06/10/1996 |
| From: | Jennifer Ford, Orsulak R ABB COMBUSTION ENGINEERING NUCLEAR FUEL (FORMERLY |
| To: | |
| Shared Package | |
| ML17229A091 | List: |
| References | |
| TP-9419-CSE96-2, TP-9419-CSE96-2104, NUDOCS 9610280104 | |
| Download: ML17229A097 (30) | |
Text
TR-9419-CSE96-1101, Rev. 0 Attachment 2 Page 1 of 23 Attachment 2 Test Procedure and Completed Data Sheets qezoa80<04 qesm4 PDR ADQCK 05000335, P PDR ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-110 Attachment 2 Page 2 of 23 TP-9419-CSE96-2104, Rev. 0 Page 1 of 11 Test Procedure Steam Generator Tube In-Situ Hydrostatic Pressure Test Tool Hydro Chamber Pressure Determination Procedure No. TP-9419-CSE96-2104 Rev. 0 ABB Combustion Engineering Nuclear Operations Prepared By; Reviewed By: 54'c dt K F. AUea.
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Coaaeehene Enynocr Date; Approved By: +C eMerero+ Date:
J. F. HalL Frmcepal C Approved By.
J. D. FcrreL Manager. Field r Opcranexn ABB Combustion Engineering Nuctear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101, Rev. 0 Attachment 2 Page 3 of 23 TP-9419SE96-2104, Rev. 0 Page 2 of 11 Table of Contents Section ntents P~ae No lo Objective 20 References 3,0 Quality Assurance 4.0 Discussion and Background 5.0 Prerequisites 6.0 Limitations and Precautions 70 Test Procedure 7.1 Static Test 72 Dynamic Test Figure 1 Data Sheet 1, Static Pressure Test Data Sheet 2, Dytmnic Pressure Test 10 Data Sheet 3, Remark Continuation Page Attachment 1 Faxed cover sheet with Review and Approval Signatures ABB Combustion Engineering Nuclear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101,Rev. 0- Attachment 2 Page 4 of 23 TP-9419-CSE96-2104. Rav. 0 Page 3 of 11 I.O Objective The objective of this test is to determine the relationship between the hydro pump outlet pressure, the hydro chamber pressure and the seal bladder pressure under flow conditions for the steam generator localized in-situ presswe test tools. In addition, static testing will be performed to establish a baseline relationship under non-flow conditions. The data under flow conditions will be used to ensure that in the event of a leaking defect indication, the leakage rate is measured at the appropriate pressure(s) within the hydro chamber. Testing will be performed on both the axial and circumferential tools.
20 References 2.1 QAM-100, Fourth Edition, Revison 4 2.2 Final Test Report for the Steam Generator Tube In-Situ Hydrostatic Test Tool. TR-ESE-'030, Rev, 00, T. R. No. 83D, dated April 5, 1994.
3.0 Quality Assurance The test described herein is to be treated as Safety Related, Quality Class 1, in accordance with the requirements in Reference 2.1.
4.0 Discussiori and Background Reference 2.2 describes the development and qualification testing for the localized in-situ test tool. The tool described in Reference 2.2 was developed to pressure test primarily circumferential defect indications in steam generator tubes at the tubesheet region. It is also applicable to the testing of axial indications. An additional tool was evolved for thc testing of axial defects which are greater in length than those which can be accommodated by the hydro chamber in thc original tool. Since the tool design for the circumferential defects has greater restrictions than those for axial defects, thc test report is bounding for the axial tool.
The localized test tool contains two pressure circuits; one for seal and gripper bladders, and onc for the hydro chamber. The hydro chamber circuit is pressurized by an air operated positive displacement pump. The bladder circuit is pressurized by either an air operated positive displacement pump or a hand pump.
The positive displacement pumps used in the system are able to maintain a precise control at a given static pressure. Under flow conditions, such as those experienced during a tube leak. the pump discharge pressure fluctuates between a high and low limit with each pump pulse. The magnitude of this band is a function of the flow rate and the restrictions within the hose/tool assembly. Due to these dynamic head losses, the actual pressure in thc hydro chamber will be less than that observed at the pump discharge.
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TR-9419-CSE96-1101, Rev. 0 Attachment 2 Page 50f23 TP-9419-CSE96-2104, Rev: 0 Page 4 of 11 Reference 2.2 describes testing which was performed under flow conditions to establish the relationship between the hydro pump discharge pressure and the hydro chamber pressure. This test consisted of measuriiig the swing of the pressure gauge at the discharge of the hydro pump at various leak rates at an initial static hydro chamber pressure of 4,000 psig as directly measured in a controlled leak test fixture.
Implementation of this data in an in-situ field test requires an iterative process as the hydro chamber pressure is not directly measurable. The process involves matching the pump discharge pressure swing relative to the desired pressure and observe the pump stroke rate as compared to the data in the test report. In addition, the test report explicitly states that the leak rate correction data apply only to the as-tested configuration.
For the testing at St. I.ucie Unit I, it was requested that the capability be provided to test in the straight tube portions at elevations well above the tubesheet. This necessitated the fabrication of hoses longer than those described in Reference 2.2. For non leaking defect indications. the length of the hose does not affect measuring the desired pressure in the hydro chamber as the system is static and the pressure is equal to that at the pump discharge. For leaking defects, the change in system resistance due to the change in hose length does have an effect on the dynamic response of the pump discharge pressure gauge and its subsequent relationship to the hydro chamber pressure. Consequently, for a leaking defect, the actual pressure in the hydro chamber is indeterminate without additional testing.
In order to determine the pressure in the hydro chamber with the current hose configuration, two methods will be considered.
I) Hydro pump discharge pressure swing correlation method, and,
- 2) Seal bladder pressure intensification method.
Item l is the method described in Reference 2.2. Item 2 is based upon an observation during laboratory testing and field application. Experience during previous testing has shown that the bladder circuit pressure increases as its initial pre-charge pressure is approached by the increasing pressure in the hydro chamber. This pressure increase has been termed 'intensification.'nce the bladder pre-charge pressure is reached in the hydro chamber, the bladder pressure will increase with increasing hydro chamber pressure.
This pressure has been observed to be approximately 200-300 psid under static conditions.
It is expend that the relationship will be similar under flow (leak) conditions.
Establishing this relationship will provide an accurate, indirect method of measuring the pressure in the hydro chamber under leaking conditions. As the bladder circuit is not in a flow path, there are no head losses to consider. Pulsations may be evident in the bladder circuit due to the reciprocating nature of the hydro pump. However, these pulsations will reflect the true pressure in the bladder circuit independent of the head losses experienced ABB Combustion Engineering Nuctear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101, Rev. 0 Attachment 2 Page 6 of 23 TP-941&CSE96-2104, Rev. 0 Page 5 of 11 by the hydro circuit. By inference, the pressure in the hydro chamber can then be determinNL This test will focus on establishing method 2 as the method of choice for determining the hydro chamber pressure under flow conditions. However, additional data will be recorded in order to provide for the use of method 1 should method 2 prove to be invalid.
5 0 Limitations and Precautions 5.1 As noted in Section 4, the method 1 correlation is a Function of system dynamic resistance. Use of the test results in method 1 correlations is limited to systems with an identical configuration to that tested. The hose configuration in this test is identical to that in Figure 2 of Reference 2.2 with the exception that the length of the 3/16" braided hose has been increased from 30 feet to 50 feet. Use of the longer hose length in the test will qualify method 2 fo'r use in the as tested configuration..
6.0 Prerequisites 6.1 All pressure gauges to be used in the test shall be verified to be within the calibration period.
Note The test procedure is intended to provtde a protocol. It is not intended to limit the type of testing conducted. As an example,
<<ddittonal pressures may be tested or conditions changed in order to adapt to lessons learned during the test. Any changes or additions shaH be recorded and explained on the appropriate data sheet. Blank data sheets may be copied to provide for each parameter change.
Note Minor leakage may occur during the conduct of this test.
Acceptability of leakage with respect to continued operation of the test is at the discretion of the test operator. However, any leakage shaH be recorded in the remarks section of the data sheet.
70 Test Procedure Note The static test will be performed using both the circumferential/axial tool and the long axial tool. The order of performance is at the discretion of the test operator. Data sheet 1 is used to record information for the static test.
A88 Combustion Engineering Nuciear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-110'1. Rev. 0 Attachment2 Page7of23 TP-9419-CSE96-2104, Rev. 0 Page 6 of 11 7,1.1 Assemble the test fixture, in-situ tool and pump circuits as shown in Figure l. Record the tool (circ. or long axial), hydro pump pressure gauge, hydro chamber pressure gauge and bladder pressure gauge serial numbers on the data sheet.
712 Operate the bladder pump to fill the bladder circuit tubing with water. Pressurize the bladder circuit to approximately 4,000 psig ~200 psig and release the pressure at the pump discharge. Repeat this process at least 10 times to remove air from the bladder CIrcuit.
713 Using the bladder pump, pressurize the bladder circuit to an initial pressure of 1,500 psig
= 100 psig as indicated by the bladder pressure gauge. Observe the pressure gauge reading to ensure that there are no significant leaks. Record the initial bladder pressure 9 0 psig hydro chamber pressure on Data Sheet 1.
7,1.4 Close/verify closed'the leak rate control valve.
Note The static test is to be conducted at target hydro chamber pressures of 1,500, 1,600, 1,800, 3,000, 4,000 and 5,000 psig.
7.1,5 Pressurize the hydro circuit to the target pressure s 100 psig as indicated by the hydro chamber pressure gauge. Observe for leaks and steady pressure readings on all gauges.
Record all pressure gauge as read values on the data sheet. Repeat this step for each of the target pressures fisted on the data sheet.
7.1,6 Ensure all necessary data have been recorded on the data sheet, signature and date signify completion.
7 1,7 Repeat steps 7.1.3 through 7.1.6 for an initial bladder pressure of 2,000 psig < 100 psig.
7 1.8 Repeat steps 7.1.1 through 7.1,7 for the second tool.
7 2 ~Dggj~g Note The dynamic test will be performed using both the circumferential/axial tool and the long axial tool. The order of performance is at the discretion of the test operator. Data sheet 2 is used to record information for the dynamic test.
7 2,1 Assemble the test fixture, in-situ tool and pump circuits as shown in Figure 1. Record the tool (circ. or long axial), hydro pump pressure gauge, hydro chamber pressure gauge and bladder pressure gauge serial numbers on the data sheet.
ABB Combustion Engineenng Nuciear Operations ABB Combustion Engineering Nuclear Operations I+ W'/
TR-9419-CSE96-1101 Rev. 0. . Attachment 2 Page 8 of 23 TP-941 94SE96-2104, Rev. 0 Page 7 af 11
,Note Ifthe hydro tool has not beta separated from the hose, the bladder circuit does not require degassing and the following step is N/A.
7,2.2 Operate the bladder pump to fill the bladder circuit tubing with water. Pressurize the bladder circuit to approximately 4,000 psig a 200 psig and release the pressure at the pump discharge. Repeat this process at least 10 times to remove air from the bladder Circuit.
7.2.3 Using the bladder pump, pressurize the bladder circuit to 1,500 psig ~ 100 psig as indicated by the bladder pressure gauge. Observe the prcssure gauge reading to ensure that there are no significant leaks. Record the initial bladder pressure 0 psig hydro chamber pressure on Data Sheet 2.
7.2.4 Close/verify closed the leak rate control valve.
Note The dynamic test is to be conducted at target hydro chamber pressures of 1,700, 3,000, 4,000 and 5,000 psig. Each target pressure requires a separate data sheet.
7.2.5 Pressurize the hydro circuit to the target pressure + 100 psig as indicated by the hydro chamber pressure gauge. Observe for leaks and steady pressure readings on all gauges.
Record all static pressures as the zero pump rate values.
P Note Iterative adjustment of the leak rate control valve aad the hydro pump air control regulator will be for establishing the desired pump stroke rate at a given target hydro chamber pressure.
7 2.6 Slowly open the leak rate control valve to establish a hydro pump stroke rate of 20 strokes/minute while maintaining thc target pressure as indicated by thc hydro chamber pressure gauge. Adjust the hydro pump air control regulator and the leak rate control valve as necessary. Ifthe hydro chamber pressure is not steady, adjust to the target pressure at approximately the middle of the swing. Record all prcssure reading's on the data sheet. Repeat this step for each of the pump stroke rates listed on the data sheet.
7,2.7 Ensure all necessary data have been recorded on the data sheet, signature and date signify completion.
7,2.8 Repeat step 7.2.4 through 7,2.7 for each of the target pressure values.
7.2.9 Repeat steps 7.2.1 through 7.2.8 for the second tool.
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Test Apparatus Configuration C
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fll fn Ilydro Pump Hydro Chamber D 4. Gauge Gauge (O
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In-Situ Tool Tube (0 Q Z
C o 0 rD Q I I-lydro 0 Pump (D
Hydro 0 Bladder Pressure Chamber D Leak Rate Vl Gauge Control Valve Bladder Pump
TR-9419-CSE96-1101, .
Rev. 0 Attachment 2 Page 10 of 23 TP-941 &CSE96-2104, Rev. 0 Page 9 of 11 Data Sheet 1 Static Pressure Test Tool (circ. or long axial)
Initial Bladder Pressnre~sig Target Hydro Observed Hydro Hydro Pump Bladder Pressure Chamber Pressure Chamber Pressure Discharge Pressure S1 S1 ( si SI Hydro Pump Discharge Pressure Gauge No.
Hydro Chamber Pressure Gauge No.
Bladder Pump Discharge Pressure Gauge No.
Remarks:
Completed by: Date:
Name tSitsaaatre Witnessed by: Date:
Name ~signattle ABB Combustion Engineenng Nudear Operations ABB Combustion Engineering Nuclear Operations
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TR-9419-CSE96-1101, Rev. 0 Attachment 2 Page 11 of 23 TP-941&CSE96-2104, Rev. 0 Page 10 of 11 Data Sheet 2 Dynamic Pressure Test Tool (circ. or long axial) initial Bladder Pressure psig Hydro Chamber Target Pressure pstg Pump Rate Hydro Chamber Hydro Pump Bladder Pressure"'
Pressure"'t Discharge Pressure" Strokes/min ( si si Maximum Minimum Maximum Maximum Minimum 0 static 20 40 60 80 100 Notes: i) For non-fiuctuaung pressure values. record pressure as the maximum pressure achieved.
Hydro Pump Discharge Pressure Gauge No.
Hydro Chamber Pressure Gauge No.
Bladder Pump Discharge Pressure Gauge No.
Remarks:
Completed by: Date:
Name. Signamre Witnessed by: Date:
Nuns.signamn ABB Combustion Engineering Nuclear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101~ev 0. Attachment 2 Page 12 of 23 TP-941 &CSE96-2104, Rev. 0 Page 11 of 11 Data Sheet 3 Remark Continuation Page Test (static or dynamic Tool (circ. or long axial)
Initial Bladder Pressure psig Hydro Chamber Target Pressure pstg Remarks:
Completed by: Date:
.'rane isigaature Witnessed by: Date:
.'raaa signamre ABB Combustion Engineering Nuctear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1 1Gi~aLQ Attachment 2 Page 13 of 23 Z8 d
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6,5. cd nse:~6- o- L Approved By:
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ASS Combuarion Enqinwring Naalaar operations TOTAL P.82 Jul LG '96 l4:51 ZGrZG'd G6Z~~t Ol telic SSZ G98 ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101, Rev. 0 Attachment 2 Page 14 of 23 TP-9419-CSE96-2104, Rev. 0 Page 9 of 11 Data Sheet 1 T I( '*. I g 'd)~
initial Bladder Pressure~Is Static Pressure Test
~ sig Target Hydro Observed Hydro Hydro Pump Bladder Pressure Chamber Pressure Chamber Pressure Discharge Pressure S1 Sl S1 S1 5'oo I 5oc
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Completedby: C~>z,,~ <~k. Date: 4 << ~~
'Nacm s Silttgure Witnessed by: 3 I~ < lol. Date:~<a/ Rte Vattse Sittaatttre ABB Combustion Engineering Nuctear Operations ABB Combustion Engineering Nuclear Operations p+->)
TR-9419-CSE96-11 Attachment 2 Page 15 of 23 TP-941 &CSE96-2104, Rev. 0 Page 9 of 11 Data Sheet 1 Static Pressure Test Tool (circ. or long axial)
Initial Bladder Pressnre~gee= sig Target Hydro Observed Hydro Hydro Pump Bladder Pressure Chamber Pressure Chamber Pressure Discharge Pressure SI s1 ( si ( si I 5ow
/tssoo 1 Ir"oa 3 05o Q tteIOO dt OC ~ee= +2 So tasse~ miso a Hydro Pump Discharge Pressure Gauge No. rS - r -I WI Hydro Chamber Pressure Gauge No. FS I I - o3~
Bladder Pump Discharge Pressure Gauge No. - - o<M Remarks:
Completed by: Ct=-~ Date: ~ " ~8 Vane; Silsatstrn slatsse St tnatttrts ABB Combustion Engineenng Nuoiear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101-,-Rev. 0 Attachment 2 Page 16 of 23 TP-941&CSE96-2104, RN'. 0 Page 9 of 11 Data Sheet 1 Static Pressure Test Tool (circ. or long axial) r QC .
Initial Bladder Pressure~/3'uc sig Target Hydro Observed Hydro Hydro Pump Bladder Pressure Chamber Pressure Chamber Pressure Discharge Pressure
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S I - loO 3~
Bladder Pump Discharge Pressure Gauge No. S - ( 7 - laO 33 Remarks:GI<t Lf LH~~ Q ~: A owg 5~,% Qj-sp o, ~ 5th'K-(<) S Q Caw,t "Is4sa Mi w W k. g I Completed by: C~u~~a l-r ~k Date: < '> ~<
stuns t Sirtaarttrc Wiutessed by: .~
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Siltarttrc Date:~d-Vd ABB Combustion Engineering Nuotear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101, Rev. 0 Attachment2 Page17of23 TP-9419-CSE96-2104, Revs 0 Page 9 of 11 Data Sheet 1 Static Pressure Test Tool (circ. or long axial) C QC Initial Bladder Pressnre~2seo sig Target Hydro Observed Hydro Hydro Pump Bladder Pressure Chamber Pressure Chamber Pressure Discharge Pressure SI SI SI SI
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~C~ ~oo Qg6~ Z Hydro Pump Discharge Pressure Gauge No. 5-i 3 - Ldeel Hydro Chamber Pressure Gauge No. PS - i l - eo 3 Bladder Pump Discharge Pressure Gauge No. 5- I - leos s RemarkS: ( )
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.'st aalu Sittaatttte Witnessed by: . Woi Date: Co-/(-~4
.'same Stttatttre ABB Combustion Engineering Nuotear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101, Rev. 0- Attachment 2 Page 18 of 23 TP-9419-CSE96-2104, Rev. 0 Page 10 of 11 Data Sheet Z Dynamic Pressure Test r
Tool (circ. or long axial) 5t 0 L initial Bladder Pressure I >~> psig Hydro Chamber Target Prmeuref keio pdg Pump Rate Hydro Chamber Hydro Pump Bladder
"
Pressure"'t Pressure'" Discharge Pressure Strokes/min st ( si Maximum Minimum Maximum Minimum Maximum Minimum 0 (static) /&5o l7o~ I 7am lpga o l9cc j 9co
/~>o
/g uO f lo&
5ptoo /go> /EoO 100 I '7 >t=e /g@ o r9su re.~
Notes: t) For non-ftuctuaung pressure values. record pressure as the maximum pressure achieved.
Hydro Pump Discharge Pressure Gauge No. 6's - l 7- l c t ~
eye ch b p* G Bladder Pump Discharge Pressure Gauge No. F5-l'7-l <<~9 Remarks:
Completed by:
Vgmg r Sithggttyg
(:7 Date: < I ~<
Witnessed by: Date: 6-il-C Vgmg ignanae ABB Combustion Engineering Nuctear Operations ABB Combustion Engineering Nuclear Operations p4-5 i
TR-9419-CSE96-1101~ev. 0 Attachment 2 Page 19 of 23 TP-941 &ZSE96-2104. Rev. 0 Page 10 of 11 Data Sheet 2 Dynamic Pressure Test Tool (circ, or long axial) %t AL Initial Bladder Pressure le~ psig Hydro Chamber Target Pressure 38~~ psig Pump Rate Hydro Chamber Hydro Pump Bladder Pressure"'
Pressure'" Discharge Pressure"'l Strokesimin SI sit Maximum Minimum Maximum Minimum Maximum Minimum 0 static) Qqoo geoP Zgl '3loo 40 Q)v gqoC Q7 oo gazoo oc
.Qj Q 3 5~qD 0'%co $ 2Oe-A/00 f+oo 100
/goo Notes: l) For non-lluctuating pressure values. record pressure as the maximum pressure achieved.
Hydro Pump Discharge Pressure Gauge No.
Hydro Chamber Pressure Gauge No. - s - l s - I 49' Bladder Pump Discharge Pressure Gauge No. A-(7- I c933 Remarks:
Completed by: C ~ g CI-i~ 5 vame t Siltature e
Witnessed by: ec i~ V tStttanare Date:~i A88 Combustion Engineering Nuclear Operations ABB Combustion Engineering Nuclear Operations r~-: <
TR-941 9-CSE96-1 101,>ev 0 Attachment 2 Page 20 of 23 Tp-941 9-CSE96-2104, Rev. 0 Page 10 of 11 Data Sheet 2 Dynamic Pressure Test Tool (circ. or long axial) 'i(> I >~>
aq~~
Initial Bladder Pressure I zc 0 psig Hydro Chamber Target Pressure+~4+ psig Pump Rate Hydro Chamber Hydro Pump Bladder Pressure'"
Pressure"'t Discharge Pressure '
Strokes/min si sl Maximum Minimum Maximum Minimum Maximum Minimum 0 static) b+~ 8'I~o !l iO
&20 t8 +ceo Q7E)C) 80 100 Notes: i) For non-fluctuaung pressure values. record pressure as the maximum pressure achevcd.
Hydro Pump Discharge Pressure Gauge No. PS -l1 - I o~~ I Hyd Ch b P G gN Bladder Pump Discharge Pressure Gauge No. Cs-t7-too33 Remarks:
Completed by: Date: rl '< 9<
.'rane i signanue Witnessed by: Date: 6 ~i 5'6 v siyenee ABB Combustion Engineenng Nuctear Operations ABB Combustion Engineering Nuclear Operations
+-3 i
TR-9419-CSE96-1101;.Re. e--- Attachment 2 Page 21 of 23 TP-941&CSE96-2104, Rev. 0 Page 10 of 11 Data Sheet 2 sr 'rr Dynamic Pressure Test Tool (circ. or long axial) lultlal Bladder Pressure~the-'h psig Hydro Chamber Target Pressure J1+0 pslg Pump Rate . Hydro Chamber Hydro Pump Bladder Pressure "
Pressure"'I Discharge Pressure "
Strokes/min sl ( si Maximum Minimum Maximum Minimum Maximum Minimum 0 static) l~ ~ l1+~ tgOO 1'Voa i~5Q IQ~o /6OO
< A-a /Qoc: dt I 0t-"s / 4tao t75 o 60 gether Zcy>> /bet o t160
~o Q I Des I3o~ /dr'eo l7ZO 7oo r Pcycp Wee
]g Cu l7om g. Ieto Notes: t) For non-fluctuaung pressure values. record pressure as the maxtmum pressure achiared.
Hydro Pump Discharge Pressure Gauge No.
hid Ch I Ih o Bladder Pump Discharge Pressure Gauge No.
h*ha.~ s- i7- foal 5 I a>>>
Remarks: lo I
Completed by; C vz a I-h~ k Vgtttc h St ttgtttye Witnessed by: Date:~th/rr V .Sittgtttgg ABB Combustion Engineering Nuclear Operations ABB Combustion Engineering Nuclear Operations
TR-94'i 9-CSE96-1101,,R&V. 0 Attachment 2 Page 22 of 23 TP-9419-CSE96-2104, Rev. 0 Page 10 of 11 Data Sheet 2 Dynamic Pressure Test Tool (circ. or long axial) A~ <
fnitial Bladder Pressure t ~cs~ psig Hydro Chamber Target Pressure 3t"S o psig Pump Rate Hydro Chamber Hydro Pump Bladder Pressure'"
Pressure"'l Discharge Pressure"'l Strokes/min Sl Maximum Minimum Maximum Minimum Maximum Minimum 0 static) %5 5C'ryos 3/o"
>So~ dl e~ '3 goo Q v~0~
n es o 7~o $ gOO Q clasO 3~o $ rfoo 9(oe ggoQ stqOsO Q ~c2 100 IL 9'~o 39~D Notes: l) For non-Auctuaung pressure values. record pressure as the mmumum pressure achieved.
Hvdro Pump Discharge Pressure Gauge No. 55- I 1 - loooI Hvdro Chamber Pressure Gauge No. s -I I ~ >~
Bladder Pump Discharge Pressure Gauge No. E5- f -0~2~ '7 Remarks:
Completed by:
Vasne rsignantte Date: >> ~>
Wimessed by. Date:~~ri c
!4 .Signature ABB Combustion Engineenng Nuclear Operations ABB Combustion Engineering Nuclear Operations
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TR-9419-CSE96.-'i iG1,MKLQ. Attachment 2 Page 23 of 23 TP-9419-CSE96-2104, Rev. 0 Page 10 of 11 Data Sheet Z Dynamic Pressure Test Tool (circ. or long axial) Cl P<
initial Bladder Pressure I >~ psig Hydro Chamber Target Pressure &3oa psig Pump Rate Hydro Chamber Hydro Pump Bladder Pressure"'
Pressure"I Discharge Pressure"'
Strokes/min SI si si Maximum Minimum Maximum Minimum Maximum Minimum 0 static) H5~~ %5oo 20 ~r~ ~9~ 93~
AO"+z. +geo gl eQ C I~o g'leo I toes 3'
3goo 100 "f5~o q$ ocs Notes: I) For non-fluctuaung pressure values. record pressure as the maximum pressure actueved.
Hydro Pump Discharge Pressure Gauge No. FS. t1- /choo I Hydro Chamber Pressure Gauge No. S l - toe >~
Bladder Pump Discharge Pressure Gauge No. C" - tv - (eass Remarks: Low L~K lent Completed by: Date: b " <<
Wane.si gaamce Witnessed by:
Name Signcun ABB Combustion Engineering Nuciear Operations ABB Combustion Engineering Nuclear Operations
TR-9419-CSE96-1101, Rev. 0 Attachment 3 Page 1 of 5 Attachment 3 Pressure Gauge Calibration Records ABB Combustion Engineering Nuclear Operations p- 4/
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TR-9419-CSE96-11 Attachment3 Page4of5 STO-400-159 ABB-Combustion Engineering Page 5 of 5 Rev. 00 ~
¹xclear Operations Attachment 1 CERTlFICATE OF CAUBRATlON instrunlent Type Calibration Date Manufaaurer Calibration Due Date Range 0-
'O @cc racy Calibration Document:
Mfg. Serial No. gl Procedure C.E lO No P'5 -(7 /db ZB [ ) Manutacturer s Specifications Test Equipment Used To Perform Calibration:
K~~ Test Equipment Senal or ID No.
V -oo<
Test Equipment Serial or lo No.
CAiJBRATlON RESULTS Standard Value As Found i As Left Standard Value As Found As Left (Cg lo CAUSRATION HAS af EH P& FORM EO UnUDNQ MEASUREMEHT Ofvlcf5 WHICH H*vE KNOWN RELATIONSIII&To Nss STANOAAOS Wlifaf SUCH ST*NO*ROS KXIS . WHcfaf 5UCH STAHOARO5 Oo NQT Q(IST, AH A~QVEO IVOC OURE WAnicN IH ACCOROAHCE Wnl TH MAHUFA~iRfcL'5 RECQMMfiIQATIQNS HA5 BfcEN USEQ AHO THE STAHOAAOS OOCUMEHi co.
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1 ACCEPTEO ( 1 REJECTED ORGANIZATION:
ABB Combustion Engineering Nuclear Operations
TR-941 9-CSE96-1 10~ev Q. Attachment 3 Page 5of5 STD-400-159 ABB-Combustion Engineering page 5 of 5 Rev. 00 Nuclear Operations Attachment 1 CERTlFICATE OF CALIBRATlON Instrunlent Type Calibrarion Date Manufacturer Calibration Oue Date Range 0- ra eevraeyg~2FS CalIbratIon Oacurnent.
Mfg. Serial No. (+ Pracedure ~~~ Rev.
C-E ID No. ) Manufacturer's Specifications Test Equipment Used To Perform Calibration:
Test Equipment Serial or IO No. Test SquIonlent Serial or IO No.
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lo CAUSRATloN H*5 IEKH PEaIFORMKO UnUZINO MEASUREMENT QEVIC'ES WHICH HAVK KNOWN RELATIONSHIPS Ta Nes STANQARQS WHERE SUCH STANOARQS KXISi. WHERE SUCH 5i ANOARQ5 QO NOT EXIST. AN APPROVEQ PROCEQUR WRITTEN IN ACCOROANCE VIPiil THE MANUFA~iRER'5 RFCOarIMEVQATloaIS HAS BEgaI USEO ANO THE STANOAROS QOCUMEN a =O.
R":MAR(S CALIBRAT "0 BY:
()Cl ACC:?T"=D I l R"= J"=CT"-O ORGAraNaIZATION:
ABB Combustion Engineering Nuclear Operations Ig(