ML20106B533

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Forwards Investigation Into Sources of Chloride in Fort St Vrain Primary Circuit. Rept Re Investigations of Effects of Chlorides on Major Components in Primary Circuit Will Be Sent by 850228
ML20106B533
Person / Time
Site: Fort Saint Vrain Xcel Energy icon.png
Issue date: 01/31/1985
From: Warembourg D
PUBLIC SERVICE CO. OF COLORADO
To: Johnson E, Johnson E
NRC OFFICE OF INSPECTION & ENFORCEMENT (IE REGION IV)
References
P-85036, TAC-55294, TAC-57248, NUDOCS 8502110665
Download: ML20106B533 (23)


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t Public Service Company @OcHoImde  ;

i January 31, 1985 Fort St. Vrain Unit No. 1 P-85036 Regional Administrator @ @ {2 0W2 %' t

. Region IV Nuclear Regulatory Commission FEB - i ig5 f 611 Ryan Plaza Drive, Suite 1000 .

Attention: Mr. E. H. Johnson .l-wh Docket No. 50-267

SUBJECT:

Chloride Source Report

REFERENCES:

1) NRC Letter, R. D. Martin to 0. R. Lee, 1/17/85
2) PSC Letter, O. R. Lee to E. H. Johnson, 1/28/85 (P-85030)

Dear Mr. Johnson:

Please find attached our report "An Investigation into the Sources of Chloride in the Fort St. Vrain Primary Circuit." As we indicated in our January 15, 1985 meeting, we are also preparing a report regarding our investigations of the effects of chlorides on major-components in the primary circuit. This report will be sent to you on or before February 28, 1985.

If you have any questions, please call Mr. M. H. Holmes at (303) 571-8409.

i Very truly yours, 0 rY. J'Ywd D. W. Warembourg (/

Manager, Nuclear Engineering Division DW/ MEN /ksc Attachment hc)O 5 g O R IGrl d 8502110665 850131 gDRADOCK 05000267 PDR f0 D L l h

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l AN INVESTIGATION INTO THE SOURCES OF CHLORIDE IN THE FORT ST. VRAIN PRIMARY CIRCUIT 1.0

SUMMARY

AND CONC 1USION The discovery of chloride stress corrosion of a Fort St. Vrain (FSV) CRD cable prompted an investigation into the possible sources of the chloride. The total chlorine (Cl) in the primary c?rcuit is speculated to be 100 g, not including possible higher amounts in crevice areas. Samples of virtually all materials of construction in the primary circuit were screened for possible release of chloride either by water leaching or by heatup. It was found that almost all materials tested leached chloride, presumably as salt, with PCRV concrete leaching the most. In heatup tests, fuel rods were found to release hcl gas when heated to 1740 F. Subsequent long term heating of the fuel rods caused no further release of hcl. The total amount of hcl released from the core 1 fuel into the primary circuit was about 90 gm. The following is a list of major conclusions of this investigation:

1. Chloride on the CRD cable and on the bolt is more concentrated than found on other primary coolant surfaces.

This suggests concentration of Cl in crevices or stagnant areas.

2. The water ingressed into FSV is not a source of chlorine, except for possible leaching that it causes.
3. The fuel releases hcl gas during startup, under dry conditions there is no continuous release, under wet conditions at operating temperature the fuel may release small amounts of hcl.
4. Core graphite (H-327) and side reflector graphite (HLM) are not major sources under dry or wet conditions.
5. The titanium (Ti) sponge is not a major source of chlorine. It is possibly a minor transient source during initial heatup, which possibly contaminated the CRDs above the shield plug.
6. Leaching of concrete and/or thermal insulation is not ruled out, however, leaching would yield chlorine as salt, which is non volatile, and therefore may not readily circulate. Circulation of small amounts of salt particulates entrained in the helium is, of course, possible.
7. Multiple sources are quite probable.

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2.0 Introduction Control rod cables and some circulator bolts have experienced stress corrosion cracking accelerated by chloride. The chlorine content of the cable in the cracked region is 138 pg/gm wire.

Chlorine on'the C2102 bolt was 1 mg. These values equate to 10 and 14 pgm C1/cm 2 for wire and bolt respectively. These concentrations of chlorine are higher than that found on the circulator inlet duct about 2 pgm/cm 2or on plateout probe diffusion-tubes which were about 1 pgm C1/cm 2

. This suggests that-the chloride concentrates on surfaces with cracks or crevices like the cable or the bolts, relative to smooth or well swept surfaces. Extrapolating 1 to 2 pgm C1/cm 2 to all metallic surface, 7 x 107 cm yields a total burden of 50 to 200 gm. The 2

total could be greater due to the possible concentration in crevices or stagnant areas.

Tests were conducted to determine the most likely source or sources of chloride in the reactor. Materials of construction within the PCRV were tested for potential chlorine content or release. These include FSV water, concrete,.Ti sponge, fuel,

-graphite, and ceramic insulation. The release of chlorine.can potentially. occur from these materials during intitial heatup, and later via hydrolysis reactions during water ingress, or in the case of Kaowool and concrete, by water leaching. Large ingress would cause condensation of water on the relatively cool penetration walls, subsequently' causing chlorine containing rain onto the control rod cables. Evaporation of water from the cables would concentrate chlorine thereon. Table 1 lists the important potential sources. Notice that there are two potential' species, hcl gas which would be easily transported around the-circuit and salt which would be less easily transported. The hcl gas, therefore, may be responsible for C1 contamination on virtually all swept surfaces while leaching of' salt would result in high local concentrations, particularly in the bottom plenum or other areas where water would accumulate.

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TABLE 1 SOURCES OF CHLORINE IN THE PRIMARY CIRCUIT Species Source Released . Transport Mechanism Fuel rods hcl Heatup and hydrolysis of metal chloride H-327/H-451 graphite hcl Heatup and hydrolysis of metal chloride PGX/HLM graphite hcl Heatup and hydrolysis of metal chloride Ti sponge hcl Heatup and hydrolysis of metal chloride Ceramic insulation Salt Water leaching due to condensation on (Kaowool, masrock, PCRV liner etc.)

Concrete Salt Water leaching of core support floor Water Salt Direct ingress with water. leaks 8

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-3.0 EXPERIMENTAL 3.1 Phase I - Screening The work is in two phases. In phase I all materials were screened by leaching in boiling water to determine which material.is a likely source. In addition, the water sources at FSV were tested to determine the chlorine content. Table 2 lists the various water sources at FSV and their chlorine content.

In Table 2, all of the water sources, systems 21, 22, 31, 46, and 47, are low in chlorine, i.e., chlorine is in the ppb range. System 23, however, is water removed from the.

primary circuit which contains a few ppm to 400 ppm chlorine. In other words, water enters the primary circuit free of chlorine and comes out contaminated with chlorine. Clearly, there is a source of chlorine within the PCRV.

Table 3 lists the screening tests on the potential sources within the PCRV. The results in Table 3 show that the PCRV concrete is by far the largest source of chlorine in the system. How the chlorine in the concrete.would get in the primary circuit is not clear, however. Presumably, during shutdown, some water in the support floor concrete could leak into the PCRV through the cracked liner and carry with it salts leached from the concrete. Obviously, this source would be difficult t: quanti fy.

The other sources, all have low ppm levels of chlorine but because they have large total masses, the total chlorine can be'significant. For example, the HLM graphite, total weight approximately 7 x 105 lbs, could contain almost a kilogram of leachable chlorine, whereas the fuel rods have only up to 230 g leachable. These figures do not tell the whole story, for all of these materials have a residual chlorine content that is not easily leached. The residual chlorine ranges from 10 to 100 ppm in the graphite and kaowool, up to 1000 ppm in the i

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c TABLE 2 ANALYSIS OF WATER SYSTEMS AT FSV(*}

No. System ppm Chlorine 21 Circulator bearing water <0.025 22 Main steam <0.020 to 0.193 31 Feedwater <0.020 to 0.090 46 Liner cooling <0.020 to 0.090 47- Purification system cooling 0.088 to 0.470 23 Drier regeneration 3.8 to 4.0 23 HPS front end knockout pot 3.8 to 400 (a)All data supplied by PSCo Chemistry. The system

23. values may be high because of C1 contamination in the sample storage drums.

TABLE 3 RESULTS OF WATER LEACHING (a) 0F PRIMARY CIRCUIT MATERIALS Total Leachable Mass In Chlorine in Chlorine Sodium Reactor Reactor (d)

Material (ppm) (ppm) (kg) (g)

Fuel rods 9 27,000 230 H-327 graphite <1 1.0 220,000 <220 H-451 graphite <1 <0.2 21,000 <21 PGX-112 graphite <1 '0.3 50,000 <50 PGX-138 graphite <1 0.5 50,000 <50 HLM graphite 2.1 0.2 320,000 627 6

PCRVconcrete(b) 160 1.8 >10 n1,000 (floor)

Kaowool 10 to 44(c) 27,000 270 to 1,200(c)

Masrock ~23 5,000 100 Quartz et silice 9 400 4 Ti sponge 44 10 95 4 (fresh)

(a) Boiling crushed materials 2 hours2.314815e-5 days <br />5.555556e-4 hours <br />3.306878e-6 weeks <br />7.61e-7 months <br /> in deionized water.

(b)The concrete also had 325 ppm sulfate and other ions including nitrate, formate end acetate.

(c)The specification on leachable C1 in Kaowool is 10 ppm one

" archive" sample leached as much as 44 ppm, this value is probably not representative of that in the reactor.

(d) Error bands or uncertainties have not been applied to these values because they are based on leaching single samples. Obviously, the uncertainty would be large, perhaps factor 6 of 2+.4.

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Ti sponge and concrete. _. The fuel rods contain in the range 1 to 20 ppm chlorine. Some of the residual chlorine may be released as hcl gas during heatup or hydrolysis at elevated temperatures. -Tests to determine the amounts and sources of the' gaseous form are discussed in the phase II work.

3.2 Phase 2 Heatup/ Hydrolysis Results Phase 2 work involves heating candidate materials to their reactor operating temperature in flowing dry and wet helium. The apparatus and test method are shown in

. Appendix A. The dry helium step would remove volatile chlorine (or hcl) and simulates a normal heatup in the reactor. The wet' helium step may cause hydrolysis of metal chlorides creating hcl gas by the reaction.

H2 O + MCl 2 = 2 HCit + MO where M = Fe, Mg, etc.

3.2.1 Ti sponge Titanium sponge was felt to be a likely source because the control rod drive penetrations are purged with purified helium which comes directly from the Ti beds. Furthermore, the manufacture of Ti sponge involves the reduction of TiCl. by Mg metal._ The final product can contain up to several thousand ppm of chlorine as MgC1. 2 The MgC12 .is subject to hydrolysis via the'above chemical reaction, however, it is difficult to create a scenario whereby moisture contacts the sponge while at operating temperature. One possible sequence would be the following.

Following icing in the LTA exchanger, the system is regenerated by purging the LTA backwards into the waste gas system. If the LTA is not completely dried out prior to establishment of normal flow and further, and if the Ti bed is still hot, then some water could contact the sponge while it is in operation. The results of the phase 2 tests on the sponge are shown in Table 4.

Table 4 shows that during initial heatup of the Ti sponge about 0.6 to 3 g of chlorine (tests 1 and 5) 4 could have been released from the 210 lb. getter bed at FSV. Upon longer heating times, the amount released would trickle down to approximately 0.0005 g/hr (average of tests 2 and 7) or in fact to zero (based on the FSV sponge tests). _If the sponge were subjected to water vapor, the rate of chlorine release could be about 0.01 g/hr (test 4) or-virtually zero (test 12 on FSV sponge). It is

TABLE 4 '

RESULTS OF PHASE 2 TESTS ON TI SPONGE (Temperature All Tests - 7000F)

FSV FSV

, Initial Continuous Test Weight Time Chlorine Heatup Release No. Material (g) Hours Gas (a) (p g) pg/hr (g) (g/hr) i Blank Empty tube 17 He 21 1.2 1 Fresh Ti sponge 80.0 5.5 He 2698 3.2 2 Fresh Ti sponge 80.0 63.5 He 99 1.5 0.0004 3 Fresh Ti sponge 80.0 6 He/ 138 23 0.025 HO 2

4 Fresh Ti sponge 80.0 18.5 He/ 157 8.5 0.009 HO 2

5 Fresh Ti sponge 78.6 2 He/H2 (8) 497 0.6 6 Fresh Ti sponge 78.6 17.5 He/H2 57 3 0.002 7 Fresh Ti sponge 78.6 24.5 He/H2 41 1.7 0.0006 8 'used FSV sponge 46.8 3.75 He/H2 41 10.9 0.02 9 Used FSV sponge 46.8 67.25 He/H2 44 0.65(b) 0 10 Used FSV sponge 46.8 46.25 He/H2 36 0.78(b) 0 12 Used FSV sponge 46.8 72.5 He/H2 / 32.8 0.45(b) 0 HO 2

(a)In Run 5 the gas was changed from pure He or helium containing 25,000 ppm water vapor to a mix-ture of He and 1000 ppm H2 or He/100 ppm H2 /25,000 ppm H2 0. The addition of H2 was thought to simulate H2 in the reactor and to maximize the production of hcl gas.

(b)Less than background run No. 1.

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concluded thai initial heatup.of the sponge can release a few-grams of chlorine (probably less than 3 g)-but:proglonged heating and/or exposure to moisture has little effect on chlorine release.

Furthermore, while short exposures'to water. vapor may- be possible, it is difficult to imagine a long term exposure of the sponge to water vapor. It may be concluded that the Ti sponge is not the major source of chlorine in the primary circuit.

3.2.2- Graphite HLM graphite and H-327 graphite were coarsely crushed and-subjected to'heatup in dry helium followed by wet helium. The HLM was heated to 1300 F, simulating the side reflector- temperature while the H-327 was heated to 1800*,'the fuel element temperature. .The_.results are shown in Table 5.

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} RESULTS OF HEATUP AND HYDROLYSIS OF GRAPHITE i

Chlorine Released l Wei ht Tgmp Time Total

, Test No. Sample (g Gas ( F) (Hr) (pg) g/ core (a) Cgber 4 HLM 66.8 He/H 2 1300 24 34 ND I

5 HLM 66.8 H3/H2/H2O 1300 24 - 29 ND 4 6 H-327 145.0 He/H 2 1800 3 40 ND

(a)g hcl released from entire FSV core inventory after furnace blank of
40 ugm subtracted.

ND = not detected or hcl less than blank.

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'These results show that graphite does not release gaseous chlorine or hcl upon heatup or exposure to water vapor.

3.2.3 Fuel Rods It was surmised that fuel rods could be a sourca of chlorine for the following reasons. During fuel manufacturing, particles are coated with sic by thermal decomposition of methyl trichlorosilane,

.which results in some residual chlorine in the fuel particles. In addition, fuel rods are leached with hcl gas after the hot press and carbonizaticn-steps to remove trapped or uncoated uranium and thorium.

The hcl leaching is accomplished during the final

, high temperature anneal step at 2900 to 3300 F, which effectively removes most.of the hcl from the rod. Some residual chlorine remains, however, typically in the low ppm range.

At GA Technologies, as.part of fuel production, QA testing, and qualification, finished fuel rods are routinely heated in the high temperature mass spectrometer to measure the chlorine vapor pressure above the rod, and therefore the potential for chlorine release into the primary circuit. When rods are heated up in vacuum in the lab apparatus they invariably release about 1 to 50 pg of hcl gas per rod at around 1000 CF (This is from 0.1 to 5 ppm in the rods).

Since the rods were annealed at up to 3300 F during the hcl leach step the release of hcl gas during the modest heatup in the. mass spectrometer was puzzling. It was concluded that either the leach /high fire process contaminated the rods or that the hcl gas was formed during storage in air-due to hydrolysis of metal chlorides. Furthermore, if the'latter occurred it was expected that hydrolysis in the reactor should also occur during normal operation where a few ppm moisture is available or during shutdowns where large amounts of water are present.

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  • i l TABLE 6 i

SUPMARY OF PHASE 2 HEATUP/ HYDROLYSIS OF FUEL RODS

, t j hcl hcl Released l'

Mass Spec. hcl Tube Furnace 'from core,'q Test Fuel Year No. Rods- Wet He No. Rods Mass Tube ppm (a)

Dry (asHg Tested Spec Furnace (b)

!t No. Segment Service Tested ppm ppm /hr I

1 Core 1 1 0.28 3 3.7 3 2 Core 1 2 0.71 5 3 Core 1 3 0.70 5 3.2 0,06 6 4 Core 1 4 0,5 5 0,75 2

!, 5 Core 1 6 0.67 .1 0.33 6 20 90-6 Core 7 0.5 1 0.26 0.03 6 3 2 i 7 Core 8 0,10 6 1 8 Core 9 0.4 6 2 l 9 Core 10 4 .3,5. 4 15 4-

! 10 Core 101st(c) 11 Core 10mid(c)

! 12 Core 10last(c) l 6

(a) l ppm hcl = 50g hcl released, calculated by 10-0 gm/gmx4x10 rodsx11 gms/ rod, 1 -(b)~ The total released from the. tube furnace was divided by 0.79, which was the collection efficiency, prior to calculating the total amount recovered.

l (c) Uncertainties or error bands have not been assigned, a factor of 2 uncertainty i might be appropriate.

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To verify the results of the hcl observation in the mass spectrometer and to determine the affect of hydrolysis a. number of fuel rods have been heated in the Phase II apparatus. The rods included an -

archive specimens from the initial core loading including 1, 3, 4 and 6 year fuel, and rods from each of the reload segments 7, 8, 9 and 10. The results are summarized in Table 6. Details of these results including all background or blank determinations are given in Appendix B.

The results of Table 6 show that the initial core fuel rods averaged about 0.5 ppm based on averaging 19 mass spectrometer tests. This means a release of about 20 g of Cl from core 1 heatup. In 4 tube furnace tests, on 21 fuel rods, the average hcl found was 1.4 ppm which converts to 90 gm released from the initial core.

In the tests where hydrolysis.was tried two rod batches showed small hcl releases, equivalent to 1

, to 3 pgm/hr from the core. This could be important during reactor operation .and high moisture concentration.

It is apparent from the table that the initial core released about 90 g hcl upon startup in 1976.

Heatup of each reload contributed an additional gram or so. This amount of release is fairly consistent with that speculated to be in the primary circuit, about 50 to 200 g. It may be concluded that hcl gas released from the fuel is a major contributor to the total Cl burden. The mass 1

spectrometer results are known to be non-quantitative on total release. The tube furnace results are much less ambiguous and are more quantitatively correct.

A list of conclusions of Phase 2 Heatup and Hydrolysis Tests is given below.

1. Initial heatup of . fuel rods in core 1 released about 90 g hcl. Prolonged heating did not increase the release.
2. Titanium sponge released 1 to 3 g hcl on initial heatup. Prolonged heating did not increase the release.
3. Heat up of HLM side reflector and H-327 fuel element graphite did not release hcl.
4. Hydrolysis of Ti sponge, or graphite did not cause hcl release.
5. Hydrolysis of fuel at operating temperature and high moisture would cause a small t

release of hcl gas, about-1 to 3 gm cl per hour.

3.3 Neutron Activation of Chlorine Chlorine 35 has a large neutron capture cross section (43 barns) creating Cl-36 which has a half-life of 3 x 105 yr and is a pure beta emitter (0.7 MeV). It was surmissed that if chlorine found on the cable (or elsewhere in the primary circuit) contained Cl-36, then it would prove that either the source of the chlorine was the core, or '

least, the chlorine had circulated in the pi y circuit, becoming activated, prior to plating out in the system.

Accordingly, a number of samples from the primary circuit were analyzed for Cl-36 and total C1 content. The results are given in Table 7.

The results in Table 7 clearly show that the chlorine found on corroded cable, the circulator duct and the circulator bolts has been subjected to a degree of activation equivalent to 24 to 80 days in core at 70% power.

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TABLE 7 RESULTS OF CHLORINE 36 ANALYSIS 4

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Time in Total Chlorine Chlorine 36 Neutron Service Total 2 Total pci 36 Activation Sample EFPD Found pgm/cm Found gm 35 Days at 70%

Cable wire near corroded 10 yrs 138 ug/g (a) 10 23 pci/g wire 167 43

. area 676 EFPD 30" above corroded area 90 pg/g 6 0.086 oci/g wire 1 0.2 Plateout probe tube sections 5 yrs BE, B1, B4, B6 408 EFPD 6 vg 0.7 pci 11.4 2.9 -

Tube Sections B-13 8 pg 2 0.11 pci 14.3 3.7 Circulator C2102 2 inlet duct (234cm ) 7 to (c) 110 pg 2(b) 23 pci 212 54 bolt 352 EFPD 990 pg 14 309 pci 312 80 Circulator C2104 bolt A 659(d) 250 99 3.6 340 pci 92 24 bolt B EFPD 120 99 1.7 110 pci 136 35 HPS KO POT water 6/84 ingress 3.8 ppm 10.2 2.6 RSS Balls MID 21 10 yr 8 pg/ ball 0.08 0.02 RSS Balls BATT 21 10 yr 7 pg/ ball 0.8 0.2 (a) 33 99 surface /gm wire also found. ,

(b) Analysis of wipe was increased by a factor of 4 reflecting a decon factor of .24.

(c) C2102 was in service for 3 months, 7EFPD, prior to shutdown on June 20, 1984. The total service time was 352 EFPD. The efficiency of decon efforts prior to recent service is unkown.

The chlorine found on the cable 30 inches above the corrosion failure on the plateout probe and in the HPS knockout pot has apparently been subjected to substantially less activation. This is not totally understood. The following is offered in explanation. The water obtained Cl-36 from the HPS knockout pot in late October, 1984 ppm total C1 and a ratio of 10.2 pci Cl-36/gC1. This low ratio suggests that this water sample contains chlorine which is not representative of that in the primary circuit, or in otherwords, it was contaminated with stable C1. The contamination could have come from the sample storage drum. Or, it could have leached from non activated locations inside the primary circuits, since the water sample was obtained 3 to 4 months after reactor shutdown.

The Cl found in the plateout probe diffusion tube also has a low Cl-36 content. Either these samples were contaminated by handling or storage since November, 1981, or, it suggests the major Cl ingress into the primary circuit occurred after the probe was removed on November 9, 1981 which was 54 days into cycle 3 operation. The low chlorine 36, found on the cable above the corrosion failure, means that this area was inside the shield plug where it was well swept with purified helium, thereby inhibiting contact with primary coolant.

The lowest Cl-36 ratio was found on RSS balls from hopper 21. This shows that the water leaked into the hopper did not carry chlorine from the primary circuit with it.

The Cl-36 found on the corroded cable could not have been due to in situ neutron activation because this particular control rod, 21, was in region 7 which was unrodded most of the time. This means that the cable was wound on the drum above the shield canister. The neutron flux in this location would be 4 or 5 orders of magnitude less than in the core. This virtually proves that at least some of the chlorine on the cable came from the primary circuit. Also, chlorine on the circulator could not have been activated in situ because of the low neutron flux in the lower plenum.

The chlorine found on the corroded cable and on the circulators experienced neutron activation equivalent to an average 47 days in core at 70%

power. This means that most of the chlorine was not continuously released from the core, because much of it would have experienced up to 1000 days of neutron activation. It is certainly possible that the chlorine found in the circuit is a mixture of that which was released from core 1 and a 4

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smaller amount released much later, which would be highly activated.

Another extreme possibility is that a large portion of the chlorine is in constant circulation. For example, residence time in a core is about 0.3 seconds which is 3% of the total cycle time of 10 seconds. If all of the chlorine has circulated continuously for 1000 days of reactor operation, it would exhibit a Cl-36 ratio equivalent to an activation of 1000 x 0.03 = 30 days. This degree of activation is approximately what was found on the cable and on the circulator. However, if there was continuous circulation, there would have been continuous cleanup by the HPS, and the chloride removed would be many times that in the primary circuit or several thousand grams. This seems to be rather unlikely.

It is concluded that only a small fraction of the Cl is circulating, the larger portion being plated out or concentrated in crevices.

Conclusion of Cl-36 Analysis

1. The Cl-36 concentrations in the primary coolant show that the source of chlorine is the active core, or if not the chlorine found was in almost continuous circulation.

The former is must more likely.

2. The core does not continuously release C1, otherwise the " equivalent activation" would be several hundred days.
3. There is another source wihch is low chlorine 36 and has apparently contaminated the upper part of the cable, evidently in and above the shield plug. This chlorine was not well mixed with primary circuit chlorine.
4. The Cl-36 ratios in the primary circuit are consistent with a mixture of chlorine activation times: a large fraction of relatively non-activated C1 (either released from the core on initial startup or from leaching of concrete or insulation) and a smaller fraction of highly activated C1, such as might have been released later.

! 5. Some of the above chlorine mixture would circulate and become activated, thereby increasing the Cl-36 ratio.

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6. The low Cl-36 content of the plateout probe diffusion tube suggests'that the major C1 ingress. occurred after November, 1981.

l 4.0 Overall Conclusions (consistent with Cl-36 analysis and heatup tests).

1. The fuel is not a continuous source of Cl rather it is a f transient source upon initial heatup. The initial core could have' released about 90 g C1.

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2. Exposure of fuel to high water vapor at operating l temperatures causes a relatively small release of C1,
about 1 to 3 g/hr, from the core.
3. Graphite is not a source of, hcl.
4. Titanium sponge is a minor transient source, up to 3 g, on

. initial heatup, and could be the non active chlorine source in control rod drive mechanism compartment above the shield plug.

5. Leachable sources such as concrete or insulation could lead to high salt levels locally but would not necessarily contribute to the circulating inventory.

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'. . l APPENDIX A PHASE II TEST APPARATUS AND PROCEDURE The apparatus for determining the release of hcl gas from FSV materials shown in Fig. A-1.

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Figure A-1. Heatup and hydrolysis apparatus for measurements of hcl release.

The method is to place the samples in the silica boat in the quartz furnace tube, establish helium flow, turn furnace on to desired temperature (950 C for fuel rods and H-327 graphite, 800 C for HLM and PGX graphite, 370 C for Ti sponge), remove and replace hcl collection flask at I to 5 hour5.787037e-5 days <br />0.00139 hours <br />8.267196e-6 weeks <br />1.9025e-6 months <br /> intervals, continuing to 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> total. If hydrolysis is required, moisture saturator is valved in for additional 24 to 100 hour0.00116 days <br />0.0278 hours <br />1.653439e-4 weeks <br />3.805e-5 months <br /> periods. Furnace background or blank values are determined by performing tests using empty furnace tube prior to addition of the sample, and also by running for long times after the hcl is released from the sample.

Collection flasks are submitted to analytical chemistry for chlorine measurements by means of ion chromatography, the sensitivity of which is below 0.1 ppm chlorine.

A number of standards were run in which known amounts of hcl were added to the furnace, hcl collected in the above method and submitted to analytical chemistry. The results of those calibrations are shown in the table below.

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TABLE A-1 s

hcl CALIBRATION STANDARDS Furnace Chlorine

. HC1.Added Tgmp Time- Removed Recovery (pgm) ( C) (hr) (pgm) (%)

465 950- 4.25 336 -72 j 3650 950 4 2924 80 i' 20.6 3033- 83 j 785 950 4 518 66 i

L 19.75 584 74 i

Note: Average recovery: 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> = 73%; 20 hours2.314815e-4 days <br />0.00556 hours <br />3.306878e-5 weeks <br />7.61e-6 months <br /> = 79%.

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APPENDIX B-1 DETAILS hcl RELEASED FROM FUEL RODS MASS SPECTROMETER RESULTS Fuel hcl ppm Rod No. Segment Leached MS CR 14-200012-21 Core 1 1x 0.51 CR 14-20024-19 Core 1 1x 0.26

CR 14-30001-0029(1) Core 1 1x 0.77 CR 14-30001-0029(2) Core 1 1x 1.81 CR 14-30001-0029(3) Core 1 1x 0.38 CR 14-30010-0027 Core 1 1x 0.31 CR 14-30019-0026 Core 1 1x 0.20 CR 14-40014-0032 Core 1 1x 0. 50 CR 14-2001-24(1) Core 1 1x 0.69 CR 14-2001-24(2) Core 1 1x 0.66 CR 14-2001-24(3) Core 1 1x 1.41 CR 14S-10046-1 Core 1 1x CR 14S-10050-13 Core 1 1x I CR 14N-10066-2 Core 1 1x CR 14-140013-51-0034 Core 1 1x CR 14-4001-51-0037 Core 1 1x 4

CR 14-10125-1 Core 1 1x 0.34 CR 16-10125-1 Core 1 2x 0.40 CR 18-10125-1 Core 1 3x 0.10 j CR 14N-60078-2 Core 1 1x 0.67 CR 14N-10311-17-00 Core 7 1x 0.52

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I APPENDIX B-2

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DETAILS OF hcl RELEASED FROM FUEL RODS USING THE TUBE FURNACE METHOD l

. Furnace- Dry Helium Purge Furnace Wet Helium  !

L Blank hcl hcl Blank hcl hcl

, Fue1~ Before 4 hrs 20 hrs After 4 hrs 20 hrs 4 Rod Number Segment pg ug pg ug ug/hr ug/hr 2 ea CR 14-30048-1S Core 1 0.46 173 236 5.6 2 ea CR 14-30051-1N Core 1 0.46 173 236 5.6 I 2 ea CR 14-30053-1N Core 1 0.46 173 236 5.6 2 ea CR 14-60078-2 Core 1 1.8- 29.5 56 1.46 2 ea CR 14-60080-2 Core 1 1.8 29.5 56 1.46 i 2 ea CR 14-60089 Core 1 1.8 29.5 '56 1.46

2 ea CR 14-10046-1 Core 1 3.0 270 3.0 2 ea CR 14-10050-13 Core 1 3.0 270 3.0 l 2 ea CR'14-10066-2 . Core 1 3.0 270 3.0 2 ea CR 14-10300-00 Seg 7 1.8 21.01 44.2 1.8 i 2 ea CR 14-10318-16 Seg 7 1.8 21.01 44.2 1.8 2 ea CR 14-10335-17 Seg 7 1.8 21.01 44.2 1.8  ;
_ 2 ea CR 14-20001-24 Seg 8 1.86 10.22 21.8 1.0 2 ea CR 14-20024-19 Seg 8 1.86- 10.22 21.8 1.0

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i 2 ea CR 14-20012-21 Seg 8 1.86 10.22 21.8 1.0 2 ea CR 14-30001-0429 Seg 9 1.45 24.5 39 0.72 .i l

2 ea CR 14-30010-0027 Seg 9 1.45 24.5 39 0.72

! ~2 ea CR.14-30019-0026 Seg 9 1.45 24.5 39 0.72 s

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- l o o APPENDIX C

! CALCULATIONS OF CHLORINE - 36 FORMATION Calculate the fonnation of Cl-36(t1/2 = 3x10 5yr) from 1 gm of stable C1 by-neutron activation in FSV at 70% power.

pci C1 36/gcl = -AN354at/3.7x104 dps/pci 23 i Where: N 35 = atoms C1 35 = l9}5g le = 1.3x10 0

0.75 = fraction 35 in C1 l 4 = neutron flux at 70% power 4x1013 i

A = 7.5x10~I4 '

?

o = c1 -35 cross section, 43x10-24 ,2 t = time, seconds assume 1 day = 8.64x10 4 In one day at 70% power in core a gram of stable C1 yicids -

l

" -I4 1.3x10 22 4 4 c- y 7.5x10 4x10 13 43x10-24 8.64 x10 /3.7x10 = 3.9 The cable with leach found 167 ucgc + 3.9 = 43 days activation at 70% power.

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-. - . - - . . - - - _ , _ . . - - ,. . . - - _