JP2006078338A - Space dose rate monitor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a space dose rate monitor of which fluctuations in the internal temperature of a radiation detector are small and can perform stable measurement all year round. <P>SOLUTION: The space dose rate monitor comprises the radiation detector 5 for detecting ambient radiation, a temperature sensor 6 for measuring the temperature of the radiation detector 5, a heater 17 and a Peltier element 18 for maintaining the temperature of the radiation detector 5, and a detector mantle 7 which houses the radiation detector 5 therein and reflects direct sunlight. A heat insulator 19 is provided throughout the inner surface of the detector mantle 7 to thermally insulate the radiation detector 5. A sunshading cover 21 is provided which prevents a stand pipe 8 supporting the radiation detector 5 from being exposed to direct sunlight. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an air dose rate monitor, and more particularly to an air dose rate monitor for measuring the air dose rate of the surrounding environment in a nuclear power plant, an accelerator utilization facility, a nuclear fuel reprocessing facility, and the like.

Air dose rate monitors for monitoring environmental radiation levels are installed around facilities such as nuclear power plants, accelerator facilities, and nuclear fuel reprocessing facilities. Conventional air dose rate monitors are often installed by the following two installation methods.
(1) A case where a detection unit including a radiation detector for detecting radiation is installed on the ceiling of a dedicated station building, and a measurement unit is installed in the station building.
(2) The detection unit is installed on the ground surface or building pole, and the measurement unit is installed in the building.

  In the case of the station air dose rate monitor in the above installation method (1) where the detector is installed on the ceiling of the station building, an opening is provided on the ceiling of the station building and a short tube with a flange is provided on the opening. The detection unit is installed on the flange, and the measurement unit is installed inside the air-conditioned station. Since the detection unit is directly exposed to the environment, the inside of the detector becomes hot when receiving direct sunlight in summer, and the temperature becomes low during snow in winter. For this reason, the conditioned air in the station is blown by a dedicated blower so that the apparatus operates stably throughout the year. In addition, the temperature is raised by a heater installed in the detection unit at a low temperature where the amount of heat is insufficient due to blowing, and when still insufficient, the heater installed in the blower is operated to blow the heated air. When the capacity is increased to cover only the heater installed in the detection unit, the detector locally heats. As described above, since the temperature adjustment of the detection unit is based on the ventilation of the conditioned air in the station building, the temperature of the detection unit depends on the flow of heat to and from the detection unit from the surrounding environment and the conditioned air temperature. In general, the annual outside air temperature is -10 to 40 ° C, and the air conditioning is only cooling. Therefore, the temperature inside the station is about 5 to 30 ° C, and the internal temperature of the detection unit is adjusted to about 15 to 35 ° C.

  In the case of the pole-type air dose rate monitor in the installation method (2) in which the detection unit is installed on the ground surface or the building pole, the temperature is adjusted only with a small-capacity heater installed in the detection unit. Therefore, the temperature inside the detection unit is 5 to 45 ° C.

  Thus, in the conventional air dose rate monitor, the annual fluctuation range of the internal temperature of the detection unit is large. For this reason, a method has been proposed in which temperature compensation is performed using the spectrum peak of a detector signal pulse output as a result of the reaction of natural radiation K-40 with the radiation detector as an index. However, in this method, the spectrum peak as an index is affected by the radiation of the daughter nuclide of Radon Tron, so it is necessary to switch to temperature compensation based on a temperature sensor during rainfall when the radiation dose of the daughter nuclide changes. There is. In temperature compensation based on this temperature sensor, the temperature characteristics of the detector are individually measured at the factory shipment stage, and the compensation coefficient and compensation equation based on the data are installed as software in the measurement unit. The temperature is measured, and temperature compensation is performed by the software (see, for example, Patent Document 1).

Japanese Patent No. 3153484

  The temperature compensation by the natural radioactivity K-40 in the conventional air dose rate monitor is because the count rate of the radiation of K-40 is very small, so that the statistical compensation is suppressed and the indicated temperature compensation is performed with high accuracy. Has a problem in that it cannot follow the temperature change of the radiation detector because it requires spectrum measurement for several hours.

  Also, temperature compensation by the temperature sensor is different in the transient response of temperature change between the temperature sensor and the radiation detector due to the difference in heat transfer in heat input and output and the heat capacity, which is indicated as a compensation error. There was a problem of affecting.

  Further, the detector using an ionization chamber has a problem that the output signal of the ionization chamber is easily affected by humidity in addition to temperature because of the minute current.

  As a countermeasure against humidity, the detector is enclosed in a sealed container including its peripheral circuits, and a moisture absorbent is put in the sealed container to dehumidify. However, the price of the sealed container is high because it requires a high degree of airtightness. In addition, there is a problem that the moisture absorbing agent needs to be periodically replaced.

  The present invention has been made to solve such problems, and an object of the present invention is to obtain a low-cost air dose rate monitor in which the temperature fluctuation of the radiation detector is small and stable measurement can be performed throughout the year.

  The present invention relates to a radiation detector for detecting radiation in the environment, a thermostatic means for making the temperature of the radiation detector constant, a light reflecting means for accommodating the radiation detector inside and reflecting extraneous light. An air dose rate monitor equipped with

  The present invention relates to a radiation detector for detecting radiation in the environment, a thermostatic means for making the temperature of the radiation detector constant, a light reflecting means for accommodating the radiation detector inside and reflecting extraneous light. Since the air dose rate monitor is equipped with, the fluctuation of the internal temperature of the radiation detector is small, and the measurement can be performed stably throughout the year at a low price.

Embodiment 1 FIG.
Hereinafter, an air dose rate monitor according to Embodiment 1 of the present invention will be described with reference to the drawings. As shown in FIG. 1, the NaI (TI) scintillator 1 and the photomultiplier tube 2 are optically joined, and are connected so that the output of the photomultiplier tube 2 is input to the preamplifier 3. A high voltage power source 9 is connected to the photomultiplier tube 2, and the photomultiplier tube 2 supplies a high voltage necessary for converting the fluorescence into electrons and multiplying the electrons. A NaI (TI) scintillator 1, a photomultiplier tube 2, and a preamplifier 3 are sealed in a detector case 4 to constitute a radiation detector 5. A temperature sensor 6 (temperature measuring means) for measuring a temperature change of the radiation detector 5 is attached to the outside of the side surface of the detector case 4 so as to be in close contact therewith. The detector jacket 7 (light reflecting means) includes a radiation detector 5 and a temperature sensor 6 and is attached to a stand pipe 8 (support means). The detector jacket 7 is made of, for example, a plastic having a low thermal conductivity, and is coated with a white pigment so that the reflection efficiency of external light (particularly direct sunlight) is high, and the surface is made smooth. Finished. By doing so, the direct sunlight is reflected by the detector jacket 7 and the temperature rise of the surface can be suppressed to about 5 ° C. or less with respect to the environmental temperature.

  A ribbon-shaped small heater 17 (constant temperature means (heating / cooling means)) is attached in close contact with the outside of the side surface of the detector case 4. The heater 17 may be provided by being wound, or may be provided in close contact with a part or the whole of the side surface. When the environmental temperature is low and heat is taken away from the radiation detector 5, the radiation detector 5 is heated by the heater 17. In addition, a small Peltier element 18 (a constant temperature means (heating / cooling means)) is closely attached to the outside of the bottom surface of the detector case 4. The surface of the Peltier element 18 opposite to the detector case 4 is attached in close contact with the upper flange of the stand pipe 8. When the ambient temperature is high and the radiation detector 5 needs to be cooled, the radiation detector 5 is cooled by the Peltier element 18. Although two Peltier elements 18 are provided in FIG. 1, the number is not limited to this, and the minimum necessary number may be provided. Further, a heat insulating material 19 (constant temperature means (thermal insulating means)) is arranged on the entire inner surface of the detector jacket 7, and the radiation detector 5 is arranged inside the heat insulating material 19. Since the radiation detector 5 can be thermally insulated from the detector jacket 7 by the heat insulating material 19, heat conduction from the outside to the radiation detector 5 becomes gentle. An awning cover 21 (constant temperature means (awning means)) is arranged to shade the stand pipe 8 so that it is not exposed to direct sunlight.

  The output of the preamplifier 3 is connected to the main amplifier 10, and the output of the main amplifier 10 is connected to the A / D converter 11. The A / D converter 11 is connected so as to exchange data with the arithmetic unit 14. The output of the temperature sensor 6 is connected to the temperature measurement unit 12. The output of the temperature measurement unit 12 is connected to the calculation unit 14 and to the temperature control unit 20. The temperature control unit 20 inputs a temperature signal obtained as a result of the measurement by the temperature measurement unit 12 and controls ON / OFF of the heater 17 and the Peltier element 18 so as to eliminate the difference by comparing with a predetermined set value. To do. The output of the calculation unit 14 is output to the outside via the output unit 16 and is connected to the D / A converter 13. The output of the D / A converter 13 is connected to the main amplifier 10. A memory 15 is connected to the calculation unit 14. The memory 15 stores the calculation program of the calculation unit 14, dose rate data and calculation results of the calculation unit 14 and various alarms, temperature compensation coefficient table, alarm determination reference value, wave height spectrum based on wave height data, and initial positions of index spectrum peaks. Remember.

  The NaI (TI) scintillator 1 emits fluorescence when γ rays are incident, and the photomultiplier tube 2 converts the fluorescence into electrons and multiplies them to generate current pulses. The preamplifier 3 converts the current pulse into a voltage pulse and outputs the voltage pulse to the outside as the output of the radiation detector 5. The main amplifier 10 amplifies the voltage pulse output from the radiation detector 5, and the A / D converter 11 converts the wave height of the amplified voltage pulse into wave height data which is digital data. On the other hand, the temperature measurement unit 12 receives the output of the temperature sensor 6 and converts the output into a temperature signal having a voltage corresponding to the detected temperature. The calculation unit 14 receives the wave height data from the A / D converter 11 and the temperature signal from the temperature measurement unit 12, weights the wave height data, calculates and outputs the dose rate, and outputs the temperature signal. And digital data for controlling the gain of the main amplifier 10 based on the temperature compensation coefficient table of the memory 15. The D / A converter 13 converts the digital data calculated by the calculation unit 14 into analog data that can control the gain of the amplifier 10 and outputs the analog data to the main amplifier 10. Further, the output unit 16 outputs dose rate data and an alarm as a calculation result to display the screen (alarm sound may be issued for the alarm), and outputs the calculation result to the outside of the air dose rate monitor.

Next, the operation | movement about suppression of the heat | fever entering / exiting to the radiation detector 5 and the constant temperature of the radiation detector 5 is demonstrated. As described above, the detector mantle 7 is, for example, a plastic molded product having a smooth finish using a white pigment. By doing so, the direct sunlight is reflected by the detector jacket 7 and the temperature rise of the surface can be suppressed to about 5 ° C. or less with respect to the environmental temperature. In addition, heat transfer is moderated by the heat insulating material 19 disposed inside the detector jacket 7.
Thereby, since the amount of heat transmitted to the radiation detector 5 is suppressed to a slight amount, the necessary cooling capacity is reduced, and by attaching the small Peltier element 18 in close contact with the bottom of the detector case 4, sufficient Cooling can be performed.
Also, in the opposite case where the ambient temperature is low and heat is taken away from the radiation detector 5, the required heating capacity is reduced for the same reason, so a small ribbon heater 17 is attached in close contact with the detector case 4. Thus, sufficient heating can be performed.
In this way, by suppressing the heat input and output of the radiation detector 5, the temperature of the detector case 4 can be made constant at a low cost, and the temperature characteristics of the radiation detector 5 can be improved by making the temperature of the detector case 4 constant. It can be suppressed and stable measurement can be performed throughout the year.

  As described above, in this embodiment, the radiation dose in the environment is detected by the radiation detector 5 and the radiation dose in the environment is continuously measured based on the detection signal output from the radiation detector 5. A temperature measurement unit 12 that is a temperature monitor for measuring the temperature of the radiation detector 5 using the temperature sensor 6; a heater 17 that is a constant temperature means for maintaining the radiation detector 5 at a constant temperature; and a Peltier element. 18 and the calculation unit 14, the radiation detector 5 is included to protect the environment, and the detector mantle 7 is a light reflecting means for reflecting direct sunlight (external light), and the radiation detector 5 from the detector mantle 7. Since the heat insulating material 19 which is a heat insulating means for heat insulation is provided, the variation in the internal temperature of the radiation detector 5 is small and the internal temperature can be easily managed. Since it thermostatized at ribbon heater 17, can be a low power consumption to obtain the spatial dose rate monitor low cost, it is possible to perform stable measurement throughout the year by using the spatial dose rate monitor.

Embodiment 2. FIG.
Hereinafter, an air dose rate monitor according to Embodiment 2 of the present invention will be described with reference to FIG. As shown in FIG. 2, in the present embodiment, an ionization chamber 25 and a current / frequency converter 26 are hermetically installed inside a detector case 27 to constitute a radiation detector 28. A dehumidifier 29 (dehumidifying means) is closely attached to the outside of the bottom surface of the detector case 27. Further, the digital pulse output from the current / frequency converter 26 is input to the counter 31 and counted. The count data obtained by the counter 31 is input to the calculation unit 32. A memory 33 and an output unit 16 are connected to the calculation unit 32.

  Similarly to the first embodiment, the temperature sensor 6 is attached in close contact with the outside of the side surface of the detector case 27, and the detector jacket 7 encloses the radiation detector 28 and the temperature sensor 6 and stands pipe. 8 is attached. A heat insulating material 19 is disposed on the entire inner surface of the detector jacket 7. The output of the temperature sensor 6 is connected to the temperature measurement unit 12. The output of the temperature measurement unit 12 is connected to both the calculation unit 32 and the temperature control unit 20, and the temperature control unit 20 compares the temperature signal obtained as a result of the measurement by the temperature measurement unit 12 with a predetermined set value, and calculates the difference. The Peltier element 18 is controlled so as to be eliminated. Also in the present embodiment, the small Peltier element 18 is attached in close contact with the bottom of the detector case 27. Also in the present embodiment, the sunshade cover 21 is arranged so as to shade the standpipe 8 so that it is not exposed to direct sunlight.

  The ionization chamber 25 reacts with gamma rays in the space to ionize the enclosed gas and outputs an ionization current. The high voltage power supply 30 supplies a high voltage for collecting ions and electrons generated in the ionization chamber 25 to the electrodes. The current / frequency converter 26 converts the ionization current output from the ionization chamber 25 into, for example, a digital pulse having a frequency proportional to the current, and outputs the digital pulse as an output from the radiation detector 28. The counter 31 counts digital pulses output from the radiation detector 28. The calculation unit 32 inputs the count data of the counter 31 and the temperature signal from the temperature measuring device 12, converts the count data into a count rate, calculates and outputs a dose rate based on the count rate, Based on the signal and the temperature compensation coefficient table stored in the memory 33, temperature compensation of the dose rate is performed. The memory 33 stores a calculation program of the calculation unit 32, dose rate data as a calculation result of the calculation unit 32, various alarms, a temperature compensation coefficient table, and an alarm determination reference value. In addition, the dose rate of the calculation result is an example of an engineering value of the environmental radiation dose, and may be a dose equivalent rate as a matter of course.

  FIG. 3 is a diagram showing a functional structure of the solid electrolyte membrane of the dehumidifier 29 used in the present embodiment. As shown in FIG. 3, the dehumidifier 29 includes a solid electrolyte membrane 291, an anode 292, a cathode 293, a mounting plate 294, and a mounting hole 295. The dehumidifier 29 takes in water vapor from the anode 292 side and discharges it from the cathode 293 side to the outside. The solid electrolyte membrane 291 is a functional membrane having proton conductivity, for example. The solid electrolyte membrane 291 has a structure sandwiched between an anode 292 and a cathode 293. When a DC voltage of about 3 V is applied between the anode 292 and the cathode 293, hydrogen ions move through the solid electrolyte membrane 291 with water molecules. The anode 292 and the cathode 293 are porous and have a catalytic action. The anode 292 takes in water vapor and decomposes into oxygen ions and hydrogen ions by the catalytic action. The oxygen ions become oxygen gas on the surface of the anode 292 and become an airtight box. The hydrogen ions move inside the solid electrolyte membrane 291 by an electric field and are combined with oxygen in the outside air by the catalysis of the cathode 293 and released as water vapor. At this time, water attached to the hydrogen ions is also evaporated from the surface of the cathode 293 and released to the outside air. In this way, dehumidification inside the detector jacket 7 is performed. Therefore, it goes without saying that the anode 292 is provided in the detector jacket 7 and the cathode 293 is arranged in contact with the outside.

The solid electrolyte membrane 291 may be made of, for example, Nafion (trade name) manufactured by DuPont, and the like, which is an electrically insulating transparent film that is harmless even if touched by hand. Note that the voltage applied between the anode 292 and the cathode 293 is as low as about 3 V, and it is safe even if a leakage occurs. As shown in the chemical formula of FIG. 4, this film has a structure having a fluorine-based resin in the main chain and a sulfonyl group SO ₃ ⁻ capable of adding a proton in the side chain. FIG. 4 shows a mechanism in which hydrogen ions move inside the solid electrolyte membrane 291 using Nafion. The hydrogen ions move in the direction of the electric field along with the sulfonyl group SO ₃ ⁻ .

  Thus, in the present embodiment, the dehumidifier 29 that is a dehumidifying means for dehumidifying the space inside the radiation detector 28 is provided, and in addition to the suppression of the temperature change of the radiation detector 28 by the Peltier element 18, the solid state Since the ionization chamber 25 can be maintained under suitable conditions by the dehumidifier 29 using the electrolyte membrane 291, stable measurement can be performed. Further, since the solid electrolyte membrane 291 is used for the dehumidifier 29, maintenance such as hygroscopic agent replacement can be reduced.

Embodiment 3 FIG.
Hereinafter, the air dose rate monitor according to Embodiment 3 of the present invention will be described with reference to FIG. FIG. 5 shows the structure of the detector jacket 7. In FIG. 5, CFRP (Carbon Fiber Reinforced Plastics) 34 is a molded product in which carbon fiber is impregnated with resin and solidified, and the surface layer 35 is gel-coated using titanium oxide as a white pigment, Finished with a white smooth surface. By doing so, the detector jacket 7 is reinforced by the carbon fiber, and the surface deposits are decomposed by active oxygen by ultraviolet rays contained in sunlight by the photocatalytic action of titanium oxide, and washed by being washed by rain. In addition, since the propagation of moss and the like is suppressed, it is possible to prevent the reflection efficiency of direct sunlight from deteriorating for a long time. Therefore, stable measurement can be performed throughout the year. Since other configurations are the same as those in the first embodiment or the second embodiment, the description thereof is omitted here.

  As described above, in the present embodiment, as a light reflecting means, a molded product obtained by impregnating carbon fiber with a resin and solidified is subjected to gel coating treatment using a white pigment and finished to a smooth white surface. Since the outer jacket 7 is provided, titanium oxide is included in the white pigment, and the deposits are decomposed and cleaned by the catalytic action of titanium oxide, so that the deposits on the surface are exposed to ultraviolet rays contained in sunlight by the photocatalytic action of the titanium oxide. Since it is decomposed with active oxygen, washed with rain and washed, and the growth of moss and the like is suppressed, the reflection efficiency of direct sunlight does not deteriorate, so that stable measurement can be performed throughout the year.

Embodiment 4 FIG.
Hereinafter, the air dose rate monitor according to Embodiment 4 of the present invention will be described with reference to FIG. In FIG. 6, the sunshade cover 21 (constant temperature means (awning means)) is made of, for example, a material that does not transmit the same kind of sunlight as the detector mantle 7 in order to prevent the standpipe 8 from being heated by direct sunlight. It is a cover. The stand pipe 8 has a structure in which the detector cable 22 passed through the conduit 23 laid in the ground 24 passes and supports the radiation detector (5 or 28). By attaching the sunshade cover 21 to the standpipe 8, it is possible to prevent the standpipe 8 from being heated by direct sunlight, so that the air in the standpipe 8 convects and the temperature in the detector mantle 7 is increased. Can be suppressed. As a result, it becomes easy to keep the temperature in the detector jacket 7 at a constant temperature, and stable measurement can be performed throughout the year. Since other configurations are the same as those in the first embodiment or the second embodiment, the description thereof is omitted here.

  As described above, in the present embodiment, as the means for isolating the radiation detectors 5 and 28, the sunshade cover 21 is further attached to the stand pipe 8 of the radiation detectors 5 and 28. Since the pipe 8 can be prevented from being heated by direct sunlight, the rise of the temperature in the detector jacket 7 can be suppressed by the convection of the air in the stand pipe 8. As a result, it becomes easy to keep the temperature in the detector jacket 7 at a constant temperature, and stable measurement can be performed throughout the year.

Embodiment 5. FIG.
Hereinafter, an air dose rate monitor according to Embodiment 5 of the present invention will be described with reference to FIG. As shown in FIG. 7, in the present embodiment, a heat exchanger 37 is provided in contact with the radiation detector 5. The heat exchanger 37 is provided with a constant temperature water circulator 36 via a pipe 38. Inside the constant temperature water circulator 36, a heater and a freezer are provided (not shown), and constant temperature water having a constant water temperature is generated using them. The generated constant temperature water flows through the pipe 38 to the heat exchanger 37 and passes through the radiation detector 5. The inside of the radiation detector 5 is cooled or heated by the constant temperature water and kept at a constant temperature. Thus, the heat exchanger 37, the pipe 38, and the constant temperature water circulator 36 constitute a constant temperature fluid passage means that allows the constant temperature fluid to pass through the radiation detector 5. Other configurations in the present embodiment are the same as those in the first embodiment shown in FIG. 1, and therefore, are denoted by the same reference numerals, and the description thereof is omitted here. However, in the present embodiment, the heater 17 and the Peltier element 18 shown in FIG. 1 are not provided, but may be used together with the constant temperature water circulator 36 if necessary. Moreover, although the heat insulating material 19 and the sunshade cover 21 are not illustrated, if they are appropriately provided as necessary, the efficiency of isothermalization is further improved.

  In FIG. 7, a constant temperature water circulator 36 is a device that creates constant temperature water by controlling on / off of a heater and a freezer and circulates this constant temperature water using a pump. The constant temperature water is guided from the constant temperature water circulator 36 through a pipe 38 to the heat exchanger 37 provided in contact with the radiation detector 5 and circulated.

  The output of the temperature sensor 6 attached to the radiation detector 5 is input to the temperature measurement unit 12 and the temperature of the radiation detector 5 is measured. The measured temperature is input to the calculation unit 14, and the set temperature of the constant temperature water circulator 36 is changed. The operation control of the constant temperature water circulator 36 is performed in this way. By the temperature control by this closed loop, the inside of the radiation detector 5 can be kept constant even with a large temperature change due to annual seasonal variation.

  As described above, in the present embodiment, as a means for isolating the radiation detector 5, the output of the temperature sensor 6 is used to control the constant temperature water circulator 36 having a heater and a freezer, thereby controlling the constant temperature. Since the structure allows water to pass through the radiation detector 5, the temperature inside the radiation detector 5 can be maintained at a constant temperature even with a large temperature change due to annual seasonal variation by temperature control using a closed loop.

  In the above description, constant temperature water has been described as an example. However, the present invention is not limited to this case, and any constant temperature fluid can be used as long as the temperature can be constant. In the above description, the example in which the configuration of the present embodiment is applied to the first embodiment has been described. However, the present invention is not limited to this, and the present invention can be applied to any of the second to fourth embodiments.

It is a block diagram which shows the structure of the air dose rate monitor which concerns on Embodiment 1 of this invention. It is a block diagram which shows the structure of the air dose rate monitor which concerns on Embodiment 2 of this invention. It is explanatory drawing which shows the structure of the dehumidifier in the air dose rate monitor which concerns on Embodiment 2 of this invention. It is explanatory drawing which shows the mechanism by which the hydrogen ion of Nafion which is one of the solid electrolyte membranes of the dehumidifier in the air dose rate monitor which concerns on Embodiment 2 of this invention moves. It is a block diagram which shows the structure of the detector mantle in the air dose rate monitor which concerns on Embodiment 3 of this invention. It is a partial block diagram which shows the structure of the air dose rate monitor which concerns on Embodiment 4 of this invention. It is a block diagram which shows the structure of the air dose rate monitor which concerns on Embodiment 5 of this invention.

Explanation of symbols

  1 NaI (TI) scintillator, 2 photomultiplier tube, 3 preamplifier, 4 detector case, 5 radiation detector, 6 temperature sensor, 7 detector jacket, 8 standpipe, 9 high voltage power supply, 10 main amplifier, 11 A / D converter, 12 Temperature measurement unit, 13 D / A converter, 14 Calculation unit, 15 Memory, 16 Output unit, 17 Heater, 18 Peltier element, 19 Thermal insulation, 20 Temperature control unit, 21 Awning cover, 22 Detector cable, 23 Conduit, 24 Earth, 25 Ionization chamber, 26 Current / frequency converter, 27 Detector case, 28 Radiation detector, 29 Dehumidifier, 30 High voltage power supply, 31 Counter, 32 Calculation unit, 33 Memory, 34 CFRP, 35 surface layer, 36 constant temperature water circulator, 37 heat exchanger, 38 tube.

Claims (7)

A radiation detector for detecting radiation in the environment;
Constant temperature means for constant temperature of the radiation detector;
An air dose rate monitor comprising: a light reflecting means for accommodating the radiation detector therein and reflecting extraneous light. The constant temperature means is
2. The air dose rate according to claim 1, further comprising: a thermal insulation unit that is provided between the radiation detector and the light reflection unit and thermally insulates the radiation detector from the light reflection unit. monitor. Further comprising a temperature measuring means for measuring the internal temperature of the radiation detector,
The constant temperature means is
The air dose rate monitor according to claim 1 or 2, further comprising heating / cooling means for heating or cooling the radiation detector based on an output from the temperature measuring means. A dehumidifying means for dehumidifying the internal space of the radiation detector;
The air dose rate monitor according to any one of claims 1 to 3, wherein the dehumidifying means has a solid electrolyte membrane.   5. The detector jacket according to claim 1, wherein the light reflecting means includes a detector jacket in which a molded article obtained by impregnating a carbon fiber with a resin and solidified is gel-coated with a white pigment containing titanium oxide. The air dose rate monitor according to item 1. Further comprising support means for supporting the radiation detector;
The air dose rate monitor according to any one of claims 1 to 5, wherein the thermostatic means includes an awning means attached to the support means. The constant temperature means is
The constant temperature fluid passage means for allowing the constant temperature fluid to pass through the radiation detector based on the output from the temperature measurement means for measuring the temperature of the radiation detector. The air dose rate monitor according to any one of the above items.

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