Development of on-Line Monitoring Device for Marine Radioactive
Pollution
Xinsheng Lv, Guoxiu Qin
*
, Xiaoli Lin, Keyu Meng and Jinming Ma
Shenyang Institute of Engineering, 18 Puchang Dr, 110136 Shenyang, Liaoning, China
Keywords: Nuclear Accident, Seawater Radioactivity, on-Line Monitoring, Plastic Scintillator
Abstract: On-site measurements are indispensable to swiftly and precisely evaluate the magnitude of radioactive
contamination triggered by a nuclear accident or terrorist attack in the ocean. Consequently, an on-line
monitoring device for marine radioactive pollution has been developed. A plastic scintillator was used as the
detector of the device, and a pump was used to extract the seawater around the measuring region, ultimately
enabling continuous on-line measurement. The device measures sea water for 10 minutes, and the minimum
detectable activities of
137
Cs and
60
Co are 1.7 Bq/L and 2.1 Bq/L, respectively. It can promptly and efficiently
the detect events of excessive radioactivity in wastewater and give an alarm signal. The device will be critical
for monitoring radioactive pollution in the maritime region around nuclear power plants, and it has the benefits
of a quick measuring time, a high monitoring frequency, and a high degree of real-time monitoring, allowing
for the early identification of accidents and the implementation of emergency strategies.
1 INTRODUCTION
Developing nuclear power is an excellent technique
to alleviate environmental problems and optimize the
energy structure. In the process of nuclear power
development, the safety of nuclear reactors is very
important. Once a nuclear leakage accident occurs, it
will have a great impact on the environment (Arvela
et al. 1990; Lee et al. 2017; Fereshteh et al. 2021). In
2011, a serious nuclear accident occurred at the
Fukushima nuclear power plant in Japan, resulting in
the release of huge quantities of radionuclide into the
environment (Kinohita et al. 2011; Nakano and
Povinec, 2012). As a nearby territory, China
immediately carried out a vast number of radioactive
monitoring projects. Traditional marine radioactivity
monitoring consists of collecting samples of seawater,
biological organisms, and sediments from critical
sites 1 to 4 times per year, which are then transported
back to the appropriate laboratory for processing and
analysis (Vlastou et al. 2006; Tsabaris 2008). Using
γ-ray spectrometer to measure samples in laboratory
is a time consuming method, which requires chemical
pretreatment of the measured samples. This non real-
time and discontinuous method is difficult to
effectively monitor the marine radioactive pollution,
*
Corresponding author
and it is even more difficult to realize the early
warning of marine radioactive pollution.
On April 13
th
, 2021, the Japanese government
officially agreed to discharge sewage from the
Fukushima Daiichi Nuclear Power Plant into the
ocean at a cabinet meeting that day. Since then, Japan
intends to discharge 1.25 million tons of nuclear
sewage into the sea, with the goal of starting to
discharge in two years. While TEPCO has claimed
that after treatment, most of the radionuclides in the
nuclear sewage except
3
H can be removed. However,
monitoring data reveal that there are radioactive
material residues such as
14
C,
60
Co and
90
Sr that are
difficult to completely remove in the nuclear sewage
after "filtration". β radionuclides, such as
3
H,
14
C and
90
Sr, cannot be monitored online by γ spectrometry,
hence the question of how to monitor β radionuclides
in the water near nuclear power plants in real-time
and precisely has emerged as an essential one.
Furthermore, with the development of nuclear power,
the construction of real-time monitoring network for
radioactivity in sea areas around nuclear power plant
has also been put on the agenda. It will be a trend to
develop a radiation monitoring network along the
whole coast with online monitoring, real-time early
Lv, X., Qin, G., Lin, X., Meng, K. and Ma, J.
Development of on-Line Monitoring Device for Marine Radioactive Pollution.
DOI: 10.5220/0011889200003536
In Proceedings of the 3rd International Symposium on Water, Ecology and Environment (ISWEE 2022), pages 35-39
ISBN: 978-989-758-639-2; ISSN: 2975-9439
Copyright
c
2023 by SCITEPRESS Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
35
warning and other functions (Wedekind et al. 1999;
Tsabaris 2005; Katsumi and Pavel, 2020).
2 INSTRUMENT DESIGN
The designed online monitoring device for marine
radioactive pollution is mainly composed of a
detector, a sampling chamber, a lead chamber and
signal processing unit (see Figure 1). To complete the
continuous measurement and indication of seawater,
the device is required to have the following
characteristics: 1) high sensitivity is required of the
detector; 2) a superior shield layer and fewer
background count; 3) cleanliness and anti-fouling
should be priorities while designing the sampling
chamber; 4) easy to manufacture and reasonable cost;
5) stable, dependable performance over an extended
period of time, as well as simple maintenance.
Figure 1: Structure diagram of the online monitoring device
for marine radioactive pollution.
2.1 Detector Selection
Plastic scintillator is a kind of organic scintillator that
may be used to detect α particles, β particles, γ rays,
neutrons and fission fragments (Suffian et al. 2020;
Kagami et al. 2020). It is widely used in the
measurement of some low-level radioactive or liquid
samples. Plastic scintillator has several benefits,
including its ease of production, low cost, great
mechanical strength, ability to be molded into a
variety of forms, stable performance, strong radiation
resistance, and high corrosion resistance. Plastic
Scintillators are thus perfect for β radionuclide
monitoring in the marine environment. To detect
radioactivity in seawater in real time, the plastic
scintillator is built as a nested mode of circular rings,
with the outermost detector separating the sampling
chamber into an inner and an outer portion (see Figure
2). Seawater enters from the bottom of the detector,
and there are some overflow holes with a diameter of
5 mm on the top of each circle ring detector. When the
pumped seawater exceeds the overflow hole, it will
gradually fill the whole sampling chamber through the
overflow hole, and finally flow out of the sampling
chamber through the water outlet.
Figure 2: Structure of the plastic scintillator detector.
2.2 Design of Lead Chamber
The concentration of radionuclides in the measured
seawater is low most of the time. To reduce the
influence of background, the typical low-background
lead chamber is used as shield. The designed lead
chamber is a cylinder with a size of Φ 40×50 cm, the
thickness of lead is 5 cm. Since natural lead materials
contain
210
Pb and other radionuclides, a 2-mm copper
layer was added to the inside of the lead chamber to
shield the radiation of radioisotopes of lead.
2.3 Design of Sampling Chamber
The sampling chamber is positioned within the lead
chamber, and its size is Φ 25×30 cm. Its main
function is to continuously collect seawater into the
sampling chamber. The sampling vessel is composed
of ABS plastic that is resistant to impact, heat, and
low temperatures. The bottom is equipped with an
input and an outlet for water, enabling the continuous
collection and discharge of seawater. The inner wall
of the sampling chamber (light-transmitting at the
top) is covered with aluminum foil to isolate the
interference of the outside world to the detector and
the photomultiplier tube, and reflect the fluorescence
produced by the interaction of radiation with the
detector back to the photomultiplier tubes.
2.4 Data Processing Unit
The data processing unit consists of signal
discrimination, filtering shaping, and counting
display, which is mainly used to process the nuclear
signal output from the detector and display the results.
Pump
Seawater
Data
processing
Discharge
Lead chamber
Photomultiplier
tube
Light guide
Detector
Sampling
chamber
Pump
Seawater
Data
processing
Pump
Seawater
Data
processing
Discharge
Lead chamber
Photomultiplier
tube
Light guide
Detector
Sampling
chamber
ISWEE 2022 - International Symposium on Water, Ecology and Environment
36
Firstly, the nuclear signals are filtered by signal
discrimination, then it is turned into a Gaussian
waveform and noise interference is minimized. In the
counting display module, the nuclear signals are
classified and counted after filtering, and the result
are displayed.
3 TECHNICAL INDICATORS OF
THE INSTRUMENT
3.1 Minimum Detectable Activity
One of the key performance indicators of the
measuring equipment is the minimum detectable
activity (MDA). It refers to the smallest amount of
radioactivity in a sample or medium that may be
detected with a particular degree of confidence (Choi
et al. 2019). In general, the smaller the MDA in the
same time, the better the detection performance of the
instrument. However, MDA characterizes the
qualitative analysis ability of the system for the
existence of nuclides, which cannot characterize the
quantitative measurement accuracy of the system for
nuclide activity. At the 95% confidence level, MDA
can be expressed as:
2.71 4.65 B
MDA
t
ε
+
=
(1)
where B is the background count; t is the live time of
counting; ε is the detection efficiency. The change
trend of MDA of
137
Cs and
60
Co in seawater with
measurement time by this device is shown in Figure
3.
Figure 3: The change trend of MDA of
137
Cs and
60
Co in
seawater with measurement time by the designed device.
The seawater containing
137
Cs and
60
Co with an
activity concentration of 5 Bq/L were measured
respectively in the laboratory, and the technical
indicators when the device was used as the "activity
detection" function were obtained: the MDA of
137
Cs
and
60
Co were 1.7 Bq/L and 2.1 Bq/L respectively
after 10 minutes of measurement. For the seawater
containing
137
Cs and
60
Co with an activity
concentration of 5 Bq/L, the statistical uncertainty of
measurement for 10 minutes is less than 10%.
3.2 Monitoring Performance of the
Instrument
The MDA test results indicate that the device is
capable of detecting β radionuclide contamination
events in a short time frame. As a real-time
monitoring device, the measurement results must be
provided continuously in a short time. The shorter the
measurement interval, the more precisely the data
may be represented throughout time. In the case of
real-time monitoring, after deducting the background,
the count of the device is less and obeys the Poisson
distribution. The false alarm rate and the missing
alarm rate of the monitoring equipment are the two
most crucial and contradictory technical indicators.
According to the calibration results of the detection
efficiency of the device, based on the Poisson
distribution law, we have formulated the exceeding
threshold and compiled the real-time monitoring
program.
The measured results show that when the activity
concentration of
137
Cs is 5 Bq/L, the total count rate
of the monitoring device is 2.7 cps, or an average of
162 counts per minute. This means that the
mathematical expectation for the device to count in
two minutes is 324. According to Poisson
distribution, the corresponding probability density
was calculated with 324 as the expected value. For
setting different exceeding threshold y (the alarm will
be given if the counts detected in any 2 minutes is
y), "probability of reaching the threshold" is equal to
the curve area on the right side of the medium
threshold.
Set the monitoring cycle of the designed device to
2 minutes. When the count of two adjacent cycles is
greater than or equal to the exceeding threshold, the
device will automatically give an alarm signal. By
setting the threshold value in this way, the number of
false alarms per year can be controlled below 0.1. For
radionuclides with activity concentration greater than
5 Bq/L in seawater, the missing alarm rate is less than
1% after 20 minutes of measurement.
To test the performance of the device, seawater
containing
137
Cs with an activity concentration of 5
Bq/L was measured and monitored continuously for
100 cycles. The monitoring results were analyzed,
and it was found that 60 cycles sent out alarm signals,
Development of on-Line Monitoring Device for Marine Radioactive Pollution
37
with an average delay of 4.52 minutes and a
maximum delay of 7 minutes. Count 100 cycles, and
the results are shown in Figure 4. It can be seen from
Figure 4 that the count obtained by the device is in
good agreement with the Poisson distribution, and it
is effective to use the Poisson distribution law to
design the alarm program.
Figure 4: Comparison of counting statistics of 100 cycles
with the theoretical Value of Poisson distribution.
4 CONCLUSIONS
The designed online monitoring device for
radioactive contamination in seawater has a high
degree of sensitivity, can provide information on
radioactive contamination in seawater in a short
period of time, and has the function of rapid
measurement of radioactive activity concentration in
seawater. In the "detection" aspect, the plastic
scintillators with a low price, stable performance,
good radiation resistance and corrosion resistance.
Combined with the 14.7 L sampling chamber in the
lead chamber, excellent MDA was obtained by
reducing the background. Taking
137
Cs as an
example, MDA measured for 10 minutes can reach
1.7 Bq/L.
As for the "Alarm" feature, we have adopted the
optimized design of inlet and outlet waterways, so
that the seawater in the sampling chamber can be
updated quickly. We have also developed a set of
"short time and less counting" design method based
on Poisson distribution to determine the alarm
threshold and minimize the false alarm rate and
missing alarm rate within a reasonable and acceptable
detection time. For seawater containing
137
Cs with an
activity concentration of 5 Bq/L, it takes only 4.52
minutes on average to give an alarm, and the
probability of missing an alarm after 20 minutes of
monitoring is less than 1%.
ACKNOWLEDGEMENTS
This work was supported by the Shenyang Science
and Technology Bureau (No. 20-206-4-03). The
authors would like to express thanks to the China
Institute of Atomic Energy for its support of this
work.
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