JPH01250087A - Digital radiation monitor device - Google Patents

Abstract

PURPOSE:To confirm the soundness of the monitor device while eliminating the need to fit a bug source by providing a function for setting a lower-limit warning set value below the lower-limit range of a measurement range. CONSTITUTION:The radiation detection signal from a digital radiation detector 1 is inputted to a measuring instrument 3. A control part 32 measures a radiation level and displays the result on a graphic display part 34 in bar and digitally. When the measured value of the radiation level is lower than the lower limit of the measurement range of the measuring instrument 3, the graphic display part 34 displays the measured value only digitally. If abnormality, e.g. a down scale is generated in the monitor device, the measured value is lower than the lower-limit warning set value, so its lower-limit warning output is sent out through a digital output part 36.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a digital radiation monitoring device installed in a nuclear power plant that handles radioactive materials.

(Prior Art) Generally, a radiation monitor device is installed in a nuclear power plant such as a nuclear power plant that handles radioactive materials. This radiation monitoring device detects radiation using radiation detectors installed in each area and process of a nuclear power plant, and continuously monitors the radioactivity level using a measuring device. This system is designed to issue a warning to the operator when the temperature exceeds the specified level. As this type of radiation monitoring device, analog radiation monitoring devices have conventionally been widely used.

This analog radiation monitoring device detects radiation using analog radiation detectors (GM tube detectors, etc.) installed in each area and process of a nuclear power plant.
The radioactivity level is calculated in an analog manner using a measuring device (logarithmic dose rate meter, etc.) and displayed on a hardware meter.

By the way, in this type of analog radiation monitor device, when the background level is usually out of the measurement range of the monitor device, the meter display will be in a state as shown by the broken line A in FIG. 5. Furthermore, since the lower limit alarm setting value for generating a lower limit alarm when the monitor device is abnormal can only be set within the measurement range of the monitor device, a lower limit alarm will be generated in such a state. Therefore, in this case, is the background level normally low?

It becomes impossible to determine whether the indication has become low due to an abnormality in the monitor device. Therefore, in analog radiation monitor devices, in order to confirm the health of the monitor device, the meter display is forced to be in the state shown by solid line B in Figure 5 (a state above the lower limit alarm setting value). , a bug source for each analog radiation detector installed in the plant.
is installed so that a lower limit alarm is generated only when there is an abnormality in the monitor device.

However, such a device has various problems as described below.

(a) Since a bug source (ray source) is attached to each analog radiation detector, for example, 50 units are attached per plant, it is extremely difficult to manage them.

(b) The set value of the bug source must be as low as possible in consideration of the influence on the measurement equipment, as well as the half-life of the bug source and the accuracy of the 1llllJ constant device.

It is necessary to correct the sensitivity of each detector, making it extremely difficult to set and adjust the set value of the bug source.

For example, the measuring range of the measuring device is 10 to 1 to 103 mR.
The method for adjusting the bug source of the /H detector is shown below. That is, ■lower limit alarm setting value -〇, 1% (10IIlv),
■Lower limit reset span = 2±1% (FS), ■Bug source half-life S: approximately 28.8 years, attenuation amount per year 2.
When set to 4%, considering the reset span difference when returning from the lower limit from ■ and ■, 93.196 or more -1,3X10-"m R/H or less ■,
From ■, considering the attenuation of the bug source, 02.5% or more -1,26
1,3+1.26)XIO'-2,56XIO-'a+
It is necessary to do more than R/H. Here, considering the 5% setting error of the bug source itself, (2,56X10-'m R/H) ±2,5%-
~3. 2 X 10"'m R/H needs to be set as an initial setting value using a radiation source (S0) Therefore, in order to set the R/H to a value such as It is attached to the device.

(Issue 8 to be solved by the invention) As described above, in the conventional analog radiation monitoring device, a bug source must be attached to each analog radiation detector in order to confirm the health of the monitoring device. There was a problem.

The purpose of the present invention is to eliminate the need for installing a bug source, and
An object of the present invention is to provide a digital radiation monitoring device that allows checking the health of the monitoring device.

[Structure of the Invention] (Means for Solving the Problem) In order to achieve the above object, the present invention provides a digital radiation detector that is installed in a nuclear power plant that handles radioactive materials and detects radiation, and a digital radiation detector that detects radiation. The radioactivity level measured by the radiation detector is displayed as a bar on a display means having a predetermined measurement range and continuously monitored, and when the radioactivity level exceeds a predetermined level, a message to that effect is displayed. In a digital radiation monitor device consisting of a measuring device that generates an alarm, there is a function to digitally display measured values below the lower limit of the measurement range on the display means, and a function to generate a lower limit alarm when the monitor device itself is abnormal. lower limit alarm set value.

The II constant device is equipped with a function to set the measurement range below the lower limit.

(Function) Therefore, in the digital radiation monitor device of the present invention, the lower limit alarm set value can be set below the lower limit of the measurement range, so that even if the background level is normally below the lower limit of the measurement range of the measurement device, If the lower limit alarm set value is set below this value, the lower limit alarm will be generated only when the monitor device is abnormal, making it possible to eliminate the need for a bug source. In addition, by being able to digitally display measured values that are below the lower limit of the measuring range of the measuring device, even if the measured value is between the lower limit of the measuring range and the lower limit alarm setting value, the digital display allows you to check the health of the monitoring device. It becomes possible to confirm.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing an example of the configuration of a digital radiation monitoring device according to the present invention. As shown in the figure, this digital radiation monitoring device is composed of a digital radiation detector 1, a field unit 2, and a measuring device 3.

Further, the digital radiation detector 1 and the field unit 2 are connected by a coaxial cable 4, and the field unit 2 and the measurement device 3 are connected by an optical fiber cable 5.

Here, the digital radiation detector 1 is installed in each area and process of a nuclear power plant that handles radioactive materials, and uses, for example, a pulse type detector. This digital radiation detector 1 is equipped with a minute signal processing circuit and a high-voltage power supply for the detector, and detects radiation and converts an analog signal corresponding to the radiation into a digital signal and outputs the digital signal. In addition, the field unit 2 is equipped with a transmission circuit and an electrical/optical conversion circuit, and in order to transmit signals for N detector channels (for example, 16 channels) to the measuring device 3 by optical multiplexing, This is what we do. Furthermore, the measuring device 3 is capable of processing detector signals for M channels (for example, 32 channels maximum) in one unit, and includes an optical/electrical conversion circuit 31 and a control section 32.
, a display control section 33 , a graphic display section 34 , an analog output section 35 , a digital output section 36 , and a communication circuit 37 . Note that 38 is an optical/electrical conversion circuit 31. Control unit 32. This is a pass line for connecting the analog output section 35, digital output section 361, and communication circuit 37 to each other.

Here, the optical/electrical conversion circuit 31 converts an optical signal transmitted from the field unit 2 into an electrical signal corresponding to the optical signal and outputs the electrical signal. Further, the control unit 32 inputs the output signal from the optical/electric conversion circuit 31, and performs the following (a) to
It has each of the functions (i).

(a) A function to calculate a monitor level based on the output signal from the optical/electric conversion circuit 31. (b) A function to output the calculation result in (a) in analog form to an external recorder or the like via the analog output section 35. (c) A function of outputting the calculation result in (a) via the communication circuit 37 in response to a data transmission request from a host computer or the like. (d) A function for displaying the calculation results in (a) in a bar format and digitally on the graphic display section 34 in response to a data display request from the display control section 33.

(e) A function that generates an alarm output to the outside via the digital output section 36 when the radioactivity level exceeds a predetermined level as a result of the calculation in (a). (f) Function to digitally display measured values below the lower limit of the measurement range of the measuring device 3 on the graphic display section 34 via the display control section 33; (g) Generate a lower limit alarm when the main body of the monitor device is abnormal; A function to set the lower limit alarm setting value for the measurement device 3 below the lower limit of the measurement range. (h) A function to generate a lower limit alarm output to the outside via the digital output section 36 when the main body of the monitor is abnormal. (i
) (h) determines whether the occurrence of the lower limit alarm output is caused by an abnormality in the digital radiation detector 1 or the measuring device 3, and displays the determination result on the graphic display unit 34 via the display control unit 33. Ability to display digitally. Note that the graphic display section 34 is composed of, for example, an EL display.

In the digital radiation monitoring device configured as described above, the radiation detection signal detected by the digital radiation detector is converted into a digital signal and input to the field unit 2 through the coaxial cable 4. The field unit 2 performs optical multiplexing, converts the input signal into an optical signal, and transmits the optical multiplexed signal to the measuring device 3 through the optical fiber cable 5.

On the other hand, in the optical/electrical conversion circuit 31 of the #j determination device 3, the optical signal transmitted from the field unit 2 is converted into an electrical signal and output. The control section 32 performs a monitor level calculation based on this electrical signal, and the result of this calculation is outputted in analog form to an external recorder or the like via the analog output section 35. Further, this calculation result is outputted via the communication circuit 37 in response to a data transmission request from a host computer or the like. Furthermore, the measured value of the radioactivity level, which is the result of this calculation, is displayed as a bar and digitally on the graphic display section 34 in response to a data display request from the display control section 33, thereby confirming the health of the monitor device. be able to. In this case, if the radioactivity level, which is the result of the above calculation, exceeds a predetermined level, an alarm output to that effect is generated externally via the digital output unit 36 to notify the operator. Ru.

On the other hand, the measured value of the radioactivity level, which is the result of the above calculation, is
If it is below the lower limit of the measurement range of the measuring device 3, only the digital display of the measured value is performed on the graphic display section 34 via the display control section 33, so that the health of the monitoring device can be confirmed. In addition, if the normal background level is below the lower limit of the measurement range of the measuring device 3, the lower limit alarm setting value for generating a lower limit alarm when the monitor device main body is abnormal is, for example, equivalent to the normal background level. is set to the value of Therefore, even if the background level is normally below the lower limit of the measurement range of the measuring device 3, the lower limit alarm output is not generated. On the other hand, if an abnormality (generally downscaling) occurs in the monitor device, the above-mentioned calculation result will be below the lower limit alarm set value, and the lower limit alarm output to that effect will be output from the digital output section 36. is generated to the outside via the , and this can be confirmed. In addition, when this lower limit alarm output is generated, a simulated pulse is input to the measuring device 3 as a calibration mode as shown in Fig. 4, and the lower limit alarm output is determined depending on whether the display due to fidgeting is performed normally. It is determined whether the occurrence is due to an abnormality in the digital radiation detector 1 ′ or the measuring device 3 , and the determination result is digitally displayed on the graphic display section 34 via the display control section 33 . That is, if the display using the simulated pulse is performed normally, it will indicate that "the digital radiation detector 1 is abnormal", and conversely, if the display using the simulated pulse is not performed normally, it will indicate that the "measuring device 3 is abnormal". will be displayed.

FIG. 2 shows an example of a bar display and a digital display of the measured value when the measured value of the radioactivity level, which is the calculation result, is within the measurement range of the measuring device 3. Further, FIG. 3 shows an example of a digital display of the measured value when the measured value of the radioactivity level, which is the calculation result, is below the lower limit of the measurement range of the measuring device 3. As shown in Fig. 3, when the background level is normally below the lower limit of the measurement range of the measuring device 3, that value is set as the lower limit alarm setting value, so that the #1 constant value becomes the upper limit of the measurement range. Even if the measured value is between the maximum and alarm set values, the health of the monitoring device can be confirmed by displaying the measured value on a digital display.

As described above, in the digital radiation monitor device of this embodiment, the lower limit alarm setting value can be set below the lower limit of the measurement range of the measuring device 3, so that the background level is normally lower than the lower limit of the measuring range of the measuring device 3. Even if it is below, if you set the lower limit alarm setting value to the value equivalent to that value, the lower limit alarm will be generated only when the monitor device is above the value.
It becomes possible to eliminate the need for bug sources that were previously necessary. Therefore, it is necessary to attach a bug source to each analog radiation detector, which is very difficult to manage, and it is very difficult to set the setting value of the bug source. All problems can be solved. In addition, by being able to digitally display the measured value below the lower limit of the measuring range of the measuring device 3, even if the measured value is between the lower limit of the measuring range of the measuring device 3 and the lower limit alarm setting value, the digital display This makes it possible to check the health of the monitor device. Furthermore, even if the background level is normally below the lower limit of the measurement range of the measuring device 3, a lower limit alarm output can be generated only when the monitor device is abnormal, and in this case, the lower limit alarm output can be generated using a digital method. It is also possible to determine whether the abnormality is caused by the abnormality in the radiation detector 1 or the measuring device 3.

In the above embodiment, the field unit 2 was provided between the digital radiation detector 1 and the measuring device 3, but this is not necessarily essential to the present invention.

Furthermore, in the above embodiment, when the normal background level is below the lower limit of the measurement range of the measuring device 3, the lower limit alarm setting value is set to a value equivalent to the normal background level. It's good.

[Effects of the Invention] As explained above, according to the present invention, in a digital radiation monitor device composed of a digital radiation detector and a measuring device, measured values below the lower limit of the measurement range can be digitally displayed on the display means. function, and a lower limit alarm setting value to generate a lower limit alarm when the monitor device is abnormal.

Since the measuring device is equipped with a function to set the measurement range below the lower limit, it is possible to provide a digital radiation monitoring device that can confirm the health of the monitoring device while eliminating the need for installing a bug source.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of a digital radiation monitoring device according to the present invention, FIGS. 2 and 3 are diagrams showing display examples of measured values in the same embodiment, and FIG. FIG. 5 is a flowchart for explaining the calibration operation in the same embodiment, and is a diagram showing an example of a conventional display of measured values. 1... Digital radiation detector, 3... Measuring device,
31... Optical/electric conversion circuit, 32...-control unit, 33
...Display control section, 34...Graphic display section, 3
5... Analog output section, 36... Digital output section,
37... Communication circuit, 38... Pass line. Applicant's agent Patent attorney Takehiko Suzue Figure 4 b'qn-

Claims (1)

[Claims] A digital radiation detector installed in a nuclear power plant that handles radioactive materials to detect radiation, and a display means having a predetermined measurement range for the radioactivity level measured by the digital radiation detector. A digital radiation monitor device comprising a measuring device that displays a bar on the radioactivity level and continuously monitors the radioactivity level, and issues an alarm when the radioactivity level exceeds a predetermined level. A function to digitally display measured values below the lower limit of the measurement range on the display means, and a function to set the lower limit alarm setting value to generate a lower limit alarm when the monitor device is abnormal, below the lower limit of the measurement range. A digital radiation monitoring device, characterized in that the measuring device comprises: