JP6892340B2 - Radiation monitoring system and radiation monitoring method - Google Patents

Description

An embodiment of the present invention relates to a radiation monitoring technique for a facility that handles radioactive substances.

Traditionally, nuclear power plants or nuclear fuel handling facilities have radiation monitoring systems that measure the radiation emitted from pipes. In such a system, the analog signal output by the radiation detector is converted into a digital signal. Then, the concentration of the radioactive substance is calculated based on the digitized dose value and flow rate value.

In addition, there is a device that measures the radiation count rate using a diode pump circuit. This diode pump circuit outputs the pulse signal output from the radiation detector as a logarithmic value.

Jikkenhei 2-107086

Devices that process digital signals consist of semiconductor chips and software. When a high-performance and complicated digital device is used for a radiation monitoring system, there is a problem that it is difficult to fully grasp all the processing contents generated under various conditions and it is difficult to secure reliability. Further, when the analog signal output from the radiation detector is converted into a digital signal, the fraction is cut off, so that the value deviates from the true value by repeating the signal conversion. In particular, if the measurement is continued for a long period of time, the values deviating from the true values are accumulated, and the error may become larger.

An embodiment of the present invention has been made in consideration of such circumstances, and provides a radiation monitoring technique capable of performing processing in the state of an analog signal and ensuring sufficient reliability and accuracy. The purpose is.

The radiation monitoring system according to the embodiment of the present invention includes a radiation detector that outputs a detection signal when detecting radiation emitted from a radioactive substance contained in a fluid, and a radiation detector to which the detection signal is input and a count rate of the radiation. A specific circuit that outputs a detection logarithmic value proportional to the logarithmic value of the fluid, and an integrated flow rate transmitter that outputs a value obtained by integrating the flow rates of the fluid from the start of detection using the radiation detector to the present. A logarithmic conversion circuit that converts the value output by the integrated flow transmitter into a logarithmic flow rate logarithmic value and outputs the value, and the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and the flow rate logarithmic value. It is provided with a concentration calculation circuit for calculating.

According to the embodiment of the present invention, there is provided a radiation monitoring technique capable of performing processing in the state of an analog signal and ensuring sufficient reliability and accuracy.

The block diagram which shows the radiation monitoring system of 1st Embodiment. The flowchart which shows the radiation monitoring method of 1st Embodiment. The block diagram which shows the radiation monitoring system of 2nd Embodiment. The flowchart which shows the radiation monitoring method of 2nd Embodiment. The block diagram which shows the radiation monitoring system of 3rd Embodiment. The flowchart which shows the radiation monitoring method of 3rd Embodiment.

(First Embodiment)
Hereinafter, the present embodiment will be described with reference to the accompanying drawings. First, the radiation monitoring system of the first embodiment will be described with reference to FIGS. 1 and 2. Reference numeral 1 in FIG. 1 is a radiation monitoring system.

The radiation monitoring system 1 is provided in a facility that handles radioactive materials, such as a nuclear power plant or a nuclear fuel handling facility. Such facilities manage the annual exposure of workers. In particular, according to 10CFR20 issued by the United States Nuclear Regulatory Commission, the annual exposure control of workers in the central control room of a nuclear power plant should be carried out by monitoring the concentration of radioactive materials around the workers. ing.

As an example of monitoring the concentration of radioactive substances, a sample gas is extracted from a pipe for sending air to the main control room, and the radiation emitted from the radioactive substances contained in the sample gas is detected. Then, when the detected radiation dose is high and it is determined that the concentration of the radioactive substance is equal to or higher than a predetermined threshold value, an alarm is output to notify the worker of the radioactive contamination.

In the prior art, the radiation detector is placed inside or near a pipe through which a predetermined fluid flows. Then, this radiation detector is used to detect the radiation emitted from the fluid flowing through the pipe. The detection signal when radiation is detected is converted into a digital signal by a radiation detector or a preamplifier. This digital signal is transmitted to the radiation monitor. This radiation monitor counts and outputs the radiation dose based on the input digital signal.

Further, in addition to measuring the radiation dose, there is a desire to accurately calculate the concentration of radioactive substances contained in the fluid by using the flow rate, pressure, or temperature of the fluid flowing through the pipe. The flow rate is a physical quantity representing the amount of movement of a fluid (liquid or gas). That is, the flow rate indicates the amount of movement per unit time. The flow rate of the present embodiment is a volumetric flow rate and represents the volume when the fluid F moves per unit time.

It is possible to perform complicated processing such as calculating the concentration of radioactive substances using a digital device. In digital devices, a CPU or the like performs logical operations and numerical operations according to a predetermined instruction set.

However, in order to grasp all the processing contents of such a digital device, it is necessary to confirm all of the circuit configuration of the microchip and the source code of the software. Further, even if all the processing contents of the digital device are grasped, the processing result may fluctuate when actually used. In particular, since digital processing executed in a digital circuit is basically discrete value processing, a defect in software or hardware may cause a peculiar output under certain conditions. For example, a specific value may output a significantly different result. In addition, an event that has not occurred during the development test of the digital circuit may occur after the digital circuit is installed in the field. When the function of the digital circuit is impaired due to a cause such as a coding error, it becomes a failure factor for a plurality of subsequent processes using the processing result, which is called a common cause failure. Common cause caused by software When a failure occurs, it is difficult to identify the cause of the failure.

When digital devices are used in systems that monitor radioactive materials and ensure safety at nuclear power plants, it is necessary to verify in advance that they will not cause failures of common cause. Here, it takes a huge amount of verification man-hours to confirm that it functions correctly in all cases of signal processing. In addition, there is a risk that the installation of the system will not be permitted unless the explanation to the regulator is ensured.

In recent years, regulations by regulatory authorities when using such digital devices for safety systems have been tightened. Considering this, there is a risk in using a digital device for the radiation monitoring system 1. Therefore, in the present embodiment, the concentration of the radioactive substance is measured only by processing the analog signal without using a digital device, so that a common cause failure does not occur. In addition, simple processing ensures accountability to regulators.

As shown in FIG. 1, in a nuclear power plant or the like, a pipe 2 through which a predetermined fluid F flows is provided. The fluid F may be a gas such as air or a liquid such as water. The concentration of the radioactive substance contained in the fluid F is measured using the radiation monitoring system 1.

The detection pipe 3 for extracting the detection fluid F from the pipe 2 is branched. One end and the other end of the detection tube 3 are connected to the pipe 2, respectively. The fluid F that has passed through the detection pipe 3 returns to the pipe 2 again. The detection tube 3 is provided with a filter unit 4 in which a filter for securing a trace amount of substances contained in the fluid F is arranged. The filter is replaced with a new one every time a regular inspection is performed. Further, examples of substances accumulated in the filter include dust or iodine in the air.

The radiation monitoring system 1 of the first embodiment is proportional to a radiation detector 5 that outputs a detection signal when it detects radiation emitted from a radioactive substance contained in the fluid F, and a logarithmic radiation count rate. The diode pump circuit 6 that outputs the detected logarithmic value, the integrated flow rate transmitter 7 that outputs the integrated value of the flow rate of the fluid F flowing through the detection tube 3, and the value output by the integrated flow rate transmitter 7 are logarithmicized. A logarithmic conversion circuit 8 that converts the flow rate to a numerical value and outputs it, a conversion coefficient circuit 9 that outputs a conversion coefficient used for converting the concentration of radioactive substances, and a concentration calculation circuit 10 that calculates the concentration of radioactive substances contained in the fluid F. And the management device 11 in which the calculated concentration of the radioactive substance is input.

The radiation detector 5 detects the radiation emitted from the filter unit 4. The radiation detector 5 outputs a pulsed detection signal when radiation having a specific energy or more is incident. For example, when radiation is incident on the radiation detector 5, a one-pulse signal is output when the voltage corresponding to the intensity of the energy lost in the radiation-sensitive region of the radiation detector 5 is equal to or higher than a certain value. Will be done. Then, this detection signal (analog signal) is input to the diode pump circuit 6. The diode pump circuit 6 (charge pump circuit) is an electronic circuit that raises a voltage by combining a capacitor and a switch.

Generally, the measurement range of the radiation count rate is about 6 to 7 decades (1.0 × 10-1 cps to 1.0 × 106 cps). A diode pump circuit 6 can be used for a wide range of measurements. By counting the pulse signal output from the radiation detector 5 by the diode pump circuit 6, the value output from the diode pump circuit 6 becomes the voltage value of the log (counting rate). The diode pump circuit 6 makes it possible to accurately calculate the count rate in a wide range even if it is an analog circuit.

When a detection signal (pulse signal) is input from the radiation detector 5, the diode pump circuit 6 (specific circuit) outputs a detection logarithmic value proportional to the logarithmic radiation count rate. The logarithm used in this embodiment is a common logarithm with a base of 10.

The integrated flow rate transmitter 7 outputs a value obtained by integrating the flow rates of the fluid F flowing through the detection tube 3 from the start of detection using the radiation detector 5 to the present. This value is output as an analog signal.

The logarithmic conversion circuit 8 is a circuit that converts a value input using an analog signal into a logarithmic value and outputs the value. The value output from the integrated flow rate transmitter 7 is input to the logarithmic conversion circuit 8. Then, the logarithmic conversion circuit 8 converts the value input from the integrated flow rate transmitter 7 into a logarithmic flow rate logarithmic value and outputs the logarithmic value. The flow rate logarithmic value is a logarithmic value of the volumetric flow rate of the fluid F, and is a volume logarithmic value relating to the volume of the fluid F.

A digital element such as a microchip is not used in the logarithmic conversion circuit 8. However, if it is a microchip having a simple circuit configuration, it may be mounted on the logarithmic conversion circuit 8. That is, there is no possibility that the processing result will fluctuate when actually used, and if it is a known microchip, it may be mounted on the logarithmic conversion circuit 8.

The conversion coefficient circuit 9 outputs a conversion coefficient used for converting the concentration of radioactive substances. The conversion coefficient is a count for converting the detected logarithmic value (counting rate) into a concentration (becquerel). When calculating the concentration of radioactive substances, the radiation count rate (cps) is multiplied by the conversion factor (Bq / cps). The conversion coefficient circuit 9 is provided with an operation unit 12 for the administrator to perform an operation for setting the conversion coefficient in advance.

The concentration calculation circuit 10 can add or subtract the detection logarithmic value input from the diode pump circuit 6 and the flow rate logarithmic value input from the logarithmic conversion circuit 8. Further, the concentration calculation circuit 10 can calculate the concentration of the radioactive substance contained in the fluid F by adding or subtracting a conversion coefficient to the value after adding or subtracting the detected logarithmic value and the flow rate logarithmic value. It is possible.

In the present embodiment, since the value used for calculating the concentration of the radioactive substance is logarithmic, it is not necessary to perform multiplication or division, and the concentration of the radioactive substance can be calculated by addition or subtraction. That is, the addition of the numerical value after the logarithmic conversion corresponds to the multiplication of the numerical value before the logarithmic conversion, and the subtraction of the numerical value after the logarithmic conversion corresponds to the division of the numerical value before the logarithmic conversion. In this way, the count rate output from the diode pump circuit 6 as a logarithmic value can be used as it is. Therefore, the conversion error of the numerical value can be minimized.

By adding or subtracting a predetermined logarithm in the concentration calculation circuit 10, a calculation corresponding to log ((detection logarithm × conversion coefficient) ÷ flow rate logarithm) is performed. Further, since the conversion coefficient also corresponds to the logarithmic value, the process of converting to the concentration of the radioactive substance can be performed by adding or subtracting the logarithmic value.

The value of the concentration of the radioactive substance calculated by the concentration calculation circuit 10 is input to the control device 11. The management device 11 determines whether or not the concentration of the radioactive substance is equal to or higher than a predetermined threshold value. Here, the management device 11 outputs an alarm when the concentration of the radioactive substance is equal to or higher than the threshold value, and notifies the worker of the radioactive contamination.

Next, the radiation monitoring method executed by the radiation monitoring system 1 will be described with reference to the flowchart of FIG. In addition, FIG. 1 is referred to as appropriate. In the description of each step in the following flowchart, for example, the part described as "step S11" is abbreviated as "S11".

As shown in FIG. 2, first, the radiation detector 5 starts detecting radiation. Here, the radiation detector 5 outputs a detection signal when radiation having a specific energy or more is incident (S11). Next, the detection signal output from the radiation detector 5 is input to the diode pump circuit 6. Here, the diode pump circuit 6 outputs a detection logarithmic value proportional to the logarithmic value of the radiation count rate counted based on the input of the detection signal (S12).

Next, the integrated flow rate transmitter 7 outputs a value obtained by integrating the flow rates of the fluid F flowing through the detection tube 3 (S13). This value is input to the logarithmic conversion circuit 8. Next, the logarithmic conversion circuit 8 converts the value input from the integrated flow rate transmitter 7 into a logarithmic flow rate logarithmic value and outputs it (S14).

Next, the detected logarithmic value output from the diode pump circuit 6 is input to the concentration calculation circuit 10. Further, the flow rate logarithmic value output from the logarithmic conversion circuit 8 is input to the concentration calculation circuit 10. Here, the concentration calculation circuit 10 subtracts the flow rate logarithmic value from the detection logarithmic value (S15).

Next, the conversion coefficient circuit 9 outputs the conversion coefficient (S16). This conversion coefficient is input to the concentration calculation circuit 10. Next, the concentration calculation circuit 10 adds a conversion coefficient to the value after subtracting the flow rate vs. value from the detection pair value (S17). Then, the concentration calculation circuit 10 calculates the concentration of the radioactive substance contained in the fluid F (S18). The concentration of the radioactive substance calculated by the concentration calculation circuit 10 is input to the management device 11.

(Second Embodiment)
Next, the radiation monitoring system 1A of the second embodiment will be described with reference to FIGS. 3 to 4. The same components as those shown in the above-described embodiment are designated by the same reference numerals, and duplicate description will be omitted.

As shown in FIG. 3, the radiation monitoring system 1A of the second embodiment is a pressure transmitter 13 that outputs a measured value of the pressure of the fluid F flowing through the detection tube 3 in addition to the configuration of the first embodiment described above. And a temperature transmitter 14 that outputs a measured value of the temperature of the fluid F flowing through the detection tube 3.

The pressure transmitter 13 outputs a measured value of the pressure of the fluid F flowing through the detection tube 3 as an analog signal. This value is input to the logarithmic conversion circuit 8. Then, the logarithmic conversion circuit 8 converts the value input from the pressure transmitter 13 into a logarithmic pressure logarithmic value and outputs the logarithmic value.

This pressure logarithmic value is input to the concentration calculation circuit 10. Then, the concentration calculation circuit 10 adds or subtracts the detection logarithmic value and the pressure logarithmic value to correct the concentration of the radioactive substance. In this way, it is possible to correct the fluctuation of the concentration of the radioactive substance based on the pressure of the fluid F.

The temperature transmitter 14 outputs a measured value of the temperature of the fluid F flowing through the detection tube 3 as an analog signal. This value is input to the logarithmic conversion circuit 8. Then, the logarithmic conversion circuit 8 converts the value input from the temperature transmitter 14 into a logarithmic temperature logarithmic value and outputs the logarithmic value.

This temperature logarithmic value is input to the concentration calculation circuit 10. Then, the concentration calculation circuit 10 adds or subtracts the detection logarithmic value and the temperature logarithmic value to correct the concentration of the radioactive substance. In this way, it is possible to correct the fluctuation of the concentration of the radioactive substance based on the temperature of the fluid F.

By adding or subtracting a predetermined logarithm in the concentration calculation circuit 10, the calculation corresponding to log ((detection logarithm × conversion coefficient) ÷ (flow rate logarithm × pressure vs. value × temperature vs. value)) can be performed. Made.

Further, even if the values output from the integrated flow rate transmitter 7 are signals of the same value, the amount of substance of the fluid F actually flowing differs depending on the pressure and temperature. For example, the amount of substance of the flowing fluid F fluctuates according to the equation of state (PV = nRT). Therefore, in the second embodiment, the correction based on the pressure and the temperature is performed in order to accurately calculate the concentration of the radioactive substance.

Next, the radiation monitoring method executed by the radiation monitoring system 1A will be described with reference to the flowchart of FIG. In addition, FIG. 3 is referred to as appropriate.

As shown in FIG. 4, first, the radiation detector 5 starts detecting radiation. Here, the radiation detector 5 outputs a detection signal when radiation having a specific energy or more is incident (S21). Next, the detection signal output from the radiation detector 5 is input to the diode pump circuit 6 (specific circuit). Here, the diode pump circuit 6 outputs a detection logarithm value proportional to the logarithm of the count rate of radiation counted based on the input of the detection signal (S22).

Next, the integrated flow rate transmitter 7 outputs a value obtained by integrating the flow rates of the fluid F flowing through the detection tube 3 (S23). This value is input to the logarithmic conversion circuit 8. Next, the logarithmic conversion circuit 8 converts the value input from the integrated flow rate transmitter 7 into a logarithmic flow rate logarithmic value and outputs it (S24).

Next, the pressure transmitter 13 outputs a measured value of the pressure of the fluid F flowing through the detection tube 3 (S25). This value is input to the logarithmic conversion circuit 8. Next, the logarithmic conversion circuit 8 converts the value input from the pressure transmitter 13 into a logarithmic pressure logarithmic value and outputs it (S26).

Next, the temperature transmitter 14 outputs a measured value of the temperature of the fluid F flowing through the detection tube 3 (S27). This value is input to the logarithmic conversion circuit 8. Next, the logarithmic conversion circuit 8 converts the value input from the temperature transmitter 14 into a logarithmic temperature logarithmic value and outputs it (S28).

Next, the detected logarithmic value output from the diode pump circuit 6 is input to the concentration calculation circuit 10. Further, the flow rate logarithmic value, the pressure logarithmic value, and the temperature logarithmic value output from the logarithmic conversion circuit 8 are input to the concentration calculation circuit 10. Here, the concentration calculation circuit 10 subtracts the value obtained by adding the flow rate vs. value, the pressure vs. value, and the temperature vs. value from the detection log value (S29).

Next, the conversion coefficient circuit 9 outputs the conversion coefficient (S30). This conversion coefficient is input to the concentration calculation circuit 10. Next, the concentration calculation circuit 10 adds a conversion coefficient to the value after subtracting the value obtained by adding the flow rate vs. value, the pressure vs. value, and the temperature vs. value from the detection log value (S31). Then, the concentration calculation circuit 10 calculates the concentration of the radioactive substance contained in the fluid F (S32). The concentration of the radioactive substance calculated by the concentration calculation circuit 10 is input to the management device 11.

(Third Embodiment)
Next, the radiation monitoring system 1B of the third embodiment will be described with reference to FIGS. 5 to 6. The same components as those shown in the above-described embodiment are designated by the same reference numerals, and duplicate description will be omitted.

In the above-described embodiment, the radioactive substances accumulated in the filter of the filter unit 4 provided in the detection tube 3 are monitored, but in the radiation monitoring system 1B of the third embodiment, the radiation is not used. Calculate the concentration of the substance. In the third embodiment, when a fluid containing a radioactive rare gas flows through the detection tube 3, the radiation emitted by the fluid F accumulated in the container having a constant sampling volume is detected and divided by the sampling volume. The concentration of radioactive substances is calculated by carrying out.

As shown in FIG. 5, in the radiation monitoring system 1B of the third embodiment, the sampler container 15 provided in the detection tube 3 for temporarily storing the fluid F and the volume inside the sampler container 15 (sampler volume) are logarithmic. It is provided with a volume-to-value circuit 16 that outputs the converted volume-to-value.

The radiation detector 5 detects the radiation emitted from the fluid F stored inside the sampler container 15. The volume logarithmic value is a logarithmic value of the volume inside the sampler container 15, and is a constant value (fixed value) corresponding to the sampler container 15. Further, the volume-to-value circuit 16 is provided with an operation unit 17 for performing an operation for the administrator to set the volume-to-value in advance. It should be noted that a constant volume-to-value circuit may be stored in advance in the volume-to-value circuit 16 without providing the operation unit 17.

The volume-to-value output from the volume-to-value circuit 16 is input to the concentration calculation circuit 10. In the concentration calculation circuit 10, the detection logarithmic value input from the diode pump circuit 6 and the volume vs. numerical value input from the volume vs. numerical circuit 16 are added or subtracted. By adding or subtracting a predetermined logarithmic value in the concentration calculation circuit 10, the calculation corresponding to log ((detection vs. numerical value × conversion coefficient) ÷ (volume vs. numerical value × pressure vs. numerical value × temperature vs. numerical value)) can be performed. Made.

Next, the radiation monitoring method executed by the radiation monitoring system 1B will be described with reference to the flowchart of FIG. In addition, FIG. 5 is referred to as appropriate.

As shown in FIG. 6, first, the radiation detector 5 starts detecting radiation. Here, the radiation detector 5 outputs a detection signal when radiation having a specific energy or more is incident (S41). Next, the detection signal output from the radiation detector 5 is input to the diode pump circuit 6 (specific circuit). Here, the diode pump circuit 6 outputs a detection logarithm value proportional to the logarithm of the count rate of radiation counted based on the input of the detection signal (S42).

Next, the volume logarithmic circuit 16 outputs a volume logarithmic value corresponding to the internal volume (sampler volume) of the sampler container 15 (S43). Next, the pressure transmitter 13 outputs a measured value of the pressure of the fluid F flowing through the detection tube 3 (S44). This value is input to the logarithmic conversion circuit 8. Next, the logarithmic conversion circuit 8 converts the value input from the pressure transmitter 13 into a logarithmic pressure logarithmic value and outputs it (S45).

Next, the temperature transmitter 14 outputs a measured value of the temperature of the fluid F flowing through the detection tube 3 (S46). This value is input to the logarithmic conversion circuit 8. Next, the logarithmic conversion circuit 8 converts the value input from the temperature transmitter 14 into a logarithmic temperature logarithmic value and outputs it (S47).

Next, the detected logarithmic value output from the diode pump circuit 6 is input to the concentration calculation circuit 10. Further, the volume logarithmic value, the pressure logarithmic value, and the temperature logarithmic value output from the logarithmic conversion circuit 8 are input to the concentration calculation circuit 10. Here, the concentration calculation circuit 10 subtracts the value obtained by adding the volume vs. value, the pressure vs. value, and the temperature vs. value from the detection log value (S48).

Next, the conversion coefficient circuit 9 outputs the conversion coefficient (S49). This conversion coefficient is input to the concentration calculation circuit 10. Next, the concentration calculation circuit 10 adds a conversion coefficient to the value after subtracting the value obtained by adding the volume vs. value, the pressure vs. value, and the temperature vs. value from the detected logarithmic value (S50). Then, the concentration calculation circuit 10 calculates the concentration of the radioactive substance contained in the fluid F (S51). The concentration of the radioactive substance calculated by the concentration calculation circuit 10 is input to the management device 11.

Although the flowchart of the present embodiment illustrates a mode in which each step is executed in series, the context of each step is not necessarily fixed, and even if the context of some steps is exchanged. good. Also, some steps may be executed in parallel with other steps.

In the present embodiment, the diode pump circuit 6 is illustrated as a specific circuit, but the specific circuit may be a circuit other than the diode pump circuit 6. For example, when the radiation detector 5 outputs a pulsed detection signal, a circuit that counts the number of pulses and obtains a logarithmic count rate may be used as a specific circuit. Further, when the radiation detector 5 outputs a detection signal indicating a predetermined value by increasing or decreasing the current, a circuit that amplifies the value of this current with a logarithmic amplifier may be a specific circuit.

According to the embodiment described above, processing is performed in the state of an analog signal by providing a concentration calculation circuit that calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and the predetermined logarithmic value. It is possible to ensure sufficient reliability and accuracy.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, changes, and combinations can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

1 (1A, 1B) ... radiation monitoring system, 2 ... piping, 3 ... detection tube, 4 ... filter section, 5 ... radiation detector, 6 ... diode pump circuit, 7 ... integrated flow transmitter, 8 ... logarithmic conversion circuit, 9 ... Conversion diode circuit, 10 ... Concentration calculation circuit, 11 ... Management device, 12 ... Operation unit, 13 ... Pressure transmitter, 14 ... Temperature transmitter, 15 ... Sampler container, 16 ... Volume vs. numerical circuit, 17 ... Operation unit , F ... Fluid.

Claims (7)

A radiation detector that outputs a detection signal when it detects radiation emitted from radioactive substances contained in a fluid,
A specific circuit to which the detection signal is input and outputs a detection logarithm proportional to the logarithm of the radiation count rate, and
An integrated flow rate transmitter that outputs a value obtained by integrating the flow rates of the fluid from the start of detection using the radiation detector to the present.
A logarithmic conversion circuit that converts the value output by the integrated flow transmitter into a logarithmic flow rate logarithmic value and outputs it.
A concentration calculation circuit that calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and the flow rate logarithmic value.
Radiation monitoring system equipped with. A container for storing therein a flow body,
A radiation detector that outputs a detection signal when it detects radiation emitted from a radioactive substance contained in the fluid, and
A specific circuit to which the detection signal is input and outputs a detection logarithm proportional to the logarithm of the radiation count rate, and
A concentration calculation circuit that calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithm and the volume logarithm of the volume inside the container.
That includes the radiological monitoring system. A radiation detector that outputs a detection signal when it detects radiation emitted from radioactive substances contained in a fluid,
A specific circuit to which the detection signal is input and outputs a detection logarithm proportional to the logarithm of the radiation count rate, and
A conversion coefficient circuit that outputs a conversion coefficient used for converting the concentration of the radioactive substance, and a conversion coefficient circuit.
A concentration calculation circuit that calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and a predetermined logarithmic value, and a concentration calculation circuit.
With
The concentration calculating circuit, the detected values after subtracting the predetermined logarithmic values from logarithm, ray monitoring system release you adding the conversion factor. A radiation detector that outputs a detection signal when it detects radiation emitted from radioactive substances contained in a fluid,
A specific circuit to which the detection signal is input and outputs a detection logarithm proportional to the logarithm of the radiation count rate, and
A pressure transmitter that outputs the measured value of the fluid pressure, and
A logarithmic conversion circuit that converts the value output by the pressure transmitter into a logarithmic pressure logarithmic value and outputs it.
A concentration calculation circuit that calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and a predetermined logarithmic value, and a concentration calculation circuit.
With
The concentration calculating circuit, ray monitoring system release you correct the density of the radioactive substances on the basis of the pressure logarithm. A radiation detector that outputs a detection signal when it detects radiation emitted from radioactive substances contained in a fluid,
A specific circuit to which the detection signal is input and outputs a detection logarithm proportional to the logarithm of the radiation count rate, and
A temperature transmitter that outputs the measured value of the fluid temperature, and
A logarithmic conversion circuit that converts the value output by the temperature transmitter into a logarithmic temperature logarithmic value and outputs it.
A concentration calculation circuit that calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and a predetermined logarithmic value, and a concentration calculation circuit.
With
The concentration calculating circuit, ray monitoring system release you correct the density of the radioactive substances on the basis of the temperature logarithm. The radiation monitoring system according to any one of claims 1 to 5, wherein the specific circuit is a diode pump circuit. A step in which a radiation detector outputs a detection signal when it detects radiation emitted from a radioactive substance contained in a fluid.
A step in which the detection signal is input to a specific circuit, and the specific circuit outputs a detection logarithmic value proportional to the logarithm of the radiation count rate.
A step in which the integrated flow rate transmitter outputs a value obtained by integrating the flow rates of the fluid from the start of detection using the radiation detector to the present.
A step in which the logarithmic conversion circuit converts the value output by the integrated flow rate transmitter into a logarithmic flow rate logarithmic value and outputs the step.
A step in which the concentration calculation circuit calculates the concentration of the radioactive substance contained in the fluid based on the detected logarithmic value and the flow rate logarithmic value.
Radiation monitoring methods including.

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