Change 0 to Procedure CP/O/B/8100/13, Chemistry Procedure for Determination of Copper - Furnace Aa

ML20080P535
Person / Time
Site:	Catawba
Issue date:	11/14/1983
From:	Cox J, Evans L, Painter R DUKE POWER CO.
To:
Shared Package
ML20080P419	List: ML20080P417 ML20080P421 ML20080P430 ML20080P443 ML20080P446 ML20080P449 ML20080P452 ML20080P460 ML20080P466 ML20080P469 ML20080P485 ML20080P488 ML20080P498 ML20080P505 ML20080P518 ML20080P526 ML20080P531 ML20080P535 ML20080P547 ML20080P549 ML20080P554 ML20080P561 ML20080P569 ML20080P575 ML20080P578 ML20080P586 ML20080P590 ML20080P598 ML20080P602 ML20080P605
References
CP-O-B-8100-13, NUDOCS 8402220575
Download: ML20080P535 (9)
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Form 34731 (10-81)

(Formerly SPD 1002-1)

DUKE POWER COMPANY (1) ID No: CP/0/B/8100/13 PROCEDURE PREPARATION Change (s) o to PROCESS RECORD 0 Incorporated (2) STATION: Catawba (3) PROCEDURE TITLE: Chemistry Procedure for the Determination of Copper -

Furance AA (4) PREPARED BY: (( DATE: / /!/V/f3 (5) REVIEWED BY: YM bo+ b DATE: // /4/ - /3 Cross-Disciplinary Review By: kR)

(6) TEMPORARY APPROVAL (IF NECESSARY):

By: (SRO) Date:

By: Date:

(7) APPROVED BY: V. Date: J/hY!O ,

( / e (8) MISCELLANEOUS: (}

Reviewed / Approved By: Date:

Reviewed / Approved By: Date:

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MASTER FILE l

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8402220575 840215 PDR ADOCK 05000413 PDR E

Form 34634 (4 8U SPD 10012 DUKE POWER COMPANY NUCLEAR SAFETY EVALUATION CHECK LIST (1) STATION: catawba UNIT: 1 2 3 OTHER: Shared (2) CHECK LIST APPLICABLE TO: CP/0/B/8100/13 (3) SAFETY EVALUATION - PART A The item to which this evaluation is applicable represents:

Yes No -

A change to the station or procedures as described in the FSA or a test or experiment not described in the FSAR?

If the answer to the above is "Yes", attach a detailed description of the item being evaluated and an identification of the affected section(s) of the FSAR.

(4) SAFETY EVALUATION - PART B Yes No Will this item require a change to the station Technical 0pecifications?

If the answer to the above is "Yes," identify the specification (s) affected and/or attach the applicable pages(s) with the change (s) indicated.

(5) SAFETY EVALUATION - PART C As a result of the item to which this evaluation is applicable:

/

Yes No Will the probability of an accident previously evaluated in the FSAR be increased?

Yes No - Will the consequences of an accident previously evaluated in the FSAR be increased?

Yes No '

May the possibility of an accident which is different than any already evaluated in the FSAR be created?

l Yes No , Will the probability of a malfunction of equipment i

important to safety previously evaluated in the FSAR l be increased?

Yes No /' Will the consequences of a malfunction of equipment important to safety previously evaluated in the FSAR be increased?

Yes No / May the possibility of malfunction of equipment i important to safety different than any already evaluated in the FSAR be created?

Yes No - Will the margin of rafety as defined in the bases to any Technical Specification be reduced?

If the answer to any of the preceding is "Yes", an unreviewed safety question is involved. Justify the conclusion that an unreviewed safety question is or is not invo ved. Attach additional pages as necessary.

(6) PREPARED BY: 4h v DATE: // / M.R7 (7) REVIEWED BY: 6w DA'IE: /h/%78 (8) Page 1 of /

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Form 18855 (3-80)

DUKE POWER COMPANY ALARA EVALUATION CHECKLIST (1) Station cor.ch. Unit: 1 2 3 Other: Shared (2) Checklist Applicable to: CP/0/B/8100/13 (3) ALARA Evaluation Check those items below which were considered applicable during the preparation and review of this document.

Flushing and dre.ining were used to minimize source - strength and con-tamination levels prior to performing an operation.

Permanent and/or movable shielding was specified for reduction of levels.

Use of permanent or temporary local exhaust ventilation systems was used for control of airborne contamination.

Operation was designed to be completed with the least practicable time spent in the radiation field.

Appropriate tools and equipment were specified for the operation to be performed.

The operation was designed considering the minimum number of people necessary for safe job completion.

Remote handling equipment and other special tools were specified to reduce external dose.

( _ Contamination - control techniques were specified.

l The operation was designed to be conducted in areas of as low an i exposure as practicable.

Additional ALARA considerations were:

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l L/ ALARA Principles were not considered since the procedure did not involve work in a radiation area.

l (5) Prepared by: / Date >//N/@

(6) Reviewed by: A Date // -/F-/ 7 l

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CP/0/B/8100/13 DUKE POWER COMPAhT CATAWBA NUCLEAR STATION CHEMISTRY PROCEDURE FOR THE DETERMINATION OF COPPER - FURNACE AA 1.0 DISCUSSION 1.1 Scope This procedure describes the determination of copper by furnace atomic absorption spectroscopy.

1.2 Principle Refer to CP/0/B/8100/41.

1.3 Precision and Interferences 1.3.1 The precision and accuracy of this procedure will be determined by Quality Control Cha,rt data.

1.3.2 This procedure is applicable for copper concentrations in the range of approximataly 0.5 ppb to 40 ppb. Samples of higher concentration should be diluted into this range with cation polished water or Super-Q water.

1.4 Limits and Precautions d

1.4.1 The limits and precautions given in CP/0/B/8100/41 should be followed.

1.4.2 Every effort should be made to minimize contamination when analyzing metals in the ppb range.

1.4.3 All volumetric flasks, pipet tips, and sample cups should be stored in ~ 10* HNO: and rinsed thoroughly with cation-polished water or Super-Q water immediately prior to use.

2.0 APPARATUS 2.1 Perkin-Elmer Model 4000 Atomic Absorption Spectrophotometer with HGA 500 Furnace and AS-40 Autosampler 2.2 Copper hollow cathode lamp 2.3 Nalgene volumetric flasks 2.4 Eppendorf pipets

CP/0/B/8100/13 Page 2 of 6 ,

. ~2. 5 Sample cups for autosampler 2.6 Argon

• 3.0 REAGENTS 3.1 Copper Stock Solution (1000 ppm Cu) ,

3.1.1 1000 ppm Copper Reference Standard Solution (e.g. Fisher Atomic Absorption Reference Standard Solution)

Alternately, a 1000 ppm copper stock solution can be prepared by adding 2.5119 1 0.0010 grams of oven dried

(~ l hr. @ ~ 105'C). cupric sulfate (CuSO.) plus 2 ml of concentrated nitric acid (HNO3 ) to a 1000 ml volumetric flask and diluting to volume with cation polished water or Super-Q water.

3.2 Copper Standard Solution 3.2.1 10 ppm Copper Pipet 1 ml of the 1000 ppm Cu stock solution (Section 3.1) into a 100 m1, acid washed, nalgene volumetric flask. Add 0.2 al of concentrated nitric acid (EN0s). Dilute to volume with cation-polished water or Super-Q water. This standard should be prepared weekly.

3.2.2 20 ppb Copper Pipet 200 microliters of 10 ppm Cu standard solution into a 100 m1, acid washed, nalgene volumetric flask. Add 0.2 al of concentrated nitric acid (HN02 ). Dilute to volume with cation-polished water or Super-Q water. This sample should be prepared daily.

3.2.3 5 ppb Copper Pipet 50 microliters of 10 ppm Cu standard solution into a 100 m1, acid washed., nalgene volumetric flask. Add 0.2 ml of concentrated nitric acid (RN0s). Dilute to volume with cation polished water or Super-Q water. This standard should be prepared daily.

3.3 Cation-Polished Water and Super-Q Water Cation polished water and Super-Q water should have a resistence in excess of 13 mogohms.

4.0 PR02EDURE 4.1 Sample Collection

CP/0/B/8100/13 Pago 3 of 6 4.1.1 Samples should be collected in nalgene bottles which have l been stored filled with - 10% HNO3 . The sample bottles l must be rinsed thoroughly with cation polished water or Super-Q water. Also, immediately upon returning to the lab, add enough concentrated nitric acid (HNO3 ) to make the final sample ~ 0.2% HNO: (e.g. 1 m) HNO in a 500 m1 sample bottle). Shake the sample.

4.1.2 The sample should be analyzed as soon as possible after collection but within 6 hcurs.

4.1.3 The sample should be shaken well immediately prior to pouring it into the sample cup.

4.2 Instrument Setup 4.2.1 Spectrophotometer l

Turn on instrument and optomize lamp alignment per  :

Section 4.1 of CP/0/B/8100/41. The correct wavelength )

for copper is 324.7 nm and the correct slit setting is 0.7 nm.

4.2.2 Autosampler 4.2.2.1 Press "3TANDBY" to take the autosampler out of the standby mode.

4.2.3 Furnace 4.2.3.1 Press " STANDBY" to take the furnace out of standby.

4.2.3.2 Press "130" and " TEMP".

4.2.3.3 Press "6" and " RAMP TIME".

4.2.3.4 Press "20" and " HOLD TIME".

4.2.3.5 Press " STEP" to advance to Step 2.

l 4.2.3.6 Press "900" and " TEMP".

i 4.2.3.7 Press "10" and " RAMP TIME".

4.2.3.8 Press "20" and " HOLD TIME".

4.2.3.9 Press " STEP" to advance to Step 3.

4.2.3.10 Press "2250" and " TEMP".

4.2.3.11 Press "0" and " RAMP TIME".

4.2.3.12 Press "5" and " HOLD TIME".

4.2.3.13 Press "-5" and "RE0".

. o CP/0/B/8100/13 Page 4 of 6

. 4.2.3.14 Press "-1" and " READ".

4.2.3.15 Press "50" and " INT FLOV".

4.2.3.16 Press " STEP" to advance to Step 4.

4.2.3.17 Press "2600" and " TEMP". _

4.2.3.18 Press "1" and " RAMP TIME".

4.2.3.19 Press "2" and " HOLD TIME".

4.2.3.20 If you wish to check your entries, press " CHECK".

Then pr,ess the appropriate step number and " STEP".

Then press the key for the parameter you wish to check.

EXAMPLE: If you wish to check the entry you made for ramp time on Step 2, press

" CHECK", "2", " STEP", and " RAMP TIME".

To exit the check mode, press " CHECK". Then press "1", " STEP" to return to Step 1.

4.2.4 Ensure that a standard graphite tube is in the furnace.

See CP/0/B/8100/41, Section 4.3, NOTE.

4.2.5 Optical Temperature Sensor Optomize the Optical Temperature Sensor per Section 4.5 of CP/0/B/8100/41. The atomization temperature is 2250'C.

This must be done for cach element.

4.2.6 Graphite Tube Ensure that the graphite tube is free of any residual copper by performing Section 4.4 of CP/0/B/8100/41.

4.3 Sensitivity Check 4.3.1 Fill an acid washed, thoroughly rinsed sample cup with cation polished or Super-Q water and place it in the AZ slot on the sample tray.

4.3.2 Pour a portion of 20 ppb Cu standard solution into an acid washed, thoroughly rinsed, sample cup and place it in the number 1 slot on the tray.

4.3.3 On the Autosampler controller:

4.3.3.1 Press "60" and " SAMPLE VOLUME".

4.3.3.2 Press "1" and "LAST SAMPLE".

4.3.3.3 Press " RESET" and allow the tray to reset.

4.3.3.4 Press " START /STOP".

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s CP/0/B/8100/13 Page 5 of 6

. 4.3.4 At the end of the atomization cycle, for the 20 ppb ste.ndard observe the strip chart recorder. If the absorbence is not 1st least 0.20 absorbence units (20 small chart divisions), stop the analysis. Review Sections 4.2 and 4.3 and/or call the responsible Chemistry Supervisor.

4.4 Quality Control Chart Data and Sample Analysis ,

4.4.1 Load the sample tray es follows:

Position Standard / Sample AZ 0.2% HNO as used to make standards

'l S1 20 ppb Cu standard solution 1 5 ppb Cu standard solution 2 5 ppb Cu standard solution 3+ Samples (3 cups for each sample) 4.4.2 Press " RESET" on the Autosampler controller.

4.4.3 Press "AZ" on the spectrophotometer.

4.4.4 Press " MANUAL" on the Autosampler controller and allow the Autosampler to sample the AZ position twice. Then press

" MANUAL" again to stop sampling.

4.4.5 On the spectrophotometer:

4 4.4.5.1 Press " CONC" and " PEAK HEIGHT".

4.4.5.2 Press "20.0" and "SI" 4.4.5.3 Press "5" and "t" -

4.4.6 On the Autosampler Controller:

4.4.6.1 Press the number corresponding to the last sample and press "LAST SA'!PLE".

4.4.6.2 Press "1" and "# STDS".

4.4.7 Press "AZ" on the spectrophotometer.

4.4.8 If the recorder is being used, press " REC MAN", re-sero the recorder (to 10 chart divisions) and press " REC MAN" again.

4.4.9 On the Autosampler controller, press " START /STOP" to initiate the analyses.

NOTE: If the analysis has to be repeated, press "AES", " CONT", and "AZ". Then repeat

, Steps 4.4.2, 4.4.5, 4.4.7, 4.4.8 and 4. .9.

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CP/0/B/8100/13 Page 6 of 6 e

4.4.10 Read and record the results from tne display en the spectrophotometer. The results from samples 1 and 2 will be the Quality Control Chart data. Two of the three results for each sample must agree with each other within the limits of the current Quality Control Charts.

4.4.11 If the results are higher than the upp,er limit of the linear range given in 1.3.2, dilute with cation polished or Super-Q water and multiply the results by the dilution factor. If the results are less than the lower limit in 1.3.2, report the results as less than that number.

4.4.12 This analysis is subject to environmental contamination within the lab. If the results of this analysis are higher than expected, repeat the analysis using the same sample from the original sample bottle but loading it into a different sample cup.

5.0 REFERENCES

, 5.1 Perkin-Elmer Model 4000 Atomic Absorption Spectrophotometer Operator's Manual 5.2 Perkin-Elmer AS-40 Autosampler Operator's Manual 5.3 Perkin-Elmer HGA-500 Graphite Furnace Operator's Manual 5.4 Perkin-Elmer Analytical Methods for Graphite Furnace A.A.S.

6.0 ENCLOSURES None l i... mm. -

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