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Entergy Nuclear Operations, Inc.600 Rocky Hill Road Plymouth, MA 02360 Pilgrim Nuclear Power Station September 19, 2013.U.S. Nuclear Regulatory Commission Attn: Document Control Desk Washington, D.C. 20555

SUBJECT:

Entergy Nuclear Operations, Inc.Pilgrim Nuclear Power Station Docket No.: 50-293 License No.: DPR-35 Response to NRC Request for Additional Information

-Pilgrim Nuclear Power Station PR-03 and PR-05 Fifth Ten-Year Inservice Testing (IST)Program (TAC NO. MF 0370)

REFERENCE:

1. NRC Request for Additional Information Related to PR-03 and PR-05, dated July 1, 2013 (TAC No. MF0370)2. Entergy Letter No. 2.12.088, Pilgrim Nuclear Power Station Fifth Ten-Year Inservice Testing (IST) Program and Request for Approval of IST Relief Requests PR-03 and PR-05, dated December 6, 2012 3. Entergy Letter No 2.07.056, Response to NRC Request for Additional Information Related to Pilgrim Inservice Testing (IST) Relief Request PR-03 (TAC NO. MD2478), Attachment 2, "HPCI Main Pump Vibration Data", dated July 12, 2007 LETTER NUMBER: 2.13.076

Dear Sir or Madam:

The Attachments to this letter provide the Entergy Nuclear Operations, Inc., (Pilgrim) response to the NRC Request for Additional Information (Reference

1) related to Pilgrim Relief (PR) -03 and PR-05, included in the Pilgrim Fifth Ten-Year Inservice Testing Program (References 2 and 3).Attachment 1 provides responses to the NRC RAI, which includes as Attachment 2, the revised IST PR-05, Rev. 1 and Enclosure 1, which provides HPCI Pump vibration data from 2008 to 2013. Reference 3 provides HPCI Pump vibration data for testing conducted during early 2007.This letter contains no commitments.

KtL PNPS Letter 2.13.076 Page 2 of 2 Please do not hesitate to contact me at (508) 830-8403, if there are any questions regarding this submittal.

Sincerely, Joseph R. Lync Manager, Pilgrim Licensing Attachment 1: Pilgrim Response to NRC Request for Additional Information Related to IST PR-03 and PR-05 (4 pages)Attachment 2: Revised Relief Request, PR-05 (Revision

1) (2 pages)Enclosure 1: HPCI Pump Configuration and Historical Vibration Results (61 pages)cc: Mr. William M. Dean Regional Administrator, Region 1 U.S. Nuclear Regulatory Commission 2100 Renaissance Blvd., Suite 100 King of Prussia, PA 19406-2713 Ms. Nadiyah Morgan, Project Manager Office of Nuclear Reactor Regulation U.S. Nuclear Regulatory Commission One White Flint North Mail Stop O-8-C2A 11555 Rockville Pike Rockville, MD. 20852-2738 USNRC Senior Resident Inspector Pilgrim Nuclear Power Station Attachments to Letter Number 2.13.076 Pilgrim Response to NRC Request for Additional Information Related to IST PR-03 and PR-05 Attachment 1: Pilgrim Response to NRC Request for Additional Information Related to IST PR-03 and PR-05 (4 pages)Attachment 2: Revised Relief Request, PR-05 (Revision

1) (2 pages)Enclosure 1: HPCI Pump Configuration and Historical Vibration Results (61 pages)(Total 67 Pages)

Attachment I to Entergy Letter No. 2.13.076 Page 1 of 4 Response to NRC RAI Questions for Standby Liquid Control System Pumps RAI PR-05-1 ISTB-5300(a)(1) is applicable to Group A and comprehensive pump tests. The standby liquid control (SLC) pumps are Group B pumps. Is the alternative that is requested only applicable to the comprehensive pump test for the SLC pumps?Response: Yes, the Standby Liquid Control (SLC) pumps are categorized as Group B (standby system) pumps.The alternative is requested for flow measurement during the hydraulic portion of the comprehensive pump test. The vibration parameters for the comprehensive pump test are obtained with the SLC pump in recirculation mode, and are recorded after a 2 minute hold period following establishment of the SLC pump reference discharge pressure.

Relief Request PR-05 has been revised to clarify that the alternative requested is for the comprehensive pump test. The revised PR-05, Rev. 1 is attached as Attachment 2 to this letter.RAI PR-05-2 Please describe other alternatives for measuring flow rate that have been considered, such as installing instrumentation for measuring flow rate (permanent or temporary), and explain why these could not be implemented.

Response: Ultrasonic (UT) flow instrumentation has been considered for flow measurement of the SLC pumps.Historically, two efforts to install and utilize a UT flow system (both portable and permanent units)through plant design change process have been attempted for SLC pump flow measurement.

These flow systems were later abandoned due to intermittent erratic flow measurement readings and overall unacceptable flow repeatability.

The SLC pump system has limited sections of straight piping that are not impacted by upstream tee fittings, elbows, and/or valves in the discharge test line. These pipe sections experience high levels of turbulence which undermines UT flow signal reliability.

Other straight piping sections in the test loop, do not remain completely full of fluid (required for reliable UT signal), which also impacts UT flow signal reliability and measured flow rate. Benchmark testing of the previously installed UT flow meters has shown that modification of the SLC test circuit piping will most likely be necessary to implement reliable and repeatable UT flow system testing.The test tank measurement methods for the SLC pumps are highly accurate, as measuring the volume that a pump system delivers over a specified period of time is a reliable and repeatable method for determining flow rate. Measuring the fluid volume or fluid weight that a pump delivers over a specified period is a commonly applied method for determining actual flow rate when calibrating ultrasonic flow meters. It is believed that replacement of the flow measurement tank with ultrasonic flow meters, and implementation of associated SLC discharge pipe modifications, would not produce flow measurement results that are more accurate or repeatable than the current method of determining system flow rate through measuring test tank level change.

Page 2 of 4 Therefore, PNPS believes that installing an ultrasonic flow measurement system to facilitate pump testing in accordance with the ASME OM Code would impose a hardship without a compensating increase in level of quality and safety.RAI PR-05-3 Please explain why the existing test tank cannot be replaced with a larger test tank.Response: Replacement of the SLC pump test loop flow measurement test tank with a larger size would not significantly increase pump flow measurement accuracy or repeatability as the current flow measurement configuration meets a high standard for accuracy and repeatability.

The marginal benefit that might be realized would not change the observed in-service test results or improve pump hydraulic performance monitoring.

Therefore, PNPS believes that installing a larger test tank to facilitate pump testing in accordance with the ASME OM Code would impose a hardship without a compensating increase in level of quality and safety.Response to NRC RAI Questions for HPCI System Pumps RAI PR-03-1 It is stated in part, in Section 6 of the Reference, that, "Enclosures 1 and 2 (of Entergy Outgoing NRC Letter 02.08.007) provide HPCI pump vibration spectrum at locations required by the operators manager (OM) Code procedure." The vibration information in Enclosures 1 and 2 is for the time period from 1994 to 2005. Please provide the high-pressure coolant injection (HPCI) pump vibration spectrum for the time period from 2006 through 2012.Response: Entergy has supplied vibration data from the 2008 through 2012 time frame in Enclosure 1 to this Attachment.

Entergy Letter 02.07.056, Attachment 2, "HPCI Main Pump Vibration Data (10 pages)" provided HPCI pump vibration spectrum for testing conducted during early 2007 (Reference 3).RAI PR-03-2 It is stated in part, in the second bullet of Section 5 of the Reference, that, "Quarterly lubrication oil sampling and periodic laboratory analysis as appropriate for the pressure-fed bearings..." Please provide a more detailed explanation as to what is meant by "periodic laboratory analysis as appropriate." Response: The quarterly lubrication oil sampling and periodic laboratory analysis for the pressure-fed bearings on the Turbine, Main pump, and Gear Reducer consists of the following:

Page 3 of 4* Quarterly lubrication oil sampling analysis will be performed.

This includes analysis for viscosity, water content, chemical changes, and contaminants including ferrous particles.

• Once/cycle (i.e., once/2 years) laboratory analysis of the lubrication oil for the pressure-fed bearings on the Turbine, Main pump, and Gear Reducer will be performed.

The Laboratory reviews include but not limited to particle wear analysis, acid number readings, analytical ferrogram and oxidation stability.

This type of monitoring will detect degradation of the turbine or pump bearings due to accelerated wear, fretting, surface fatigue, or oil contamination." In addition to the above sampling, when the quarterly lubrication oil sampling analysis shows that a more detailed analysis is warranted, then an oil sample is also sent out for the more comprehensive laboratory analysis.RAI PR-03-3 The HPCI main pump proposed vibration values at vibration points P3H, P4H, and P4V, for the Acceptable Range, at vibration points P3H, P4H, and P4V for the Alert Range, and for vibration points P3H and P4H for the Required Action Limit are higher than the proposed values at the same points in Alternative Request PR-03 Revision 3, which was authorized by the NRC staff. Please explain why you are proposing to increase the vibration values as stated above over what was authorized in Alternative Request PR-03 Revision 3.Response for P3H and P4H: Alternative Request -Absolute Vibration Level Criteria for P3H and P4H Acceptable Range of P3H < 1.06 in/sec and P4H < 0. 70 in/sec Alert Range of P3H > 1.06 in/sec to 1.3 in/sec and P4H > 0.70 in/sec to 0.83 in/sec Absolute Vibration Required Action Limit of P3H > 1.26 in/sec and P4H > 0.83 in/sec The absolute Acceptable, Alert, and Required Action values contained within Alternative Request PR-03 Revision 3 were not authorized by the NRC approved SER. Instead the approval SER provided substitute absolute Acceptable, Alert, and Required Action values, which have now been incorporated into Alternative Request PR-03 Revision 4.Background Information:

The HPCI main pump proposed vibration values for Alternative Request PR-03 Revision 3 at vibration points P3H and P4H, for the Acceptable Range, at vibration points P3H, P4H for the Alert Range, and for vibration points P3H and P4H for the Required Action Limit were based upon an obtained vibration value resulting from the vibration point spectrum overall value with the discrete peak at 4X Booster pump RPM extracted (using the mean-squared subtraction method). This information is provided in the 2 nd paragraph of the Alternate Testing section and is identified as a footnote (**) at the bottom of the Main Pump table. The SER, sent by NRC letter dated August 27, 2008 (TAC No.MD8052), that authorized PR-03 Revision 3 as an alternative did not embrace the approach (to subtract the discrete peak at 4X Booster pump RPM) identified within the Main Pump table. Instead the SER approved Alternative Request PR-03 Revision 3 by specifying substitute absolute overall vibration criteria for vibration points P3H and P4H (which is not based upon discrete peak subtraction at 4X Booster pump RPM).

Page 4 of 4 The absolute overall vibration criteria for the acceptable range, alert range and required action limit specified within the approval SER for PR-03 Revision 3, have been placed into the proposed Alternative Request PR-03 Revision 4 (5 th interval).

Alternative Request -Relative Vibration Level Criteria for P3H and P4H Relative Vibration Acceptance Limit for P3H and P4H < 1.1 Vr (Alert Value of > 1. 1 Vr)The relative (value based upon multiple of reference vibration) overall vibration values provided within the approval SER for PR-03 Revision 3, for the acceptable and alert ranges has been modified to equal 1.1 Vr, in lieu of the 1.05 Vr value specified within the PR-03 Revision 3 approval SER. Pilgrim revised the proposed acceptable and alert ranges to 1.1 Vr because it is believed that an Alert criteria based upon a 5% change (1.05 Vr) in overall vibration amplitude is too close to the normal expected band for overall vibration amplitude, and therefore, small vibration amplitude increases which can be expected to occur occasionally during long term vibration monitoring (period of years) will intermittently place the pump into Alert status. When an IST component intermittently triggers an Alert vibration criterion it is essentially considered to reside in IST Alert status, which is undesirable.

Response for P4V: The HPCI main pump vibration values for proposed Alternative Request PR-03 at vibration point P4V, for the Acceptable Range, Alert Range and Action Required Limit are the same as specified within the OM Code, and therefore, are in compliance with the OM Code criteria.

Alternative Request PR-03 revision 4 states (page Alternate Testing, 3 rd paragraph last bullet): "The Table rows for P4V and P8A are in compliance with the OM Code vibration criteria and have been placed into this Relief Request for information only." Enclosure 1: HPCI Pump Configuration and Historical Vibration Test results (61 Pages)

Attachment 2 to Entercy Letter No. 2.13.076[5] PUMP RELIEF REQUEST PR-05 (Revision 1)Information to Support NRC Re-Approval of a 10CFR50.55a Request for Use During a New 10-Year Interval Inservice Testing Program Pumps: P-207A and P-207B System: Standby Liquid Control System (1101)Class: 2 Function: Provides a method of shutting down the Reactor without use of the control rods.Test Requirements:

ISTB-5300(a), Duration of Tests (1) For the Group A test and the comprehensive test, after pump conditions are as stable as the system permits, each pump shall be run at least 2 min. At the end of this time, at least one measurement or determination of each of the quantities required by Table ISTB-3000-1 shall be made and recorded.Relief Requested:

Determine the Standby Liquid Control (SLC) pump hydraulic parameter (measured flow rate)by establishing the reference pump discharge pressure during the procedure initial conditions (prior to the start of the flow measurement test) in lieu of running the pump for at least 2 minutes after pump conditions are as stable as the system permits.Basis For Relief: The Standby Liquid Control (SLC) pumps are categorized as Group B (standby system)pumps. During the hydraulic portion of the comprehensive pump test, the SLC pumps are tested by pumping fluid from the SLC storage tank into a test tank. The test tank capacity does not allow operation of the pump for much longer than 3 minutes.The SLC system was not designed with flow meter instrumentation in the flow test loop and uses a test tank to determine flow rate by measuring the change in tank level over a period of time. Due to physical limitations of the size of the tank, the pump run time for measuring the hydraulic test parameter of flowrate is limited. Design, fabrication, and installation changes would have to be made to comply with the ISTB-5300(a) requirement.

The 2 minute hold time is an OM Code requirement in order to achieve stable pump performance parameters before the test data is recorded.

The present surveillance test procedure has provided consistent hydraulic test results and produces good repeatability.

During testing, the initial test conditions are established by operating each SLC pump in recirculation mode and adjusting the pump discharge test flow (throttle) valve to obtain the test reference discharge pressure.

Once the reference test pressure has been established and stable conditions are observed, the pump is stopped and the pump discharge path is realigned to the test tank. Next the pump is started, the reference pressure is again verified while pumping into the test tank, and the pump is again stopped. After the initial test tank level is measured, the pump is restarted and allowed to run for exactly 3 minutes. The test tank final level is measured and the pump flow rate is calculated.

Pump flow rate calculations meet the requirements of table ISTB-3510-1 for measured values.

Attachment 2 to Entergy Letter No. 2.13.076[5] PUMP RELIEF REQUEST PR-05 (CONTINUED)

When using the test tank flow circuit; the pump suction pressure remains constant because the pump suction is aligned to the SCL storage tank (insignificant tank level change), and the pump discharge head remains constant because the test tank discharge piping is not submerged (no back pressure from test tank fluid level).Alternate Testing: The pump test procedure will establish the pump reference discharge pressure prior to conducting the 3-minute pump test run. When the initial conditions for reference discharge pressure are established, the SLC pump will be stopped and initial test tank level will be measured.

Then the SLC pump will be run for a duration of exactly 3 minutes. An accurate measurement of the initial test tank level and final test tank level will be used to determine the measured test flow rate.This alternative was requested by PNPS by letter dated October 29, 2003, and approved for the 4th Inservice Testing Ten-Year Interval as RP-05, Revision 0, on April 30, 2004 (NRC Letter from James W. Clifford, Office of Nuclear Reactor Regulation to Michael Kansler, Entergy Nuclear Operations, Dated April 30, 2004) (No TAC NO. was assigned).

The proposed relief was approved pursuant to 10CFR50.55a(a)(3)(ii).

Changes to Applicable ASME Code Section Applicable Code and Addenda: OM-2004 Edition through OMb-2006 Addenda Applicable Code Requirement:

ISTB 5300(a) Duration of Tests (1) "For the Group A test and the comprehensive test, after pump conditions are as stable as the system permits' each pump shall be run at least 2 min. At the end of this time, at least one measurement or determination of each of the quantities required by Table ISTB-3000-1 shall be made and recorded." The specified Code requirement is unchanged for the ASME OM Code 1995 Edition, with the 1996 Addenda ISTB 5.6.3, comprehensive test requirement:

ISTB 5.6.3, Comprehensive A Test: "After pump conditions are as stable as the system permits' each pump shall be run at least 2 min. At the end of this time, at least one measurement or determination of each of the quantities required by table ISTB 4.1-1 shall be made and recorded." Duration of Re-Approval for Proposed Alternative:

This relief is requested for the duration of the PNPS 5th Inservice Testing Ten-Year Interval (December 7th, 2012 through December 6th, 2022).

ENCLOSURE 1 HPCI PUMP CONFIGURATION AND HISTORICAL VIBRATION TEST RESULTS (Total 61 oaces)(Pilgrim seeks Authorized Alternative of Required Action Limit for P3H and P4H Points.)HPCI Pump Layout 1. HPCI Pump Vibration Monitoring Program Reg. Action Requested Alternative Point P3H Data 2. P3H HPCI Vibration Spectrum Data, Feb 20, 2008 3. P3H HPCI Vibration Spectrum Data, May 22, 2009 4. P3H HPCI Vibration Spectrum Data, Feb 18, 2010 5. P3H HPCI Vibration Spectrum Data, Aug 16, 2011 6. P3H HPCI Vibration Spectrum Data, Feb 14, 2012 7. P3H HPCI Vibration Spectrum Data, May 29, 2013 Reg. Action Requested Alternative Point P4H Data 8. P4H HPCI Vibration Spectrum Data, Feb 20, 2008 9. P4H HPCI Vibration Spectrum Data, May 22, 2009 10. P4H HPCI Vibration Spectrum Data, Feb 18, 2010 11. P4H HPCI Vibration Spectrum Data, Aug 16, 2011 12. P4H HPCI Vibration Spectrum Data, Feb 14, 2012 13. P4H HPCI Vibration Spectrum Data, May 29, 2013 Point P3V Data 14. P3V HPCI Vibration Spectrum Data, Feb, 20,2008 15. P3V HPCI Vibration Spectrum Data, May 22, 2009 16. P3V HPCI Vibration Spectrum Data, Feb 18, 2010 17. P3V HPCI Vibration Spectrum Data, Aug 16, 2011 18. P3V HPCI Vibration Spectrum Data, Feb 14, 2012 19. P3V HPCI Vibration Spectrum Data, May 29, 2013 Point P3A Data 20. P3A HPCI Vibration Spectrum Data, Feb, 20,2008 21. P3A HPCI Vibration Spectrum Data, May 22, 2009 22. P3A HPCI Vibration Spectrum Data, Feb 18, 2010 23. P3A HPCI Vibration Spectrum Data, Aug 16, 2011 24. P3A HPCI Vibration Spectrum Data, Feb 14, 2012 25. P3A HPCI Vibration Spectrum Data, May 29, 2013 Point P4V Data 26. P4V HPCI Vibration Spectrum Data, Feb, 20,2008 27. P4V HPCI Vibration Spectrum Data, May 22, 2009 28. P4V HPCI Vibration Spectrum Data, Feb 18, 2010 29. P4V HPCI Vibration Spectrum Data, Aug 16,2011 30. P4V HPCI Vibration Spectrum Data, Feb 14, 2012 31. P4V HPCI Vibration Spectrum Data, May 29, 2013 Point P7H Data 32. P7H HPCI Vibration Spectrum Data, Feb, 20,2008 33. P7H HPCI Vibration Spectrum Data, May 22, 2009 34. P7H HPCI Vibration Spectrum Data, Feb 18, 2010 35. P7H HPCI Vibration Spectrum Data, Aug 16, 2011 36. P7H HPCI Vibration Spectrum Data, Feb 14, 2012 37. P7H HPCI Vibration Spectrum Data, May 29, 2013 Point P7V Data 38. P7V HPCI Vibration Spectrum Data, Feb, 20,2008 39. P7V HPCI Vibration Spectrum Data, May 22, 2009 40. P7V HPCI Vibration Spectrum Data, Feb 18, 2010 41. P7V HPCI Vibration Spectrum Data, Aug 16,2011 42. P7V HPCI Vibration Spectrum Data, Feb 14, 2012 43. P7V HPCI Vibration Spectrum Data, May 29, 2013 44. P8H 45. P8H 46. P8H 47. P8H 48. P8H 49. P8H Point P8H Data HPCI Vibration Spectrum Data, Feb, 20,2008 HPCI Vibration Spectrum Data, May 22, 2009 HPCI Vibration Spectrum Data, Feb 18, 2010 HPCI Vibration Spectrum Data, Aug 16, 2011 HPCI Vibration Spectrum Data, Feb 14, 2012 HPCI Vibration Spectrum Data, May 29, 2013 Point P8V Data 50. P8V HPCI Vibration Spectrum Data, 51. P8V HPCI Vibration Spectrum Data, 52. P8V HPCI Vibration Spectrum Data, 53. P8V HPCI Vibration Spectrum Data, 54. P8V HPCI Vibration Spectrum Data, 55. P8V HPCI Vibration Spectrum Data, Feb, 20,2008 May 22, 2009 Feb 18, 2010 Aug 16, 2011 Feb 14, 2012 May 29, 2013 Point P8A Data 56. P8A HPCI Vibration Spectrum 57. P8A HPCI Vibration Spectrum 58. P8A HPCI Vibration Spectrum 59. P8A HPCI Vibration Spectrum 60. P8A HPCI Vibration Spectrum 61. P8A HPCI Vibration Spectrum Data, Feb, 20,2008 Data, May 22, 2009 Data, Feb 18, 2010 Data, Aug 16, 2011 Data, Apr 29, 2012*Data, May 29, 2013*April 29, 2012 data is submitted since Feb. 14, 2012 spectrum data is not available for point P8A.

HPCI PUMP VIBRATION DATA POINTS P3H, P3V, P3A, P4H, P4V, P7H, P7V, P8H, P8V, P8A X203. P20S. HP'1 TURBINE & PUMP TOV.TI 1 V P`3A PM 1 P4Y IURB7NE OUTBCVRD H-ORIZONTAL TURBINE OUTBOARD VERTiCAL IURBINE OtJTBOArD AXIAL TURBINE iNBOARD HORIZONTAL TURBINE VERTICAL PUMP Y.B- -HORiZONTAL PUMP L-B. VERTICAL PUMP i.B. AXIAL PUMP I.B- QRIZONTAL PUMP i.B. VERTICAL G i!'GOV GOA P7V paii GEAR iNBOARD -.HORiZONTAL GEAR INBOARD VERTICAL GEAR OUTBOARD !{ORIZONTAL GEAR OUTBOARD VERTICAL GEAR OUTBOARD AXIAL PUMP OUTBOARD -ORIZONTAL PUMP OJTBOARM VERTICAL PUMP OULTBOARD

-50RIZONTAL PUMP OUfTBOARD VERTICAL PUMP O.TBOARO AXIAL 1ST -IST, P205 HPCI @42.5k HPCI ISTR -P3H #3 BEARING-PUMP HORIZONTAL U w U 0 S A-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:25:22 OVRALL= .7261 V-DG PK = .7164 LOAD =4250.0 RPM 4011.RPS 66.85 0)C C.40 wi 0.2 0 0 I 3 4 5 6 Frequency in Order 1.5 1.2 0.9 ROUTE WAVEFORM 20-FEB-08 23:25:22 PK = .7326 PK(+) = 1.18 PK(-) = 1.22 CRESTF= 2.36 U U)C U 0 0.6 0.3 0-0.3-0.6-0.9-1.2-1.5 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.016 134.77.522 IST -IST, P205 HPCI @42.5k 1.0 HPCI ISTR -P3H #3 BEARING-PUMP HORIZONTAL ROUTE SPECTRUM 22-MAY-09 13:36:59 OVRALL= .8124 V-DG o.8 PK = .8072 0: LOAD =4250.04038.0.6 RIPS= 67.30> 0.4 0.2 0-0 1 2 3 4 5 6 Frequency in Order 1.5ROUTE WAVEFORM 1.2 22-MAY-09 13:36:59 0.9,- PK(+) = 1.34 SPK(-) =1.26 0 .6 .. t, 4.ý :1 ~. bCRESTF= 2.32 0.3b i I " 60 218 4 00Fe: 157 T-0.3 ,-1.52L1 1 0 6 10 10 40 00Ordr: 2.016 60 20 80 40 00Freq: 135.70 Time in mSecs Spec: .602 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3H #3 BEARING-PUMP HORIZONTAL 1.0 0.8 ROUTE SPECTRUM 18-FEB-10 16:46:34 OVRALL= .7368 V-DG PK = .7322 LOAD =4250.0 RPM= 3998.RPS = 66.63 C)lie CL C4 0.6 0.4 o.Lo.0.2 0 1 2 3 4 5 6 Frequency in Order 1.5 1.2 0.9 ROUTE WAVEFORM 18-FEB-10 16:46:34 PK = .6616 PK(+) 1.16 PK(-) = 1.06 CRESTF= 2.49 C)S U)C 0 0.6 0.3-0.3-0.6-0.9-1.2 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.017 134.39.595 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3H #3 BEARING-PUMP HORIZONTAL in 0 IL 0.8 -0.6 0.4 t ROUTE SPECTRUM 16-AUG-11 11:26:23 OVRALL= .8749 V-DG PK = .8658 LOAD =4250.0 RPM= 3996.RPS = 66.60 0, Li 0.2 0 2 3 4 5 6 Frequency in Order 1.5 1.2 0.9 0 0.6 0.3 0-T I ROUTE WAVEFORM 16-AUG-11 11:26:23 PK = .7368 PK(+) =1.29 PK(-) = 1.22 CRESTF= 2.48 ii-U.3-0.6-0.9-1.2-1.5 ii I ii Ii 1* 4.--1-0 60 120 180 Time in mSecs 240 300 Ordr Freq: Spec: 2.027 135.00.447 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3H #3 BEARING-PUMP HORIZONTAL C.)C)(n C U 41'p 0-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 14-FEB-12 12:02:59 OVRALL= .7001 V-DG PK = .6922 LOAD =4250.0 RPM = 4013.RPS = 66.88 CN 0 9 0 0n 0.2 0 1 2 3 4 5 6 Frequency in Order 1.5 1.2 0.9 U 0 C C C)0'p 0.6 0.3-0.3 HI ROUTE WAVEFORM 14-FEB-12 12:02:59 PK = .8183-PK(+) =1.32 PK(-) = 1.36-CRESTF= 2.35-0.6-0.9-1.2-1.5 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.015 134.77.439 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3H #3 BEARING-PUMP HORIZONTAL C.)C 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 29-MAY-13 23:41:02 OVRALL .7447 V-DG PK = .7384 LOAD =4250.0 RPM= 4020.RPS = 66.99 ROUTE WAVEFORM 29-MAY-13 23:41:02 PK = .5921 PK(+) = .9708 PK(-) = 1.02 CRESTF= 2.45 0.2 0 Frequency in Order 1.2 0.9 0.6 0.3 U S C C.)0 S 0-0.3-0.6-0.9-1.2 0 60 120 180 240 Time in mSecs 300 Ordr Freq: Spec: 2.019 135.23.522 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4H #4 BEARING-PUMP HORIZONTAL u 0 a-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:27:24 OVRALL= .5961 V-DG PK = .5905 LOAD =4250.0 RPM = 4018.RPS = 66.97 ROUTE WAVEFORM 20-FEB-08 23:27:24 PK = .4928 PK(+) = .9209 PK(-) = .8212 CRESTF= 2.64 0.2 0 Frequency in Order U 4~C C 4, 0 S 1.2 1.0 0.8 0.6 0.4 0.2-0.0-0.2-0.4-0.6-0.8-1.0 0 60 120 180 240 Time in mSecs 300 Ordr.Freq: Spec: 2.016 135.00.175 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4H #4 BEARING-PUMP HORIZONTAL U 0 1.0 0.8 0.6 0.4 0.2 0 1.0 0.8 t÷CD 0ý04 0 R ROUTE SPECTRUM 18-FEB-10 16:47:57 OVRALL= .4676 V-DG PK = .4023 LOAD =4250.0 RPM= 4001.RPS = 66.68 ROUTE WAVEFORM 18-FEB-10 16:47:57 PK = .4648 PK(+) =.8023 PK(-) = .9456 CRESTF= 2.88 U S C C U 0 0.6 0.4 0.2-0.0-0.2-0.4-0.6-0.8-1.0-1.2 0 1 3 4 5 6 Frequency in Order--------1 A i j ij 1 VIJ lJ SI /0 60 120 180 Time in mSecs 240 300 Ordr;Freq: Spec: 2.018 134.53.279 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4H #4 BEARING-PUMP HORIZONTAL IL 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 16-AUG-11 11:33:20 OVRALL- .7261 V-DG PK = .7228 LOAD =4250.0 RPM 4001.RPS = 66.68 0.2 0 Frequency in Order 1-2 0.9 0.6 ROUTE WAVEFORM 16-AUG-11 11:33:20 PK = .6237 PK(+) = 1.08 PK(-) 1.07 CRESTF= 2.45 ci 0 Ii 0 0 0.3 0-0.3-0.6-0.9-1.2 0 60 120 180 240 300 Time in mSecs Ordr: Freq: Spec: 2.017 134.53.409 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4H #4 BEARING-PUMP HORIZONTAL 43 IJ~C a-t.0 0.8 0.6 0.4 ROUTE SPECTRUM 14-FEB-12 12:06:25 OVRALL= .7394 V-DG PK = .7365 LOAD =4250.0 RPM= 4020.RPS = 67.00 0, 0" 01 CN 0.2 0 0>04 0 1 2 3 4 5 6 Frequency in Order 1.2 0.9 0.6 0 0.3 0 ROUTE WAVEFORM 14-FEB-12 12:06:25 PK = .8083 PK(÷)= 1.07 PK(-) = 1.27 CRESTF= 2.22-0.3-U.9 --0.9-1.2-1.5 0 60 120 180 Time in mSecs 240 300 Ordr: Freq: Spec: 2.018 135.23.272 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4H #4 BEARING-PUMP HORIZONTAL 1.0 ROUTE SPECTRUM 29-MAY-13 23:44:24 OVRALL= .7070 V-DG 0.8 PK = .7051 o LOAD =4250.0) 0RPM 4006.S"RPS 66.76.E 0.6 0 0** N> 0.4 eýe 0.2 I0 __ ______. _____ ________________________

0 1 3 4 5 6 Frequency in Order ROUTE WAVEFORM 1.2! 29-MAY-13 23:44:24 PK = .6932 0.9PK(+) =1.12 0.9 :: =1.05 0.9Am~ ~ > /CRESTF= .2 0..E 0.3 Uo 0-04.3-0, i-12 Ordr: 2.019 0 60 120 180 240 300 Freq: 134.77 Time in mSecs Spec: .258 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3V #3 BEARING-PUMP VERTICAL 0 IL 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:26:18 OVRALL-- .3380 V-DG PK = .3334 LOAD =4250.0 RPM= 4014.RPS = 66.91 ROUTE WAVEFORM 20-FEB-08 23:26:18 PK = .4930 PK(+) = .9124 PK(-) =.8917 CRESTF= 2.62 0.2 0 Frequency in Order 0.6 0.4 0.2 0 0.0-0.2-0.4-0.6-0.8-1.0-1.2-1.4-1.6 T 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.018 135.00.189 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3V #3 BEARING-PUMP VERTICAL 1.0 T ROUTE SPECTRUM 22-MAY-09 13:37:48 OVRALL= .3202 V-DG 0.8 -PK = .3159 LOAD =4250.0 n0RPM= 4038..RPS 67.30 0.6 0 o> 0.4 0.0 0 0 0 3 4 5 6 Frequency in Order 0.8 ...ROUTE WAVEFORM 0.6 j 22-MAY-09 13:37:48 IPK = .3048 PK(+) = .5628 0.4 PK(-)=.6002 UII ~ iK0.2 ,,!Z Oi t'l )I-0.2 ,,I i' ' 'Ii ,, , l z~-0.04I l~-0.6-0.8 1 Ordr: 2.016 0 60 120 180 240 300 Freq: 135.70 Time in mSecs Spec: .149 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3V #3 BEARING-PUMP VERTICAL U)0 1.00.0.61 0.4 4 ROUTE SPECTRUM 18-FEB-10 16:47:00 OVRALL= .3329 V-DG PK = .3275 LOAD =4250.0 RPM= 3995.RPS= 66.59 040 C3ýCýW)0.2 0>0 0 1 2 3 Frequency in Order 4 5 6 0.8 0.6 ROUTE WAVEFORM 18-FEB-10 16:47:00 PK = .3248 PK(+) = .6867 PK(-) = .6484 CRESTF= 2.99 U (0 U 0 0.4 0.2-0.0-0.2-0.4-0.6-0.8 a 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.017 134.30.189 IST -IST, P205 HPCI @42.5k HPC$ ISTR -P3V #3 BEARING-PUMP VERTICAL 0 0 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 16-AUG-11 11:26:50 OVRALL= .2803 V-DG PK = .2735 LOAD =4250.0 RPM = 4004.RPS = 66.74 0.2 0 Frequency in Order 0.8 0.6 ROUTE WAVEFORM 16-AUG-11 11:26:50 PK = 2806 PK(+) = .5753 PK(-) = .5357 CRESTF= 2.90 U S'I, U 0 0 0.4 0.2-0.0-0.2-0.4-0.6 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.016 134.53.106 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3V #3 BEARING-PUMP VERTICAL Li ci C C U 0 0 a.1.0 0.8 0.6 0.4 ROUTE SPECTRUM 14-FEB-12 12:13:08 OVRALL= .3535 V-DG PK = .3456 LOAD =4250.0 RPM = 8000.RPS 133.33 9 0.2 0 T-0 1 2 3 4 5 6 Frequency in Order 0.8 0.6 0.4 I ROUTE WAVEFORM 14-FEB-12 12:13:08 PK = .3645 PK(+) =.6877 PK(-) = .7579 CRESTF= 2.94 U ci (0 C C Li 0 0.2-0.0-0.2-0.4-0.6-0.8-1.0 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.000 266.72.00069 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3V #3 BEARING-PUMP VERTICAL 1.0 0.8 ROUTE SPECTRUM 29-MAY-13 23:57:40 OVRALL= .3890 V-DG PK = .3826 LOAD =4250.0 RPM= 4016.RPS = 66.93 0 IL 0.6 0.4 C C U)0.2 Frequency in Order 1.0 0.8 0.6 ROUTE WAVEFORM 29-MAY-13 23:57:40 PK = .4015 PK(+) = .7720 PK(-) = .7790 CRESTF= 2.74 0 a)In C C U 0 S 0.4 0.2-0.0-0.2-0.4-0.6-0.8-1.0 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.017 135.00.178 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3A #3 BEARING-PUMP AXIAL U an U 0 a~.1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:26:56 OVRALL= .3630 V-DG PK = .3616 LOAD =4250.0 RPM= 4016.RPS = 66.93 0.2 0.1 0 0 I 3 Frequency in Order 4 5 6 0.6 0.4 ROUTE WAVEFORM 20-FEB-08 23:26:56 PK = .3669 PK(+) = .5322 PK(-) = .5835 CRESTF= 2.25 U an C 4'ci 0'I 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.017 135.00.297 iST -IST, P205 HPCI @42.5k HPCI ISTR -P4H #4 BEARING-PUMP HORIZONTAL C C)1.0 0.8 0.6 0.4 ROUTE SPECTRUM 19-AUG-09 09:48:52 OVRALL= .5812 V-DG PK = .5765 LOAD =4250.0 RPM= 4013.RPS = 66.89 0.2 0 0 2 3 4 5 6 Frequency in Order 1.2 0.9 0.6---I--"T" U 0 0.3 0 kIl IJ ROUTE WAVEFORM 19-AUG-09 09:48:52 PK = .6230 PK(+) : 1.08 PK(-) = 1.11 CRESTF= 2.52-0.3-0.6-0.9-1.2-1.5!L L 0 60 120 180 Time in mSecs 240 300 Ordr Freq: Spec: 2.018 135.00.356 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3A #3 BEARING-PUMP AXIAL 1.0 *i'a 0 IL 0.8 0.6 0.4 ROUTE SPECTRUM 18-FEB-10 16:47:30 OVRALL= .3314 V-DG PK = .3297 LOAD =4250.0 RPM = 4003.RPS 66.72 N'4 04 C..0.2 0 1~ C 0 0 o.U3 0 1 2 3 4 5 6 Frequency in Order 0.8 0.6 ROUTE WAVEFORM 18-FEB-10 16:47:30 PK = .3112 PK(+) = .5710'PK(-) = .4713 CRESTF= 2.59 0, a U)o 0>0.4 0.2-0.0-0.2-0.4-0.6 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.016 134.53.273 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3A #3 BEARING-PUMP AXIAL 1.0 ,- r I ROUTE SPECTRUM 16-AUG-11 11:27:16 OVRALL= .3416 V-DG 0.8 PK = .3377 LOAD =4250.0 RPM = 4000.0. RPS 66.67 S 0.6> 0.4 0.2 0 1 2 3 4 5 6 Frequency in Order 0.8 lROUTE WAVEFORM 0.6 16-AUG-11 11:27:16 0.6{~ , PK = .3885 0. f ! PK =.637 1 PK(-) =.7520-~U ~I, ICRESTF=2.74 0.2 h-0.0 ' t-0.6 I:-::: t__ __ __-0.6 8-41.0 Ordr: 2.018 0 60 120 180 240 300 Freq: 134.53 Time in mSecs Spec: .199 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3A #3 BEARING-PUMP AXIAL 0 IL 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 14-FEB-12 12:05:48 OVRALL= .3336 V-DG PK = .3305 LOAD =4250.0 RPM= 4012.RPS = 66.86 0.2 0 C'4 0 C4-r-0 o I~1 0 1 2 3 Frequency in Order 4 5 6 0.8 0.6 ROUTE WAVEFORM 14-FEB-12 12:05:48 PK = .3658 PK(+) = .5765 PK(-) = .5227 CRESTF= 2.23 U 0 C C a.9 S 0.4 0.2-0.0-0.2-0.4-0.6 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.016 134.77.265 IST -IST, P205 HPCI @42.5k HPCI ISTR -P3A #3 BEARING-PUMP AXIAL C)0 C U 0 0 a-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 29-MAY-13 23:58:30 OVRALL= .3125 V-DG PK = .3088 LOAD =4250.0 RPM= 4010.RPS = 66.84 0.2 Frequency in Order 0.8 0.6 ROUTE WAVEFORM 29-MAY-13 23:58:30 PK = .3379 PK(+) = .5605 PK(-) =.5920 CRESTF= 2.48 Li a C C C)0 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.016 134.77.236 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4V #4 BEARING-PUMP VERTICAL 0 IL 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:27:56 OVRALL= .1788 V-DG PK = .1627 LOAD =4250.0 RPM= 4020.RPS = 67.00 ('40 N 0.2 0 I', 0 I 3 4 5 6 Frequency in Order 0.4 0.3 ROUTE WAVEFORM 20-FEB-08 23:27:56 PK = .1840 PK(+) = .3417 PK(-) = .3448 CRESTF= 2.65 0 CD 0.2 0.1-0.0-0.1-0.2-0.3-0.4 0 60 120 180 240 Time in mSecs 300 Ordr Freq: Spec: 2.018 135.23.09045 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4V #4 BEARING-PUMP VERTICAL 1.0 --- T- ROUTE SPECTRUM 19-AUG-09 09:49:19 0.8 OVRALL= .1566 V-DG 0.8 PK = .1382 LOAD =4250.0 RPM= 4019.S 0.6 RPS 66.99 0,>~ 0.4 0.2 0.21' , '01 3 4 5 6 Frequency in Order 0.4 t ROUTE WAVEFORM 0.3 AUG-09 09:49:19 PK = .1633 0.2 I PK(-) = .3270.,, II, -.,Ii o ; I iI CRESTF= 2.83-o.0 , Jil l tl "'" 1 I"-0.2 '-0.3 -60 120 180 240 300 Freq: 135.00 Time in mSecs Spec: .07111 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4V #4 BEARING-PUMP VERTICAL ROUTE SPECTRUM 18-FEB-10 16:48:24 OVRALL= .1445 V-DG u- LOAD =4250.0* I RPM= 3999.-RPS 66.65.E 0.6 a 0> 0.4 (L tI 0.20 040 0 1 1 oj 0 1 2 3 4 5 6 Frequency in Order 0.3 1 V -ROUTE WAVEFORM 18-FEB-10 16:48:24 0.2 PK = .1493 i J1 PK(-) =.2912 I 1 CRESTF= 2.76-010 iU I o -0.1-0.2 I-0.3 _Ordr: 2.019 0 60 120 180 240 300 Freq: 134.53 Time in mSecs Spec: .07042 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4V #4 BEARING-PUMP VERTICAL 1.0 ROUTE SPECTRUM 16-AUG-11 11:28:44 OVRALL= .1722 V-DG 0.8 PK = .1610 u LOAD =4250.0 cnRPM = 4009.RPS= 66.81 C= 0.6> 0.4 a-0.2 0t 0J 0 1 2 3 4 5 6 Frequency in Order 0.4 ROUTE WAVEFORM 0.3 16-AUG-11 11:28:44 PK = .1571 PK(+) =.2789 0.23 pie ~i e~l r'i'Vi~"" ~ TCRESTF 3.16"0.4 I i Ordr 2.014 0 60 120 180 240 300 Freq: 134.53 Time in mSecs Spec: .09045 IST -IST, P205 HPCI @42.5k HPCI ISTR -P4V #4 BEARING-PUMP VERTICAL 1.0 SPECTRUM 14-FEB-12 12:07:29 OVRALL= .1774V-DG 0.8 PK = .1672 LOAD =4250.0 RPM 4012.07 6 RPS 66.86 ,- 0.6 ZT 0> 0.4 0.2 0 0 3 4 5 6 Frequency in Order 0.3 fROUTE WAVEFORM 14-FEB-12 12:07:29 PK(+) =.2614 1il l p q)I =.3138 0.2 Gil t i~ CRESTF= 2-64.0~ I Ordr: 2.019 60 120 180 240 300 Freq: 135.00 Time in mSecs Spec: .08412 MI I -15 1, E205 HPCI G P42.5k HPCI ISTR -P4V #4 BEARING-PUMP VERTICAL 0 IL 1.0 0.8 0.6 0.4 (%4 0 ("40 0.2 0 0.6 0.4 0 a U)ROUTE SPECTRUM 29-MAY-13 23:55:42 OVRALL= .2226 V-DG PK = .2175 LOAD =4250.0 RPM= 4013.RPS 66.88 ROUTE WAVEFORM 29-MAY-13 23:55:42 PK = .2147 PK(+) = .3740 PK(-) = .3920 CRESTF= 2.58 I 3 4 5 6 Frequency in Order U C C U 0 7.0.2-0.0-0.2-0.4-0.6 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 2.015 134.77.146 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7H #7 BEARING-PUMP INBOARD HORIZ 1.0 ROUTE SPECTRUM 20-FEB-08 23:28:36 OVRALL= .3077 V-DG PK = .1840 LOAD =4250.0 RPM = 2010.RPS = 33.50 0 I0 0.8 0.6 0.4 0.2 0 M R 0 4 0 I 2 3 Frequency in Order 5 6 0.8 0.6 ROUTE WAVEFORM 20-FEB-08 23:28:36 PK = .3084 PK(+) = .6591 PK(-) = .7197 CRESTF= 3.30 0 (I)C U 0 0 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.037 135.23.110 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7H #7 BEARING-PUMP INBOARD HORIZ U 0 U a S a-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 22-MAY-09 13:42:10 OVRALL= .3217 V-DG PK = .2347 LOAD =4250.0 RPM= 2035.RPS = 33.92 0.2 0 Co 0 0 U, I 4 0 I 2 3 Frequency in Order 5 6 0.8 0.6 U S U 0 S 0.4 0.2-0.0-0.2-0.4-0.6-0.8 ROUTE WAVEFORM 22-MAY-09 13:42:10 PK = .3306 PK(+) = .7041 PK(-) = .6201 CRESTF= 3.01 Ordr: 4.Freq: 13 Spec: .1 0 60 120 180 240 Time in mSecs 30(000 5.70 185 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7H #7 BEARING-PUMP INBOARD HORIZ 1.0 -[ ROUTE SPECTRUM 18-FEB-10 16:50:13 OVRADL.= .280 V-DG 0.8 PK = .1666 0LOAD =4250.0 RPM= 2000.0. RPS 33.33 E 0 0> 0.4 a. I CL 01_,_ Frequency in Order 0.8 -ROUTE WAVEFORM 0.6 118-FEB-10 16:50:13 PK = .2742 PK(+) w.6851:3 { K~kI~, ~it~ ~ II ~PK(-) = .4941 Or0.0403 0 60120180 40 00 rdq: 14.536 Time in mSecs Spec-, .101 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7H #7 BEARING-PUMP INBOARD HORIZ 1.0 ROUTE SPECTRUM 16-AUG-11 11:30:27 OVRALL= .3262 V-DG 0.8 PK = .2264 t LOAD =4250.0 RPM = 2015.--) RPS 33.58 ,E- 0.6 4 0> 0.4 a,.00 1 2 3 4 5 6 Frequency in Order 0 .a ROUTE WAVEFORM C) .6 16-AUG-11 11:30:27 PK(+) = .6791 0 j! PK(.) =.5820 III~ ICRESTF= 2.97-0.2 ! ii t !I iIt-0.6-0.8 -Ordr: 3.999 0 60 120 180 240 300 Freq: 134.30 Time in mSecs Spec: .141 HPCI ISTR -P7H #7 BEARING-PUMP INBOARD HORIZ Z 0 d)1.0 0.8 0.6 0.4 N0 ROUTE SPECTRUM 14-FEB-12 12:08:39 OVRALL= .3029 V-DG PK = .2527 LOAD =4250.0 RPM= 4015.RPS = 66.92 0.2 0 0 4 0 I 2 3 Frequency in Order 5 6 0.8 0.6 0.4 0 4)0.2-0.0-0.2-0.4-0.6-0.8 ROUTE WAVEFORM 14-FEB-12 12:08:39 PK = .3100 PK(+) = .7328 PK(-) =.6800 CRESTF= 3.34 Ordr: 4.035 Freq: 270.00 Spec: .02028 0 60 120 180 240 Time in mSecs 300 ZY -IST, P205 HPCI @42.5k HPCI ISTR -P7H #7 BEARING-PUMP INBOARD HORIZ 1.0 0.8 II ROUTE SPECTRUM 29-MAY-13 23:48:06 OVRALL= .3171 V-DG PK = .1905 LOAD =4250.0 RPM= 2000.RPS = 33.33 C C 0 0.6 0.4 0.2 04 0 Frequency in Order 0.8 0.6 0.4 ROUTE WAVEFORM 29-MAY-13 23:48:06 PK = .3328 PK(+) =.7126 PK(-) =.7636 CRESTF= 3.24 Li a'C Li a-i 0.2-0.0-0.2-0.4-0.6-0.8-1.0 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.050 135.00.142 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7V #7 BEARING-PUMP INBOARD VERTICAL 0 IL 1.0 0.8 0.6 0.4 I -I---- I 0 ROUTE SPECTRUM 20-FEB-08 23:29:12 OVRALL= .3358 V-DG PK = .0958 LOAD =4250.0 RPM = 2008.RPS 33.46 0.2 0 0 I 2 3 Frequency in Order 4' 5 6 1.0 0.8 0.6 ROUTE WAVEFORM 20-FEB-08 23:29:12 PK = .3460 PK(+) = .7884 PK(-) =.6790 CRESTF= 3.22 (3 0 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.035 135.00.06248 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7V #7 BEARING-PUMP INBOARD VERTICAL U C)CO C U 0 S 0~1.0 0.8 0.6 0.4 0.2 ROUTE SPECTRUM 22-MAY-09 13:42:44 OVRALL= .2633 V-DG PK = .1137 LOAD =4250.0 RPM 2021.RPS 33.68 04 4 C 0 0 I 2 3 Frequency in Order 4'5 6 0.8 0.6 U 0)0.4 0.2-0.0-0.2-0.4-0.6 ROUTE WAVEFORM 22-MAY-09 13:42:44 PK = .2746 PK(+) = .6146 PK(-) = .5301 CRESTF= 3.17 Ordr: 4.036 Freq: 135.94 Spec: .06214 0 60 120 180 240 Time in mSecs 300 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7V #7 BEARING-PUMP INBOARD VERTICAL 1.0 ROUTE SPECTRUM 18-FEB-10 16:50:47 OVRALL= .2231 V-DG 0.8 PK = .0992 LOAD =4250.0 ai RPM = 2000.__.6 RPS =33.33> 0.4 0.2 0 2 3 4 .5 6 Frequency in Order 0.6- --1" -ROUTE WAVEFORM 18-FEB-10 16:50:47 0.4 IPK = .2351 1 11/41 TPK(+) =.4951 0.2 PK(-) =.4685 0.2~ CRESTF= 2.98 All 11!-0.-0.2 P-0.4 II-0.6 1 ___120 180 Ordr: 4.029 60 1 Freq: 134.30 Time in mSecs Spec: .05178 IST -IST, P205 HPCI @42.5k HPCI ISTR -P7V #7 BEARING-PUMP INBOARD VERTICAL 1.0 ROUTE SPECTRUM 16-AUG-11 11:30:54 I OVRALL= .2795 V-DG 0.8 -PK = .1123 LOAD =4250.0 u) RPM= 2021.C RPS 33.69 0.6-> 0.4 Y.0.2{___r 0 2 3 4 5 6 Frequency in Order 0.8 ROUTE WAVEFORM 0.6 16-AUG-11 11:30:54 0.6 PK = .3178 0. PK(+)= 5W83 0.4 " PK(-) = .6345 02 ,InCRESTF=

2.82-0 0 ti t! "I If, , z° oiliti ll !'1 ý2i 1H1 T-01.6-0.81 _ ____ I Ordr: 4.001 0 60 120 180 240 300 Freq: 134.77 Time in mSecs Spec: .07215 IST -IST, P205 HPCI @,42.5k HPCI ISTR -P7V #7 BEARING-PUMP INBOARD VERTICAL 10 ROUTE SPECTRUM 14-FEB-12 12:09:25 OVRALL= .3021 V-DG 0.8 PK = .2831 08LOAD =4250.0 RPM= 4010.-RPS 66.84.E 0.6 0> 0.4 0.2 0-0 0 1 2 3 4 5 6 Frequency in Order 0.8 -ROUTE WAVEFORM 14-FEB-12 12:09:25 0.6 PK = .2995 PK(+) =.7006 0.4 PK(-) = .5466 CRESTF= 3.31__ 0.2 60 120 180 Ordr 4.033 ime in mScs.03 IST -iST, P205 HPCi @42.5k HPCI ISTR -P7V #7 BEARING-PUMP INBOARD VERTICAL 1.0 I 'I ROUTE SPECTRUM 29-MAY-1 3 23:48:56 OVRALL= .2415 V-DG 0.8 PK = .0939 oLOAD =4250.0 RPM= 2015.C RPS= 33.58 mc 0.6 0> 0.4 0.2 " 0 1 2 3 4' 5 6 Frequency in Order 0.8 ROUTE WAVEFORM 0.6 29-MAY-13 23:48:56 PK = .2730 PK(+) = .5069 0.4 PK(-) =.6543 o U,* IHCRESTF=

3.39 0.2 ,/I°oI+00 II ~t j'-0.4-0.6-0.8 Ordr: 4.035 0 60 120 180 240 300 Freq: 135.47 Time in mSecs Spec: .05938 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8H #8 BEARING-PUMP OUTBOARD HORIZ 0 a'C,, C C U 0 U 0.1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:29:48 OVRALL= .3723 V-DG PK = .2795 LOAD =4250.0 RPM= 2008.RPS = 33.47 ROUTE WAVEFORM 20-FEB-08 23:29:48 PK = .3936 PK(+) = .7891 PK(-) = .6403 CRESTF= 2.84 0.2 0 Frequency in Order 1.0 0.8 0.6 U U U)C U 0 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.033 135.00.210 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8H #8 BEARING-PUMP OUTBOARD HORIZ In 0.8 ROUTE SPECTRUM 22-MAY-09 13:43:17 OVRALL= .3486 V-DG PK = .2870 LOAD =4250.0 RPM= 2000.RPS = 33.33 0 Oh U 0 0.0.6 0.4 0.2 0 C4J 0ýC1 0 (0 N.-0 1 2 3 Frequency in Order 4 5 6 0.8 0.6 0.4 U Oh 0)U 0 0 0.2-0.0-0.2-0.4-0.6-0.8 ROUTE WAVEFORM 22-MAY-09 13:43:17 PK = .3632 PK(+) = .7157 PK(-) = .7145 CRESTF= 2.79 Ordr: 4.071 Freq: 135.70 Spec: .231 0 60 120 180 240 Time in mSecs 300 m I -it-f, P205 HPCI §42.5k HPCI ISTR -PSH #8 BEARING-PUMP OUTBOARD HORIZ E 0 I0 1.0 0.8 0.6 0.4 0.2 ROUTE SPECTRUM 18-FEB-10 16:51:25 OVRALL= .3697 V-DG PK = .2489 LOAD =4250.0 RPM 2001.RPS 33.36 0 1 2 3 44 5 6 Frequency in Order 1.0 0.8 0.6 ROUTE WAVEFORM 18-FEB-10 16:51:25 PK = .3776 PK(+) =.7481 PK(-) =.6597 CRESTF= 2.80 ci e-0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.033 134.53.193 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8H #8 BEARING-PUMP OUTBOARD HORIZ 1.0 0.8 ROUTE SPECTRUM 16-AUG-11 11:31:19 OVRALL= .3890 V-DG PK = .3135 LOAD =4250.0 RPM= 2007.RPS = 33.45 0 0 to C U a a-0.6 0.4 0.2 0l)0.1.6 0 I 2 3 Frequency in Order 4: 5 0.8 0.6 T.ROUTE WAVEFORM 16-AUG-11 11:31:19 PK = .3824 PK(+) = .7153 PK(-) = .6544 CRESTF= 2.65 C 0 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.036 135.00.238 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8H #8 BEARING-PUMP OUTBOARD HORIZ U 0 U)C U a 0 a-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 14-FEB-12 12:10:05 OVRALL .3940 V-DG PK = .3749 LOAD =4250.0 RPM 4015.RPS = 66.91 0.2 0 0 1 2 3 4 5 6 Frequency in Order 1.0 0.8 0.6 ROUTE WAVEFORM 14-FEB-12 12:10:05 PK = .4159 PK(+) = .7618 PK(-) = .7583 CRESTF= 2.59 C 0 0.4 0.2-0.0-0.2-0.4-0.6-0.8-1.0 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.035 270.00.03021 Po j --H a, ruN m-PUMi OUT4BoAK HPCI ISTR -P8H #8 BEARING-PUMP OUTBOARD HORIZ 72 0 IL 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 29-MAY-13 23:49:56 OVRALL= .3865 V-DG PK = .294 LOAD =4250.0 RPM 2010.RPS= 33.50 0.2 0 3 Frequency in Order 1.0 0.8 0.6 ROUTE WAVEFORM 29-MAY-13 23:49:56 PK = .3778 PK(+) = .8160 PK(-) =.6850 CRESTF= 3.05 C u 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.037 135.23.228 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8V #8 BEARING-PUMP OUTBOARD VERTICL 0 0£fl C 0 0 0 a-1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:30:22 OVRALL= .3329 V-DG PK = 1684 LOAD =4250.0 RPM 2000.RPS 33.33 0.2 ft Co 0 0 0 I 2 3 Frequency in Order 4 5 6 ROUTE WAVEFORM 20-FEB-08 23:30:22 PK = 2.26 PK(+) = 3.27 PK(-) 2.82 CRESTF= 2.04 C., 0 C, 2 0-1-2 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 4.057 135.23.09252 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8V #8 BEARING-PUMP OUTBOARD VERTICL U G)U)C U 0 a.1.0 0.8 0.6 0.4 ROUTE SPECTRUM 22-MAY-09 13:43:50 OVRALL= .3343 V-DG PK = .1720 LOAD =4250.0 RPM = 2033.RPS : 33.89 0.2 0 0 1 2 3 4 5 6 Frequency in Order 1.0 0.8 0.6 ROUTE WAVEFORM 22-MAY-09 13:43:50 PK = .3159 PK(+) =.7569 PK(-) = .6753 CRESTF= 3.39 U S U)U a'p 0.4 0.2-0.0-0.2-0.4-0.6-0.8 0 60 120 180 240 Time in mSecs 300 Ordr: Freq: Spec: 3.997 135.47.115 iST -IST, P205 HPCI @42.5k HPCI ISTR -P8V #8 BEARING-PUMP OUTBOARD VERTICL 1.0 IROUTE SPECTRUM 18-FEB-10 16:52:00 OVRALL= .3372 V-DG 0.8 PK = .1432 LOAD =4250.0.64 RPM =2000.," 06 iRPS =33.33 0.I 00 m> 0.4 0.2 R 0 1 2 3 4 5 6 Frequency in Order 0.8 1 ROUTE WAVEFORM 0.6 j18-FEB-10 16:52:00 PK(+) = .6810 0.4 !PK(-) =.5171~ f. I PK = 3.318-o4 ! ' '-0.8 Time in mSecs Spec: .08907 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8V #8 BEARING-PUMP OUTBOARD VERTICL 1.0 --ROUTE SPECTRUM 16-AUG-11 11:31:42 OVRALL= .3590 V-DG 0.8 PK =.1177 a FT LOAD =-4250.0 0) RPM 1998.-.RPS= 33.30 0.6 0 o> 0.4 0.2 o 0 1 2 3 4, 5 6 Frequency in Order 1.0 T ROUTE WAVEFORM 0.8 16-AUG-11 11:31:42 PK = .3702 0.6 I PK(+) = .7366 04 CRESTF= 2.81 0 pi l oo I t I 0-0.61 J-0.8 _ _ _ --4 ~ ~ ~ ~ ~ _______________

____Ordr: 4.033 0 60 120 180 240 300 Freq: 134.30 Time In mSecs Spec: .04833 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8V #8 BEARING-PUMP OUTBOARD VERTICL 1.0 --- -- ROUTE SPECTRUM 14-FEB-12 12:10:44 OVRALL= .3749 V-DG 0.8 PK = .3536 LOAD =4250.0 en RPM = 4003.RPS = 66.72 72 0.6 0> 0.4 a. o 0.2 01 0 1 2 3 4 5 6 Frequency in Order 0.8 ROUTE WAVEFORM 0.6 14-FEB-12 12:10:44 I.6PK = .3757 PK(+) = .6673 0.4 PK(-) = .6986 C llI Iit n. i ,Id-0.01' ii-0.2 .-0.4 1-0.6 Ordr: 4.039 0 60 120 180 240 300 Freq: 269.53 Time in mSecs Spec: .02140 HPCI ISTR -P8V #- BEARING-PUMP OUTBOARD VERTICL 1.0 ' IROUTE SPECTRUM 29-MAY-13 23:50:40 OVRALL= .3535 V-DG 0.8 PK = .1717 LOAD =4250.0 RPM =2027.RPS = 33.78 0.6 0> 0.4 C.0.2 0 1 2 23 4 5 6 Frequency in Order 1.0 -ROUTE WAVEFORM 0.8 29-MAY-13 23:50:40 PK = .3735 0.6 PK(+) = .7949 T PK(-) = .6409 0.4 CRESTF= 3.01 0.2-0).0 0-0.2 REF.-0.4 I-0.6 i"0.8, Ordr 4.003 60 120 180 240 300 Freq: 135.23 Time in mSecs Spec: .105 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8A #8 BEARING-PUMP OUTBOARD AXIAL.23'I 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 20-FEB-08 23:31:02 OVRALL= .1597 V-DG PK = .1374 LOAD =4250.0 RPM= 2028.RPS = 33.79 0.2 C4D 0 0i 0 0 I 2 3 Frequency in Order 4 5 6 0.4 0.3 0 0.2 0.1-0.0-0.1-0.2-0.3 ROUTE WAVEFORM 20-FEB-08 23:31:02 PK = .1466 PK(+) = .2866 PK(-) =.2969 CRESTF= 2.86 Ordr: 3,999 Freq: 135.14 Spec: .01456 0 60 120 180 240 Time in mSecs 300 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8A #8 BEARING-PUMP OUTBOARD AXIAL 1.0 ROUTE SPECTRUM 22-MAY-09 13:44:39 OVRALL= .1612 V-DG PK = .1425 o LOAD =4250.0 RPM= 2035.RPS= 33.92 0.6 CL 0.S0 .4 0.2 oI_ __ __ __ __ __ _ I 0 1 2 3 4 5 6 Frequency in Order 0.5 -_ __ -, ROUTE WAVEFORM 0.4 122-MAY-09 13:44:39 0 I PK = .1716 0.3 PK(+) = .3552 PK(-) = .3608 0.2 ,t4CRESTF=

2-97 0.1 -0.4 .Ordr: 4.003 o 60 120 180 240 300 Freq: 135.77 Time in mSecs Spec: .01681 IST -IST, P205 HPCI @42.5k HPCI ISTR -PBA #8 BEARING-PUMP OUTBOARD AXIAL 1.0 -0.8 0.6 1 ROUTE SPECTRUM 18-FEB-10 16:52:40 OVRALL= .1554 V-DG PK = .1331 LOAD =4250.0 RPM 2015.RPS : 33.58 0 0.4 0.2 0 04-p 0 1 2 3 Frequency in Order 4 5 6 0.6 0.4-1-- --1 1 ....... ... .=ROUTE WAVEFORM 18-FEB-10 16:52:40 PK = .1642 PK(+) = .3772 PK(-) = .3696 CRESTF= 3.25 C.5 0.2-0.0-0.2-0.4-0.6 ii I.... ----- -------_ _ ~ J ._ _ ....... .0 60 120 180 240 300 Ordr: Freq: Spec: 3.999 134.30.01976 Time in mSecs IST -IST, P205 HPCI @42.5k 1.0__HPCI ISTR -P8A #8 BEARING-PUMP OUTBOARD AXIAL 1.0 I ROUTE SPECTRUM 16-AUG-11 11:32:06 OVRALL= .1639 V-DG 0.8 PK = .1422 0LOAD =4250.0 RPM = 2021.RPS = 33.68 0.6 +Z,~0 a> 0.4 0.2 4o V-0 1 2 3 5 6 Frequency in Order 0.4 -ROUTE WAVEFORM 0.3 16-AUG-11 11:32:06 PK = .1554 0.2 PK(-) = .3107 i~ I +CRESTF= 2.85"0.1-0.3-0.4 __ _ _ __ ___Ordr: 4.001 0 60 120 180 240 300 Freq: 134.77 Time in mSecs Spec: .01467 IST -IST, P205 HPCI @42.5k HPCI ISTR -P8A #8 BEARING-PUMP OUTBOARD AXIAL 9L 1.0 0.8 0.6 0.4 ROUTE SPECTRUM 29-APR-12 03:01:11 OVRALL= .1631 V-DG PK = .1407 LOAD =4250.0 RPM 2000.RPS 33.33 0.2 0 N A 0 I 2 3 Frequency in Order 4 5 6 0.6 0.4 U a, C U 0 0.2-0.0-0.2-0.4-0.6 ROUTE WAVEFORM 29-APR-12 03:01:11 PK = .1779 PK(+) = .3815 PK(-) = .3967 CRESTF= 3.15 Ordr: 4.001 Freq: 133.36 Spec: .00712 0 60 120 180 240 Time in mSecs 300