JPH09197049A - Radiation detection device for monitoring high-temperature incinerator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation detection device for monitoring high- temperature incinerator which can be used simply by shielding heat fro a high- temperature sample box and forcibly cooling devices including the radiation detector with air at room temperature. SOLUTION: An area excluding that closer to a radiation detector 7 out of a high-temperature part including a sample box 1 which becomes a heat source is covered with a heat-insulating material 13 with a reflection material, outer-surrounding equipment 12 and 72 made of an electrically conductive thin plate with a polishing surface are arranged at the sample box 1 and a radiation detector body 73, for example, a closed-end cylindrical heat insulator 9a made of an electrically conductive thin plate with a polishing surface while enclosing the radiation detector 7 is arranged between the sample box 1 and the radiation detector 7, wind is blown to an area between the radiation detector 7 and the heat insulator 9a by an air-cooling fan 20 for cooling, for example, the radiation detector 7 and the heat shield 9a, and at the same time, heated air on the bottom part of the heat shield 9b is replaced, thus preventing heat transfer due to conduction and convection.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation detector for a high temperature incinerator monitor for monitoring radioactive substances contained in exhaust gas of an incinerator for reducing the volume of waste in a nuclear power plant or the like.

[0002]

2. Description of the Related Art A high-temperature incinerator monitor is a method for measuring the concentration of radioactive substances contained in exhaust gas when incinerating in order to reduce the volume of waste such as used ion-exchange resin in nuclear facilities such as nuclear power plants. It is necessary for constant monitoring due to regulations. In order to measure the concentration of radioactive substances, the dust in the exhaust gas is collected by a filter, and the radiation (mainly gamma rays) emitted from the collected dust is detected by a radiation detector that is placed close to the filter. measure.

FIG. 6 is a conceptual diagram showing an example of a high temperature incinerator monitor according to the prior art. The exhaust gas from the incinerator is cooled by the cooling device 6 before entering the monitor in order to prevent the corrosive gas components and water contained therein from corroding the piping and the like. Then, water is removed and the sample gas is guided to the monitor at room temperature. The incinerator exhaust gas introduced through the incinerator exhaust gas introduction pipe 4 to the sample box 1 (in the claims, expressed as a dust trapping filter storage portion, but hereinafter referred to as a sample box) is
The dust contained therein is collected by the filter 2 set in the filter holder 3, and the radiation emitted from the dust is measured by the radiation detector 7 arranged directly above the sample box 1. The exhaust gas that has passed through the filter 2 is sent from the exhaust gas exhaust pipe 5 to the outside of the monitor. The sample box 1 and the radiation detector 7 are surrounded by a lead shield 80 in order to shield radiation from the outside and perform accurate measurement.

In this method, since hydrochloric acid and the like are generated by the cooling in the former stage, it is necessary to configure the cooling device 6 and the drain 61 with a corrosion-resistant material that is resistant to corrosion by the hydrochloric acid. Further, it has a drawback that accurate measurement cannot be performed because a part of dust is removed together with the corrosive gas and water, and that it requires a cooling device and is expensive. An example of this is JP-A-6-242291.

FIG. 7 is a conceptual diagram showing an example of a high temperature incinerator monitor according to the prior art which does not cool the exhaust gas. This is shown in Japanese Utility Model Laid-Open No. 61-193388. The exhaust from the incinerator is not cooled (approximately 200
C.), and the dust therein is collected by the filter as in FIG. 6 and measured by the radiation detector 7 arranged immediately above. In FIG. 7, a portion corresponding to the sample box 1 of FIG. 6 is illustrated as a high temperature DUT 10. In this case, the radiation detector 7 is heated by the heat from the DUT 10 at a high temperature, and the radiation detector 7 cannot fully exhibit its function. Therefore, the radiation detector 7 is connected to the vacuum bottle 40 and two bottomed cylindrical gas flow members. The radiation detector 7 is cooled by the air-cooling fan 20, and at the same time, the wind of the air-cooling fan 20 is passed between the two bottomed cylindrical gas circulation members 30 to form an outer bottomed cylindrical gas circulation member. The vacuum bottle 40 is cooled by spraying it onto the bottom of the vacuum bottle 40 from a through hole 31 formed in the bottom of the vacuum bottle 40. The vacuum bottle 40 and the bottomed tubular gas flow member 30 have a thickness of 1 to 2 mm.
Although it was manufactured by using the stainless steel plate of No. 3, the temperature of the radiation detector 7 was below the required temperature of 45 ° C. If the bottomed tubular gas flow member 30 is structured to allow cooling water to flow and the cooling water flows, the required temperature can be satisfied, but the structure becomes complicated and the cost increases.

FIG. 8 is a conceptual view showing an example of another high temperature incinerator monitor according to the prior art which does not cool the exhaust gas. This is disclosed in JP-A-62-153788. In this case as well, the exhaust gas from the incinerator is introduced without being cooled, and the dust therein is collected by the filter as in FIG. 6 and measured by the radiation detector 7 arranged immediately above it. In FIG. 8 as well, a portion corresponding to the sample box 1 in FIG. 6 is shown as a high temperature DUT 10. Also in this case, since the radiation detector 7 is heated by the heat from the high temperature DUT 10, the radiation detector 7
A heat radiating fin provided at the end of the heat pipe 70 attached to the bottomed tubular heat transfer tube 50 by surrounding the bottomed tubular heat transfer tube 60 and the bottomed tubular heat transfer tube 50 between them. 74 cooling fan 20
To prevent the heat from being transferred to the radiation detector 7. The temperature of the radiation detector 7 is kept at 60 ° C. by forming the bottomed tubular heat insulating tube 60 with a fluororesin and the bottomed tubular heat transfer tube 50 with a material having a large thermal conductivity such as aluminum or copper.
It is possible to reduce to the following.

Since this structure requires a heat pipe, cooling fins, etc., it has a drawback that the structure is complicated, and the required temperature of the radiation detector 7 of 45 ° C. has not been reached.
Another conventional high-temperature incinerator monitor that does not cool the exhaust gas is a water-cooled system or a system that cools with cooled air, both of which are large-scale auxiliary equipment such as a water circulation device and a refrigerator. Is required, and it becomes economically expensive, including maintenance work for that.
Relocation is also difficult due to the need for piping and more equipment. Examples of these are JP-A-57-23874, JP-A-57-309698 and JP-A-63.
There is a publication of -302386.

[0008]

As described in the section of the prior art, cooling the exhaust gas from the incinerator has problems in terms of corrosion resistance and measurement accuracy. It is necessary to lead to the sample box without condensation. However, on the other hand, it is necessary to keep the temperature of the radiation detector at 45 ° C. or lower in order to fully exhibit the function of the radiation detector.

Therefore, the object of the present invention is to maintain the temperature of the radiation detector for measuring the radiation from the sample box introduced while maintaining the high temperature state where the exhaust gas from the incinerator does not condense at 45 ° C. or less. Another object of the present invention is to provide a simple radiation detection device for a high temperature incinerator monitor of a room temperature air cooling system.

[0010]

Means for suppressing the transfer of heat from a heat source to an object is to suppress heat dissipation from the heat source as much as possible. There are three points: to suppress heat reception as much as possible and to suppress heat transfer between them as much as possible.

According to the present invention, (1) in order to suppress the heat dissipation from the heat source as much as possible, 1.1) by covering the high temperature part with a heat insulating material with a reflecting material except for the part which needs to be exposed. , The heat dissipation area is minimized. 1.2) At least the surface of the sample box 1 facing the radiation detector 7 is covered with an envelope made of a thin plate of a good electric conductor in a non-adhesive state to suppress radiation heat radiation.

This effect is further improved by making the surface of the thin plate made of a material having good electrical conductivity a polished surface or a smooth state, and is further enhanced by reducing the thickness to 15 to 70 μm. The reason why a thin plate made of a material with good electrical conductivity is used is that the thermal emissivity is proportional to the square root of the resistivity of the material, and it is greatly reduced when the thickness is thin. Further, the reason why the surface is made to be a polished surface or a smooth state is that the thermal emissivity is further reduced thereby. (Reference: Introduction to Heat Transfer, Written by Kudo, Yokendo, Material for Heat Transfer Engineering, Japan Society of Mechanical Engineers) For reference, the thermal emissivity ε on the polished surface at 200 ℃ is (heat transfer engineering (Source: Revised 4th Edition), Silver ε = 0.025 Copper ε = 0.03 Gold, Aluminum ε = 0.035 Iron ε = 0.07 Stainless steel ε = 0.13 For surface conditions (according to heat transfer overview), Polished surface of aluminum ε = 0.04 Aluminum Rough surface ε = 0.07 Polished surface of copper ε = 0.02 Matte surface of copper ε = 0.22 For the plate thickness (according to heat transfer general theory), in the case of iron, it is extremely thin ε ＝ 0.06 0.02mm ε ＝ 0.22 0.05mm ε ＝ 0.45 0.1 mm ε = 0.65 0.2 mm ε = 0.81 Extremely thick ε = 0.83 Note that according to the above-mentioned literature, the amount of heat transferred by radiation between the two parallel planes is proportional to the surface area (T ₁ ⁴ −T ₂ ⁴ ) And 1 / [(1 / ε ₁ ) + (1 / ε ₂ ) -1] (Equation 1). Here, the suffix 1 represents the high temperature side, the suffix 2 represents the low temperature side, T represents the absolute temperature, and ε represents the emissivity.

Since exhaust gas containing corrosive gas components and water passes through the inside of the sample box 1, the sample box 1 must be made of a corrosion resistant material. As can be seen from the above thermal emissivity data, corrosion-resistant materials such as stainless steel have considerably higher thermal emissivity than electrical conductors. (2) In order to suppress heat reception of the radiation detector as much as possible, the radiation detector is surrounded by an envelope made of a thin plate of a good electric conductor to reduce the absorbed radiant heat quantity.

In this case as well, it is effective to make the surface of the envelope a polished surface or a smooth state, like the envelope of the sample box. The reason why a thin plate with good electrical conductivity is used for the envelope of the radiation detector and the surface is polished or smooth is that as the thermal emissivity decreases, the amount of absorbed radiant heat decreases. Is. (3) In order to suppress the heat transfer between the heat source and the radiation detector as much as possible, it is completely insufficient to suppress the heat transfer by radiation, so 3.1) First, heat transfer by conduction and convection. In order to reduce the temperature to a negligible level, a blower is provided to replace the air layer between the heat source and the radiation detector.

3.2) In order to reduce the heat transferred by radiation when the heat transfer by conduction and convection is sufficiently small, a heat shield member made of a thin plate of good electrical conductivity is provided between the sample box and the radiation detector. There is. Note that the air blown by the blowing means for replacing the air layer cools the heat shield member and the envelope, and thus serves to further reduce the heat transferred by radiation.

With the amount of heat reaching the radiation detector sufficiently reduced by the above means, the radiation detector is cooled by air at room temperature using an air-cooling fan to keep the temperature of the radiation detector within the required temperature range. There is.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION As described in detail in the preceding paragraph, the basic idea of the present invention is to make the heat radiation area of the heat source as small as possible, and to sufficiently reduce the heat transfer by conduction and convection from the heat source by the blower means. In this state, heat transfer due to radiation is reduced by providing a heat shield member and an envelope made of a thin plate of a good electric conductor, and the radiation detector is cooled to the required temperature range by air cooling with air at room temperature.

A detailed description will be given below with reference to examples.

[0019]

【Example】

(First Embodiment) FIG. 1 is a conceptual diagram of a first embodiment of the radiation detecting apparatus for high temperature incinerator monitor according to the present invention.
The same parts as those in the prior art use the same reference numerals, and the same applies to the following embodiments.

The incinerator exhaust gas is guided to the sample box 1 by the incinerator exhaust gas introduction pipe 4 (in the figure, an exhaust gas introduction pipe), passes through the filter 2 set in the filter holder 3, and is discharged to the outside from the exhaust gas exhaust pipe 5. To be done. When passing through the filter 2, dust therein is collected by the filter, and radiation (γ rays) emitted from the dust is arranged outside the sample box 1 and directly above the filter 2. Measured by 7.

Since the exhaust gas contains corrosive gases such as hydrogen chloride, NO _x and SO _x, and moisture, the sample box 1 is made of a corrosion-resistant stainless steel or a metal material having excellent corrosion resistance such as titanium. ing. Exhaust introduction pipe 4,
The sample box 1 and the exhaust / exhaust pipe 5 are heated to 185 to 200 ° C. by the introduction pipe heater 41, the sample box heater 11, and the exhaust pipe heater 51 so that the corrosive components and water in the exhaust gas are not condensed. .

An aluminum sample box envelope having a 0.1 mm-thick polished surface for suppressing heat radiation on a part of a surface and a side surface of the sample box 1 facing the radiation detector 7. 12 is attached in a non-contact state.
The non-contact state is to reduce the heat conduction to the envelope 12 and to lower the temperature of the envelope 12 as much as possible, and to reduce the temperature of the sample box 1 to condense the components in the exhaust gas. This is to prevent

Of the surface of the envelope 12 for the sample box,
The surface other than the surface facing the radiation detector 7, the side surface of the sample box 1, the surfaces of the exhaust gas introduction pipe 4 and the exhaust gas exhaust pipe 5 are covered with a heat insulating material 13 with a reflector. Except for the portion of the sample box envelope 12 facing the radiation detector 7, applying a heat insulating material coating to this part increases the distance between the sample box envelope 12 and the radiation detector 7. This is because the signal from the dust collected on the filter 2 becomes small in that state, and the required sensitivity cannot be secured.

On the side of the radiation detector 7, a duct 21 for sending air is arranged between the surface of the radiation detector 7 and the envelope 12 for the sample box. Air cooling fan 20 installed outside the shield 80
The radiation detector 7 cools the radiation detector 7 and replaces the heated air between the radiation detector 7 and the sample box envelope 12.

The effect of the sample box envelope 12 in this embodiment is that the radiation surface on the heat source side is the sample box 1 when the outer container of the radiation detector 7 is made of stainless steel.
By changing from stainless steel to aluminum having the polished surface of the envelope 12 for the sample box, the radiation heat received by the radiation detector 7 is reduced to about 10%. However, the emissivity of stainless steel is 0.5, and the emissivity of aluminum with a polished surface is 0.03.
And 5. If the emissivity of the polished surface is 0.13, the emissivity of stainless steel will be about 40%.

In this embodiment, the sample box envelope 12 is cooled by the air sent between the radiation detector 7 and the sample box envelope 12, so that the temperature drop corresponds to The radiation heat received by the radiation detector 7 is further reduced. In this example, the thickness of the aluminum of the envelope 12 for the sample box was 0.1 mm, but 15 to 70
When the thickness is reduced to μm, the radiation heat received by the radiation detector 7 is significantly reduced as described in the section (Means for Solving the Problems).

(Second Embodiment) FIG. 2 shows a second embodiment of the present invention.
It is a conceptual diagram of the Example of. The difference of this embodiment from the first embodiment is that the outer container of the radiation detector 7 is a radiation detector envelope 72 in which copper having a polishing surface with a thickness of 1 mm is plated with gold.

When the radiation heat received by the radiation detector 7 in this embodiment is compared with that in the first embodiment, it is about 60% of that in the first embodiment. In this embodiment, the outer container of the radiation detector 7 is replaced with the radiation detector envelope 72 in which copper is plated with gold, but a radiation detector envelope may be added. (Third Embodiment) FIG. 3 is a conceptual diagram of a third embodiment of the present invention.

The difference of this embodiment from the second embodiment is that the heat shield member 8 (hereinafter abbreviated as heat shield) made of an aluminum flat plate having a thickness of 0.1 mm is used for the sample box 1 and the radiation detector 7. Between the heat shield holding member 81 and the heat shield fixing member 82, and the air sent from the duct 21 to replace the heated air, the heat shield holding member 81 and the heat shield fixing member 82 are provided. It is being sent between and.

In this embodiment, the air sent to replace the heated air does not directly hit the sample box envelope 12, so that the air causes the sample box envelope 12 to exceed the limit. The sample box 1 is cooled and, as a result, the sample box 1 is cooled, and there is no fear of dew condensation inside the sample box 1. Therefore, since sufficient air can be sent to the surface of the heat shield 8, the replacement of the heated air is completed, and the temperature of the heat shield 8 is set to the sample box in the case of the first or second embodiment. The temperature can be much lower than the temperature of the envelope 12, and the radiation heat received by the radiation detector 7 is significantly reduced.

(Fourth Embodiment) FIG. 4 shows a fourth embodiment of the present invention.
It is a conceptual diagram of the Example of. In this embodiment, the flat heat shield 8 in the third embodiment is replaced with a bottomed cylindrical heat shield 9 made of aluminum having a 1 mm thick surface as a polished surface. The air sent from the air-cooling fan 20 is directly fed from the upper portion of the bottomed tubular heat shield 9 to the bottom 91 of the bottomed tubular heat shield 9.
And the radiation detector 7 and the bottomed cylindrical heat shield 9
It flows through a hole formed in the vicinity of the center of the upper bottom plate of the bottom portion 92 of the plate 92, flows outward along the lower bottom plate, and is discharged to the outside through the hole formed in the outer peripheral portion.

In this embodiment, the cooling air for the radiation detector 7 simultaneously cools the bottomed tubular heat shield 9, and further the air heated at the bottom 92 of the bottomed tubular heat shield 9. Also works to replace the. The air emitted from the bottom to the outside acts as an air curtain of the radiation detector 7, and the air heated in the sample box 1 or the like comes into contact with the tube portion 91 of the radiation detector 7 and the radiation detector 7 It prevents the transfer of heat to.

In the structure described here, the largest source of radiant heat to the radiation detector 7 is the bottom portion 92 of the bottomed cylindrical heat shield 9. Therefore, if the thickness of the bottom plate of the bottom portion 92, especially the lower bottom plate is set to 15 to 70 μm, the emissivity of that portion becomes small, and the radiation heat received by the radiation detector 7 is greatly reduced. (Fifth Embodiment) In this embodiment, the bottomed cylindrical heat shield 9 made of aluminum in the fourth embodiment is tripled.
Figure 2 shows the conceptual diagram.

The cooling air from the air-cooling fan 20 is first passed through the duct 21 and the radiation detector 7 and the inner heat shield 9a.
Between the inner heat shield 9a and the intermediate heat shield 9c, through the vent hole 93 opened in the lower part of the inner heat shield 9a, and sent to the upper, The heat shield 9c passes through a ventilation hole 93 formed in the upper part of the heat shield 9c, exits between the middle heat shield 9c and the outer heat shield 9b, and is sent downward again to the outer heat shield 9b.
The air outlet that is released into the space inside the lead shield 80 through the ventilation hole 93 that is opened in the lower part of the
It is sent out through 22. Although this hole is shown as a straight line in the figure, it is formed in a dogleg shape or the like if necessary so as not to impair the shield effect of the lead shield 80.

In the figure, the vent hole 93 is provided in the tubular heat shield tube portion having a bottom, but the position of the hole is determined by the balance with the fluid resistance depending on the replacement condition of the heated air at the bottom portion. It is important to. Considering mainly the replacement of the heated air, it is desirable that the hole is near the center of the bottom plate, but in this case, the fluid resistance becomes large. Thickness as a bottomed tubular heat shield 1
The surface of the radiation detector 7 is 3 mm, the side surface of the radiation detector 7 is 3 mm, the bottom is 1 mm, and the wind speed between the radiation detector 7 and the inner cylindrical heat shield 9a is
In the case of 30 m / sec, the temperature rise of the radiation detector 7 was obtained as the temperature of the air discharged from the air cooling fan 20 + 2 ° C. This result, when combined with the temperature increase of 5 ° C. of the air in the air-cooling fan 20, is 7 ° C. higher than the temperature of the room temperature air, and if the maximum ambient temperature is 35 ° C.,
The target temperature of the radiation detector 7 is sufficiently below 45 ° C. Since it is estimated that the wind speed and the temperature rise are in inverse proportion to each other, the lower limit of the wind speed is 10 m / sec.

In the above five embodiments, the material for the envelope and the radiant heat shield has been described as aluminum or copper with gold plating, but the material is not limited to this, and it is not necessary to be limited to it, and the electrical condition may be adjusted according to environmental conditions and cost conditions. It can be used by selecting from good conductors. Regarding the thickness, the thinner it is, the more effective it is. However, it is effective to determine the thickness from practical conditions such as mechanical strength.

As for the surface condition, it is desirable that the surface is a polished surface as long as practical constraints are satisfied.

[0038]

According to the present invention, the sample box 1 which is a heat source, the incinerator exhaust gas introduction pipe 4 and the exhaust gas exhaust pipe 5 are covered as much as possible with the heat insulating material 13 with the reflecting material to reduce the heat radiation area, and the radiation detector 7 is used. The enclosure 72 made of a thin plate with good electrical conductivity
The heat absorption of the radiation detector 7 is suppressed as much as possible by surrounding with, and heat transfer due to radiation is reduced by the heat shield arranged between the sample box envelope 12 and the heat source and the radiation detector 7. Air is sent between the heat source and the radiation detector 7,
By replacing the heated air, heat transfer due to conduction and convection is prevented, and the amount of heat received by the radiation detector 7 is sufficiently reduced. As a result, the temperature of the radiation detector 7 was reduced to 45 ° C. or lower when the maximum ambient temperature was 35 ° C. by cooling with air at room temperature, and the subject of the invention could be achieved.

The envelope 12 of the sample box 1 has a simple structure, and the envelope 72 of the radiation detector 7 is changed from a container made of stainless steel in the prior art to a container made of a good electric conductor material. You can deal with it. As the heat shield, the bottomed cylindrical radiant heat shield is the most effective in view of the fact that the radiation detector 7 can be efficiently cooled, and this also has a simple structure. In accordance with these, the object of the present invention can be achieved with a relatively simple configuration in which an air cooling fan for sending cooling air and a duct are used together.

Since the envelope 72 of the radiation detector 7 is made of a material having good electrical conductivity, another effect of preventing electromagnetic noise from entering the photomultiplier tube and electronic circuit inside the detector can be obtained. To be

[Brief description of drawings]

FIG. 1 is a conceptual diagram of a first embodiment of a radiation detecting apparatus for a high temperature incinerator monitor according to the present invention.

FIG. 2 is a conceptual diagram of a second embodiment according to the present invention.

FIG. 3 is a conceptual diagram of a third embodiment according to the present invention.

FIG. 4 is a conceptual diagram of a fourth embodiment according to the present invention.

FIG. 5 is a conceptual diagram of a fifth embodiment according to the present invention.

FIG. 6 is a conceptual diagram showing an example of a radiation detecting device for a high temperature incinerator monitor according to the prior art.

FIG. 7 is a conceptual diagram showing another example of the radiation detecting device for the high temperature incinerator monitor according to the prior art.

FIG. 8 is a conceptual diagram showing still another example of the radiation detecting apparatus for the high temperature incinerator monitor according to the prior art.

[Explanation of symbols]

 1 Sample Box 11 Sample Box Heater 12 Sample Box Enclosure 13 Insulating Material with Reflective Material 14 Reflective Material 15 Insulating Material 2 Filter 3 Filter Holder 4 Incinerator Exhaust Inlet Pipe 41 Incinerator Exhaust Inlet Pipe Heater 5 Exhaust Exhaust Pipe 51 Exhaust pipe heater 6 Cooling device 61 Drain 7 Radiation detector 71 Radiation detector signal / power cable 72 Radiation detector enclosure 73 Radiation detector body 8 Heat shield 81 Heat shield holding member 82 Heat shield fixing member 9 Bottomed Cylindrical heat shield 9a Inner-bottomed tubular heat shield 9b Outer-bottomed tubular heat shield 9c Middle-bottomed tubular heat shield 91 Bottomed tubular heat shield tube 92 Bottomed tubular heat shield bottom 93 Vent hole 10 High-temperature object to be measured 20 Air-cooling fan 21 Duct 22 Air outlet 30 Bottomed tubular gas flow member 31 Flow hole 40 Vacuum bottle 50 Bottomed tubular heat insulation tube 60 Bottomed tubular heat transfer tube 70 Heat pipe 74 Heat dissipation 80 lead shield

Claims (12)

[Claims] 1. Dust contained in exhaust gas from an incinerator,
High temperature used for high-temperature incinerator monitors that collect radioactive dust in exhaust gas by collecting it with a filter inside the dust collection filter and measuring the radiation emitted from the collected dust with a radiation detector. In a radiation detection device for incinerator monitors, a dust collection filter storage part made of a corrosion-resistant metal material and at least the surface of the filter storage part facing the radiation detector is covered in a non-adhesive state. An envelope made of a thin plate of a good electrical conductor, a portion of the outer surface of the envelope other than the surface facing the radiation detector, a portion of the surface of the filter housing portion not covered by the envelope, and Insulation material that has a reflective material on the surface that covers the exhaust introduction pipe and exhaust pipe, ventilation means for cooling the radiation detector, and ventilation air for replacing the air between the envelope and the radiation detector. The radiation detecting device for a high-temperature incinerator monitor, characterized in that it comprises a stage, a. 2. The radiation detecting device for a high temperature incinerator monitor according to claim 1, wherein the surface of the thin plate of good electric conductor is a polished surface or a smooth state. 3. The radiation detecting device for high temperature incinerator monitoring according to claim 1 or 2, wherein the thickness of the thin plate of a good electric conductor is 15 to 70 μm. . 4. The radiation detecting device for a high temperature incinerator monitor according to claim 1, wherein the radiation detector includes an envelope made of a thin plate of a good electric conductor. Radiation detector for high temperature incinerator monitors. 5. The high temperature incinerator monitor radiation detecting apparatus according to claim 4, wherein the surface of the envelope of the radiation detector is a polished surface or a smooth state. Radiation detector. 6. The dust contained in the exhaust gas from the incinerator,
High temperature used for high-temperature incinerator monitors that collect radioactive dust in exhaust gas by collecting it with a filter inside the dust collection filter and measuring the radiation emitted from the collected dust with a radiation detector. In a radiation detection device for an incinerator monitor, a dust-collecting filter storage part made of a corrosion-resistant metal material, an envelope made of a thin plate of a good electric conductor surrounding the radiation detector, and a surface of the filter storage part. A heat insulating material having a reflecting material on its surface, which covers the portion not facing the radiation detector and the exhaust introduction pipe and the exhaust pipe, and is disposed between the filter housing and the radiation detector. , A heat shield member made of a thin plate of a good electric conductor, a blower unit for cooling the radiation detector, and a blower unit for replacing air between the heat shield member and the radiation detector. A radiation detecting device for a high temperature incinerator monitor, which is characterized in that 7. The dust contained in the exhaust gas from the incinerator,
High temperature used for high-temperature incinerator monitors that collect radioactive dust in exhaust gas by collecting it with a filter inside the dust collection filter and measuring the radiation emitted from the collected dust with a radiation detector. In a radiation detection device for incinerator monitors, a dust collection filter storage part made of a corrosion-resistant metal material and at least the surface of the filter storage part facing the radiation detector is covered in a non-adhesive state. An envelope made of a thin plate of a good electrical conductor, a portion of the outer surface of the envelope other than the surface facing the radiation detector, a portion of the surface of the filter housing portion not covered by the envelope, and Between the heat-insulating material having a reflecting material on the surface that covers the exhaust introduction pipe and the exhaust pipe, an envelope made of a thin plate of a good electrical conductor that surrounds the radiation detector, and between the filter housing and the radiation detector. Displaces the heat shield member made of a thin plate with good electrical conductivity, the blowing means for cooling the radiation detector, the air between the heat shield member and the radiation detector, and the air between the heat shield members. A radiation detecting device for a high temperature incinerator monitor, which is provided with: 8. The radiation detector for high temperature incinerator monitor according to claim 6 or 7, wherein at least one of the envelope of the radiation detector and the heat shield member has a polished surface or a smooth surface. Radiation detector for high temperature incinerator monitor characterized by 9. The radiation detecting apparatus for a high temperature incinerator monitor according to claim 6, wherein the heat shield member has a bottomed cylindrical shape surrounding the radiation detector. Radiation detector for high temperature incinerator monitors. 10. The radiation detecting apparatus for a high temperature incinerator monitor according to claim 9, wherein the bottomed tubular heat shielding member has a plate thickness of 0.05 to 2 mm in a tubular portion facing a side surface portion of the radiation detector. A radiation detecting apparatus for a high temperature incinerator monitor, wherein a plate thickness of a bottom portion of the heat shielding member arranged between the filter housing portion and the radiation detector is 15 to 70 μm. 11. The radiation detecting device for high temperature incinerator monitoring according to claim 9 or 10, wherein the cylindrical heat shield member having a bottom has a multiple structure. apparatus. 12. The radiation detecting apparatus for a high temperature incinerator monitor according to claim 9, wherein a blower means for cooling the radiation detector, a heat shield member and a radiation detector are provided. Is a common air-cooling fan with a blowing means for displacing the air between the radiation detectors, and the air is first directed downward between the radiation detector and its closest bottomed cylindrical heat shield member. The bottomed cylindrical heat shielding member, and sends it out through a ventilation hole formed in the lower portion of the bottomed cylindrical heat shielding member.
It is said that the process of sending upwards to the space between the adjacent bottomed cylindrical heat shielding member, sending out from the hole opened above the second adjacent bottomed cylindrical heat shielding member, and sending the next interval downward is repeated. Radiation detection device for high temperature incinerator monitors, characterized in that the air is blown into the system.