JP2010121949A - Mobile type personal dosimeter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile type personal dosimeter which can set a maximum integrated dose (measuring range) in a given period of time to be large sufficiently, while having high sensitivity, and thus can surely perform expected radiation measurement. <P>SOLUTION: The mobile type personal dosimeter includes a detecting part which detects an ionization current generated by ionization caused by radiation, an integrator which integrates an output current signal from the detecting part and outputs it as a voltage signal and which is equipped with a reset switch, and an arithmetic processing part which sequentially adds up a dosage calculated based on the output voltage signal from the integrator and detects an integrated dose in the given period. Accompanying the operation of the reset switch, the data on the integrated dose from the time of start of measurement or the time of the previous operation of the reset switch are output to a memory and an accumulated exposure dose of a person being a dosimeter holder is recorded, while measurement is performed continuously, with the integrated dose at the time of operation of the reset switch made an initial value. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a portable personal dosimeter.

  For example, personal exposure management is important for workers and users of nuclear power plants, medical facilities and plants that use radiation and radioisotopes, radiation handling facilities such as laboratories, users, and residents in the surrounding areas. For example, it is stipulated that the radiation dose received by an individual during his / her lifetime or for a certain long period of time must be a predetermined value or less.

  Currently, for example, a so-called pocket dosimeter is known as a personal exposure dose monitor for performing personal exposure management. For example, an ionization current generated by an ionizing action due to radiation is detected, and a radiation dose corresponding to the ionization current is determined. An ionization chamber type to be measured has been proposed (for example, see Patent Document 1).

  In such an ionization chamber type dosimeter, since the amount of ionization current detected is very small (for example, on the order of pA), for example, the output current signal from the detector is converted into a voltage signal by an integrator. It has been broken. Here, as the integrator, for example, an integrator having a reset mechanism for periodically discharging the accumulated charge of the capacitor is used.

JP 2005-257383 A

  In the ionization chamber type dosimeter as described above, the output voltage Vout [V] from the integrator is obtained by the following equation (1). As is clear from this equation (1), the resolution of the dosimeter ( The detection limit or the minimum detection unit) and the maximum integrated dose (measurement range), which is the detection upper limit amount during a certain time, depend on the capacity of the capacitor constituting the integrator. That is, when a capacitor with a small capacity is used, high resolution can be obtained and radiation measurement can be performed with high accuracy, but the maximum integrated dose is reduced. On the other hand, when a capacitor having a large capacity is used, the maximum integrated dose can be set large, but the resolution becomes low and radiation measurement cannot be performed with high accuracy.

  The present invention has been made based on the circumstances as described above, and sets the maximum integrated dose (measurement range) for a certain period of time to a sufficient size while having high sensitivity. An object of the present invention is to provide a portable personal dosimeter capable of reliably performing intended radiation measurement.

A portable personal dosimeter according to the present invention includes a detection unit that detects an ionization current generated by an ionization effect due to radiation, an integrator that integrates an output current signal from the detection unit and outputs the voltage signal, and an integrator A portable personal dosimeter comprising an arithmetic processing unit that sequentially accumulates radiation doses calculated on the basis of the output voltage signal and detects an integrated dose during a certain period of time,
The integrator includes a reset switch that periodically discharges the accumulated charge of the capacitor that constitutes the integrator,
Along with the operation of the reset switch, data on the accumulated dose from the start of measurement or the accumulated dose from the previous activation of the reset switch is output to the memory, and the accumulated dose that the individual dosimeter holder has been exposed to is recorded. In addition, the measurement is continuously performed using the integrated dose when the reset switch is operated as an initial value.

  In the portable personal dosimeter of the present invention, the reset switch in the integrator is configured to be activated when the accumulated charge amount of the capacitor reaches 80 to 95% of the capacitance of the capacitor. preferable.

  Furthermore, in the portable personal dosimeter of the present invention, it is preferable that a capacitor having a capacitance of 100 to 300 pF is used as the capacitor in the integrator.

  Furthermore, in the portable personal dosimeter of the present invention, it is preferable that an integrator provided with a reset switch made of a semiconductor switch is used.

  According to the portable personal dosimeter of the present invention, for example, the accumulated dose during a certain time until the reset switch is activated is output to the memory every time the reset switch is activated, and the memory The cumulative exposure dose is managed, and radiation measurement is continuously performed with the cumulative dose at the time of reset switch operation as the initial value, so that, for example, a capacitor with a small capacity is used as a capacitor in the integrator. Even if a large-capacity capacitor is used, it is configured to have a measurement range (maximum integrated dose during a certain period of time) that is substantially the same as or larger than that when a large-capacitance capacitor is used. Therefore, the intended radiation measurement can be performed with high accuracy and reliably over a long period of time.

FIG. 1 is a block diagram showing an outline of a configuration of an example of a portable personal dosimeter according to the present invention, and FIG. 2 is an explanatory diagram showing an outline of a configuration of a detection unit in the portable personal dosimeter of the present invention.
This portable personal dosimeter (hereinafter simply referred to as “dosimeter”) 10 is a voltage obtained by integrating a detection unit 11 that detects an ionization current generated by an ionization action due to radiation, and an output current signal from the detection unit 11. An integrator 20 that outputs the signal, an arithmetic processing unit 25 that sequentially integrates the radiation doses calculated based on the output voltage signal from the integrator 20 and detects an integrated dose during a predetermined time, and this calculation A display unit 30 for displaying the cumulative dose of radiation calculated by the processing unit 25, and an alarm unit 40 for informing that the exposure dose of the individual holding the dosimeter 10 has exceeded a predetermined value (alarm point); And an external output unit 50 that outputs data relating to the detected integrated dose during a certain period of time to an external device such as an external memory 60 connected to the dosimeter 10, for example. .

  The detection unit 11 is made of, for example, a resin box having an inner surface provided with a conductive material such as carbon, and includes an ionization chamber 12 that outputs an ionization current due to incident radiation. For example, a collector electrode 13 formed by coating a conductive material such as carbon on the surface of a rod-shaped resin is arranged such that one end thereof extends airtightly through the wall of the ionization chamber 12 via the insulating member 14. A voltage applying means 15 for providing a potential difference between the collecting electrode 13 and the ionization chamber 12 is provided. Here, the voltage application means 15 is constituted by, for example, a DC power source, and applies a negative voltage to the ionization chamber 12, for example.

  The integrator 20 includes a reset switch Sw that periodically discharges the electric charge accumulated in the capacitor C. The reset switch Sw is ON / OFF controlled based on a command signal from the arithmetic processing unit 25.

  The capacitor C constituting the integrator is preferably one having a capacity of, for example, 100 to 300 pF. Thereby, the dosimeter 10 can be configured to have the desired resolution, and the intended radiation measurement can be reliably performed with high accuracy.

Hereinafter, the operation of the dosimeter 10 will be described.
In the dosimeter 10, when radiation enters the ionization chamber 12, an ionization current generated by the ionization action of the radiation is output through the collector electrode 13, and the amount of charge accumulated in the capacitor C in the integrator 20. That is, a voltage signal corresponding to the integration value of the ionization current is output from the integrator 20, and the radiation amount calculated based on the output voltage signal is sequentially integrated in the arithmetic processing unit 25, and integration for a fixed time. When the dose is detected and the result is displayed on the display unit 30 and when it is detected that the accumulated dose has exceeded the set alarm point, the dosimeter holder is detected by the alarm unit 40 by, for example, a buzzer sound. To be notified.

  Thus, as described above, the resolution of the dosimeter 10 and the maximum accumulated dose during a certain time (for example, the time until the reset switch Sw is activated) depend on the capacitance of the capacitor C in the integrator 20. More specifically, for example, in an ionization chamber that generates an ionization current of 1 pA / s by incidence of radiation at a constant dose rate of 1 μSv / h (amount of change in dose per unit time (1 hour)), the integrator 20 When the power supply voltage of the amplifier 21 is set to 5 V, when the capacitor C having a capacity of, for example, 100 pF is used, the resolution is 10 [mV / (μSv)] and the maximum integrated dose is 500 [μSv] (the time until the capacitor C is saturated is 500 s). Therefore, the dosimeter 10 has a high resolution although the value of the maximum accumulated dose is small, and the capacitor C has a capacity of, for example, When the one having 1000 pF is used, the resolution is 1 [mV / (μSv)] and the maximum accumulated dose is 5000 [μSv] (capacitor The time until C is saturated is 5000 s). Therefore, the dosimeter 10 can be set to a large maximum integrated dose, but has a low resolution.

However, in the dosimeter 10, before the capacitor C in the integrator 20 is saturated, the reset switch Sw is operated based on the ratio of the charge amount accumulated in the capacitor C to the capacity of the capacitor C, and the reset switch Accompanying the operation of Sw, data relating to the accumulated dose during the time from the start of measurement to the time of the reset switch operation or the time from the previous reset switch operation to the time of the reset switch operation is output to the external memory 60. Thus, the cumulative exposure dose to which the individual dosimeter holder has been exposed is recorded, and radiation measurement is continuously performed with the accumulated dose at the time of the reset switch operation as an initial value.
That is, as the capacitor C in the integrator 20, for example, a capacitor having a small capacity is used, and the operation of the reset switch Sw is controlled as described above, whereby the reset switch Sw is operated as shown by the solid line arrow in FIG. 3. Each time, the measurement is continued with the accumulated dose (Sv ₁ , Sv ₂ , Sv ₃ , Sv ₄ ,...) At the time of reset switch operation as an initial value. A measurement range Sv that is substantially the same as or larger than that when a capacitor C having a large value is used can be obtained, and radiation measurement itself can be performed with high accuracy (resolution).

  The reset switch Sw in the integrator 20 is preferably configured to be activated when the accumulated charge amount of the capacitor C reaches 80 to 95%, for example, 90% of the capacity of the capacitor C. As a result, the frequency of ON / OFF control of the reset switch Sw can be reduced as much as possible, and the occurrence of a time lag due to the ON / OFF control of the reset switch Sw can be reliably prevented.

  In the above, the data recorded in the external memory 60 may include not only the data related to the integrated dose but also the integration time, the dose rate, etc., for example.

  As described above, the dosimeter 10 can be configured to have a high sensitivity while having a sufficiently large measurement range. For example, the order of dose rate is microsievert / hour [ μSv / h] in a low dose rate environment, or when monitoring the accumulated dose (exposure) over a short period of time in such an environment, This is also useful when monitoring the accumulated dose.

As mentioned above, although embodiment of this invention was described, this invention is not limited to said embodiment, A various change can be added.
For example, the portable personal dosimeter itself may be configured to include a memory for managing the cumulative exposure dose for an individual.
Further, the specific configuration of the detection unit and the integrator, for example, the magnitude of the voltage applied to the ionization chamber, the capacitance of the capacitor in the integrator, the power supply voltage of the amplifier, and the like are not particularly limited, and are appropriately determined according to the purpose. Can be set.

It is a block diagram which shows the outline of a structure in an example of the portable personal dosimeter of this invention. It is explanatory drawing which shows the outline of a structure of the detection part in the portable personal dosimeter of this invention. It is a conceptual diagram for demonstrating operation | movement of the portable personal dosimeter of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Portable personal dosimeter 11 Detection part 12 Ionization chamber 13 Collector electrode 14 Insulation member 15 Voltage application means 20 Integrator 21 Amplifier 25 Arithmetic processing part 30 Display part 40 Alarm part 50 External output part 60 External memory C Capacitor Sw Reset switch

Claims (4)

Calculated based on a detection unit that detects an ionization current generated by the ionizing action due to radiation, an integrator that integrates an output current signal from the detection unit and outputs it as a voltage signal, and an output voltage signal from the integrator A portable personal dosimeter comprising an arithmetic processing unit that sequentially accumulates radiation doses and detects an accumulated dose for a certain period of time,
The integrator includes a reset switch that periodically discharges the accumulated charge of the capacitor that constitutes the integrator,
Along with the operation of the reset switch, data on the accumulated dose from the start of measurement or the accumulated dose from the previous activation of the reset switch is output to the memory, and the accumulated dose that the individual dosimeter holder has been exposed to is recorded. In addition, the portable personal dosimeter is characterized in that the measurement is continuously performed with the integrated dose at the time of operation of the reset switch as an initial value.   2. The portable personal dosimeter according to claim 1, wherein the reset switch in the integrator is activated when the accumulated charge amount of the capacitor reaches 80 to 95% of the capacitance of the capacitor.   The portable personal dosimeter according to claim 1 or 2, wherein a capacitance of the capacitor in the integrator is 100 to 300 pF.   The portable personal dosimeter according to any one of claims 1 to 3, wherein the reset switch in the integrator is a semiconductor switch.

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