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Environmental radioactivity measurements and measurements assurance programs in Switzerland
Environment International, Vol. 1, pp. 89-96, 1978. Pergamon Press. Printed in Great Britain.
Environmental Radioactivity Measurements and Measurements Assurance Programs in Switzerland J. Czarnecki Federal Office of Energy, Wiirenlingen, Switzerland
The measurement capabilities of the various laboratories involved in radiation protection measurements in Switzerland are described. Intercomparisons of the results of radioactive effluent measurements from Swiss Nuclear-Power-Stations (NPS) show good agreement. The expected additional doses in the neighbourhood of the operating NPS are about 1 mrad/y. Typical measurement methods already used and planned for future use in the vicinity of the NPS are discussed. (Responsibilities; laboratories; capabilities; measurements; results; programs)
Introduction The worldwide use of radioactive material in medicine and industry, and the construction of nuclear power stations (NPS) have created new problems in the field of low-level radiation measurements. The purpose of these measurements is to ensure that the radioactivity in the biosphere due to industrial activities remains low. Here we describe the laboratories involved with such measurements and the measurement programs in Switzerland. The laboratories involved in radiation protection measurements
We can distinguish between two types of laboratories. One is mainly responsible for the control of radioactive discharges from the nuclear industry. The other is involved with the measurement of the amount of these discharged radioactive materials which have found their way into the environment. Figure 1 defines the laboratories and Fig. 2 their responsibilities. Table 1 shows the measurement devices the laboratories use. The nuclear power station laboratories specialize in measurements of gas and liquid effluents. As well as these measurements Nuclear Safety Division of the Swiss Federal Office of Energy (ASK) and Swiss Federal Radioactivity Surveillance Commission (KUER) must specilize in environmental measurements. The laboratories of the Radiation Protection Section of the Federal Office of Public Health in Switzerland (EGA) and the Swiss National Accident Insurance Fund (SUVA) handle problems arising from the use of radioactive substances in medicine and industry. The laboratory of the Swiss Federal Institute for Water Resources and Water Pollution Control (EAWAG) makes control measurements of surface and ground water, including the control of radioactivity in fish, microorganisms and sediment. Therefore this laboratory specializes in 9°Sr, 3H and "gross"/3
measurements. Finally, the KUER laboratory surveys the radioactivity in the environment, i.e. in the whole Swiss biosphere. All laboratories are able to make radiochemical analysis. There is a close cooperation between the laboratories mentioned. Environmental radioactivity measurements
Two types of measurements are carried out in the vicinity of nuclear-power stations: measurements before tile NPS goes into operation (preoperational measurements) and measurements during the whole operational period of the nuclear-power station. The first type of measurements should give the base line radioactivity, the second type the additional radioactivity due to the radioactive release of the NPS. Since for a modern NPS the radioactive releases are very low, the measurement technique used and the measurement problems are the same whether the nuclearpower station is in operation or not. The very low additional doses to the population in the neighbourhood of NPS are negligible. Therefore the measurement of these low doses (about 1 mrad/y at the highest expected ground concentration) seems not to be necessary. Despite, this public opinion has compelled the controlling authorities to survey very carefully the radioactivity in the vicinity of a NPS. This has led to the applicatior/of very elaborate measurement techniques, i.e. ASK
-
NUCLEAR SAFETY DIVISION OF THE SWISS FEDERAL OFFICE OF ENERGY
KUER
-
SWISS FEDERAL RADIOACTIVITY SURVEILLANCE COMMISSION
EAWAG -
SWISS FEDERAL INSTITUTE FOR WATER RESOURCESAND WATERPOLLUTIONCONTROL
SUVA
SWISS NATIONAL ACCIDENT INSURANCE FUND
EGA
-
RADIATION PROTECTION SECTION OF THE FEDERAL OFFICE OF PUBLIC HEALTH IN SWITZERLAND
Fig. 1. 89
90
J. Czarnecki Control of Radiation Protection and Environmental Radioactivity in Switzerland
NPS Releases Laboratories ~
[ \
\
~c
Dispersion " Dilution Impact ..... 1 ~ ' ~ Reconcentration. ~ k , eCm~l~n~,/Biosphere
"--...--"
/i
[pe~onnel expose!
~
/ ;
,,
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I
Dose
',
ASK EGA SUVA
ponslbdlty field of the KUER
Fig. 2 the measurement of the dose rate with pressure-ionization chambers and the identification of the contributing radioactive nuclides with Ge (Li) -detectors. Such measurements are carried out at a few selected points in the vicinity of the plant. The measurement time varies from a week to a few months. The program starts about one year before the NPS goes into operation and is then repeated each year. Many publications describing the measurement technique and the achieved results can be found in the literature (Black, 1972; Auxier, 1973). The main difficulties connected with these measurements are the following: (i) The dose rate at a point caused by the natural background radioactivity can differ from the mean value by + 20%. In Switzerland this is equivalent to a dose-rate variation of + 20 mrad/y. The variation is caused by changing soil humidity, by washout of radon daughters, by different thicknesses of the snow cover during the winter months, etc. (ii) The dose rate caused by natural background radioactivity is not the same at two points separated by several kilometers. Therefore a reference point for the background radiation cannot be determined, and the measurements must give the absolute dose rate value. (iii) The calibration of the ionization chambers and the Ge (Li) -detector for the in situ measurements must be done with an appropriate accuracy of about -+ 5-10%. Table 2 shows results of dose-rate measurements using a pressurized ionization chamber and a Ge (Li) spectrometer. The agreement between the dose rate values measured with these instruments is very good (Beck, 1972; Cardinale, 1971). Such results should be achieved in routine measurements. The laboratories of the controlling bodies (ASK, KUER) have five pressurized ionization chambers. In the newest models magnetic cassettes are used to record data. In our laboratory the information is fed from the cassettes into a mini-computer (ND-812). Calculations performed by the computer should allow us to determine the dose-rate contribution of the radon daughters (slow component in comparison with the gaseous effluent plume component) (Gogolak, 1974). We hope that we can measure hourly
dose-rate variations, due to radioactivity released from the nuclear-power stations, as low as 0.1 gR/h using the chambers and the computer. For in situ 7-ray spectrometric measurements we use Ge (Li) detectors and a ND-100 pulshight analyser. The field experiments started two months ago. Together with simultaneously measured meteorological data, the use of another computer program allows the determination of atmospheric diffusion factors. These are used to supplement the diffusion calculations. Such experiments are under way at the NPS of Mtihleberg (BWR). The 133 Xe concentrations in air are measured using on-site sampling, followed by laboratory low temperature adsorption on charcoal. Special equipment was developed for this purpose. The 133 Xe measurements are done by the Lab of Low Level Counting of the University of Bern and KUER. Measurement assurance program
The assurance program for monitoring radioactive effluents is based on the following approach: Comparison between laboratories Four times a year samples of gaseous and liquid effluents, as well as air-filter samples, are taken from each NPS. The laboratories of the nuclear power stations and of the controlling bodies, ASK and KUER, analyse these samples. Table 3 gives as an example the results of such a comparative analysis. A good agreement between the results was achieved for many nuclides. But a difference in the measured activity concentration up to a factor 5 exists for some nuclides. The causes of these differences are not yet quite clear. It should be mentioned that the sampling, treatment and analyses of the samples were carried out during the routine measurement program of all the laboratories. Some errors arise due to different nuclear data given in different Tables of Nuclides and also to the different energy peaks used in various laboratories to disentangle, e.g. the 6SSkeV (11°rnAg) from the 662 keV (137Cs-laTmBa); o/her errors arise from the standards used for the' calibration of the counting equipment. These standards have
Environmental radioactivity measurements
91
Table 1. I. Lab:
MEASUREMENT EQUIPMENT
No
1.
Type o f measurement
Input/Output
Apparatus
Dot. type
ND-4420
Spectroscopy
ASK/EIR
8 ADC, ND-812 Computer: 16 k ND-4420 B u f f e r : 16 k
32 k
Josslble use Lab Field
Teletype Faclt (HSP) Remex (HSP) Plotter
1.1
y
Ge(Li) 10 % rel. elf,
N0-4420
X
X
1.2
y
Ge(Li) 10 & re1. elf.
ND-4420
X
X
Ge 16x5 mm
ND-4420
X
X
Teletype Facit (HSP) Remex (HSR) Plotter
X
X
1.3
X ,Y
1.4
c:
Surface B a r r i e r Diode: 330 mm 2
ND-4420
1.5
(~
Surface Barrier Diode: 330 mm 2
ND-4420
1.6
(x
Surface B a r r i e r Diode: 300 mm2
ND-4420
Surface Barrier Diode: 2000 mm 2
ND-4420
1.7
1.8
c~
Surface Barrier Diode: 2000 mm 2
ND-4420
1,9
y
NaI{TI); WBC 4"x4"
ND-IOO/4K
1.10
y
NBI(TI); 131 1 1-x1" [ T h y r o i d )
S i n g l e Channel PHA
Printer
X
1.111
y
NaI(TI); 1251 l"xlmm (Thyroid)
S i n g l e Channel PHA
Printer
X
1,12
y
Ge(Li) 6 % rel.
1.131 Spectroscopy + Personal Ooslmetry
:2.
6 - Spectroscopy
ND-4410
1ADC, ND-812 Computer: 8 k ND-4410 B u f f e r : 4 k
Teletype/Tape Cassette
X
ND-4420
2 ADC, ND-812 Computer: 16 k ND-4420 B u f f e r 8 k
Teletype/HSP-HSR/DOS
X
Minicomputer,
X
elf.
Records
Liquid Sc. Oet.
4 ADC ( w i t h Router)
Betaszlnt BF-5000
Printer
3.1
B - Total
GM-Antlcolncldence
Scaler
Printer
X
3.2
8 - Total
GM-Anticolncldence
Scaler
Printer
X
4.1
e - Total
Proportional Chamber 300 cm 2
4.2
~ - Total
Proportional Chamber 7 cm 2
5.1
Oosarate (pR/h)
High-pressure Ionlsation Chamber
RSS-111
Paper Tape recorder, Tape cassette system Interface to ND-B12
X
X
5.2
Doserate (pR/h)
High-pressure Ionisatlon Chamber
RSS-111
Paper Tape recorder
X
X
5.3
Ooserate [pR/h)
Scintilation Detector
Szlntomat
L i n e a r ranges from 2 pR/h - 3000 m R/h
X
X
92
J. Czarnecki
MEASUREMENT
No
1.
Type oF measurement
Pet.
EOUIPMENT
ND-4420 or Elsclnt Meda
1.1
y'
Ge(LI) 9 . I % t e l , eFf.
1.2
y
Ge(Li) 18 % r e l . e l f .
1.3
y
NaI(TI) 3"x3"
1.4
y
NaI(TI) 3"x3"
y
2.1
cL
2 ADC,
ND-2200/4K
KUER
Input/Output
N0-812 Computer: 16 k ND-4420 Buffer : 8 k 24 k
I ADC
~osslble use LaP Field
Teletype, HSP-HSR Plotter, Tape cassette system
X
X
Printer, Plotter HSP Card-punch
RCL-512 or Elsoint
NaI(TI) 1V2"xIV2"
Meda
PHA
Single Channel
RCL-512 or Elsclnt Meda
Chamber 2.2
Lab:
Apparatus
type
Spectroscopy
1.5
2.
RCL-512 SurFace Barrier Detector, 200 mm 2 lot Elscint Made
e
2.3
(X - Total
3.1
8-Spectroscopy
Scintilatlon Detector
Scaler/Timer
(T)
Scaler
5oaler/Conicidence
Scaler/Printer
2x RCA 8850 PM 4.1
8 - Total
4.2
8 - Total
5.1
Ooserate
5.2
Ooserate
GM-Counter
Scaler
GM-Antlooincldence
Scaler
(pR/h)
High-pressure Ionlsatlon Chamber
RSS-111
Paper Tape recorder
X
X
(~R/h)
Sclntilatlon Detector
Szlntomat
Linear ranges from 2 pR/h - 3000 m R/h
X
X
MEASUREMENT
No
Scaler/Prlnter
Type of measurement
3, Lab:
EOUIPMENT
Oat, type
Input/Output
Apparatus
(PWR)
possible use Lab Field
!1.1
y - Spectrometry
Gs(Li);BOxlO -6 m"
JN 90
1.2
y - Spectrometry
Ge(Li);33x10 -6 m"
JN Didac 4000
1ADC
Printer
1,3
y - Spectrometry
Ge(Lt);45x10
JN Oidac
I ADC
Printer
X
X
1.4
y - Spectrometry
various
Single Channel PHA
Scaler
X
X
2.
a /8 - Total
Prop.
FrSeseKe + HSpfner
Scaler
X
3,
B - Total
Liquid
Scaler
X
4.
Doslsrate
Scintilation Detector
-6
NaI
counter sclnt.
m~
(48 K)
Nuclear Power Station - 8aznau
800
Panex Szlntomat
x 2
2 ADC
Floppy Disk TJJ Silent 700
Linear ranges from 2 pR/h - 3000 m R/h
X
X
93
Environmentalradioactivitymeasurements
MEASUREMENT EQUIPMENT
No
Type o f measurement
4.
Lab:
Nuclear Power Station - MOhleberg (BWR)
Apparatus
Oct. type
1,1
y - Spectroscopy
G e ( L i } ; 4 4 x 1 0 -6 m3
Hlstomat
1.2
y - Spectroscopy
Nal (TI)
Leben
Input/Output
(2000)
I ADC
(BOO)
possible u s e Lab Field
Teletype
I ADC
Printer,
Plotter
3"x3" 1.3
y - Spectroscopy
2.1
B - Total
2.2
B - Total
NaI (T1) 3"x3" GM-Anticoincldence Proportional Counter
MEASUREMENT
No
Type o f measurement
I.
y - Spectroscopy
!2.
B - Spectroscopy
3.
~ * B - Total
4.
8 - Total
5.
Doserate
S i n g l e Channel PHA NE SR3
Scaler
Landis and Gyr
Scalar
Frieseke
Scaler
+ H6pfner
EQUIPMENT
Det. type
NsI(TI)
Liquid Sc. Proportional Counter 180 cm 2 GM
5.
Type o f measurement
SUVA
Apparatus
Input/Output
)osslble u s e Lab I Field
Printer / S c a l e r Timer
Landis and Gyr Single Channnel PHA Packard C 2425
Teletype
Herfurt
Herfurt
Ionisation Chambers
6.
I No
Lab:
Pet. type
L~b:
Low Level Counting Lab of the University o f Bern
Apparatus
I1.1
Spectroscopy
Proportional Counte~s from 10×10" m3 t o 2 . 8 x 1 0 -6 m3
1.2
Spectroscopy
Ge(Li)
ND Multlchannel
PHA
1,3
Spectroscopy
NaI (T I)
ND Multlchennel
PHA
Input/Output
possible usa Lab Field
NO Multichannel PHA
neither the proper radionuclide compositon nor the proper relative nuclide activity as the "rad" waste from lightwater-cooled nuclear-power stations. Furthermore all the laboratories involved use different geometries (containers and different measurement configurations). The controlling body cannot demand that all laboratories use the same containers and measurement configurations. Recommendations from the ICRM would perhaps be helpful in this matter. A further reason for the differences could be the dissimilar chemical properties (pH value, solubility, etc.) of the reactor sample and the sample used to the cross-
checking measurements. Adsorption on the bottle wall and precipitation of undissolved components can affect the results. A typical example of such problems is shown in Table 4. The pH value of the sample was unusually high. Differences between the first measurement in all three laboratories were probably caused by the differences in the measurement geometries used in particular laboratories.
Round-robin measurements To make round-robin measurements a laboratory prepares
94
J. Czarnecki Table 2. Examples of field measurements made with GE(LI) detectors, NAI(TL) detectors and ionization chambers ~IRIH DETECTOR LOCATION TYPE
K
U
T
CS
ZR-NB
OTHER
SUM
ION CHAMBER
JOLIET. Ill 1971
GE(LI) NAI(TL)
2.8 2,7
1,2 i,i
2.5 2,4
0,2 0,3
0,3 0,2
0.i
7,I 6,7
7,8
CHANNAHAN, 111 1971
GE(LI) NAI(TL)
2,6 2,4
1,0 1,1
1,9 1,8
0,2 0,2
0,3 0,2
0,1
6,1 5,7
5,9
MORRIS. Ill 1971
GE(LI) NAI(TL)
2,2 2.2
1,4 1.2
1,7 1,8
0,i 0,i
0.3 0,2
< 0,i
5,7 5,5
WATERFORD. CONN, 1971
GE(LI) NAI(TL)
1.7 1,7
1,7 1,4
3,0 3.4
0,6 0,4
0,2 0,I
7,2 7,0
7.6
WATERFORD. CONN, 1971
GE(LI) NAI(TL)
2,4 2.4
1,6 2,1
2,9 3,1
0,7 0,4
0.2 0,i
7,8 8.1
8,0
FORKED RIVER, N,J, GE(LI) 1971 NAI(TL)
0,2 0,2
0,8 0,9
L~,9 0,8
0,6 0,7
0,2 0,2
2,7 2,8
2.6
FORKED RIVER, N,J, GE(LI) 1971 NAI(TL)
0,3 0,3
0,5 0,5
0,6 0,5
0,8 0,8
0,1 0,1
-
2,3 2,2
2,1
DENVER, COLO, 1965
NAI(TL)
3,4
2,4
7,4
0,3
0,2
13,7
13.8
BIKINI, ATOLL 1967
NAI(TL)
0
0
0
19,0
5,8
24,8
24.0
Table 3. Liquid effluent measurement comparison LABORATORIES
ASK,
SAMPLE
LIQUID WASTE FROM NPS-BEZNAU
COLLECTING DATE
20, 6, 1975
TABLE OF NUCLEAR DATA USED
NPS-BEZNAU
CEN,
~SK
JUELICH 1971
KUER
VARIOUS
(PWR) AND KUER
11,45 H LARA-1975
NANOCURIES PER LITER
UNITS NUCLIDE
NPS-BEZNAU
NPS-BEZNAU
ASK
KUER
144Ce
ii0
112
90
141 Ce
22
23
17
103 Ru
120
%
104
51Cr 137Cs
560
360
438
99
27
125Sb 95Zr 95Nb 58Co 54Mn
66 120
75
55
177
90
180
119
146
340
22~
231
42
29
60Co
310
194
198
124Sb 131I
880
841
807
134Cs 110mAg 65 Zn 106Rb 1/,0La
29,7
24.8
6
2,0
5
5,1
7
1,4 6,4
163 22
127 1,0
95
Environmental radioactivity measurements Table 4. "Rad" waste 3' -analyses from waste disposal tank NPS-Beznau, 9 June 1976 (units: nCi/l)
NPS-BEZNAU
ASK
KUER
GE(LI)[ G** 3
PART OF THE ORIGINAL SAMPLE *) 260 cc DILUTION TO 550 cc (SHAKEN) G** 3
9,6,1976
14,9,1976
15,9,1976
13,9,1976
268
78
108
85
ORIGINAL SAMPLE 500 cc G*"
DATE
G~
1
9,6,1976
2
9,6,1976
54Mn
i00
cc
AFTER i DAY SEDIMENTATION G**
3
(SHAKEN) G** 4
58Co
40
6O
429
113
156
117
60Co
250
38O
3421
877
1360
875
134Cs
1400
2100
6590
1865
2100
2220
137Cs
3200
4100
14840
4200
4760
4680
* From the original sample 170 cms was taken for SR-90 and T-measurements. ** Measurements geometry Table 5. Interlaboratory comparison
LABORATORIES:
EIR-ASK,
KUER,
NPS-BEZNAU (PWR),
NPS-MUEHLEBERG (BWR) DATE
MARCH, 1975
SAMPLE TYPE :
DRIED SOLUTION
UNITS
NANOCURIES
(PREPARED BY ASK/EIR LAB)
NUCLIDE
EXPECTED
ASK/EIR
KUER
NPS-BEZNAU
241Am
39,63
46,2
52,8
97,0
24,0
57Co
23,8
29.5
28,0
28,0
23,0
134Cs
34,8
33.4
33,4
39,0
51,0
137Cs
56,63
55,0
57,5
59,0
74,0
60Co
41,2
43,9
39,4
40,0
56,0
a sample composed o f a selected number o f radionuclides. The activity of the nuclides is carefully chosen. All the other laboratories have to measure the sample and report the results. Round-robin measurements were made two to four times a year. Table 5 shows some results of such measurements. The agreement between the results is good except for 241 Am.
Calibration of the counting equipment using laboratory standards The precision of the measurement results is a function of the type and quality of laboratory standards. In most of
NPS-MUEHLEBERG
our standards from well established foreign laboratories are used (IAEA, Saclay, NBS, Amersham, Brookhaven, etc.).
Conclusions
1. The measurement problems arising due to the necessity to control the radioactive effluents can be treated with a satisfactory accuracy by the nuclear-power-station laboratories. 2. Representative standards should be available in respect o f the measurements of the effluents from NPS.
96 3. The Labs o f the NPS laboratories should be traceable to the laboratories o f the control organizations. 4. The laboratories o f the control organizations (ASK, KUER, SUVA, EGA) should be traceable to internationally "well-known" laboratories. 5. To realize our environmental measurement program we look for standards (a) composed o f natural matrices and containing only natural radioactivity in various concentrations, and (b) composed o f natural matrices and containing natural and artificial radionuclides.
Acknowledgements - I wish to express my thanks to Mr. H. Voelkle, KUER; Mr. H. Loosli and Mr. R. Schleicher, University of Bern; Mrs. M. Bezzegh, EAWAG; Mr. E. Kaufmann, SUVA; Mr. W. Goerlich, Swiss Reactor Research Institut; Mr. M. Heise, NPS-Beznau; Mr. J. P. Ghysels and Mr. G. Schriber, NPS-Miihleberg; for their assistance in the measurements and the information about the capabilities of their laboratories. The critical review of the manuscript by Mr. W. Jeschki, ASK and the editorial work by Mrs. S. Segat and Miss Wyssmann when typing the manuscript are also much appreciated.
J. Czarnecki
References Auxier J. A., Christian D. J., Jones T. D., Kerr G. D., Perdue P. T., Shinpaugh W: H. and Thorngate J. H. (1973) Contribution of natural terrestrial sources to the total radiation dose to man, Oak Ridge National Laboratory-TM--4323, Oak Ridge, TN. Beck H. L., De Campo J. A. and Gogolak C. (1972) In Situ Ge (Li) and NaI (T1) gamma-ray spectrometry, Health and Safety Laboratory-258, New York. Beck H. L., Lowder W. M., Bennett B. G., and Condon W. Y. (1966) Further studies of external environmental radiation, Health and Safety Laboratory-170, New York. Cardinale A., Fritelli L., Lembo G., Gere F. and Ilari O. (197t) Studies of the natural background radiation in Italy, Health Physics 20, 285. De Campo J. A., Beck H. L., and Raft P. U. (1972) High pressure argon ionization chamber systems for the measurement of environmental radiation exposure rates, Health and Safety Laboratory (USA)-260, New York. Gogolak C. and Miller K. M. (1974) Method for obtaining radiation exposure due to a boiling water reactor plum from continuously monitoring ionization chambers, Health Physics 27~ 132. International Atomic Energy Agency (1974) Environmental survaillance around nuclear installations, Proceedings of a Symposium, Warsaw, 5 - 9 Nov. 1973. Jkaya M. (1976) Natural radiation dose in Akiyoshi Cavern and on Karst Plateau, Health Physics 3 It 76.
Environmental Radioactivity Measurements and Measurements Assurance Programs in Switzerland J. Czarnecki Federal Office of Energy, Wiirenlingen, Switzerland
The measurement capabilities of the various laboratories involved in radiation protection measurements in Switzerland are described. Intercomparisons of the results of radioactive effluent measurements from Swiss Nuclear-Power-Stations (NPS) show good agreement. The expected additional doses in the neighbourhood of the operating NPS are about 1 mrad/y. Typical measurement methods already used and planned for future use in the vicinity of the NPS are discussed. (Responsibilities; laboratories; capabilities; measurements; results; programs)
Introduction The worldwide use of radioactive material in medicine and industry, and the construction of nuclear power stations (NPS) have created new problems in the field of low-level radiation measurements. The purpose of these measurements is to ensure that the radioactivity in the biosphere due to industrial activities remains low. Here we describe the laboratories involved with such measurements and the measurement programs in Switzerland. The laboratories involved in radiation protection measurements
We can distinguish between two types of laboratories. One is mainly responsible for the control of radioactive discharges from the nuclear industry. The other is involved with the measurement of the amount of these discharged radioactive materials which have found their way into the environment. Figure 1 defines the laboratories and Fig. 2 their responsibilities. Table 1 shows the measurement devices the laboratories use. The nuclear power station laboratories specialize in measurements of gas and liquid effluents. As well as these measurements Nuclear Safety Division of the Swiss Federal Office of Energy (ASK) and Swiss Federal Radioactivity Surveillance Commission (KUER) must specilize in environmental measurements. The laboratories of the Radiation Protection Section of the Federal Office of Public Health in Switzerland (EGA) and the Swiss National Accident Insurance Fund (SUVA) handle problems arising from the use of radioactive substances in medicine and industry. The laboratory of the Swiss Federal Institute for Water Resources and Water Pollution Control (EAWAG) makes control measurements of surface and ground water, including the control of radioactivity in fish, microorganisms and sediment. Therefore this laboratory specializes in 9°Sr, 3H and "gross"/3
measurements. Finally, the KUER laboratory surveys the radioactivity in the environment, i.e. in the whole Swiss biosphere. All laboratories are able to make radiochemical analysis. There is a close cooperation between the laboratories mentioned. Environmental radioactivity measurements
Two types of measurements are carried out in the vicinity of nuclear-power stations: measurements before tile NPS goes into operation (preoperational measurements) and measurements during the whole operational period of the nuclear-power station. The first type of measurements should give the base line radioactivity, the second type the additional radioactivity due to the radioactive release of the NPS. Since for a modern NPS the radioactive releases are very low, the measurement technique used and the measurement problems are the same whether the nuclearpower station is in operation or not. The very low additional doses to the population in the neighbourhood of NPS are negligible. Therefore the measurement of these low doses (about 1 mrad/y at the highest expected ground concentration) seems not to be necessary. Despite, this public opinion has compelled the controlling authorities to survey very carefully the radioactivity in the vicinity of a NPS. This has led to the applicatior/of very elaborate measurement techniques, i.e. ASK
-
NUCLEAR SAFETY DIVISION OF THE SWISS FEDERAL OFFICE OF ENERGY
KUER
-
SWISS FEDERAL RADIOACTIVITY SURVEILLANCE COMMISSION
EAWAG -
SWISS FEDERAL INSTITUTE FOR WATER RESOURCESAND WATERPOLLUTIONCONTROL
SUVA
SWISS NATIONAL ACCIDENT INSURANCE FUND
EGA
-
RADIATION PROTECTION SECTION OF THE FEDERAL OFFICE OF PUBLIC HEALTH IN SWITZERLAND
Fig. 1. 89
90
J. Czarnecki Control of Radiation Protection and Environmental Radioactivity in Switzerland
NPS Releases Laboratories ~
[ \
\
~c
Dispersion " Dilution Impact ..... 1 ~ ' ~ Reconcentration. ~ k , eCm~l~n~,/Biosphere
"--...--"
/i
[pe~onnel expose!
~
/ ;
,,
}
]
I
Dose
',
ASK EGA SUVA
ponslbdlty field of the KUER
Fig. 2 the measurement of the dose rate with pressure-ionization chambers and the identification of the contributing radioactive nuclides with Ge (Li) -detectors. Such measurements are carried out at a few selected points in the vicinity of the plant. The measurement time varies from a week to a few months. The program starts about one year before the NPS goes into operation and is then repeated each year. Many publications describing the measurement technique and the achieved results can be found in the literature (Black, 1972; Auxier, 1973). The main difficulties connected with these measurements are the following: (i) The dose rate at a point caused by the natural background radioactivity can differ from the mean value by + 20%. In Switzerland this is equivalent to a dose-rate variation of + 20 mrad/y. The variation is caused by changing soil humidity, by washout of radon daughters, by different thicknesses of the snow cover during the winter months, etc. (ii) The dose rate caused by natural background radioactivity is not the same at two points separated by several kilometers. Therefore a reference point for the background radiation cannot be determined, and the measurements must give the absolute dose rate value. (iii) The calibration of the ionization chambers and the Ge (Li) -detector for the in situ measurements must be done with an appropriate accuracy of about -+ 5-10%. Table 2 shows results of dose-rate measurements using a pressurized ionization chamber and a Ge (Li) spectrometer. The agreement between the dose rate values measured with these instruments is very good (Beck, 1972; Cardinale, 1971). Such results should be achieved in routine measurements. The laboratories of the controlling bodies (ASK, KUER) have five pressurized ionization chambers. In the newest models magnetic cassettes are used to record data. In our laboratory the information is fed from the cassettes into a mini-computer (ND-812). Calculations performed by the computer should allow us to determine the dose-rate contribution of the radon daughters (slow component in comparison with the gaseous effluent plume component) (Gogolak, 1974). We hope that we can measure hourly
dose-rate variations, due to radioactivity released from the nuclear-power stations, as low as 0.1 gR/h using the chambers and the computer. For in situ 7-ray spectrometric measurements we use Ge (Li) detectors and a ND-100 pulshight analyser. The field experiments started two months ago. Together with simultaneously measured meteorological data, the use of another computer program allows the determination of atmospheric diffusion factors. These are used to supplement the diffusion calculations. Such experiments are under way at the NPS of Mtihleberg (BWR). The 133 Xe concentrations in air are measured using on-site sampling, followed by laboratory low temperature adsorption on charcoal. Special equipment was developed for this purpose. The 133 Xe measurements are done by the Lab of Low Level Counting of the University of Bern and KUER. Measurement assurance program
The assurance program for monitoring radioactive effluents is based on the following approach: Comparison between laboratories Four times a year samples of gaseous and liquid effluents, as well as air-filter samples, are taken from each NPS. The laboratories of the nuclear power stations and of the controlling bodies, ASK and KUER, analyse these samples. Table 3 gives as an example the results of such a comparative analysis. A good agreement between the results was achieved for many nuclides. But a difference in the measured activity concentration up to a factor 5 exists for some nuclides. The causes of these differences are not yet quite clear. It should be mentioned that the sampling, treatment and analyses of the samples were carried out during the routine measurement program of all the laboratories. Some errors arise due to different nuclear data given in different Tables of Nuclides and also to the different energy peaks used in various laboratories to disentangle, e.g. the 6SSkeV (11°rnAg) from the 662 keV (137Cs-laTmBa); o/her errors arise from the standards used for the' calibration of the counting equipment. These standards have
Environmental radioactivity measurements
91
Table 1. I. Lab:
MEASUREMENT EQUIPMENT
No
1.
Type o f measurement
Input/Output
Apparatus
Dot. type
ND-4420
Spectroscopy
ASK/EIR
8 ADC, ND-812 Computer: 16 k ND-4420 B u f f e r : 16 k
32 k
Josslble use Lab Field
Teletype Faclt (HSP) Remex (HSP) Plotter
1.1
y
Ge(Li) 10 % rel. elf,
N0-4420
X
X
1.2
y
Ge(Li) 10 & re1. elf.
ND-4420
X
X
Ge 16x5 mm
ND-4420
X
X
Teletype Facit (HSP) Remex (HSR) Plotter
X
X
1.3
X ,Y
1.4
c:
Surface B a r r i e r Diode: 330 mm 2
ND-4420
1.5
(~
Surface Barrier Diode: 330 mm 2
ND-4420
1.6
(x
Surface B a r r i e r Diode: 300 mm2
ND-4420
Surface Barrier Diode: 2000 mm 2
ND-4420
1.7
1.8
c~
Surface Barrier Diode: 2000 mm 2
ND-4420
1,9
y
NaI{TI); WBC 4"x4"
ND-IOO/4K
1.10
y
NBI(TI); 131 1 1-x1" [ T h y r o i d )
S i n g l e Channel PHA
Printer
X
1.111
y
NaI(TI); 1251 l"xlmm (Thyroid)
S i n g l e Channel PHA
Printer
X
1,12
y
Ge(Li) 6 % rel.
1.131 Spectroscopy + Personal Ooslmetry
:2.
6 - Spectroscopy
ND-4410
1ADC, ND-812 Computer: 8 k ND-4410 B u f f e r : 4 k
Teletype/Tape Cassette
X
ND-4420
2 ADC, ND-812 Computer: 16 k ND-4420 B u f f e r 8 k
Teletype/HSP-HSR/DOS
X
Minicomputer,
X
elf.
Records
Liquid Sc. Oet.
4 ADC ( w i t h Router)
Betaszlnt BF-5000
Printer
3.1
B - Total
GM-Antlcolncldence
Scaler
Printer
X
3.2
8 - Total
GM-Anticolncldence
Scaler
Printer
X
4.1
e - Total
Proportional Chamber 300 cm 2
4.2
~ - Total
Proportional Chamber 7 cm 2
5.1
Oosarate (pR/h)
High-pressure Ionlsation Chamber
RSS-111
Paper Tape recorder, Tape cassette system Interface to ND-B12
X
X
5.2
Doserate (pR/h)
High-pressure Ionisatlon Chamber
RSS-111
Paper Tape recorder
X
X
5.3
Ooserate [pR/h)
Scintilation Detector
Szlntomat
L i n e a r ranges from 2 pR/h - 3000 m R/h
X
X
92
J. Czarnecki
MEASUREMENT
No
1.
Type oF measurement
Pet.
EOUIPMENT
ND-4420 or Elsclnt Meda
1.1
y'
Ge(LI) 9 . I % t e l , eFf.
1.2
y
Ge(Li) 18 % r e l . e l f .
1.3
y
NaI(TI) 3"x3"
1.4
y
NaI(TI) 3"x3"
y
2.1
cL
2 ADC,
ND-2200/4K
KUER
Input/Output
N0-812 Computer: 16 k ND-4420 Buffer : 8 k 24 k
I ADC
~osslble use LaP Field
Teletype, HSP-HSR Plotter, Tape cassette system
X
X
Printer, Plotter HSP Card-punch
RCL-512 or Elsoint
NaI(TI) 1V2"xIV2"
Meda
PHA
Single Channel
RCL-512 or Elsclnt Meda
Chamber 2.2
Lab:
Apparatus
type
Spectroscopy
1.5
2.
RCL-512 SurFace Barrier Detector, 200 mm 2 lot Elscint Made
e
2.3
(X - Total
3.1
8-Spectroscopy
Scintilatlon Detector
Scaler/Timer
(T)
Scaler
5oaler/Conicidence
Scaler/Printer
2x RCA 8850 PM 4.1
8 - Total
4.2
8 - Total
5.1
Ooserate
5.2
Ooserate
GM-Counter
Scaler
GM-Antlooincldence
Scaler
(pR/h)
High-pressure Ionlsatlon Chamber
RSS-111
Paper Tape recorder
X
X
(~R/h)
Sclntilatlon Detector
Szlntomat
Linear ranges from 2 pR/h - 3000 m R/h
X
X
MEASUREMENT
No
Scaler/Prlnter
Type of measurement
3, Lab:
EOUIPMENT
Oat, type
Input/Output
Apparatus
(PWR)
possible use Lab Field
!1.1
y - Spectrometry
Gs(Li);BOxlO -6 m"
JN 90
1.2
y - Spectrometry
Ge(Li);33x10 -6 m"
JN Didac 4000
1ADC
Printer
1,3
y - Spectrometry
Ge(Lt);45x10
JN Oidac
I ADC
Printer
X
X
1.4
y - Spectrometry
various
Single Channel PHA
Scaler
X
X
2.
a /8 - Total
Prop.
FrSeseKe + HSpfner
Scaler
X
3,
B - Total
Liquid
Scaler
X
4.
Doslsrate
Scintilation Detector
-6
NaI
counter sclnt.
m~
(48 K)
Nuclear Power Station - 8aznau
800
Panex Szlntomat
x 2
2 ADC
Floppy Disk TJJ Silent 700
Linear ranges from 2 pR/h - 3000 m R/h
X
X
93
Environmentalradioactivitymeasurements
MEASUREMENT EQUIPMENT
No
Type o f measurement
4.
Lab:
Nuclear Power Station - MOhleberg (BWR)
Apparatus
Oct. type
1,1
y - Spectroscopy
G e ( L i } ; 4 4 x 1 0 -6 m3
Hlstomat
1.2
y - Spectroscopy
Nal (TI)
Leben
Input/Output
(2000)
I ADC
(BOO)
possible u s e Lab Field
Teletype
I ADC
Printer,
Plotter
3"x3" 1.3
y - Spectroscopy
2.1
B - Total
2.2
B - Total
NaI (T1) 3"x3" GM-Anticoincldence Proportional Counter
MEASUREMENT
No
Type o f measurement
I.
y - Spectroscopy
!2.
B - Spectroscopy
3.
~ * B - Total
4.
8 - Total
5.
Doserate
S i n g l e Channel PHA NE SR3
Scaler
Landis and Gyr
Scalar
Frieseke
Scaler
+ H6pfner
EQUIPMENT
Det. type
NsI(TI)
Liquid Sc. Proportional Counter 180 cm 2 GM
5.
Type o f measurement
SUVA
Apparatus
Input/Output
)osslble u s e Lab I Field
Printer / S c a l e r Timer
Landis and Gyr Single Channnel PHA Packard C 2425
Teletype
Herfurt
Herfurt
Ionisation Chambers
6.
I No
Lab:
Pet. type
L~b:
Low Level Counting Lab of the University o f Bern
Apparatus
I1.1
Spectroscopy
Proportional Counte~s from 10×10" m3 t o 2 . 8 x 1 0 -6 m3
1.2
Spectroscopy
Ge(Li)
ND Multlchannel
PHA
1,3
Spectroscopy
NaI (T I)
ND Multlchennel
PHA
Input/Output
possible usa Lab Field
NO Multichannel PHA
neither the proper radionuclide compositon nor the proper relative nuclide activity as the "rad" waste from lightwater-cooled nuclear-power stations. Furthermore all the laboratories involved use different geometries (containers and different measurement configurations). The controlling body cannot demand that all laboratories use the same containers and measurement configurations. Recommendations from the ICRM would perhaps be helpful in this matter. A further reason for the differences could be the dissimilar chemical properties (pH value, solubility, etc.) of the reactor sample and the sample used to the cross-
checking measurements. Adsorption on the bottle wall and precipitation of undissolved components can affect the results. A typical example of such problems is shown in Table 4. The pH value of the sample was unusually high. Differences between the first measurement in all three laboratories were probably caused by the differences in the measurement geometries used in particular laboratories.
Round-robin measurements To make round-robin measurements a laboratory prepares
94
J. Czarnecki Table 2. Examples of field measurements made with GE(LI) detectors, NAI(TL) detectors and ionization chambers ~IRIH DETECTOR LOCATION TYPE
K
U
T
CS
ZR-NB
OTHER
SUM
ION CHAMBER
JOLIET. Ill 1971
GE(LI) NAI(TL)
2.8 2,7
1,2 i,i
2.5 2,4
0,2 0,3
0,3 0,2
0.i
7,I 6,7
7,8
CHANNAHAN, 111 1971
GE(LI) NAI(TL)
2,6 2,4
1,0 1,1
1,9 1,8
0,2 0,2
0,3 0,2
0,1
6,1 5,7
5,9
MORRIS. Ill 1971
GE(LI) NAI(TL)
2,2 2.2
1,4 1.2
1,7 1,8
0,i 0,i
0.3 0,2
< 0,i
5,7 5,5
WATERFORD. CONN, 1971
GE(LI) NAI(TL)
1.7 1,7
1,7 1,4
3,0 3.4
0,6 0,4
0,2 0,I
7,2 7,0
7.6
WATERFORD. CONN, 1971
GE(LI) NAI(TL)
2,4 2.4
1,6 2,1
2,9 3,1
0,7 0,4
0.2 0,i
7,8 8.1
8,0
FORKED RIVER, N,J, GE(LI) 1971 NAI(TL)
0,2 0,2
0,8 0,9
L~,9 0,8
0,6 0,7
0,2 0,2
2,7 2,8
2.6
FORKED RIVER, N,J, GE(LI) 1971 NAI(TL)
0,3 0,3
0,5 0,5
0,6 0,5
0,8 0,8
0,1 0,1
-
2,3 2,2
2,1
DENVER, COLO, 1965
NAI(TL)
3,4
2,4
7,4
0,3
0,2
13,7
13.8
BIKINI, ATOLL 1967
NAI(TL)
0
0
0
19,0
5,8
24,8
24.0
Table 3. Liquid effluent measurement comparison LABORATORIES
ASK,
SAMPLE
LIQUID WASTE FROM NPS-BEZNAU
COLLECTING DATE
20, 6, 1975
TABLE OF NUCLEAR DATA USED
NPS-BEZNAU
CEN,
~SK
JUELICH 1971
KUER
VARIOUS
(PWR) AND KUER
11,45 H LARA-1975
NANOCURIES PER LITER
UNITS NUCLIDE
NPS-BEZNAU
NPS-BEZNAU
ASK
KUER
144Ce
ii0
112
90
141 Ce
22
23
17
103 Ru
120
%
104
51Cr 137Cs
560
360
438
99
27
125Sb 95Zr 95Nb 58Co 54Mn
66 120
75
55
177
90
180
119
146
340
22~
231
42
29
60Co
310
194
198
124Sb 131I
880
841
807
134Cs 110mAg 65 Zn 106Rb 1/,0La
29,7
24.8
6
2,0
5
5,1
7
1,4 6,4
163 22
127 1,0
95
Environmental radioactivity measurements Table 4. "Rad" waste 3' -analyses from waste disposal tank NPS-Beznau, 9 June 1976 (units: nCi/l)
NPS-BEZNAU
ASK
KUER
GE(LI)[ G** 3
PART OF THE ORIGINAL SAMPLE *) 260 cc DILUTION TO 550 cc (SHAKEN) G** 3
9,6,1976
14,9,1976
15,9,1976
13,9,1976
268
78
108
85
ORIGINAL SAMPLE 500 cc G*"
DATE
G~
1
9,6,1976
2
9,6,1976
54Mn
i00
cc
AFTER i DAY SEDIMENTATION G**
3
(SHAKEN) G** 4
58Co
40
6O
429
113
156
117
60Co
250
38O
3421
877
1360
875
134Cs
1400
2100
6590
1865
2100
2220
137Cs
3200
4100
14840
4200
4760
4680
* From the original sample 170 cms was taken for SR-90 and T-measurements. ** Measurements geometry Table 5. Interlaboratory comparison
LABORATORIES:
EIR-ASK,
KUER,
NPS-BEZNAU (PWR),
NPS-MUEHLEBERG (BWR) DATE
MARCH, 1975
SAMPLE TYPE :
DRIED SOLUTION
UNITS
NANOCURIES
(PREPARED BY ASK/EIR LAB)
NUCLIDE
EXPECTED
ASK/EIR
KUER
NPS-BEZNAU
241Am
39,63
46,2
52,8
97,0
24,0
57Co
23,8
29.5
28,0
28,0
23,0
134Cs
34,8
33.4
33,4
39,0
51,0
137Cs
56,63
55,0
57,5
59,0
74,0
60Co
41,2
43,9
39,4
40,0
56,0
a sample composed o f a selected number o f radionuclides. The activity of the nuclides is carefully chosen. All the other laboratories have to measure the sample and report the results. Round-robin measurements were made two to four times a year. Table 5 shows some results of such measurements. The agreement between the results is good except for 241 Am.
Calibration of the counting equipment using laboratory standards The precision of the measurement results is a function of the type and quality of laboratory standards. In most of
NPS-MUEHLEBERG
our standards from well established foreign laboratories are used (IAEA, Saclay, NBS, Amersham, Brookhaven, etc.).
Conclusions
1. The measurement problems arising due to the necessity to control the radioactive effluents can be treated with a satisfactory accuracy by the nuclear-power-station laboratories. 2. Representative standards should be available in respect o f the measurements of the effluents from NPS.
96 3. The Labs o f the NPS laboratories should be traceable to the laboratories o f the control organizations. 4. The laboratories o f the control organizations (ASK, KUER, SUVA, EGA) should be traceable to internationally "well-known" laboratories. 5. To realize our environmental measurement program we look for standards (a) composed o f natural matrices and containing only natural radioactivity in various concentrations, and (b) composed o f natural matrices and containing natural and artificial radionuclides.
Acknowledgements - I wish to express my thanks to Mr. H. Voelkle, KUER; Mr. H. Loosli and Mr. R. Schleicher, University of Bern; Mrs. M. Bezzegh, EAWAG; Mr. E. Kaufmann, SUVA; Mr. W. Goerlich, Swiss Reactor Research Institut; Mr. M. Heise, NPS-Beznau; Mr. J. P. Ghysels and Mr. G. Schriber, NPS-Miihleberg; for their assistance in the measurements and the information about the capabilities of their laboratories. The critical review of the manuscript by Mr. W. Jeschki, ASK and the editorial work by Mrs. S. Segat and Miss Wyssmann when typing the manuscript are also much appreciated.
J. Czarnecki
References Auxier J. A., Christian D. J., Jones T. D., Kerr G. D., Perdue P. T., Shinpaugh W: H. and Thorngate J. H. (1973) Contribution of natural terrestrial sources to the total radiation dose to man, Oak Ridge National Laboratory-TM--4323, Oak Ridge, TN. Beck H. L., De Campo J. A. and Gogolak C. (1972) In Situ Ge (Li) and NaI (T1) gamma-ray spectrometry, Health and Safety Laboratory-258, New York. Beck H. L., Lowder W. M., Bennett B. G., and Condon W. Y. (1966) Further studies of external environmental radiation, Health and Safety Laboratory-170, New York. Cardinale A., Fritelli L., Lembo G., Gere F. and Ilari O. (197t) Studies of the natural background radiation in Italy, Health Physics 20, 285. De Campo J. A., Beck H. L., and Raft P. U. (1972) High pressure argon ionization chamber systems for the measurement of environmental radiation exposure rates, Health and Safety Laboratory (USA)-260, New York. Gogolak C. and Miller K. M. (1974) Method for obtaining radiation exposure due to a boiling water reactor plum from continuously monitoring ionization chambers, Health Physics 27~ 132. International Atomic Energy Agency (1974) Environmental survaillance around nuclear installations, Proceedings of a Symposium, Warsaw, 5 - 9 Nov. 1973. Jkaya M. (1976) Natural radiation dose in Akiyoshi Cavern and on Karst Plateau, Health Physics 3 It 76.