JP2006017505A - Electronic dosimeter, adapter for calibration, and calibration method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic dosimeter for enhancing workability when executing calibration work, etc. <P>SOLUTION: This electronic dosimeter 100 comprises a control part 1, a battery 5, a communication part 6, and a detection module 2 equipped with a detection part 3 and a nonvolatile storage part 4. The detection module 2 can be attached to and detached from the electronic dosimeter 100 by means of a connector 7 as an attaching/detaching part. Calibration is performed with the detached detection module 2 attached to an adapter 101 for calibration of a size smaller than the electronic dosimeter 100. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an electronic dosimeter for measuring radiation.

  An electronic dosimeter that measures radiation integrates a detection unit, control unit, display unit, and operation unit that detect radiation, and is configured to be housed in a single case together with a battery that serves as a drive source for each element. ing. In particular, in portable electronic dosimeters, these elements are completely fixed to the case with screws, etc. at the time of production in order to suppress the impact of dropping, etc. Generally, the structure is difficult to open and close. In addition, the constant for adjusting the sensitivity of the detection unit to radiation is generally stored in a storage unit provided on the same substrate as the control unit.

Further, regarding calibration of dosimeters as described above, an apparatus for calibrating a plurality of dosimeters is known (see, for example, Patent Document 1).
JP 2002-169000 A

  When an electronic dosimeter is used for measuring environmental doses in a radiation control area, it is often fixed to a wall. For this reason, when performing calibration for the required radiation sensitivity, it is necessary to remove the entire fixed dosimeter and irradiate with a radiation source to perform calibration.

  As for the calibration device, there is a limited area where a fixed dose can be emitted from the radiation source of the calibration device, and a dose for calibration is irradiated to a dosimeter with a large case (outer shape). In this case, the number of lights that can be irradiated at one time is limited, and work efficiency is poor.

  Even if the detection unit of the dosimeter fails, the entire dosimeter must be removed and repaired.

  As described above, conventional electronic dosimeters have problems in work efficiency and maintainability when performing calibration and the like.

  In view of the above-described conventional problems, an object of the present invention is to improve workability at the time of performing calibration work of an electronic dosimeter.

  In order to achieve the above object, an electronic dosimeter of the present invention is a dosimeter comprising a detection module for detecting radiation, and a control unit for counting signals output from the detection module, and the like. The detection module includes a detection unit that detects radiation and a nonvolatile storage unit, and the detection module is detachable from the control unit.

  The electronic dosimeter of the present invention is a dosimeter comprising a detection module for detecting radiation, and a control unit for counting signals output from the detection module, wherein the detection module emits radiation. A detection unit for detecting and a non-volatile storage unit for storing correction information related to the detection unit; the detection module is detachable from the control unit; and the detection module itself stores correction information of the detection unit. It is what you have.

  According to this configuration, for example, when the electronic dosimeter is mounted on a wall or the like, it is not necessary to remove the entire electronic dosimeter from the wall or the like when performing calibration work, and only the detection module is mounted on the electronic dosimeter. Can be easily removed. And since the correction | amendment information of the detection part is memorize | stored in the non-volatile memory | storage part of detection module itself, it can attach and use for another electronic type dosimeter.

  The calibration adapter according to the present invention includes a placement unit for placing the detection module removed from the dosimeter, and a signal output from the detection module connected to the detection module placed on the placement unit. And a control unit that performs counting and the like, and the outer dimensions are smaller than the outer dimensions of the electronic dosimeter.

  According to this configuration, only the detection module can be calibrated by placing the detection module removed from the dosimeter on the calibration adapter.

  As described above, according to the present invention, the electronic dosimeter detection module is structured to be detachable from the electronic dosimeter, thereby calibrating the electronic dosimeter fixed to the wall or the like. It is possible to easily perform work such as repairing a failure of the radiation detection unit provided inside.

  Moreover, the calibration workability can be improved by performing calibration with the detection module mounted on a calibration adapter smaller than the electronic dosimeter.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS.

  FIG. 1 is a block diagram showing a schematic configuration of an electronic dosimeter 100.

  In FIG. 1, reference numeral 1 denotes a control unit that controls the electronic dosimeter 100. The control unit 1 includes a storage unit 21 that stores detected doses, a display unit 22 that displays doses, and the like. It consists of a CPU (Central Processing Unit) unit 23 for performing calculations, a power source control unit 24 for controlling the battery 5 described later, and an operation unit 26 for performing operations such as power input.

  Reference numeral 2 denotes a detection module, which includes a detection unit 3 that detects a dose and a nonvolatile storage unit 4 that stores correction information related to the detection unit 3. Reference numeral 5 denotes a battery as a power supply unit that supplies power to the control unit 1.

  Reference numeral 6 denotes a communication unit for communicating with an external device. The communication unit 6 can be wireless, optical, wired, or the like. Reference numeral 7 denotes a connector as an attachment / detachment part for attaching / detaching the control unit 1 and the detection module 2, and the connector 7 allows the detection module 2 to be attached when the electronic dosimeter 100 is calibrated or the detection unit 3 is repaired. The detection module 2 can be detached from the control unit 1, and the detection module 2 can be attached to the control unit 1 after the calibration of the detection module 2 that has been calibrated in the detached state.

  The operation of the electronic dosimeter configured as described above will be described.

  First, the battery 5 supplies power to the power control unit 24 of the control unit 1, and the power control unit 24 supplies power to each part of the electronic dosimeter 100.

  When radiation enters the detection unit 3 of the detection module 2, the detection unit 3 outputs a pulse signal corresponding to the amount of incident radiation to the CPU unit 23 of the control unit 1. The correction information stored in the nonvolatile storage unit 4 is also transmitted to the CPU unit 23.

  The correction information refers to, for example, irradiating a dose of 1 mSv (millisievert) to an electronic dosimeter 100 incorporating a certain detection unit 3, and at this time, the detection unit 3 outputs 98 pulses as an output signal. When the CPU 23 counts 98 output pulses from the detection unit 3, the information means that it is 1 mSv, and an electronic dosimeter incorporating another detection unit 3. 100 is irradiated with a dose of 1 mSv (milli-sievert), and at this time, when the detection unit 3 outputs 100 pulses as an output signal, the CPU unit 23 generates 100 output pulses from the detection unit 3. When counted, the information means that it is 1 mSv, and is unique to each detection unit 3.

  The CPU unit 23 of the control unit 1 converts the pulse signal into a dose value based on the pulse signal output from the detection module 2 and the correction information. Here, regarding this conversion, the correction information stored in the nonvolatile storage unit 4 is information that means that when the CPU unit 23 counts 100 output pulses from the detection unit 3, it is 1 mSv. The case will be described. When the detection module 2 is connected to the control unit 1, correction information stored in the nonvolatile storage unit 4 of the detection module 2 is transmitted to the control unit 1 and stored in the storage unit 21. When radiation enters the detection unit 3 of the electronic dosimeter 100, the detection unit 3 outputs a pulse signal according to the amount of incident radiation, and this pulse signal is transmitted to the CPU unit 23. The CPU unit 23 that has received the pulse signal counts the number of pulses. For example, when the count value is 100, the pulse signal is converted into a dose value based on the count value and the correction information stored in the storage unit 21. As another example, when the count value of the number of pulses is 150, it is converted to 1.5 mSv.

  The converted dose value is displayed on the display unit 22 and stored in the storage unit 21. This dose value can also be transmitted to an external device via the communication unit 6.

  Next, the electronic dosimeter 100 that can be fixed to a wall or the like will be described as an example of the case where the electronic dosimeter 100 is used for environmental dose measurement in a radiation control area or the like, with reference to FIG.

  FIG. 2 is a structural diagram showing the external appearance of the electronic dosimeter 100. In FIG. 2, 1 is a control unit, 2 is a detection module, 5 is a battery, 6 is a communication unit, and 7 is a connector, which are the same as those described with reference to FIG. Reference numeral 8 denotes a case that can accommodate these, and has a structure that can be opened and closed. Reference numeral 9 is attached to the case 8 and is an attachment portion for attaching the electron dosimeter 100 to a wall or the like. The electronic dosimeter 100 includes a control unit 1, a detection module 2, a battery 5, a communication unit 6, a connector 7, and a case 8.

  When the electronic dosimeter 100 is fixed to a wall or the like for measuring an environmental dose in a radiation management area or the like, the electronic dosimeter 100 is fixed with a screw or an anchor bolt using a hole provided in the attachment portion 9.

  However, when the electronic dosimeter 100 is fixed to a wall or the like, it is difficult to calibrate the electronic dosimeter 100 or the like. Therefore, like the electronic dosimeter 100 of the present embodiment described with reference to FIGS. 1 and 2, the control unit 1 and the detection module 2 are connected by the connector 7, and the detection module 2 is attached to and detached from the control unit 1. By making the configuration capable of being accommodated in a case 8 that can be opened and closed, even if the electronic dosimeter 100 is fixed to a wall or the like, the detection unit 3 that needs to be calibrated by opening the case 8 and the nonvolatile The detection module 2 including the sex storage unit 4 can be easily removed.

  Next, an example in which the detection module 2 removed from the electronic dosimeter 100 is calibrated will be described.

  FIG. 3 is a block diagram showing a state where the detection module 2 removed from the electronic dosimeter 100 is attached to the calibration adapter 101.

  The calibration adapter 101 has, for example, a simple structure having only the components necessary for calibration among the components of the electronic dosimeter 100, and the mounting portion 9 and the like as in the electronic dosimeter 100 described above. The external configuration of the calibration adapter 101 is smaller than the external configuration of the electronic dosimeter 100 having the mounting portion 9.

  In FIG. 3, the calibration adapter 101 includes a connector 27 for connecting the control unit 11, the battery 25, and the detection module 2 removed from the control unit 11 and the electronic dosimeter 100. The connector 27 has the same structure as the connector 7 provided in the electronic dosimeter 100. In addition, the control unit 11 includes a storage unit 31 that stores the detected dose, a display unit 32 that displays the dose, a CPU unit 33 that calculates the dose, and a power control unit 34 that controls the battery 25. And an operation unit 35 to be described later.

  The operation of the calibration adapter 101 configured as described above will be described.

  First, the detection module 2 removed from the electronic dosimeter 100 is connected to the control unit 11 by the connector 27, so that the detection module 2 is attached to the calibration adapter 101. The battery 25 supplies power to the power control unit 34 of the control unit 11, and the power control unit 34 supplies power to each part of the calibration adapter 101 and the attached detection module 2.

  When a predetermined radiation is irradiated from a calibration radiation source (not shown) to the calibration adapter 101 to which the detection module 2 is mounted, and the radiation is incident on the detection unit 3 of the detection module 2, the detection module 2 has the amount of incident radiation. A corresponding pulse signal is transmitted to the CPU unit 33 of the control unit 11, and correction information regarding the detection unit 3 stored in the nonvolatile storage unit 4 is also transmitted to the CPU unit 33.

  The CPU unit 33 of the control unit 11 converts the pulse signal into a dose value based on the pulse signal received from the detection module 2 and the correction information. The converted dose value is displayed on the display unit 32 and stored in the storage unit 31. If necessary, a communication unit (not shown) for communicating with an external device may be incorporated in the calibration adapter 101 to communicate with the outside.

  Here, when the dose value displayed on the display unit 32 when a predetermined dose is irradiated to the calibration adapter 101 equipped with the detection module 2 is different from the predetermined value, the predetermined value is obtained. As described above, new correction information can be input from the operation unit 35, and the correction information stored in the nonvolatile storage unit 4 of the detection module 2 can be changed via the CPU 33.

  As described above, the detection module 2 includes the detection unit 3 and the non-volatile storage unit 4, and correction information regarding the detection unit 3 can be stored in the non-volatile storage unit 4. It is possible to perform calibration by removing from the dosimeter 100 and attaching it to the calibration adapter 101, and it is also possible to change correction information when calibration is performed with the calibration adapter 101.

  FIG. 4 shows a schematic structural diagram of the calibration adapter 101. In FIG. 4, 2 is a detection module that is detached from the electronic dosimeter 100 and attached to the calibration adapter 101, 11 is a control unit, 25 is a battery, 13 is a mounting unit for mounting the detection module 2, and 27 is A connector 14 for connecting the detection module 2 and the control unit 11 is a case for housing them. Since the calibration adapter 101 has only functions necessary for calibration and does not have the attachment portion 9 unlike the electronic dosimeter 100 described above, the case 14 which is the outer shape of the calibration adapter 101 is attached. The electronic dosimeter 100 having the portion 9 is smaller than the outer shape.

  Next, a calibration method of the calibration adapter 101 equipped with the electronic dosimeter 100 and the detection module 2 removed from the electronic dosimeter 100 will be described with reference to FIG. 5A is a schematic diagram illustrating an example of calibration of the electron dosimeter 100, and FIG. 5B is a schematic diagram illustrating an example of calibration using the calibration adapter 101. FIG.

  In FIG. 5, 15 is an irradiation field showing the irradiation range of radiation irradiated from a calibration radiation source (not shown), 16 is an irradiation direction of radiation irradiated from a calibration radiation source (not shown), 100 is an electronic dosimeter, 101 Is a calibration adapter. The irradiation method shown in FIG. 5 is an example in which radiation is irradiated toward the electronic dosimeter 100 or the calibration adapter 101 from a radiation source (not shown) installed below the electronic dosimeter 100 or the calibration adapter 101. Show. Moreover, since the example which uses the same radiation source for the calibration by the electronic dosimeter 100 and the calibration adapter 101 is shown, the irradiation field 15 is the same size.

  As described with reference to FIG. 4, the external dimensions of the calibration adapter 101 (projected area when viewed from the irradiation direction) are the external dimensions of the electronic dosimeter 100 (projected area when viewed from the irradiation direction). It is smaller. Therefore, as shown in FIG. 5, the number of calibration adapters 101 that can be arranged in the irradiation field 15 of the same size is larger. As described above, when the calibration is performed by using the calibration adapter 101 that has the outer dimensions smaller than the electronic dosimeter 100 and is attached with the detection module 2 detached from the electronic dosimeter 100 to perform the calibration work. The working efficiency can be improved.

  As described above, according to the present embodiment, the detection module 2 of the electronic dosimeter 100 is configured to be detachable from the electronic dosimeter 100, so that the calibration work and the repair of the detection unit 3 can be performed. It is not necessary to remove the entire electronic dosimeter 100 fixed to a wall or the like.

  In addition, by performing calibration using the calibration adapter 101 that is smaller than the electronic dosimeter 100, it is possible to irradiate many detection modules 2 at the time of calibration, so that the workability of calibration can be improved.

  In the electronic dosimeter 100 according to the present embodiment, the detection module 2 is detachable. The detection module 2 includes a detection unit 3 and a nonvolatile storage unit 4 that stores correction information related to the detection unit 3. Since the detection unit 3 and the non-volatile storage unit 4 are integrated and have correction information of the detection unit 3, the detection module 2 can be used even when attached to another electronic dosimeter 100. Is possible.

  The electronic dosimeter 100 according to the present embodiment has a detection unit (not shown) that detects the mounting of the detection module 2, and the storage unit 21 has a program for confirming the radiation detection of the detection unit 3. When the CPU 23 receives a signal indicating that the detection module 2 is mounted from the detection unit, the CPU 23 automatically calls the program from the storage unit 21 to perform a radiation detection confirmation operation. The confirmation operation is performed, for example, by transmitting a pulse signal from the CPU unit 23 to the detection unit 3 and returning a response to this signal from the detection unit 3 to the CPU unit 23. In this way, the detection module 2 is removed from a certain electronic dosimeter 100 and the detection module 2 is attached to the electronic dosimeter 100 again, or the detection module 2 is removed from a certain electronic dosimeter 100. When this detection module 2 is attached to another electronic dosimeter 100, a radiation detection confirmation operation is automatically executed. In addition, you may make it display on the display part 22 whether the operation confirmation was performed normally.

  In the above description, an example in which the operation of confirming radiation detection by the CPU unit 23 is performed based on a signal from the detection unit has been described. However, the detection unit 3 is not provided, and the CPU unit 23 periodically pulses the detection unit 3. A confirmation operation may be performed by transmitting a signal, or when the electronic dosimeter 100 is turned on, the CPU unit 23 automatically transmits a pulse signal to the detection unit 3 as described above. The confirmation operation of radiation detection may be performed.

  In this embodiment, the battery 5 is used as the power source of the electronic dosimeter 100, and the battery 25 is used as the power source of the calibration adapter 101. However, instead of the battery 5 and the battery 25, a commercial power source is converted to a direct current. It is good also as a structure which uses a commercial power supply as a power supply using the power supply device to perform.

  The electronic dosimeter of the present invention can be attached to and detached from the electronic dosimeter with a detection module having a detection unit that detects radiation and a nonvolatile storage unit that stores information related to correction of the detection unit. It is useful as a dosimeter installed on a wall.

The block diagram which shows schematic structure of the electronic dosimeter in embodiment of this invention The figure which shows schematic structure of the electronic dosimeter in embodiment of this invention The block diagram which shows schematic structure of the adapter for calibration in embodiment of this invention The figure which shows schematic structure of the adapter for calibration in embodiment of this invention (A) The figure which shows the calibration state of the electronic dosimeter in embodiment of this invention (b) The figure which shows the calibration state using the adapter for calibration in embodiment of this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Control part 2 Detection module 3 Detection part 4 Nonvolatile memory | storage part 5 Battery 6 Communication part 7 Connector 8 Case 9 Attaching part 11 Control part 13 Mounting part 14 Case 15 Irradiation field 16 Irradiation direction 21 Storage part 22 Display part 23 CPU part 24 power supply control unit 25 battery 26 operation unit 27 connector 31 storage unit 32 display unit 33 CPU unit 34 power supply control unit 35 operation unit 100 electronic dosimeter 101 calibration adapter

Claims (6)

A dosimeter comprising a detection module for detecting radiation and a control unit for counting signals output from the detection module, wherein the detection module includes a detection unit for detecting radiation and a nonvolatile storage unit. A dosimeter having the detection module removable from the control unit. A dosimeter comprising a detection module for detecting radiation and a control unit for counting signals output from the detection module, wherein the detection module detects the radiation and correction information relating to the detection unit And a non-volatile storage unit for storing the detection module, wherein the detection module is detachable from the control unit, and the detection module itself has correction information of the detection unit. The dosimeter according to claim 1 or 2, wherein the detection module can be used by being mounted on a dosimeter different from the detached dosimeter. The dosimeter according to any one of claims 1 to 3, wherein a confirmation operation for radiation detection is automatically performed when the detection module is removed and then the detection module is attached. An attachment part that can be attached to a wall surface and the like, and a case that accommodates a detection module and a control part and that can be opened and closed, the case is opened in a state of being attached to the wall surface, and the detection module can be attached and detached. 5. The dosimeter according to any one of items 1 to 4. A mounting unit for mounting the detection module removed from the dosimeter according to any one of claims 1 to 5, and the detection module mounted on the mounting unit and output from the detection module And a controller for counting signals to be detected, and a detection module calibration adapter having an outer dimension smaller than the outer dimension of the dosimeter.

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