ORNL-TM-5759.txt

  
 
 

 ORNL/TM-5759

g/L 77/

 

Distribution and Behavior of
Tritium in the Coolant-Salt
Technology Facility

 

G. T. Mays
A. N. Smith
J. R. Engel

 

 

HASTER

 

" OAK RIDGE NATIONAL LABORATORY
e OPERATED BY UNION CARBIDE CORPORATION FOR THE ENERGY RESEARCH AND DEVELOPMENT ADMINISTRATION

 
 

Printed in the United States of America. Available from
National Technical Information Service
U.S. Department of Commerce
5285 Port Royal Road, Springfield, Virginia 22161
Price: Printed Copy $4.50; Microfiche $3.00

 

 

 

This report was prepared as an account of work sponsored by the United States
Government. Neither the United States nor the Energy Research and Development
Administration/United States Nuclear Reguiatory Commission, nor any of their
employees, nor any of their contractors, subcontractors, or their employees, makes
any warranty, express or implied, or assumes any legal liability or responsibility for the
accuracy, completeness or usefuiness of any information, apparatus, product or
process disclosed, or represents that its use would not infringe privately owned rights.

 

 

 
ORNL/TM~5759
Dist. Category UC-76

Contract No. W-7405-eng-26

Engineering Technology Division

DISTRIBUTION AND BEHAVIOR OF TRITIUM IN THE
COOLANT-SALT TECHNOLOGY FACILITY

G. T. Mays A. N. Smith
J. R. Engel

Date Published - April 1977

NOTICE
This report was prepared as an account of work
sponsored by the United States Government. Neither
the United States nor the Unijted States Energy
Research and Development Administration, not any of
their employees, not any of their contractors,
subcontractors, or their employees, makes any
warranty, express or implied, or assumes any legal
liability or responsibility for the accuracy, completeness
or usefulness of any information, apparatus, product or
process disclosed, or represents that its use would not
infringe privately owned rights,

 

 

 

 

NOTICE: " This document contains information of a preliminary
nature. It is subject to revision or correction and there-
fore does not represent a final report.

Prepared by the e T
OAK RIDGE NATIONAL LABORATORY | A ? g E{\
Oak Ridge, Tennessee 37830 g%’fi@%t
.

operated by
UNION CARBIDE CORPORATION
for the
ENERGY RESEARCH AND DEVELOPMENT ADMINISTRATION

S me s s T g
pul e et POy A T e s ThoanTy b et bR AT
s bR U U Ll U‘-..i‘»lL-diSih»i{; }( UE\;_H(I“':-;?{}\
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CONTENTS
Page
ABSTRACT ...t iienineeenntnensnscacssssesnsosna e es s et easesenenaennns 1
1. INTRODUCTION .. eiennncenueonsensosannnns T isesesatesnasaaes - 2
1.1 Tritium in MSBR ...ttt enannes Ce s e et aae s 2
1.2 Tritium in the MSRE ittt iiiittineretneenennnnenn 3
1.3 Proposal for Limitation of Tritium Transport .....c.ccee.. 4
2. COOLANT-SALT TECHNOLOGY FACILITY (CSTF) vveetnnnencnernnananns 4
2.1 Primary Function and Capabilities ......ci.iieiireencnnnnnan 4
2.2 Description of Physical Parameters of CSTF .........c..... 5
2.3 Operating History of CSTF ......vuuns e r e es et s . 7
2.4 Equipment for Tritium TeSES +.iveiversreerreneeesoonnnsnenas 8
2.4.1 CSTF physical parameters for tritium tests ........ 8
2.4.2 Addition of tritium to CSTF ... vereeveonnnnnnnnns 8
2.4.3 Salt sampling ..vevevvrscrncvas Cet i ee ettt . 12
2.4.4 Off-gas sampling SYSLEM ...ivireieneneeoonoensonnes 12
2.4.5 Cooling duct air sampling system ......ccceveeeunnnn 14
2.4.6 Hydrogen partial pressure probe .......iciveennenn. 15
3. GENERAL DESCRIPTION OF EXPERIMENTS ... eerrrenreenoanns Ceenna 15
4, RESULTS OF TRANSIENT EXPERIMENTS ..ttt eernennnsreernannnsnenns 19
4.1 Experiment Tl .o eievieeiieenonosensosessonnnsesennnnnsenss 19
4.2 Experiment T2 .. .uieeeeieeensatnsenseesnssoesnnosooseanennss 22
4.3 Experiment T3 .....ccevieenns S e ceneaerstieententeaes Ceean 25
4.4 Summary of Transient Experiments T1, T2, and T3 .....c..... 29
5. RESULTS OF STEADY~STATE EXPERIMENT T4 ... vieiieenrennnnenaenns 30
5.1 Buildup and Attainment of Steady-State Conditions ........ 31
5.2 Change in Off-Gas Flow Rate ..eveveucesve Chieaseaaaas ceienn 37
5.3 Stripping Period ....... ceeseneaas Srrercranesrersarnearens 38
5.4 Tests for Tritium Concentration in Addition Gas .......... 38
6. RESULTS OF STEADY-STATE EXPERIMENT T5 ......... Ces ettt r e 38
6.1 Buildup and Attainment of Steady-State Conditions ........ 40
6.2 NaBO; Addition to CSTF ...ttt ieitneettioneenceaeronnaennas 44
6.3 B303 Addition to CSTF i vurernenteonococorosascnsrenennnss L6
6.4 Helium Leak Detector Measurements ..........oeoce.. e 47
6.5 Extraneous Source of Hydrogen in 0ff-Gas System .......... 48
6. Stripping Period .....iiiirrerirererraecartittosnesaaranens 50
7. INTERCOMPARISON AND INTERPRETATION OF EXPERIMENTAL RESULTS .... 51
8. EXTRAPOLATION TO MSBR CONDITIONS ... iverienreveesnosnnannnnnnns 53

iii
10.
11.
12.
13.

iv

Page
FURTHER EXPERIMENTATION REQUIRED « v ceveeecneonecncnncnnennnns 56
CONCLUSION 4 veetennenenneneenesnennns e eeneaeeaa U 57
ACKNOWLEDGMENTS +vvvvvuernesnssnoensncsnsnnes e .. 58

REFERENCES ........ caneas ceenaerans ceettssseevertaseeans sesass 58
10.

LIST OF TABLES

Sources and rates of production of tritium in a 1000-MW(e)

)

Operating and geometrical parameters assumed for CSTF

tritium testsS «oeeenooeens e et e e S e e e s e e esac e st e e aee s

Summary of tritium addition experiments Tl, T2, and T3

in CSTF ....... * % & & B & 5 B 0 5 s PO BB F KRS S P E RSB T FE PR s s s
Steady—-state material balance for experiment T4 ..........0...
Overall system material balance at steady-state for

exXperiment T4 .ueeeieriraeeeosneneesososnsesoenssonesnenssosnnss
Representative hydrogen partial pressure probe measurements
for experiment T4 ...vviveeenns et et e st eaat st
Steady-state material balance for experiment T5 .............

Representative hydrogen partial pressure probe measurements

for experiment T5 ..... N e e e e aae e e et e ettt ettt et e e e

Summary of tritium addition experiments T4 and T5 in CSTF

Extrapolation of results from CSTF tritium experiments to

MSBR Conditions ....... * ® ® 8 8 8 S N & s e P d & 8 & & 5 ¢ 2 4 v & ks sk PP b & s 0

10

30
34

35

36
42

44
51

54
W 0 ~N O Ut >
- . .

= e
W N = O

vii

LIST OF FIGURES

CSTF Schematic ..‘...'.....I...I........'lli'..l...l. IIIIIII “ 8

CSTF schematic for tritium experiments ........ et esas cevenns .o

Tritium addition system ........4.. Ceeresens cessaans et Cee

Off-gas sampling System ,.......eoevevrrcnnnencness ceeen

Cooling duct air sampling system .......... esearenneane

Typical hydrogen partial pressure probe measurement ....

Observed tritium concentrations in CSTF, experiment T1 ...

Observed tritium concentrations in CSTF, experiment T2
Buildup of tritium concentration in salt, experiment T2
Observed tritium concentrations in CSTF, experiment T3

Buildup of tritium concentration in salt, experiment T3

Observed tritium concentrations in CSTF, experiment T4 ...

Observed tritium concentrations in CSTF, experiment T5

LI ]
DISTRIBUTION AND BEHAVIOR OF TRITIUM IN THE
COOLANT-SALT TECHNOLOGY FACILITY

G. T. Mays A, N. Smith
J. R. Engel
ABSTRACT

A 1000-MW(e) Molten-Salt Breeder Reactor (MSBR) is
expected to produce 2420 Ci/day of tritium. As much as
607% of the tritium produced may be transported to the
reactor steam system (assuming no retention by the sec-
ondary coolant salt), where it would be released to the
environment. Such a release rate would be unacceptable.

Therefore, experiments were conducted in an engi-
neering-scale facility — the Coolant-Salt Technology
Facility (CSTF) — to examine the potential of sodium
fluoroborate, the proposed coolant salt for an MSBR, for
sequestering tritium. The salt was believed to contain
chemical species capable of trapping tritium. A series
of 5 experiments — 3 transient and 2 steady-state experi-
ments — was conducted from July of 1975 through June of
1976 where tritium was added to the CSTF. The CSTF cir-
culated sodium fluoroborate at temperatures and pressures
typical of MSBR operating conditions.

Results from the experiments indicated that over 907
of tritium added at steady-state conditions was trapped by
sodium fluoroborate and appeared in the off-gas system in
a chemically combined (water-soluble) form and that a total
of v98% of the tritium added at steady-state conditions was
removed through the off-gas system overall.

Extrapolating to MSBR conditions based on a concentra-
tion ratio of V4000 for chemically combined tritium to ele-
mental tritium in the salt observed at steady-state condi-
tions, calculations indicated that less than 10 Ci/day of
tritium would be transported to the reactor steam system.
Such a release rate would be well within established guide-
lines for release of tritium to the environment.

Although a complete understanding of the behavior of
tritium in sodium fluoroborate could not be developed from
this series of experiments due to the termination of the
Molten-Salt Reactor Program, the effectiveness of sodium
f luoroborate to trap tritium was demonstrated. Furthermore,
use of sodium fluoroborate as a secondary coolant in an MSBR
would be expected to adequately 1limit the transport of tri-
tium to the reactor steam system and environment.
1. INTRODUCTION

1.1 Tritium in MSBR

 

A 1000-MW(e) Molten-Salt Breeder Reactor (MSBR) operating at 2250
MW(t) is expected to produce tritium at a rate of 2420 Ci per full-power
day.1 The major source (Table 1) of tritium is the neutron reactions with
lithium, an important constituent of the MSBR fuel salt, which contains
uranium tetrafluoride and thorium tetrafluoride dissolved in a lithium
fluoride—beryllium fluoride carrier salt. The composition of the fuel
salt, expressed in mole percent of each constituent, is 71.7 LiF, 16 BeFj,,

12 ThFu, and 0.3 UF,.

Table 1. Sources and rates of
production of tritiug in a
1000-MW(e) MSBR

 

Production rate

 

(Ci/day)
Ternary fission 31
5Li(n,a) %H 1210
"Li(n,no0)%H 1170
19F(n,170) 2H 9
Total 2420

 

aFrom Ref. 1.

At the operating temperatures, 700977 K (800—1300°F), of an MSBR,
tritium tends to diffuse through the metal walls of the various systems.
In the migration process tritium is transferred from the primary system
to the secondary coolant salt by diffusion through the walls of the pri-
mary heat exchanger tubes. Tritium in the secondary salt is in turn
transferred through the steam generator tube walls into the steam system,
where it would be converted to tritiated water and discharged to the

environment in the steam system blowdown or the condenser cooling water.
Early calculations?

indicated as much as 1425 Ci/day, or 60%, of the tritium
produced would be transported to the reactor steam system assuming no reten-

tion of tritium by the secondary salt.

Release of the 1425 Ci/d of tritium would be unacceptably high.
The MSBR design limit objective for release was set at 2 Ci/day. The re-
sulting concentration of tritium in the water released to the environ-
ment would be well below established guidelines® for "as low as reasonably
achievable' for release of radioactive material in effluents from light
water reactors. It is assumed that an MSBR would have to meet similar

guidelines.

1.2 Tritium in the MSRE

 

Some experience with tritium in a molten-salt system was gained from
the Molten-Salt Reactor Experiment (MSRE). This reactor was operated
from 1965 to 1969 at a full power of about 7.3 MW(t). It operated at a
maximum temperature of 927 K (1210°F) with a fuel salt similar to the
MSBR fuel salt. Heat was transferred to a lithium fluoride—beryllium
fluoride coolant salt and removed from the secondary salt by blowing air
over the tubes of a radiator, which was used in place of a steam generator—
superheater, and discharging it up a stack to the atmosphere.

Tritium disposal from the MSRE never presented a significant problem.
The only measurements made were of liquid wastes for health physics moni-
toring purposes. However, a growing concern for tritium production in a
large molten-salt reactor initiated measurements for making a material
balance on tritium in the MSRE.

The calculated production rate was 54 Ci/day, and the observed dispo-
sition of tritium, not including retention in the off-gas system, amounted
to 80% of this production rate: 487% discharging from fuel off-gas system,
2% discharging from coolant off-gas system, 7% discharging in coolant
radiator air, 9% appearing in cell atmosphere, and 147 going into the core
graphite. Most of the remainder was probably held up in o0il residues in
the fuel off-gas systems.

The difference in tritium production between the MSRE at 7.4 Ci day"1
MW(t)—1 and the MSBR at 1.1 Ci day_1 MW(t)“1 is due mainly to the increased

®Li concentration that was present in the MSRE fuel salt.
1.3 Proposal for Limitation of Tritium Transport

One method proposed for limiting tritium transport to the steam system
in an MSBR is based on an isotopic exchange of tritium with a hydrogenous
impurity in the reactor secondary coolant salt. Sodium fluoroborate, the
proposed MSBR coolant salt, is an eutectic mixture containing 92 mole %
NaBF, and 8 mole % NaF. Chemical analyses have shown that the fluoroborate
salt normally contains a hydrogenous impurity produced by the reaction of
water with the salt. Laboratory experiments” indicated that deuterium,
on contacting the salt, is retained by the salt because of isotopic ex-
change with this impurity. Tritium would be expected to behave similarly.
Another potential method for trapping tritium may involve the reaction of
tritium with oxide-containing chemicals in the salt. Once in the chemi-
cally combined form, unlike the elemental form, tritium would not be avail-
able for transport to the steam system. With adjustment of the impurity
level if required, the fluoroborate salt could then be processed for re-
moval of tritium.

Experiments were then proposed for the Coolant-Salt Technology Facility
(CSTF), an engineering-scale facility, to determine sodium fluoroborate's
effectiveness in sequestering tritium. Information from the tritium ex-

periments in the CSTF was to be used in extrapolating to MSBR conditions.

2. COOLANT-SALT TECHNOLOGY FACILITY (CSTF)

2.1 Primary Function and Capabilities

The primary function of the CSTF is to circulate the sodium fluoro-
borate coolant salt at temperatures and pressures typical of MSBR operating
conditions. The facility was designed with the capability to supply cool-
ant salt to a number of side loops for the purpose of (1) extending engi-
neering-scale operating experience with the proposed MSBR coolant salt
and its cover gas, (2) investigating on-line corrosion product traps, (3)
investigating on-line salt monitoring by electrochemical means, and (4)
monitoring the corrosion characteristics of the system by means of sur-
veillance specimens. For the tritium experiments, the CSTF's function
was to circulate sodium fluoroborate while several additions of tritium

were made to determine if the coolant salt would inhibit tritium migration.
2.2 Description of Physical Parameters of CSTF

The CSTF consists of a Hastelloy N pump (the coolant salt pump which

was used in the MSRE) and about 10.7 m (35 ft) of 5-in. IPS sched-40,
6.6-mm (0.258-in.) wall Hastelloy N pipe arranged in the form of a closed
loop (Fig. 1). The system may be operated at a maximum flow of 54 x 1077
m®/s (850 gal/min) using the normal 60-Hz power supply, or at reduced flow
rates using a variable-speed motor—-generator set. The ratio of wetted
surface to salt volume (including the pump tank inventory) is about 20:1
m?/m®. In comparison, the reference-design MSBR has a salt-circulating
rate of 1 m¥/s (16,000 gal/min) for each of four cooling loops and a ratio
of wetted surface to circulating salt volume of about 50:1 m?/m3.

The CSTF has two volumes of salt which are outside the main salt
stream but which communicate with the main salt stream by means of side
loops having relatively small salt flows.* These inventories of salt
are in the bowl of the salt pump and in the salt monitoring vessel (SMV).
Each of these regions is only partly filled with salt, there being a salt-
gas interface and a gas space in each, and the gas spaces are intercon-
nected. During normal operation, inert gas is fed into the pump bowl
continuously by way of the drive shaft purge and cover gas connections.

A small flow (about 70 cm®/min) of BF3, which is used to maintain the de-
sired ratio of NaBF, to NaF in the salt, is also added to the pump bowl
vapor space to compensate for the BF; that is removed from the circulating
salt in the off-gas stream. This gas, together with volatile materials
from the salt (e.g., BF3 and H;0 reaction products, tritium, etc.), passes
from the pump bowl gas space, through the SMV gas space, and then in se-
quence through the salt mist trap, the cold trap (—80°C), the cover gas
pressure control valve, and a mineral oil bubbler. Finally, the off-gas
stream flows to the stack by way of the suction line of the containment
system ventilation blower.

All of the salt-containing piping and components of the CSTF are

enclosed in a steel containment enclosure equipped with an evacuation

 

*
In its original design, the CSTF had a third side loop passing

through the salt mist trap. Prior to the tritium test, this third loop
was disconnected and the loop-side openings were capped off.
ORNL-DWG 74-8978R

 

 

    
 
 
  

 

 

 

 

 

 

 

 

 

 

 

 

= SALT
MONITORING
785 GPM - 96 FT. HEAD
COVER GAS VESSEL E==—= = OFF-GAS 800°-1150° F. €
5-25 PSIG —BF; RECOMBINER SURVEILLANCE
AR SPECIMEN
LEVEL T7 ggkg l ‘ /J. AIR-COOLED 1
ELEMENT , , / HEAT EXCHANGER ,\’
bbb -

 

   
 

 

 

I B

MOTOR

l CONTROLLED
MANUALLY DAMPER /
AIR

OPERATED —
DAMPER | [\ —= EXHAUST
r—('—r— 7O BLOWER
P

 
  

FI.OWMETER—/

 

 

 

ECONOMIZER

 

 

 

 

 

GRAVITY f
CONNECTIONS FOR [‘ DAMPER
FUTURE EXPERIMENTS N
M A B m o[ /L_____———————-—’_’__
— O O

 

 

Ij
LOAD ORIFICE

 

 

 

FREEZE VENT \
VALVE Ttfi:GAS SUPPLY EQUALIZER LINE
FILL &
DRAIN TANK

 

'Fig. 1. CSTF schematic.
blower. The containment and ventilation system provides secondary con-
tainment for any salt leak and also provides for safe disposal of any gas
released from the facility. The enclosure is maintained at a slightly
negative pressure by the 1.4 m3/s (3000 cfm) blower. The blower suction
line is connected to parallel cooling ducts on the salt loop piping (Fig.
1) whereby more or less air can be drawn through the cooling ducts as

dictated by the loop cooling requirements.

2.3 Operating History of CSTF

The CSTF became operational for the first time in October of 1972.
Several runs° were made observing and measuring such things as cavitation
at the load orifice (Fig. 1), BF3; content of the BF3-He off-gas stream,
salt flow through the SMV, proton activity in the salt, and chemical
composition of the salt.

In February of 1973, the CSTF was placed in standby because of the
cancellation of the MSR program. From February 1973 through March 1974,
the system was maintained in standby, namely at room temperature with a
static pressure of 5 psig helium blanketing the salt-containing portions.
In April 1974, the MSR program was restarted and work was begun on recom-
missioning the CSTF in preparation to study tritium behavior in sodium
fluoroborate. Deuterium was originally to be added to the system as a
stand-in for tritium; however, the necessary analytical equipment required
for measuring the anticipated concentrations of deuterium would not have
been operational at the time the experiments were to be conducted. Conse-
quently, the decision was made to use tritium which could be measured with
available radioactive counting techniques.

Once the CSTF was restarted, two important modifications were made.
First, a second load orifice was installed in the main circulating loop.
The two orifices in series permitted operation of the loop at maximum
conditions of temperature [894 K (1150°F)] and pump speed without signifi-
cant cavitation. Second, a salt mist trap was installed in the off-gas

%
line at the outlet from the salt cold trap to prevent plugging of the

 

*
" The cold trap in Fig. 1 is a salt cold trap while the cold trap in
Fig. 2 is an off~gas cold trap.
off-gas line by deposition of frozen salt mist. The salt mist droplets
were generated in the pump bowl and were carried out with the off-gas
stream and deposited at a point where the temperature fell below the
freezing point of the salt. The salt lines (economizer in Fig. 1) from
the salt mist trap to the pump suction line were also disconnected for
the tritium tests.

During the initial operating period in 1972, salt was circulated
for 1060 hr. Since the CSTF was recommissioned in 1974, salt has been
circulated V8240 hr. On July 12, 1976, the loop was shut down following
the conclusion of the final tritium experiment and work was begun to

decommission the CSTF.

2.4 Equipment for Tritium Tests

The equipment for the tritium experiments consisted of (1) the
Coolant-Salt Technology Facility (CSTF), (2) the equipment needed to add
measured quantities of tritium to the circulating salt, (3) the sampling
and analytical equipment needed to determine the distribution of the

tritium between the various possible sinks.

2.4.1 CSTF physical parameters for tritium tests

A schematic of the CSTF as it was used in performing the tritium
experiments is presented in Fig. 2. Table 2 presents the operating and

geometrical parameters used for the CSTF tritium tests.

2.4.2 Addition of tritium to CSTF

The addition of tritium into the circulating salt stream was accom-
plished by means of a special addition tube assembly installed in the
surveillance specimen access tube (Figs. 1 and 2) in place of the regular
surveillance specimen holder. The surveillance specimen station was orig-
inally designed to permit exposure of Hastelloy N metal coupons to salt
at normal velocities and temperatures of the loop. This location of the
addition tube ensured that the tritium could not pass directly into the
off-gas system without first coming in contact with the circulating salt.
The inner part of the addition assembly was charged with a mixture of

hydrogen and tritium at a desired pressure, the gas then permeated or
 

 

 

ORNL-DWG 76-13057

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

  

 

 

AIR
—— HELIUM PURGE
TO PUMP SHAFT Z 77 //'I*L; > T ]
5
PRESSURE ,
<t OFF-GAS SAMPLE POINT CONTROL '
(100 cm3/min) OFF-GAS
VALVE s
(1900 cm=/min)
SALT SAMPLE - \\
ACCESS POINTS .
MINERAL
r. Ol - TRITIUM
—_— , BuUBB il
BF3 - o r MIST hl'--]”COLD Y LER / ADDITION
“lsmv i1 7 TRAP - 7 : DEVICE
HELIUM ——Y TRAP U ]
AIR AIR 1
COVER GAS j T L] + * EXHAUST
(2000 cm>/min) SALT PUMP , L I | AIR
@ e ——— 1.4 ms/sec
HYDROGEN AIR
- PARTIAL * + v
PRESSURE | r
PROBE —» &
AIR
-4 3/ SAMPLE f T
1.25x10 " m /sec max POINT | 1 V_N.F.IAI»C\XJ ION
| ,
- - I \
L OWER COOLING DUCT T LOAD
5in., SCHED 40, HAST N PIPE « ’ T T \OR'F‘CES
0.054 m3/sec max * LOOP
450-650°C AIR AIR ENCLOSURE

 

EQUALIZER
LINE

 

DRAIN
TANK

 

 

 

Fig. 2.

  

\ FREEZE VALVE

CSTF schematic for tritium experiments.
10

Table 2., Operating and geometrical parameters
assumed for CSTF tritium tests

 

Main loop salt flow rate 540 x 107" m’/s 850 gal/min
(pump speed = 1790 rpm)

Bypass salt flow rates
(pump speed = 1790 rpm)

Pump bowl bypass flow rate 9.50 x 10™"* m*/s 15 gal/min
Salt monitoring vessel flow rate 1&25 x 107" m¥/s Zagal/min
Salt mist trap flow rate 0 0

Total bypass flow rate 10.75 x 10~* m®/s 17 gal/min

Main loop piping geometry

Outside diameter 141 mm 5.56 in.
Inside diameter 128 mm 5.05 in.
Wall thickness 6.6 mm 0.26 in.
Wetted surface excluding pump bowl 4.5 m? 48.4 ft?
Wetted surface in pump bowl 1.0 m? 10.8 ft?
Pump bowl surface exposed to gas 0.68 m? 7.3 ft?
space
Volumes
Loop piping including SMV and 150 x 1073 m?® 5.30 ft?
salt mist trap, excluding pump ’
bowl
Circulating salt including pump 270 x 10~% n® 9.53 ft?
bowl
Pump bowl liquid 120 x 107°% m? 4.24 ftd
SMV liquid by2 % 1073 m? 0,15 fel
Salt mist trap liquid 0 0
Pump bowl vapor space 57 x 10~ m? 2.01 ft3
SMV vapor space 7.3 x 107% n?® 0.26 ft?
Salt mist trap vapor space 2.8 x 1073 m? 0.10 ft?

 

a .
The salt lines were disconnected from the salt mist trap, so that
during the tritium test there was no salt flow or salt inventory, other
than accumulated salt mist, in the salt mist trap.
11

diffused through the wall of the Hastelloy N tube which formed the lower

end of the addition tube and was immersed in the circulating salt stream.

The Hastelloy N tube was about 120 mm (4.7 in.) long with an OD of 12.7 mm

(0.5 in.), and a wall thickness of 1.07 mm (0.04 in.), and the provision

was made to fasten metallurgical surveillance

face.

500-cm>
VOLUME

 

TRITIUM
TRANSFER
CYLINDER

PURIFIER
SAMPLE

VACUUM
1000-cm® VOLUME

HYDROGEN

   

Fig. 3.

Tritium addition

specimens to the upstream

ORNL~-DWG 75-12616R

      
   
   
  
 

%

 

  

35°C

   
 
  

VACUUM
ANNULUS -__
100 °C
ADDITION
TUBE

system.

Connected to the tritium addition assembly was the equipment needed

to supply measured quantities of tritium to the CSTF (Fig. 3).

The high-

pressure, tritium transfer cylinder was charged with tritium, and the

cylinder was connected to the addition system and charged with hydrogen

from the hydrogen supply bottle to a total pressure calculated to yield

the desired tritium isotope concentration.
was fed from the cylinder through the purifier until the 500 cm

was charged with purified gas to the desired pressure.

the 500 cm® volume was used to charge the
assembly. A d/p cell was used to measure
in the addition assembly due to diffusion

hydrogen into the salt. For a short-term

The tritium-hydrogen mixture
* volume
Purified gas from
addition tube and addition

the resulting pressure drop

of the mixture of tritium and

experiment, the reference volume

(Vr) and addition tube volume (Vp) could be charged directly without using

the 500—cm3 volume.

A rupture disk was connected to the hydrogen supply
12

to minimize the probability of overpressurizing the system. The purifier
was simply a heated palladium tube through which hydrogen isotopes diffuse
more readily than heavier gases such as 0Oz, Nz, and H20. A vacuum pump
was used to evacuate the annulus surrounding the addition tube in the high
temperature zone adjacent to the salt piping (Fig. 3). Measurements of
the-pressure rise in the vacuum annulus were used to estimate the amount
of stray leakage that occurred during the addition of tritium. A sampling
point was provided to obtain samples for mass spectrometer analysis to

determine the concentration of tritium in the addition gas.

2.4.3 Salt sampling

Salt samples for tritium analysis and for chemical analysis were
taken from the salt pool in the bbwl of the salt pump or in the SMV by
inserting a copper tube through the salt sample access pipe (Fig. 2). The
normal method was to use a ''filter stick," wherein the salt was forced into
the sample tube through a porous copper frit having a 10 um mean pore size.
An available alternate method was to use a ''bucket sampler' which had slots
in the sides of the lower end of the sample tube and functioned in the man-
ner of a water dipper. The sample was dissolved in water and counted using
scintillation counting techniques. Sample results of the tritium concen-
trations in the salt represented tritium in a chemically combined form since
any elemental tritium present in the samples would have been released in

preparing them for counting.

2.4,4 Off-gas sampling system

For water-soluble (combined) and elemental tritium in the off-gas
stream, a 100-cm’/min sample stream was taken from the 2~liter/min off-gas
stream at a point just downstream of the pump bowl and was passed through
a salt mist filter, a needle valve, a water trap to collect water-soluble
(combined) tritium, a Cu0 furnace to convert elemental tritium to triti-
ated water, and a water trap and cold trap to collect the tritiated water
(Fig. 4).

About 20 cm®/min of hydrogen was added to the sample stream to promote

efficient oxidation of the elemental tritium.
HELIUM, »e

ORNL-DWG 76-13056

 

PURGE o

 

 

 

 

 

 

 

 

REGENERATION [l SAMPLE GAS
f ol BYPASS LINE -
AlIR 7 —><3 : : S E—\
200°C—\ & : :
r_.l o
H, —— 000 i crcoooooo o
: | 1%! VENT

   
   

TRANSITION ZONE
540 TO 200°C
SALT MIST FILTER

—_———— e - ——

r
|
540°C —=
E
|

Fig. 4.

(~100 cm*/min)

CuO FURNACE
UOGOO°C CcoLD

TRAP

 

 

e e e ===

S
:

Fm—————-

 
 
 

[T S
B SRR

      

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Z A
PRE-TRAPS
FOR
WATER-SOLUBLE . '
TRITIUM AFTER TRAPS
540°C FOR ELEMENTAL
TRITIUM
Lt— 540°C OFF-GAS LINE TE,,?ECOTF'ON
1900 cm¥/min VENTILATION
BLOWER
SMV  l——_ E__"
540°C - I |I
COLD TRAP i
100°C COLD TRAP MINERAL OIL
BUBBLER

Off-gas sampling systemn.

€T
14

The salt mist filter was installed in the off-gas sample line prior
to the final two experiments to prevent salt mist droplets from being trans-
ported to cooler regions and subsequently freezing and plugging lines. The
off-gas lines leading to the sampling equipment were maintained at 370 K
(200°C) to prevent the water-soluble (combined) tritium from condensing in
the lines. A flow of helium was passed through the sampling system after
each sample was taken to purge out any remaining tritium to minimize any
bias on subsequent samples. Air flow was also provided so that the depleted
Cu0 in the furnace could be regenerated periodically. When the system was
not in the sampling mode, the 100-cm?®/min sample flow was returned to the
main off-gas flow via the sample gas bypass line. The tritium concentra-
tions of the two species were determined by scintillation counting tech-

niques.

_ ORNL-DWG T6-5258
LOOP
AR AR ENCLOSURE

   
 

APPROX.
13 m¥s AR

  
   

AIR SAMPLE

o VENTILATION BLOWER
SUCTION LINE
APPROX. 1.% m¥/s AIR

  

SALT
PIPE

LOWER COOLING DUCT
EXHAUST LINE

 
     
 
 

 

   
 

 

 

 

RECIRCULATING AIR STREAM

 

 

 
   
 
  
  

PI-TH 13 TG 20 liters/min
FILTER \
et st
CIRCULATING ™ aperox. 100 cm®/ min
PUMP
FLOW Q

QO RESTRICTOR > S )\/o)—U-o

600 *C WATER l! J]

APPROX, 20 cm®/min TRAP WET TEST
CoLD METER
TRAP

HUMIDIFIER
HELIUM ~80 °C

Fig. 5. Cooling duct air sampling system.

2.4.5 Cooling duct air sampling system

The rate of permeation of tritium through the walls of the loop was
obtained by sampling the air stream at the exit from the .lower cooling duct
on the salt loop (Fig. 5). The surface area of loop piping shrouded by the
lower cooling duct was approximately 20% of the total surface area of loop

piping. A sample tap was installed in the air line coming from the lower
15

cooling duct. This tap was connected to a diaphragm pump that circulated
sample gas at a rate of about 1700 cm’/min and vented the gas into the loop
enclosure. At the pump discharge, where the pressure was controlled at an
absolute pressure of 140 kPa, a 100~cm3/mip side stream was taken off for
sampling. The sample stream was mixed with 20 cm®/min of humidified helium,
and the combined streams were passed through a Cu0 furnace to convert the
tritium to tritiated water and then through a water trap and cold trap to
collect the tritiated water. The tritium concentration was measured by
scintillation counting.

The modifications necessary for implementing this system involved
extending the air intakes to the lower cooling duct so that the air was
drawn from outside the loop enclosure to avoid contamination of the samples
by extraneous tritium present in the enclosure. The air flow through the
lower cooling duct was calibrated by adding a known flow of tritium to the

air intake and sampling the air stream.

2.4.6 Hydrogen partial pressure probe

A probe was inserted in the main salt stream prior to experiment T4
at a point about 1.25 m downstream from the salt pump discharge (Fig. 2)
to measure the partial pressure of elemental hydrogen and ultimately deter-
mine the dissolved elemental tritium concentration in the salt. The probe
(similar in design to the addition tube) consisted of a sealed Hastelloy N
tube, 12.7 mm OD X 1.1 mm wall, connected to the necessary valving and
instrumentation to permit pressure readings inside the probe in the range

of 0.01 to 100 Pa (0.1 to 1000 um Hg).
3. GENERAL DESCRIPTION OF THE EXPERIMENTS

Hydrogen containing small amounts of tritium was added to the salt by
allowing the mixture of gas to permeate or diffuse through the walls of the
addition tube which was immersed in the circulating salt. Diffusion of
tritium through the metal walls of the addition tube into the salt as op-
posed to bubbling tritium into the salt more nearly simulated MSBR condi-
tions where tritium would be entering the secondary coolant system by

diffusion through the primary heat exchanger.
16

2 and the surface area

of the MSBR primary heat exchanger would be 50 X 10% cm®. The addition

The surface area of the addition probe was 50 cm

rate or transfer rate of gas in the experiment was about 10 times less than
under MSBR conditions in terms of cm’/hr. Therefore, the flux of gas in
terms of cm® of gas per cm? of surface area per hr was about 10° times
gréater in the experiments than under MSBR conditions.

Tritium (hydrogen) added to the CSTF was distributed among several
sinks and was considered to be in either the elemental or chemically com-
bined form. The potential sinks for distribution and respective chemical

forms were:

1. Dissolution in the salt in the elemental form.

2. Reaction with the salt to produce a chemically combined form.

3. Appearance in the off-gas system of the CSTF in both elemental and
combined forms. The concentrations of both forms in the off-gas were pro-
portional to their respective partial pressures over the salt that deter-
mined their respective concentrations in the salt in the pump bowl.

4, Dissolution in the metal of the loop walls and associated piping
in the elemental form.

5. Permeation through the loop walls in the elemental form.

Samples were taken for analysis of the combined form of tritium in
the salt, both forms of tritium in the off-gas, and elemental tritium in
the cooling duct air. The cooling duct air sampling system for measuring
the permeation rate of tritium through the pipe walls was available only
for the final two experiments. Samples of the addition gas were taken
periodically and analyzed by mass spectrometry to determine the tritium
concentration and ultimately calculate the addition rate of tritium to the
system.

A partial pressure probe for measuring the total hydrogen (elemental
protium and elemental tritium) partial pressure in the salt was also opera-
tional only for the final two experiments, which were steady-state experi-
ments. The pressure in the probe was permitted to build up over a period
of two to three days in order to allow the partial pressure of hydrogen in
the probe to be equilibrated with the partial pressure of hydrogen on the

outside of the probe in the circulating salt. The initial rise in pressure
17

was due to the buildup of the hydrogen partial pressure in the probe. The
gradual, constant increase in pressure over time was attributed to air in-
leakage and was subtracted off by extrapolating a plot'of the readings to
time zero for each respective measurement (Fig. 6). The pressure obtained
from the pressure gauges was corrected for (1) the difference between mea-
surements for hydrogen and air since the gauges are calibrated for air and
(2) thermal transpiratiocn effects® which result since the partial pressure
of interest was measured at 811 K (the operating temperature of the loop for

the experiments) and the gauges recording the measurement were at room tem-

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

perature.
ORNL DWG 77 3471
8 |
] | .
7 4 _ . . . P O ]
l —
‘ /
6 + e ——— - . Af.r__ —_ 4 -
g ! O]
5 5 i _____..——."
é /
E . ‘/ b
e
2 3 A'/ -y —_—
1.%_) /
, K
. ®
0
0 400 800 1200 1600 2000 2400 2800 3200 3600 4000

TIME (min)

Fig. 6. Typical hydrogen partial pressure probe measurement.

A Henry's Law Constant’ for hydrogen dissolved in sodium fluoroborate
was used to convert the elemental hydrogen partial pressure to a concentra-
tion of elemental hydrogen dissolved in the salt. The dissolved elemental
tritium concentration in the salt was then determined by assuming that the
ratio of tritium to hydrogen in the salt was the same as that in the addi-
tion gas. The ratio of chemically combined tritium concentration (from
salt samples extracted from the pump bowl or SMV) to the elemental tritium
concentration in the salt (from the partial pressure probe measurements)
becomes an important parameter in extrapolating results from the CSTF ex-

periments to MSBR conditions.
18

The quantity of tritium stored in the metal walls was estimated using
the following factors: (1) total hydrogen partial pressure, (2) isotopic
ratio of tritium to total hydrogen, (3) solubility coefficient’ of hydrogen
in Hastelloy N, and (4) total volume of metal of the system.

~ Both transient and steady-state experiments were conducted in the CSTF.
The three transient experiments — Tl, T2, and T3 — were run during July,
August, and September of 1975, respectively. The two steady-state experi-
ments — T4 and T5 — were conducted for approximately 65 days from February
through April of 1976 and for approximately 48 days from May through June
of 1976, respectively.

Tritium was added for about 10 hr in each of the three transient ex-
periments. The concentrations in the salt and off-gas did not become
saturated. Sampling of tritium concentrations in the salt and off-gas was
continued two to three weeks following the addition to observe the strip-
ping or removal of tritium from the system.

In the steady-state experiments, tritium was added long enough to per-
mit the tritium concentrations in the salt, off-gas, and cooling duct air
to level out. Steady-state conditions were presumed to have been attained
when the addition rate of tritium equaled the sum of the removal rates of
(1) combined (water-soluble) tritium in the off-gas, (2) elemental tritium
in the off-gas, and (3) tritium permeating the pipe walls of the CSTF.

The stripping portions of experiments T4 and T5 were observed for consid-
erably shorter periods of time than the transient experiments due to time
limitations of the MSR program.

The three transient experiments were essentially scoping experiments
in that they permitted

1. the acquisition of operational experience with the CSTF, both
general and that required for operating the CSTF for the purpose of con-
ducting tritium experiments;

2. an initial indication of sodium fluoroborate's effectiveness in
trapping or retaining tritium;

3. a determination of what further measurments and samples would be
required to better understand tritium behavior in sodium fluoroborate.

Subsequently, the cooling duct air sampling system and hydrogen par-
tial pressure probe were installed and steady-state experiments T4 and T5

were run.
19

4. RESULTS OF TRANSIENT EXPERIMENTS

4.1 Experiment T1

In experiment Tl a total of 33.6 cm® of hydrogen at 1000 ppm tritium
concentration was added to the CSTF during the 10.8-hr addition period.
Thus, about 85 mCi of tritium were added to the loop at a rate of 7.9
mCi/hr. Samples of the salt and loop off-gas were taken during the addi-
tion and for 15 days following the addition. The apparent concentrations

prior to the addition were:

1. Tritium in the salt: 1.7 nCi/g
2. Tritium in the off-gas, elemental: 1.0 pCi/em?
3. Tritium in the off-gas, water-soluble: 1.0 pCi/cm3

The data for experiment Tl (Fig. 7) are presented as absolute concentra-
tions without baseline corrections. The source for these initial concen-
trations was assumed to be tritium stored in the metal walls and/or from
carbonaceous residues accumulated during the operation of the MSRE. The
CSTF was constructed using portions of the MSRE piping. Presumably, the
tritium diffused from the metal walls into the salt and subsequently
appeared in the loop off-gas when operation of the CSTF was initiated.
During the addition period the concentration of tritium in the salt
(open circles, Fig. 7) increased almost linearly to a maximum of about
100 nCi/g and then decreased approximately exponentially over the follow-
ing three or four days to pretest concentration values. The apparent
half-life for removal was between 9 and 12 hr, depending on how the data
are extrapolated back to the end of the addition. Scatter in the sample
results and lack of a sufficient number of sample measurements of the salt
prevent a more accurate determination of the half-life for removal from
the salt. If tritium removal from the salt is assumed to be a purely
first-order process or combination of such processes, a time constant for
removal from the salt is defined. The time constant may be the sum of
several individual time constants, but the individual values would not
be identifiable. Based on the time constant (or half-life), a trapping

efficiency of the tritium by the salt can be calculated. A relatively
TRITIUM CONCENTRATION (nCi/g or pCi/cm3)

20

ORNL-DWG 75-42897

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

= 7 T T T 7T 7T 11
— é o SALT (nCi/g) —]
5 [— —_
— g ® OFF-GAS, WATER SOLUBLE (pCizem3) | —
B é A OFF-GAS, ELEMENTAL (pCi/em®) T
2 — / o —
é
103 Z
— 7 —
— ° =
5 — ]
| TRITIUM ADDITION ® —
2 — * —
7,
10% = ? . —
: / A ® :
— ;5 A | A o o | M
s Al ' "
C | . -
2 o / o o —
7 -
10! |- 2 —
— ° o -
5 . —
_ ° ® A A —
2 o a A —
° o | o
| A
10° _——_‘! Z a
e ‘ ——
S —
5 — ® -
— ® e
2f— | ® —
10-! Z
15 17 19 24 23 25 27 29 3|9
JuLy AUG
DATE , 1975
Fig. 7. Observed tritium concentrations in CSTF, experiment T1.
21

high trapping efficiency was calculated based on the 9-hr half life.
After the results from experiments T2 and T3 were analyzed where trapping
efficiencies of 507 and 557%, respectively, were determined, the trapping
efficiency of experiment Tl was re-evaluated. Based on the 12-hr half-
life, a trapping efficiency of 60% was determined.. The 60% value for the
trapping efficiency appéars to be more consistent with the values of ex-
periments T2 and T3.

The elemental tritium concentration in the off-gas (triangles, Fig.
7) rose to a maximum concentration of 830 pCi/cm?® at the end of the addi-
tion and began to decrease as soon as the addition was stopped. The de-
crease in concentration with time was too irregular to justify any quanti-
tative evaluation.

Although no measure of elemental tritium concentration in the salt is
available, a value can be inferred from the concentration of elemental
tritium in the off-gas by (1) assuming that the elemental tritium in the
off-gas samples represents release from the salt and only from the salt,
and (2) assigning reasonable values to gas stripping parameters in the
CSTF pump tank. Calculating the concentration of elemental tritium dis-
solved in the salt in this way indicated that the ratio of combined/ele-
mental tritium in the salt was about 50. It appears that chemical inter-
actions between the tritium—-containing compound in the off-gas and the
new metal of the sample line may have been responsible for the high con-
centrations of elemental tritium in the off-gas samples in this experiment,
based on the ratio of the two forms of tritium in the off-gas observed in
later experiments. The actual ratio of combined to elemental tritium in
the salt may have been higher. The combined tritium released from the
salt possibly was reacting with the surface of the new metal to consume
the combined form and to produce the elemental form. Once the metal be-~
came conditioned, the combined tritium concentrations in the off-gas began
increasing, thus explaining why the maximum concentration of combined tri-—
tium in the off-gas occurred several days after the end of the addition.
The ratio of the concentration of combined tritium in the off-gas to that
of the elemental form was substantially greater in experiments T2 and T3

than in experiment Tl. Also, the combined tritium concentrations in the
22

off-gas of experiments T2 and T3 rose to theilr maximum values at the end
of the addition periods.

- The combined or water-soluble tritium in the off-gas (closed circles,
Fig. 7) did not increase significantly until after the addition was com-
pleted and then rose to V1750 pCi/cm® before decreasing in an irregular
manner. Again, due to the scatter in the data, no quantitative evaluation
of results of the combined tritium in the off-gas was attempted.

Based on the results from experiment Tl it was apparent that the
sampling frequency in later experiments would have to be increased, espe-
cially for the 24—36 hr following the addition, to reduce the scatter and
uncertainty associated with some of the results in order to permit a mean-

ingful evaluation of the experiment.

4.2 Experiment T2

3 of hydrogen at V1100 ppm tri-

In experiment T2 approximately 34.3 cm
tium concentration was added to the CSTF for 10.4 hr. Thus, about 97 mCi
of tritium was added to the system at a rate of V9.3 mCi/hr. The indicated

tritium concentrations prior to the addition were:

1. Tritium in the salt: 1.0 nCi/g
2. Tritium in the off-gas, elemental: 1.0 pCi/cm?®
3. Tritium in the off-gas, water-soluble: 50 pCi/cm?

Samples of the salt and off-gas were taken during the addition'period and
the following 16 days. Again, no baseline corrections were applied to the
data for experiment T2 (Fig. 8).

The tritium concentration in the salt (open circles, Fig. 8) rose to
a maximum concentration of V70 nCi/g at the end of the addition and de-
creased with an apparent half-life of 12 hr. Assuming that the 1l2-hr
half-1life completely describes the processes for removal from the salt, a
trapping efficiency of 507 was calculated. The sample results of the salt
suggest possibly other mechanisms with longer time constants are present.
However, because of scatter in the data at longer times, they were not
extracted. Consequently, a single first-order process with the 12-hr half-
life was used to describe both the removal of tritium from the salt and the

initial buildup. If the longer time constant or constants could be
TRITIUM CONCENTRATION (nCi/g or pCi/cm>)

23

ORNL-DWG 75-12896

 

T TTHI

n
I

T

o SALT (nCi/g)
e OFF-GAS, WATER SOLUBLE (pCi/m?®)
A OFF-GAS, ELEMENTAL (pCi/cm®)

[ LT

I

 

T T

.

 

l

w

B
-

L LT

l

 

3

w

| TTTH

no

e—1 RITIUM ADDITION

| 1

I

 

B
o

 

w\

| T

nN
I

-

[ 1L

 

S

I

o

L

l

 

10

B

T T

 

 

 

 

»
p

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

| 19111

 

 

7 ARIIIIIMIITIHIHIHTITHTH;HHNh

Fig. 8.

7 9 i1 13 15 17 19 21

DATE, AUGUST, 1975

Observed tritium concentrations in CSTF, experiment T2.
24

extracted, the half-life for the short-term process would be less than 12
hr. However, neglecting the longer time constant and using only the 12-hr
half-life provide a reasonable basis for calculating the expected rate of
tritium buildup in the salt. The comparison of calculated and observed
inventories of tritium in the salt (Fig. 9) as functions of time during
the addition period illustrate reasonable agreement. Improved agreement
would be expected if additional time constants were factored into the cal-

culation.

ORNL-DWG 76-5254

 

     
 

CALCULATED

 

e OBSERVED

35 ! I ]j—l
|

r
25 ——— —4 —- l
| |

20 st T

 

 

 

INVENTORY OF TRITIUM N SALT (mCi}

 

 

 

 

 

 

 

-
0 i 2 3 4 5 6 7 8 9 10
TIME AFTER START OF ADDITION (hr}

 

Fig. 9. Buildup of tritium concentration in salt, experiment T2.

The maximum concentration of elemental tritium (closed triangles, Fig.
8) in the off-gas was significantly lower than in the first experiment —
40 vs 830 pCi/cm3. A possible explanation for the marked difference between
the two experiments was presented earlier in the discussion of experiment
Tl. Again assuming reasonable gas-stripping parameters for the CSTF pump,
a concentration of dissolved elemental tritium in the salt was inferred.
The ratio of combined tritium in the salt to elemental tritium in the
salt was then determined to be 530.

The combined tritium concentration (closed circles, Fig. 8) in the
off-gas increased rapidly during the addition and reached a maximum value
of 13,100 pCi/cm?® at the end of the addition. The ratio of the concentra-
tion of combined tritium in the off-gas to that of the elemental form was
substantially greater in the second experiment than in the first. The

initial decrease in concentration has an apparent half-life of 18 hr, but
25

the data again suggest the presence of other time constants. An attempt
was made to separate the time constants by assuming that the decay curve
was made up of two simple, first~order exponentials. This led to apparent
half-lives of 9.3 and 37 hr for the two processes. Numerical integration
of the water~soluble tritium data over 240 hr from the start of the addi-
tion yielded a total flow of 58 mCi through the off-gas line during the
removal period and 7.5 mCi during the addition period. Thus, a total of
65.5 mCi or about 65% of the tritium added is accounted for as combined
tritium in the off-gas stream during this test. (Numerical integration of
the elemental off-gas data showed than an insignificant amount of tritium
in this form had appeared in the off-gas system.) Calculations revealed
that only V50 mCi of tritium had been released from the salt in the com-
bined form. Thus, more tritium appeared in the off-gas system as combined
tritium than could be accounted for through release from the salt. This
discrepancy could conceivably be explained by a few apparently high off-gas
sample results used in evaluating the integrated tritium off-gas flow.
However, the magnitude of the discrepancy and evidence of long time con-
stants for removal from the salt suggest that some of the tritium added
accumulated in a reservoir other than the salt. The metal walls of the
loop could possibly retain a portion of the remaining 35% unaccounted for.
However, once the addition is stopped it would be expected that the removal
of tritium dissolved in the metal walls would be as rapid as the build-up
in the walls. Such was not the case as was observed, thus indicating a

reservoir aside from the salt and metal walls.
4.3 Experiment T3

In experiment T3 approximately 30.5 cm® of hydrogen at "v615 ppm tri-
tium concentration was added to the CSTF for 9.9 hr. As a result, about
49 mCi of tritium was added to the system at a rate of 4.9 mCi/hr. Samples
of the salt and off-gas before the addition indicated tritium concentra-

tions were:

1. Tritium in the salt: 1.6 nCi/g
2. Tritium in the off-gas, elemental: 0.4 pCi/cm3

3. Tritium in the off-gas, water-soluble: 38 pCi/cm3
26

These concentrations are comparable to those obtained at the end of both
the first and second experiments. Results from this third experiment (Fig.
10), which lasted for 24 days, again are presented uncorrected for any

baseline concentrations.

CRNL-DWG 76-5256

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

1
oL B
Hel g o SALT (nCi/g) 3
H | | OFF-GAS, WATER SOLUBLE .
N e (pCi/em®) ’
- N a OFF-GAS, ELEMENTAL (pCi /o)
N
E 10° H s | s
< _:.E | oo i f 3
o N\ | =]
SN I I -
:' —S . ' . i | t :
3 \\\ i . - ] .. . i :
2 .
€ 102 1N TRITIUM ADDITION - + -
- :Q‘/ i e ‘o8 3
= N . o
o 3 | L e . |® .
E _fi‘ | | * -
= 1 i { —
Z ) 1
§ 10! P ‘E"
o H&| ad 3
© :Q " 3
2 N 441 d, J
= N %R g °
= L @ o ]
I ol
0 LR “ olowlal 1%l o
10 E§ T A . = Ta —
2 ° % - ° =
_4% 0. Y & f &
R L —
N ° i
R ‘
41N 1
10-! LB
6 18 20 22 24 26 28 30‘ 2 4 6 8
SEPTEMBER OCTOBER
DATE, 4975

Fig. 10. Observed tritium concentrations in CSTF, experiment T3.

The tritium concentration in the salt peaked at 40 nCi/g at the end
of the addition period and decreased in a manner similar to that observed
in the previous two tests. If two first-order processes for removal of
tritium from the salt are assumed, the apparent half-lives for the processes
are 8.7 and 108 hr respectively. The tritium trapping efficiency of the
salt determined by the time constants associated with the two half-lives
was 55%. Recalling that the trapping efficiencies of experiments Tl and
T2 were 60% and 50%, respectively, the trapping efficiencies then for the
three experiments are reasonably consistent.

Using the 8.7- and 108-hr values for the half-lives, the same compari-
son as was made in experiment T2 was made between the calculated and ob-

served inventories of tritium in the salt as functions of time during the
27

addition period (Fig. 11). Extracting a second half-life for removal from
the salt as was done here in experiment T3 provides a somewhat better de-
scription of the buildup in the salt than using only one half-1ife for
describing the buildup in the salt as was done in experiment T2.

Elemental tritium in the off-gas reached a maximum concentration of
30 pCi/cm3, which was significantly higher than in experiment T2 relative
to the tritium concentration in the salt. The elemental tritium concen-
tration in the salt, which is inferred from the elemental tritium concen-
tration in the off-gas, led to a combined/elemental tritium ratio in the

salt of 380.

ORNL—DWG 76—-5255

 

] 1

20

 

 

 

 

 

— CALCULATED

OBSERVED
ofreme L
"

 

 

 

0 pb———F—— —1-

e - [ N, . [N [V U N — e — PR
5 / }
1
— |
5

0 1 2 3 4 6 7 8 9 10
TIME AFTER START OF ADDITION (hr)

 

 

 

 

 

 

INVENTORY OF TRITIUM IN SALT (mCi)

 

 

 

 

 

Fig. 11. Buildup of tritium concentration in salt, experiment T3.

The combined tritium concentration in the off-gas system at the end
of the addition was 710,200 pCi/cma. (A slightly larger value was recorded
the day after the completion of the addition, but it was believed to be
anomalously high.) This result also was significantly higher in relation
to the tritium concentration in the salt than in the second test. The time
behavior of the concentration of tritium in the off-gas was examined even
though there was a substantial amount of scatter in the data. As in the
second test, two first-order time constants were apparent. The half-life
of the more rapid process ranged from 7-15 hr, while the half-life for the
longer process was about 70 hr.

A similar treatment of this data as was done in the second experiment
indicated that after 150 hr from the start of the addition of experiment

T3, about 25 mCi of tritium had been removed from the salt and that about
28

37 mCi of tritium had passed through the off-gas line. As in the second
experiment, more combined tritium was appearing in the off-gas system than
was being removed from the salt.

Measurements of the tritium concentration in the exhaust air from the
loop enclosure of the CSTF were made shortly after the end of the addition
period in an attempt to determine the rate of tritium permeation through
the loop walls. These measurements were invalidated by simultaneous opera-
tions to dispose of excess tritium from the addition station by venting to
the loop enclosure at the end of the third addition. When the loop sample
results had reached previous baseline values, the loop sampling frequency
was reduced and several tests were made to develop a method for determining
the rate of permeation of tritium through the loop walls. Tritium was
added to the loop enclosure and to one of the cooling shrouds on the loop
piping while samples of the ventilation air were analyzed for tritium con-
tent. These tests led to the use of an air-sample tap in the discharge
line from one of the coolers and to modification of the cooler inlets to
supply fresh air (instead of air from within the enclosure) to that cooler.
The results indicated that the tritium concentration in the air leaving the
cooler would be readily and accurately measurable if anticipated loop-wall
permeation rates were experienced.

Immediately after the end of the third tritium addition, some prelim-
inary data were obtained to determine if the addition tube (or a similar
device immersed in the main salt stream) could be used to measure the par-
tial pressure of elemental hydrogen in the circulating salt. The addition
tube was evacuated several times and then "'isolated'"; it was expected that
any pressure rise within the isolated tube would be due to hydrogen diffu-
sion from the salt into the tube. After each evacuation the pressure in
the tube increased at a rate roughly consistent with the expected hydrogen
partial pressure in the salt, but the pressure did not reach a steady value.
It was sfibsequently determined that stray inleakage (presumably of air) was
occurring and that the rate of inleakage was not sufficiently comnsistent
to permit the extraction of meaningful data about the hydrogen partial
pressure. However, it appeared that a sufficiently leak-tight device could

be used to measure hydrogen partial pressure. Subsequently, such a device,
29

the hydrogen partial pressure probe, was constructed and installed in the

CSTF for the steady-state experiments.

4.4 Summary of Transient Experiments Tl, T2, and T3

Table 3 summarizes the various measured parameters and analyses for
the tritium experiments T1l, T2, and T3 performed in the CSTF.

The maximum concentrations of tritium in the salt for the three experi-
ments were consistent considering the reduced addition rate for experiment
T3. The ratios of water-scluble to elemental tritium in the off-gas for
experiments T2 and T3 are comparable. Conditioning of new sample lines was
believed to have altered the distribution of the two forms in the off-gas
in experiment Tl which would also affect the ratio of combined to elemental
in the salt since the elemental concentration in the salt was inferred from
the elemental off-gas concentration. The ratios of the concentrations of
the two species in the salt for experiments T2 and T3 are of the same order,
and a larger value for Tl similar to those obtained in T2 and T3 would have
been expected if the aforementioned conditioning phenomena had not occurred.
The trapping efficiencies (60, 50, and 557%) determined for the three experi-
ments are quite consistent. The sodium fluoroborate salt demonstrated that
it could retain a substantial fraction of the tritium added.

The amount of tritium added that was not accounted for through removal
by the off-gas and accumulation in the salt is assumed to (1) have been
stored in the metal walls of the loop, (2) have diffused through the walls,
or (3) have been stored in the undefined reservoir mentioned earlier.

Thus, it was decided to perform steady-state experiments using the
cooling duct air sampling system and hydrogen partial pressure probe de-
veloped after the completion of the transient experiments to (1) define
the distribution of tritium among the various sinks, (2) attempt to com-
plete the material balance on tritium added to the system, and (3) observe
a change, if any, in trapping efficiency at steady-state conditions as

compared to transient conditions.
30

Table 3. Summary of tritium addition experiments
Tl, T2, and T3 in the CSTF

 

 

Parameter T1 T2 T3
1. Length of addition (hr) 10.8 10.4 9.9
2. Total gas added (cm®) | 33.6  34.3 30.5
3. Total tritium added (mCi) 86 97 49
4, Average tritium addition rate (mCi/hr) 7.9 9.3 4.9
5. T2 concentration in H, (ppm) 1000 1100 615
6. T2 concentration in salt at end of addi- 74 71 40

tion (nCi/g)

7. T, concentration in off-gas at end of
addition (pCi/cm?)

Water soluble 1750 13,100 10,000
Elemental 820 40 30

8. Trapping efficiency (%) 60 50 55

9. Half-life for removal of tritium from 10.5 12 ’ 8.7
salt (hr)

10. Half-life for tritium in combined form in 9 7—15
off-gas (hr)

11. Ratio of combined to elemental in salt® 50 530 380

 

a . .
See section 7 for further discussion.

5. RESULTS OF STEADY-STATE EXPERIMENT T4

Experiment T4 — the first steady-state experiment — was started on
February 3, 1976, and was completed on April 9, 1976. An attempt was made
to start this experiment on January 27, 1976, using an addition tube pres-
sure of 560 kPa (80 psia) to obtain an addition rate of 6 cm®/hr. This
attempt was discontinued when the bypass rate of tritiated hydrogen into
the vacuum guard chamber surrounding the addition probe was found to be
significantly greater than had been observed during previous tritium tests.
This bypass rate was V14 times the rate at which tritium was reaching the
circulating salt. Measurements were made of the bypass leak rate as a
function of addition-tube pressure. Based on the results of those tests,

the addition-tube pressure was adjusted to 35 kPa (5 psia) in order to
31

keep the bypass leakage at an acceptable value (1.5 cm®/hr). The tritium
concentration of the addition gas was increased to compensate for the re-
duced gas addition rate (V1.5 cm®/hr).

Prior to the attempted addition on January 27, samples from the CSTF

showed the following tritium concentrations:

tritium in the salt: <1—8 nCi/g
combined (water-soluble) tritium on off-gas: 2050 pCi/cm3
elemental tritium in off-gas: 5-17 pCi/cm3
elemental tritium in cooling-duct air: "vBackground

Those pre-test samples taken on February 3, prior to actual start of the

test, were biased by the tritium added on the January 27 attempt.

5.1 Buildup and Attainment of Steady-State Conditions

 

The tritium concentration in the salt (open circles, Fig. 12) rose
in a manner similar to the transient tests to 500 nCi/g in about 2.5 days
following the start of the addition. It then gradually increased to a
steady-state value of 600—700 nCi/g over a three week period.

Several anomalously high concentrations of tritium in the salt were
observed during February and early March 1976. The location for salt
sampling was changed from the pump bowl to the salt-monitoring vessel (SMV)
on February 27, 1976, to permit an examination of the effects of sampling
procedure on the salt-sample results. The design of the SMV eliminates any
material that may tend to collect on the salt surface (and accumulate tri-
tium), so that "bucket' samples were taken and compared with "filter-stick"
samples which involve cover-gas flow through the sampling device. The
bucket samples from the SMV (both single and double) indicated tritium of
concentrations of 600 nCi/g *5% in the salt. Filter-stick samples taken
from the SMV utilizing the same sample method employed in the pump bowl
indicated tritium concentrations comparable to those obtained in the pump
bowl, along with several high results. Consequently, the method using the
filter stick was modified on March 16, 1976, to eliminate possible contam-

ination of the samples by material in the gas lines connected to the filter

 

*
No detectable radioactivity by comparison with blank sample.
TRITIUM CONCENTRATION

103

10

1.0

O.1

ORNL-DWG 76-13055

 

 

 

 

 

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[ {I; LOOP OFF-GAS (nC|/cm } ¢ COMBINED, ELEMENTAL : I o S ]

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= | XX * % *xi**‘*;;x’*"“”‘“&&iifl‘* X 5 i o =
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- ! ! % X X X
- : | %

Clh A 1 : 1
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= L8t ® & COOLING DUCT AIR (pCi /em3) i | a:xE
— 4 &y a a A | a L
- PA A A A A o A -% A @ a ., _]
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FEBRUARY MARCH APRIL
DATE, 1976
Fig. 12. Observed tritium concentrations in CSTF, experiment T4. |

c€
33

stick. The amount of scatter associated with samples of the salt following
the modification of the procedure was greatly reduced.

The concentration of water—-soluble (combined) tritium (closed circles,
Fig. 12) in the off-gas increased from the pre-addition level to a value of
150 nCi/cm® in about 4 days from the start of the addition. Subsequently,
it gradually rose to a steady-state value of 190 nCi/em®. At a 33-cm®/s
(2-1liter/min) off-gas flow rate the 190 nCi/em® concentration corresponds
to 22.8 mCi/hr of tritium that was appearing in the loop off-gas system in
the water—-soluble (combined) form. An analysis of the data for combined
tritium (hydrogen) in the off-gas indicates a hydrogen partial pressure of
8.3 Pa (62 um Hg) in the gas phase, assuming ideal-gas behavior and one
atom of tritium or hydrogen per molecule of compound. If this value repre-
sents equilibrium between the liquid and gas phases, the solubility coeffi-
cient for the water-soluble hydrogen form is 1.7 X 1072% atm (molecule/cm’

—20 ogtimated for the

salt)™!. This is close to the value of 1.1 x 10
solubility of HF, which is one possible form of the water—soluble compound.
The elemental tritium concentration in the off-gas (x's, Fig. 12)

showed irregular behavior and scatter for about 1 day following the start

of the addition before increasing in an orderly fashion to a value of

N22 nCi/cm®. This irregular behavior was not entirely unexpected and may
have been due to conditioning of new piping in the off-gas system that had
been installed prior to this experiment. A somewhat similar phenomenon was
observed during the first tritium addition experiment (Tl). The concentra-
tion of elemental tritium in the off-gas subsequently decreased to a steady-
state value of V10 nCi/cm®. Thus, elemental tritium was appearing in the
loop off-gas system at a rate of 1.2 mCi/hr. The gradual decrease may have
also been related to the conditioning of surfaces.

Measurable concentrations of tritium were observed in the first sample
taken from the cooling duct air only 2 hr after the start of the experiment.
These concentrations varied from 0.2-0.8 pCi/cma. A value of 0.3 pCi/cm3
was assumed for steady—-state conditions. This was the current value at
which time the concentrations of tritium in the off-gas were presumed to

have reached steady-state concentration levels (early to mid March, 1976).

Consequently, approximately 0.3 mCi/hr of tritium was permeating the walls

of the CSTF, The apparent rate of hydrogen permeation through the loop
34

walls, based on the observed tritium concentrations in the loop cooling
duct, wés between 0.7 and 2.7 X 10”% cm3(STP)/m?+s. 1If the hydrogen partial
pressure in the salt is 0.4 Pa (discussed later in this section), this rate
requires the effective permeability of the loop piping to be between 10 and
50 times lower than that of bare metal. A reduction of this magnitude
would be consistent with the presence of an oxide film on the exterior
metal surfaces.

With an addition rate of 1.65 cm’/hr of tritiated hydrogen at 5775 ppm
tritium or 24.5 mCi/hr, the following material balance at steady-state con-

ditions was made (Table 4). Therefore, at steady-state conditions the
material balance was 997 complete. Approximately 98Z of the material that

was being added appeared in the loop off-gas system. The trapping effi-
ciency at steady-state conditions was assumed to be the ratio of the rate
at which the water-soluble tritium was appearing in the off-gas system to
the addition rate of tritium. The trapping efficiency for experiment T4

therefore was "“937.

Table 4., Steady-state material
balance for experiment T4

 

 

(mCi/hr)
Addition rate 24,5
Removal rates
Off-gas, water soluble 22.8
Off-gas, elemental 1.2
Permeation of loop walls 0.3
24.3

 

As mentioned earlier there was a significant bypass of tritiated
hydrogen into the vacuum guard chamber surrounding the addition probe dur-
ing experiment T4. Therefore, an attempt at making an overall system mate-
rial balance at steady-state conditions was made (Table 5). An addition
rate of tritium was determined from the pressure drop of tritiated hydrogen
in the tritium transfer (supply) cylinder. There were several removal rate

terms associated with the addition system besides losses through the off-
35

Table 5. ©Overall system material balance at
steady-state for experiment T4

 

 

(mCi/hr)
Addition rate — as determined by pressure drop of 42.0
tritiated hydrogen in tritium transfer cylinder
Removal rates
1. Off-gas
Water-soluble (combined) 22.8
Elemental 1.2
2. Permeation of loop walls 0.3
3. Average removal rate for taking samples of the 2.4
addition gas to determine the tritium concen-
tration
4. Bypass rate into vacuum guard chamber surrounding 12.0
the addition tube
5. Loss by permeation through walls of hydrogen 3.0
purifier _—
41.7

 

gas system and loop walls. Again, a material balance of 997 at steady-state
conditions was determined.

In Table 6 are presented those hydrogen partial pressure probe measure-
ments which were considered representative during experiment T4. The higher
readings during the earlier part of the experiment were probably the result
of extraneous hydrogen introduced into the loop when installing the probe.

A value of V0.4 Pa (3 um Hg) for total hydrogen partial pressure was con-
sistent once the steady-state conditions were attained. This partial pres-—
sure of total hydrogen may be converted to a concentration of dissolved
elemental tritium in the salt using a Henry's Law Constant for hydrogen
dissolved in sodium fluoroborate and knowing the concentration ratio of
tritium to hydrogen. The ratio of the concentration of the combined tri-

tium in the salt to the concentration of elemental tritium in the salt at

steady state was about 4300, based on a 650—nCi/g concentration of combined

tritium in the salt and the 0.4 Pa partial pressure of total hydrogen.
36

Those measurements following March 12, 1976, were biased when extra-
neous hydrogen was introduced into the probe when a helium leak detector
was used in an attempt to measure the flow rate of mass 4 species — presum-
ably the same mass as an HT molecule formed once the hydrogen atoms and
tritium atoms had permeated the walls of the probe. (See Section 6.1 and
6.4 for further discussion of the helium leak detector.) The helium leak
detector measurements were intended to serve as a check on the partial

pressure probe readings, but no conclusive results were obtained.

Table 6. Representative hydrogen partial
pressure probe measurements for
experiment T4

 

H, partial pressure

 

 

Date
Pa Um Hg
February 710 0.7 5
1013 0.7 5
13-17 0.5 4
1720 0.5 4
2024 0.4 3
2427 0.4 3
February 27 — March 1 0.4 3
5—9 0.4 3
812 0.4 3

 

Assuming a half-power dependence on pressure and the same tritium to
hydrogen ratio as was present in the addition gas, an inventory of 0.5 Ci
of tritium was stored in the metal walls of the CSTF at steady-state con-
ditions based on the 0.4-Pa partial pressure of hydrogen. Using these
same assumptions and 0.4 Pa partial pressure, the observed permeation rate
through the metal walls indicated a reduction in metal wall permeability

by a factor of 30 from reference values.
37

5.2 Change in Off-Gas Flow Rate

 

Once steady-~state conditions were established, tests were conducted to
obtain data on gas-liquid equilibria in the pump bowl. If equilibrium con-
ditions had existed, decreasing the flow rate of gas in the off-gas system
would have resulted in increased concentrations of both the combined and
elemental forms of tritium in the salt and off-gas. Conversely, increasing
the flow rate of gas in the off-gas system would have decreased the concen-
trations. If conditions in the pump bowl were mass-transfer limited on the
gas side of the gas—liquid interface, changing the flow rate of gas through
the pump bowl would cause different concentration changes. Similarly, if
the mass-transfer limit were on the salt side of the interface, changes in
salt flow would provide data on the nature of the limitation. On March 23,
the flow rate of gas was lowered by a factor of 2, to 17 em®/s (1 liter/
min). The concentrations of combined tritium in the salt and off-gas in-
creased to about 1350 nCi/g and 340 nCi/cm?, respectively. Changes in the
elemental concentrations in the off-gas system and cooling duct air would
be expected to occur less rapidly because of dissolution of element tritium
in the loop piping. Concentrations of elemental tritium in the cooling-
duct air increased to 0.4—0.5 pCi/cm® compared to 0.2—0.3 pCi/cm?® concen-
trations prior to the change of off-gas flow rate. The concentration of
elemental tritium in the off-gas was perturbed by a valve replacement in
the gas-sampling system shortly bhefore the gas flow was changed. Conse-
quently, the effect of this flow rate change on the concentration of ele-
mental tritium in the off-gas is not well defined. The elemental tritium
concentration in the off-gas still, however, leveled out at about 16 nCi/
em?. Thus, the various concentrations increased approximately a factor of
2 as would have been expected if equilibrium conditions existed. The tri-
tium material balance on the system was reasonably complete, but true
steady~-state concentrations were not established with the reduced flow rate
of purge gas.

When the purge-gas flow rate was increased to 68 cm’/s (4 liters/min)

on March 30, the concentrations of tritium in the off-gas decreased by more

than the expected factor of 2 from the original steady-state condition.

With the higher flow rate of purge gas the tritium material balance on the
38

system was only about 50% complete. This suggests that, at the 68~cm?®/s
purge-gas flow rate, the gas stripping efficiency in the pump bowl is
substantially reduced. The results also suggest that additional hydrogen
(tritium) stripping may have been occurring as the purge gas flowed through

the salt-monitoring vessel (SMV).
5.3 Stripping Period

After the addition of tritium to the CSTF was stopped, sampling was
continued for only 24 hr into the stripping portion of the experiment so as
to have ample time to prepare énd conduct another steady-state experiment
before having to shut the loop down. The initial half-lives for removal

during this period as indicated by the sample results were:

11.8 hr for the water-soluble (combined) form in the salt,
7.5 hr for the water-soluble (combined) form in the off-gas, and

12.3 hr for the elemental form in the off-gas.

The values for the water-soluble form in the salt and off-gas were con-
sistent with the values obtained for the transient experiments (Table 3).
No values for removal of elemental tritium were extracted from the data of

the transient experiments.

5.4 Tests for Tritium Concentration in Addition Gas

Tests were conducted after shutdown of the loop to independently mea-
sure the tritium concentration in the addition gas used in experiment T4
for comparison with results obtained from mass spectrometer analyses. The
sampling system used for measuring tritium concentrations in the cooling-
air duct was utilized for these tests. From mass spectrometer analyses of
14 samples of the addition gas taken during experiment T4, the average
concentration of tritium in hydrogen in the addition gas was 5775 ppm.

The average tritium concentration in 5 samples taken throught the cooling-

air sampler was 5785 ppm,
6. RESULTS OF STEADY-STATE EXPERIMENT T5

" Experiment T5 — the second steady-state experiment — was started on

May 4, 1976, and was completed on June 30, 1976. (Sampling of the loop
39

off-gas was continued from July 1 — July 9, 1976, while helium was being
circulated in the loop to reduce the level of radioactivity in the CSTF

in preparation for the decommissioning of the loop.) The basic plan for
T5 was to establish steady-state conditions and then make chemical addi-
tions to the salt to determine any resulting effect on tritium behavior.

After the completion of experiment T4, a new addition probe was in-
stalled to replace the original probe, which had developed a large leak
between the addition gas chamber and the vécuum guard chamber. The new
addition probe was essentially identical to the original one with respect
to the material and geometry of the parts exposed to the circulating salt.
The two tubes differed in that the new tube did not have corrosion speci-
mens attached to the upstream face and the internal design was modified to
reduce the potential for leakage to the vacuum guard chamber.

Results from experiment T4 indicated about 937 of the tritium added
to the system at steady-~state conditions was trapped in the salt and
appeared in the off-gas system in the combined form. Since such a large
fraction of the total amount of tritium was present in the combined form,
any change imposed on the system to enhance the trapping capability of
the salt might be difficult to monitor by observing the combined concen-

‘trations in the salt and off-gas. Also, with such a relatively low par-
tial pressure of dissolved elemental hydrogen (tritium) in the salt in
experiment T4, an increase in trapping efficiency might lower the partial
pressure below the limits of the measurement capability with the present
setup of the partial pressure probe.

The addition rate of total hydrogen for experiment TS5 was to be com-
parable to the addition rate for experiment T4 but with an increase in
tritium concentration in the addition gas by a factor of "“3. The objec-
tive was to increase the tritium concentration in the loop cooling air,
which would provide a wider range of sensitivity to possible changes in
the rate of tritium permeation through the loop walls that might result
from any increase in trapping efficiency due to chemical additions to the
salt. Also, a helium leak detector was to be connected to the partial
pressure probe to measure the flow rate of tritium through the probe.
Elemental tritium permeating the walls of the probe would be expected to

form HT molecules (of mass 4) and produce a signal on the helium leak
40

detector. The partial pressure probe could be used in this manner should
the partial pressure of total hydrogen fall below the limits of the mea-
surement capability with the original setup.

The tritium concentrations in the system prior to the start of the
addition for this experiment had not reached baseline values because only
a minimal amount of time was involved in the stripping portion of experi-
ment T4 (V1 day) and startup of the loop (V5 days) in preparation for ex-
periment T5. However, the tritium concentration levels were judged to be
low enough (Vv10% of steady-state values obtained in experiment T4) to start

experiment T5.
6.1 Buildup and Attainment of Steady-State Conditions

The tritium concentration in the salt (open circles, Fig. 13) rose
rapidly for about 2.5 days following the start of the addition and at-
tained an apparent steady-state concentration of approximately 2000 nCi/g.
This concentration level was very consistent for V3 weeks as no anoma-
lously high or low concentrations were recorded. The steady-state tri-
tium concentration in the salt for experiment T4 was about 650 nCi/g,
suggesting that T5 was much like T4 except for a factor of 3 in the con-
centration of addition gas.

The water-soluble (closed circles, Fig. 13) and elemental (x's,

Fig. 13) forms of tritium in the off-gas increased rapidly for 2—3 days

following the start of the addition and then approached their respective

steady-state values more slowly. From May 10 through May 19, difficulties
were encountered in obtaining meaningful off-gas sample results due to
problems with a valve in the off-gas sampling system. On May 19, 1976,
the valve was replaced and a conditioning period of V2 days followed be-
fore the tritium concentrations in the off-gas became consistent. This
conditioning of new metal in the off-gas system also had occurred in ex-
periments Tl and T4 previously when new lines or valves were installed.
The apparent steady-state concentrations of tritium in the off-gas prior

3 for the water-soluble and

to the NaBO; addition were 655 and 20 nCi/cm
elemental forms, respectively.
Representative samples of the air from the loop cooling duct (tri-

angles, Fig. 13) were not obtained until a week after the start of the
TRITIUM CONCENTRATION

104

103

102

10

1.0

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| | { ) —_
— !COOLING DUCT AR (pCi/em3) 1 & | ha £ «: a
I i ! | spb Ba
i I | |
| | | | ! A % A ! ]
A
1:|1||_||iL1£11iHLLHIHI!I 14HIHHLIIIHUHII Illllll!flifl'lll‘[][llli[lul_
{ 5 10 15 20 25 311 9 14 19 24 301 4 9
MAY JUNE JULY
DATE, 1976
Fig. 13. Observed tritium concentrations in CSTF, experiment T5.

T4
42

tritium addition. The system had been contaminated from the tests con-
ducted to determine the tritium concentration in the addition gas after

the completion of experiment T4. After correction of this condition, the
tritium concentrations varied from 0.7—1.2 pCi/cm’®. A value of 1.0 pCi/cm’

was assumed for steady-state conditions.

Table 7. Steady-state material
balance for experiment T5

 

 

(mCi/hr)
Addition rate 83.0
Removal rates
Off-gas, water soluble 78.6
Off~gas, elemental 2.4
Permeation of loop walls 1.0
82.0

 

Prior to the start of experiment T5 the new addition probe was in-
stalled in the CSTF. The bypass rate of tritiated hydrogen into the
vacuum guard chamber for experiment T5 was neglible whereas in experiment
T4 with the original probe the bypass rate was significant, thus com-
plicating the calculation of the addition rate of gas to the salt. Based
on an addition rate of 1.68 cm®/hr of hydrogen at 19,000 ppm tritium or
83_mCi/hr, the material balance for experiment T5 at steady-state condi-
tioné is as presented in Table 7. At steady-state conditions the material
balance for experiment T5 was 99% complete as in experiment T4, Approxi-
mately 987 of the tritium that was being added appeared in the off-gas
system as in experiment T4. The trapping efficiency for experiment T5 was
95% as compared to 937% for experiment T4. The rate at which elemental
tritium appeared in the off-gas was 2% lower in experiment T5 than in ex-
periment T4. This 2% of tritium appeared as combined tritium in experi-
ment T5 since the percentage of tritium permeating the loop walls was the
same (1.2%) for both steady-state experiments.

The difference in trapping efficiencies for the two steady-state ex-

periments could be the result of the limitation of measurement capabilities
43

of the sampling systems since such a large fraction of the tritium added
appeared in the off-gas system in the water-soluble (combined) form.
However, examining the ratio of the concentrations of water-soluble tritium
in the off-gas to elemental tritium in the off-gas over the duration of

the two experiments seems to indicate that some equilibrium distribution
between the two forms was being approached. During the early part of
experiment T4 the ratio of the two species (water soluble/elemental) was
V10 and increased eventually to V20 prior to the change in off-gas flow
rate (Fig. 11). In experiment T5, once steady-state conditions were estab-
lished, the ratio further increased to 30. Conceivably, in the early
phases of the experiment a small amount of tritium being released from the
salt in the water-soluble form was reacting in the off-gas system to liber-
ate the elemental tritium. As equilibrium conditions in the off-gas system
were approached, the distribution or ratio of the two forms in the off-gas
system was approximating the actual ratio of the two forms as they were
released from the salt.

In Table 8 are presented those hydrogen partial pressure probe mea-
surements which were considered representative for experiment T5. From
May 10, 1976, until the addition of NaBO» to the loop where steady-state
or near steady-state conditions existed, the indicated partial pressure
of hydrogen was again 0.4 Pa (3 um Hg). The ratio of the concentration
of combined tritium in the salt (2000 nCi/g) to the dissolved elemental
tritium in the salt as determined by the 0.4-Pa partial pressure of hydro-
gen was V4270 as compared to V4300 for experiment T4.

Based on the 0.4-Pa partial pressure of hydrogen and assumptions made
for similar calculations for experiment T4 discussed in Section 5.1,
approximately 1.7 Ci of tritium was stored in the metal walls and a reduc-~
tion in metal wall permeability by a factor of V30 from reference values
was again indicated.

Those measurements taken after May 21, 1976, are somewhat questionable.
On May 24, 1976, an attempt was made to obtain a reading from the partial
pressure probe using a helium leak detector. Apparently, a leak had de-
veloped at the connection between the probe and the leak detector. Sub-
sequently measurements (those in June, 1976) with the probe showed that

the rate of pressure rise in the probe was considerably more rapid than
44

previously observed. Consequently, no results could be extracted from some
of the measurements, and those measurements during June of 1976, that are
presented in Table 8 may have been biased. Therefore, not much signifi-
cance should be attached to these partial pressure probe measurements in
connection with the chemical additions made to the salt during this same

time period.

Table 8. Representative hydrogen
partial pressure probe
measurements for
experiment T5

 

H, partial pressure

 

 

Date
Pa Mm Hg

May 5 0.5 4
6—7 0.7 5
1011 0.4 3
1214 0.4 3
17-19 0.5 4
2021 0.4 3
June 13 5
4—7 0.8 6
1112 0.7 5
1516 0.7 5
1718 0.5 4

 

6.2 NaBQ, Addition to CSTF

 

A total of 120 g of sodium metaborate (NaBO,) was added to the CSTF
on May 26, 1976. The purpose of this addition was to increase the free
oxide (total amount of oxide less that bound as hydroxide) content of the
salt by about 100 ppm and to determine any effect on the trapping effi-
ciency of the salt since oxide species in the salt were believed to be
involved with the trapping process. The free oxide content of the salt
prior to the NaBO,; addition was between 410 and 450 ppm. Chemical analyses

of the salt after the NaBO, addition showed a free oxide concentration of
45

V570 ppm. (The hydroxide concentrations for these samples were in the
few-ppm range such that the free oxide concentration was representative

of the total oxide concentration also.)

The tritium concentration in the salt increased from a preaddition
level of 2000 nCi/g to about 2200~2300 nCi/g. The tritium concentration
subsequently leveled out at about 2500 nCi/g and maintained this level
until the addition was stopped, being interrupted only by the transient
effects of the B;03; addition. The concentrations of both forms of tritium
in the off-gas decreased after the addition. No noticeable change from
preaddition levels occured in the tritium concentrations in the cooling
duct air immediately after the addition was made. The establishment of
the new, increased steady-state concentration of tritium in the salt with
respect to the tritium concentrations in the off-gas indicate an improve-
ment in the trapping capability of the salt. The off-gas concentrations

returned to their preaddition steady-state levels V2 days later.

During the period of time after the NaBU, addition and before the
B203; addition, changes in tritium concentrations in the system occurred.
These changes may or may not have been associated with the NaBO, addition.
However, the cause or causes of these changes could not be conclusively
identified and were not investigated further because of time limitations

associated with the MSR program.

The tritium concentration in the salt increased from V2200 to 2500
nCi/g abbut June 1, 1976. The elemental tritium concentration in the
off-gas on June 4, 1976, decreased and subsequently increased to a con-
centration V1.5 times higher than the 20-nCi/cm® concentration observed
at steady-state conditions and after the NaBO; addition. The behavior
of the cooling duct air samples was not consistent with the behavior of
the elemental tritium in the off-gas system as might have been antici-
pated since the tritium in the cooling duct air was also elemental in form.
This implies that the behavior of elemental tritium in the off-gas system
was not necessarily indicative of the behavior of elemental tritium else-

where in the loop.
46

6.3 By03 Addition to CSTF

 

On June 10, 1976, 55 g of boron oxide (B»03) was added to the CSTF.
The purpose of the B,03 addition was to further increase the oxide level
of the salt. Also, the B,03; was not completely anhydrous and, as a result,
a small amount of water was added with the B,03. The oxide level of the
salt after the B203 addition was V710 ppm compared to 570 ppm before the
B;,03 addition.

The tritium concentration in the salt increased from 2500 to 4000
nCi/g immediately after the B,0; addition. The water-soluble tritium in
the off-gas increased (from V600 to 1000 nCi/cm®) in a similar manner as
the salt did, while after the NaBO, addition it decreased. The elemental

tritium concentration in the off-gas decreased (from 30 to V15 nCi/cms)

immediately after the B;03 addition, as it had done after the NaBO, addi-

tion. (Apparently, the B,0; addition interrupted the establishment of

a new concentration level of elemental tritium in the off-gas which had
begun just before the B»03 addition.) The tritium concentrations in the
cooling duct air increased from 0.7 to 1.0 pCi/cm3 after the B,03; addi-
tion. The magnitude of the transient effect associated with the B;03
addition was greater than that resulting from the NaBO; addition. Some
34 days were required for the concentrations to return to their pre-B;0;
addition levels.

The inventory of tritium in the salt before the B,03; addition asso-
ciated with the 2000 nCi/g concentration was "1 Ci of tritium, and cor-
respondingly for the 4000 nCi/g concentration resulting after the addition
of B»03; the inventory of tritium in the salt was 2 Ci. The addition rate
for experiment T5 was only 83 mCi/hr. In order to compensate for such
a rapid increase in the inventory of tritium in the salt (and ultimately
increased concentration in the water-soluble form in the off-gas), the
B203 and water addition must have brought about the release of elemental
tritium from another reservoir, making more tritium available for trapping

by the salt.

The inventory of dissolved elemental tritium stored in the metal
walls of the loop piping would have been enough to account for the ob-
served increase in tritium inventory in the salt. Approximately 1.7 Ci

of tritium (as noted in Section 6.1) could have been stored in the metal
47

of the loop piping. However, for the metal walls to act as such a reser-
voir would require a significant decrease in the partial pressure of total
hydrogen in the salt such that hydrogen (tritium) dissolved at a higher
partial pressufe in the metal walls would have diffused from the walls
into the salt. No such decrease of partial pressure of total hydrogen
in the salt was observed from the partial pressure probe measurements.
Also, no decrease in the tritium concentration in the cooling duct air
samples was noted which would be expected to accompany a decrease in the
total hydrogen partial pressure — the driving force for hydrogen (tritium)
transport through the loop walls. (This undefined reservoir is discussed
further in Section 7.)

The decrease in the elemental tritium concentration in the off-gas
indicates an apparent increase in the trapping capability of the salt as
a result of the Bo03 addition. The water-soluble concentration of tritium
in the off-gas would have been expected to decrease as a result of increased
trapping efficiency as was observed after the NaBO, addition. However, the
resulting increases in the concentrations of tritium in the off-gas and
in the salt obscured any change in trapping efficiency that may have been

discernible by observing these two tritium concentrations.

6.4 Helium Leak Detector Measurements

The helium leak detector, as mentioned earlier, was connected to the

hydrogen partial pressure probe for flow rate measurements of mass 4

species — presumably the mass of an HT molecule after hydrogen and tritium
atoms permeated the walls of the probe. The helium leak detector was to
provide a check on the hydrogen partial pressure probe readings. Based

on the rate of pressure rise observed from the partial pressure probe
readings, a flow rate of HT molecules was determined (assuming each tritium
atom permeating the walls of the partial pressure probe combined with a
hydrogen atom) to compare with the helium leak detector reading. The helium
leak detector was also to provide an alternate method for determining the
partial pressure of hydrogen in the event the chemical additions lowered

the partial pressure of elemental hydrogen below the limits of the probe.

This was not the case, however, as significant partial pressures of total

hydrogen were observed after the two chemical additions (Table 8, p. 44).
48

Some difficulty was encountered initially in obtaining a reading on
the helium leak detector. Finally, after increasing the sensitivity of
the machine, two representative readings were obtained.

On June 7, 1976, a flow rate of 5.0 x 107!% cm®/s of mass 4 species
was recorded with the helium leak detector. Based on the hydrogen partial
pressure probe measurement for the three days preceding this helium leak
detector reading, a flow rate of 6.0 X 10710 cm3/s was calculated. Simi-
larly, on June 18, 1976, a helium leak detector reading of 2.2 X 10710

3 determined

cm®/s compared favorably with a flow rate of 4.0 x 107!% cm
from the probe measurement made during June 14—16, 1976.
Thus, the probe appeared to be a reliable measure of hydrogen partial
pressure in the loop. Even though the partial pressure of total hydrogen
may have been artificially high at the time the measurements with the two
devices were made (due to a leak in the connection between the helium leak
detector and hydrogen partial probe discussed earlier in Section 6.3), the
agreement obtained with the measurements by the two devices serves to sub-

stantiate the 0.4-Pa (3 um Hg) total hydrogen partial pressure obtained

at steady-state conditions during experiments T4 and T5.

6.5 Extraneous Source of Hydrogen in Off-Gas System

After the early failure of the helium leak detector to measure the
anticipated flow rate of HT molecules, a decision was made to determine the
concentration of hydrogen in helium in the off-gas in the event that an
extraneous source of hydrogen was present. By increasing the sensitivity
of the helium leak detector, reasonable measurements were obtained; but
the results from mass spectrometer analysis of the off-gas showed that
there was V30 ppm elemental hydrogen in helium. Assuming an elemental
tritium concentration in the off-gas system of 20 nCi/cm?® and 19,000 ppm
tritium in hydrogen from analysis of the addition gas, the elemental
hydrogen concentration in helium should have been only 0.4 ppm or a fac-
tor of 75 less than that.observed. The extraneous hydrogen could have
been supplied from the decomposition of o0il vapors resulting from an
0oil leak from the pump of the CSTF. A leak of only 0.1 cm®/day of oil
could account for enough hydrogen to increase the hydrogen concentration

in helium from 0.4 to 30 ppm.
49

This extraneous source of hydrogen could explain some of the peculiar
behavior observed in the samples of the off-gas and the gradual increase
in ratio between the water-soluble and elemental forms of tritium in the
off-gas noted during experiments T4 and T5. The extraneous hydrogen could
have been exchanged with some of the tritium in the water-soluble form in
the off-gas system. As equilibrium conditions in the off-gas system were
established, a more representative value for the distribution between the
two forms was being approached.

If extraneous hydrogen were present in the loop, the measurement of
the flow rate of HT molecules with the helium leak detector would have been
significantly lower (due to the diluent effect of the extraneous hydrogen)
than that predicted by calculations using the partial pressure probe mea-
surements, which were based on a tritium to hydrogen ratio assumed to be

the same as that of the addition gas. Since reasonable agreement was ob-

tained from measurements using the hydrogen partial pressure probe and the
helium leak detector, the indication is that if the extraneous hydrogen
was present in the off-gas system, the behavior observed in the off-gas
and pump bowl was not necessarily representative of behavior in the rest
of the loop.

However, assume the extraneous hydrogen were present in the rest of
the loop. Consider the potential effects on three of the parameters,
separately, discussed thus far: (1) The amount of tritium permeating the
loop walls of the CSTF would be greater if the extraneous hydrogen were
not present. The partial pressure of total hydrogen in the salt would be
lower by a factor of V100 (a factor of 100 is used here for discussion
purposes rather than the apparent factor of 75 mentioned earlier). As-
suming a half-power dependence on pressure for permeation of the metal
walls, the total hydrogen (and hence tritium) diffusing through the metal
walls of the system then would be decreased only by a factor of 10. But,
the tritium concentration in the hydrogen passing through the walls of
the loop would be increased by a factor of 100. The net result would be
an increase by a factor of 10 in tritium permeating the metal walls of the
CSTF. (2) The trapping efficiency of the salt could be expected to be
higher than noted in experiments T4 and T5 if the extraneous hydrogen were
not present. Since both forms of hydrogen (tritium and protium) are pre-

sumed to behave similarly, an increase in tritium concentration in the total
50

hydrogen available for trapping by the salt would result in an improved
trapping efficiency. (3) The ratio of the chemically combined tritium'in
the salt to elemental tritium dissolved in the salt would be greater than
observed if the additional hydrogen were not present. The partial pressure
of total hydrogen in the salt would be less and hence the elemental tritium
concentration in the salt which is derived from the total hydrogen partial
pressure would be less also, thus increasing the ratio of combined to ele-
mental forms in the salt.

Since the combined to elemental ratio was used for extrapolating to
MSBR conditions, the ratios determined for experiments T4 and T5 then
represent conservative values because they were based on the same tritium

concentration in hydrogen as that present in the addition gas.

6.6 Stripping Period

The stripping portion of experiment T5 was monitored for "9 days
following the termination of the addition of tritium before draining the
salt from the CSTF in preparation for decommissioning the loop. The data
for the salt and both forms in the off-gas were resolved in two components
as was done in experiment T3. The following half-lives were extracted from
the data: ‘

11.1 and 112 hr for the water-soluble (combined) form in the salt,

12.7 and 105 hr for the water-soluble (combined) form in the eoff-gas,

12.6 and 137 hr for the elemental form in the off-gas.

Again, the half-lives for removal for experiment T5 are comparable to
those obtained from experiments T1-T4.

During the stripping period more tritium was appearing in the off-gas
system than could have been supplied by the salt. This suggests the pres-
ence of the previously mentioned reservoir that apparently had built up an
inventory of tritium, and once the partial pressure of hydrogen (tritium)
in the salt began to decrease after the addition was stopped, the elemental
hydrogen (tritium) was transferred from the reservoirlto the salt where it
was trapped and eventually appeared in the off-gas system.

Helium was circulated in the loop after the salt was drained from the
loop on June 30, 1976, until July 9, 1976. Off-gas and cooling duct air

samples were taken during this period. The cooling duct air samples were
51

Table 9. Summary of tritium addition experiments
T4 and T5 in the CSTF

 

 

Parameter T4 T5
1. Length of experiment (days) 66 58
2. Average addition rate of gas (cm®/hr) 1.65 1.68
3. Average tritium concentration in addition 5775 19,000
gas (ppm)
4. Average tritium addition rate (mCi/hr) 24.5 83.0

5. Steady-state concentrations

Salt (nCi/g) 650 2000
Off-gas, water soluble (nCi/cm?®) 190 655
Off-gas, elemental (nCi/cm?) 10 20
Cooling duct air, elemental (pCi/cm?) 0.3 1.0
6. Trapping efficiency (%) 93 95
7. Ratio of chemically combined to elemental 4300 4270
in salt

8. Half-lives for removal (hr)

Salt 11.8 11.1; 112
Off-gas, water soluble 7.5 12.7; 105
Off-gas, elemental 12.3 12.6; 137

 

negligible and thus are not shown in Fig. 12. The water-soluble tritium
concentration in the off-gas was between 56 nCi/cm® and for the elemental

tritium concentration in the off-gas was V1.5 nCi/cm®.

7. INTERCOMPARISON AND INTERPRETATION OF EXPERIMENTAL RESULTS

Experiments T4 and T5 are summarized in Table 9. Analysis of data
from the two experiments indicate reasonable agreement and reproducibility
for such parameters as trapping efficiency, ratios of chemically combined
tritium in the salt to elemental tritium in the salt, and half-lives for
removal from the salt and off-gas. The material balance at steady-state
conditions for both experiments was essentially complete.

For both experiments approximately 3 weeks were required to obtain
steady-state conditions. Apparently, the reservoir discussed earlier re-
quired saturating before steady-state conditions could be established.

This would explain why lower trapping efficiencies were determined for the
52

transient experiments T1—-T3. The reservoir acted as another sink for the
tritium added during these short-term transient experiments. However, once
the system was at steady state as in experiments T4 and T5, a more accurate
evaluation of sodium fluoroborate's trapping efficiency could be made.
After the addition of tritium was stopped, the reservoir released tritium
to the salt, thus explaining the discrepancy between the amount of tritium
that appeared in the off-gas system as water-soluble and that released from
the salt during the stripping periods as noted in experiments T2, T3, and
T5.

It is thought that this reservoir may have been carbonaceous deposits
on the surfaces of the pump and pump tank resulting from the decomposition
of o0il. After completion of the experiments, the pump was disassembled.

A black carbon-like residue was observed on the shield plug and bearing
housing of the pump and on the volute support cylinder in the pump tank.
These and other surfaces exposed to the off-gas, when smeared, indicated
appreciable levels (1 x 10° — 1 X 107 dis/min) of tritium contamination.
The tritium was probably chemisorbed on the carbon. Those surfaces such as
the pump impeller, exposed only to the salt were free of the black film and
were not as highly contaminated with tritium.

In experiment T5, the additions of NaBO; and B,03 appeared to enhance
the trapping ability of sodium fluoroborate for a short period of time fol-
lowing the additions. The anticipated effects from the additions on the
tritium concentration in the cooling duct air and on the partial pressure
probe measurements did not materialize. However, the decrease in the ele-
mental tritium concentration in the off-gas and increase in tritium concen-
tration in the salt following the additions indicated improvement in trap-
ping efficiency.

The ratio of combined tritium in the salt to elemental in the salt of
V4300 determined for experiments T4 and T5 was the result of a more direct
measurement than those ratios obtained for the transient experiments (Table
3), which were significantly lower. The values for the transient experi-
ments were inferred from elemental off-gas concentrations. Since the re-
sults from the transient experiments after having conducted the steady-

state experiments revealed that these experiments were not completely
53

representative of the trapping effectiveness of sodium fluoroborate, the
ratios of combined tritium in the salt to elemental tritium in the salt
obtained for the steady-state experiments were used to extrapolate to MSBR

conditions.

8. EXTRAPOLATION TO MSBR CONDITIONS

Based on a value of V4000 for the combined to elemental ratio of
tritium in sodium fluoroborate observed in CSTF tritium addition experi-
ments T4 and T5, calculations were performed to examine the resulting
behavior and distribution of tritium in an MSBR assuming this same ratio
were established in the secondary salt of an MSBR. The same computer
program8 was used for this calculation as was used for earlier calcula-
tions that indicated as much as 1425 Ci/day of tritium could be trans-
ported to the steam system of an MSBR.

Presented in Table 10 are the results of the calculated distribu-

tion of tritium at steady-state conditions for the reference design9 MSBR:

Case 1. Reference case where no special preventive measures
are taken to mitigate the transport of tritium to the
reactor steam system.

Case 2. Modified case where a value of 4000 for the concentra-
tion ratio of combined to elemental tritium in the salt
was established in the reactor secondary or coolant

system.
The following conditions were assumed for both cases:

1. No sorption of HT or HF (TF) on the core graphite.
2. Reference value of 102 for the U“+/U3+ ratio in the fuel salt.

3. Bare-metal permeability for the steam tubes (no oxide film).

Furthermore, for the modified case, an 807 efficiency was assumed for re-
moval of the chemically combined form (water-soluble form in off-gas of
CSTF) on a 10% salt bypass stream (0.5 m>/s — MSBR reference value).

The distribution of tritium in the primary or fuel system for the
two cases 1s essentially the same, but in case 2 most of the tritium

entering the secondary system is removed in the secondary system purge
Table 10. Extrapolation of results from CSTF tritium experiments to MSBR conditions

Calculated distribution of tritium in an MSBRa for

Case 1. Reference case where no special preventive measures are taken to
mitigate the transport of tritium to the reactor steam system.

Case 2. Modified case where a value of V4000 for the concentration ratio
of combined to elemental tritium in the salt as determined from

CSTF tritium experiments was established in the reactor secondary
or coolant system.

 

Distribution of the 2420 Ci/day produced in an MSBR (percentages)

 

 

 

 

 

Primary system Secondary system Steam system
Case
Purge Permeation of Purge Permeation of T released
Elemental TF system piping Elemental TXb system piping % Ci/day
1 17.1 2.1 1.2 1.6 19.0 58.9 1425
2 16.4 2.1 1.2 0.004 80.1 0.05 0.16 4

 

“MSBR conditions assumed for both cases: (1) no sorption of HT of HF (TF) on core graphite;

(2) reference value of 10? for the U“+/U3 ratio in the fuel salt; (3) bare-metal permeability
for the steam tubes (no oxide films).

For case 2, an 807% efficiency for removal of chemically combined form from a 107% salt bypass
steam (0.5 m®/s) is assumed.

7¢
35

in the chemically combined form. Tritium permeating the walls of the
primary and secondary system could be processed for removal from the
atmosphere of the primary and secondary cells and thus these cells are
considered to be sinks for tritium. In case 2, representing the extrapo-
lation from results obtained from the CSTF tritium experiments to MSBR
conditions, only 0.16% (4 Ci/day) of the 2420 Ci/day of tritium produced
in an MSBR was transported to the reactor steam system compared with 1425
Ci/day of tritium reaching the reactor steam system in the reference case.
This release rate of tritium to the environment would be within the range
of release rates from pressurized-water reactors (PWRs) currently oper-
ating. The release rate of tritium for the MSBR includes the entire fuel
cycle, while that for PWRs would be about 80 Ci/day if releases associated

with fuel reprocessing were included.

9. CHEMISTRY OF TRAPPING PROCESS IN SODIUM FLUOROBORATE

Although it was not possible to specifically identify the mechanisms
and chemistry by which tritium was retained by sodium fluoroborate,

1% in the laboratory led to the postulation of several plausible

studies
reactions involving species known to exist in the salt along with hydrogen
(tritium) and dissolved metal fluoride.

The trapping process can be described through two equations which

actually are the net result of several reactions. First,

2H, + 2MF, + % Na3B3FgO3 € 3HF + M° + NaBF 30H. (1)

The equilibrium constant for this reaction is

3
. P3_ (NaBF 50H)

1 - .

(N3333F603)1/3 (MF,)? Péz

 

The above expression is not entirely representative of the system since

HF and NaBF3;0H can react according to:

HF + NaBF30H 2 H,0 + NaBF,. (2)
56

This equilibrium constant for this reaction is

K2=..__..I:I.I_g.(_)-___——-—
PHF(NaBFaoH)

NaBF, is not incorporated in the expression since it is the solvent.
Finally, the system could be represented by combining K; and K, into

the following expression:

P} (NaBF30H)?
F
1 : (3)

 

K3 = 7
(Na3B3Fg03) /% (MF2)2 P2 P

H, "H»20
Evaluation of the constant K3 would lead to a quantitative description
of the system. A more practical qualitative observation based on this
expression is that tritium trapping would be favored by relatively high
concentrations of oxide and/or metal fluoride in the salt along with a

relatively high value for the partial pressure of water.

10. FURTHER EXPERIMENTATION REQUIRED

The tritium addition experiments conducted in the CSTF demonstrated
sodium fluoroborate's effectiveness for sequestering tritium. However,
further experimentation and research would be required to yield a better
understanding of tritium behavior in sodium fluoroborate, to better define
basic parameters, and to explain some of the observed phenomena as a result
of conducting the experiments in the CSTF.

If the MSR program were to be continued, further investigation re-

lating to the following would be desirable:

1. The chemistry of sodium fluoroborate and the trapping process by
which tritium is retained by the salt,

2. Permeability wvalues for Hastelloy N.

3. Solubility data for the dissolution of elemental hydrogen (tri-

tium) in sodium fluoroborate.
57

4. Data on gas-liquid equilibria in the pump bowl in an effort to
explain behavior such as that observed in experiment T4 when, upon increas-
ing the off-gas flow rate to 4 liters/min, equilibrium conditions in the
pump bowl between the gas and liquid were altered drastically.

5. Identification of the sink that required saturating before steady-
state conditions could be established.

6. Determination of the existence of an extraneous source of hydrogen
in the off-gas system and its effect (if present) on the behavior and dis-

tribution of tritium in the CSTF.

11. CONCLUSION

Originally, this group of tritium experiments conducted in the CSTF
was to have been the first of several possible series of experiments to
examine the potential of sodium fluoroborate for limiting tritium transport
to the steam system of an MSBR. If favorable results were obtained from
these experiments, namely that sodium fluoroborate would retain tritium,
then further experiments and research were to be conducted to provide a
complete description of the behavior of tritium in sodium fluoroborate.
However, shortly after this series of experiments was begun, funding for
the MSR program was withdrawn, effective at the end of fiscal year 1976.
Thus, the results from these experiments could not provide a complete de-
scription or understanding of tritium behavior in sodium fluoroborate.

However, the results from these experiments, particularly experiments
T4 and T5, have in fact demonstrated in an engineering-scale facility the
effectiveness of sodium fluoroborate for trapping tritium. More than 907%
of tritium added to the CSTF at steady-state conditions appeared in the
off-gas system in a chemically combined (water-soluble) form. No chemical
additions were made to the salt under these conditions. When chemical
additions were made to the salt in experiment T5, increasing the oxide level
in the salt, the trapping efficiency of the salt appeared to be further
enhanced.

Calculations performed to extrapolate from the results obtained from
the CSTF tritium experiments to MSBR conditions indicate that the release
of tritium to the environment from an MSBR would be well within established

guidelines.
58

Therefore, sodium fluoroborate is considered the leading candidate!!
as a secondary coolant for an MSBR and would be expected to adequately
limit the transport of tritium to the reactor steam system and subsequent

release to the environment.

12. ACKNOWLEDGMENTS

The authors wish to acknowledge the efforts of D. J. Fraysier,
H. E. Robertson, and, in particular, E. L. Biddle in performing these
experiments. Also, the work done by the Analytical Chemistry Division
and R. F. Apple in analyzing the samples is gratefully acknowledged.
The authors wish to recognize, posthumously, the efforts and dedication

of A. S. Meyer in the planning and development of these experiments.

13. REFERENCES

1. R. B. Briggs and R. B. Korsmeyer, Molten-Salt Reactor Program Semi-
annual Progress Report, February 28, 1970, ORNL-4548, pp. 5354,

2. G. T. Mays, Molten-Salt Reactor Program Semiannual Progress Report,
February 28, 1975, ORNL-5047, p. 8.

Code of Federal Regulations, Title 10, Part 50, Appendix I.

4. S. Cantor and R. M. Waller, Molten-Salt Reactor Program Semiannual
Progress Report, August 31, 1970, ORNL-4622, pp. 79—82.

5. A. N. Smith, Molten-Salt Reactor Program Semiannual Progress Report,
August 31, 1974, ORNL-5011, pp. 10—14.

6. T. Takaishi and Y. Sensui, "Thermal Transpiration Effect of Hydrogen,
Rare Gases, and Methane,'" Transactions of the Faraday Society, 59,
2503 (1963).

7. R. A, Strehlow and H. C. Savage, Permeability of Hydrogen through
Structural Metal, ORNL-4881 (in preparation).

8. R. B. Briggs and C. W. Nestor, Jr., 4 Method for Calculation of the
Steady-State Distribution of Tritium in an MSBR Plant, ORNL-4804
(April 1975).

9. Oak Ridge National Laboratory, Coneceptual Design of a Single Fluid
Molten-Salt Breeder Reactor, ORNL-4541 (June 1971).

10. L. Maya, Molten-Salt Reactor Program Semiannual Progress Report,
February 29, 1976, ORNL-5132, pp. 32—34.

11. A. D. Kelmers et al., Evaluation of Alternate Secondary (and Tertiary)
Coolants for the Molten-Salt Breeder Reactor, ORNL/TM-5325 (April
1976).
. . -

oo~

*

b
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13.
14.
15.
16.
17.
18.
19-23.
24,
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.

81.
82.
83-84.

85-198.

59

ORNL/TM-5759
Dist. Category UC-76

Internal Distribution

R. F. Apple

C. E. Bamberger
Seymour Baron
J. T. Bell

E. S. Bettis

. Braunstein
A. Bredig

. B. Briggs

R. Bronstein
Brynestad

. D. Burch
Cantor

R. Clark

. E. Cooper

L. Culler

. M. Dale

H. DeVan

R. DiStefano
. R. Engel

G. G. Fee

D. E. Ferguson
L. M. Ferris

M. J. Goglia

W. R. Grimes

R. H. Guymon

W. 0. Harms

J. F. Harvey

P. N. Haubenreich
J. R. Hightower, Jr.
B

H

W

P

b= B L e

Lo H=EwwmE Gm

. F. Hitch

. W. Hoffman
. R. Huntley
. R. Kasten

38.
39.
40.
41.
42.
43.
4.
45.
46-50.
51.
52.
53.
54.
55.
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60-64.
65.
66.
67.
68.
69.
70.
71.
72,
73.
74-75.
76.
77-179.
80.

0. L. Keller

A. D. Kelmers
Milton Levenson
R. E. MacPherson
G. Mamantov

D. L. Manning
W. R. Martin

L. Maya

G. T. Mays

H. E. McCoy

L. E. McNeese
H. Postma

M. W. Rosenthal

D. Scott

M. R. Sheldon
W. D. Shults

M. D. Silverman
M. J. Skinner
A. N. Smith

I. Spiewak

D. B. Trauger
D. Y. Valentine
J. R. Weir

J. C. White

W. J. Wilcox

M. K. Wilkinson
R. G. Wymer

J. P. Young

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Director, Division of Nuclear Research and Applications, Energy
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For distribution as shown in TID-4500 under category UC-76,
Molten-Salt Reactor Technology