JPH08285988A - Radioactive gas waste dehumidifier - Google Patents

Abstract

PURPOSE: To provide a radioactive gas waste dehumidifier wherein conventional disadvantages in which high temperature was needed for regeneration of an adsorbing agent, anti-explosion measures were necessary for a processing system, interlocking of dehumidification, regeneration and cooling was complicated, a service life of the adsorbing agent was short, and running cost and maintenance cost were increased are dissolved. CONSTITUTION: A dehumidifier 5 for using a selective permeation film capable of dissolving disadvantage of a solid adsorbing agent for dehumidification of waste gas, a wet separator 3 for draining moisture separated from waste gas by the dehumidifier 5 out of a system of a waste gas processing device 20, and a circulation line 7 for circulating processed gas passing through the selective permeation film of the dehumidifier 5 toward the inlet side of the wet separator 3 are constituted. Thereby waste gas of a high degree of dryness necessary for processing of waste gas is obtained, a high temperature part is not needed, risk of explosion in not present, and dehumidification of waste gas can be performed without fear dispersion of waste gas out of the system.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention constitutes a waste gas treatment device for treating radioactive gas waste (hereinafter referred to as waste gas) generated from nuclear facilities such as a nuclear power plant, and removes moisture contained in the waste gas. The present invention relates to a radioactive gas waste dehumidifying device for removing and increasing the dryness of waste gas.

[0002]

2. Description of the Related Art In order to treat waste gas generated in a nuclear power plant or the like, there is a waste gas treatment device such as an activated carbon type rare gas hold-up device which uses activated carbon to treat the waste gas. In such a waste gas treatment device using activated carbon, the performance of the activated carbon deteriorates sharply due to the moisture flowing into the waste gas together with the waste gas.Therefore, a dehumidifying device is installed upstream of the activated carbon to treat the waste gas with a dew point. It is necessary to send the dry gas lowered to -30 ° C or lower to the activated carbon type rare gas holdup device.

As such a dehumidifying device for converting waste gas into a dry gas, a solid adsorption type using a solid adsorbent such as a molecular sieve or silk gel has been conventionally used. Further, in such a dehumidifier, a molecular sieve that adsorbs moisture, a solid adsorbent such as silkagel, etc., since adsorption performance deteriorates by adsorbing moisture, a dehumidification tower consisting of a tank filled with a solid adsorbent is used. , 3 units for use, regeneration, and spare are installed, and with the switching valve for regeneration, 2 units are regularly and alternately used, excluding the spare, from the waste gas passing between the solid adsorbents. I try to remove water.

Further, the solid adsorbent in the adsorption tower which has adsorbed water and deteriorated in performance is heated to a high temperature by an electric heater or the like,
I'm trying to play. Therefore, the dehumidifying device using the solid adsorbent has the following problems. (1) When the solid adsorbent is regenerated, it is
Although the solid adsorbent contained in the dehumidifying tower is heated up to 0 ° C or higher, the waste gas treatment system is a system for treating the waste gas containing H ₂ as a main component, so the waste gas treatment device is provided with explosion-proof measures. There is a need. (2) The interlock becomes complicated because a plurality of adsorption towers are operated in a cycle of dehumidification / regeneration / cooling by switching the switching valve. (3) The solid adsorbent needs to be replaced once every three years because the adsorption performance deteriorates due to aging as well as moisture adsorption.

Also, a dehumidifying device has been considered in which a selective permeable membrane (dehumidifying membrane) is used in place of the solid adsorbent to dehumidify the waste gas. In such a dehumidifier, H ₂ and N ₂ which are the main components of the waste gas, Xe and Kr of a small amount of radioactive noble gas, and water vapor (H ₂ O)
Using selective permeable membranes with different transmission coefficients as shown in Figure 2,
By utilizing the difference in the selective permeation performance of the selective permeation membrane, H ₂ O having a large permeation coefficient is preferentially taken out from the waste gas to dehumidify the waste gas.

Such a dehumidifier does not require a high temperature part for removing moisture (dehumidification) of waste gas including regeneration treatment of a dehumidifying medium, as compared with a dehumidifying device using a solid adsorbent described above. In addition to the safety benefits, there are advantages such as low running costs and simplification and compactness of the dehumidifier.

However, in the dehumidifying device using such a selective permeable membrane, the selective permeable membrane for dehumidification cannot be made to have high strength with little possibility of damage. If it breaks, radioactive substances in the waste gas may leak out of the system, causing troubles such as contaminating the surrounding area where the waste gas treatment device is installed. Therefore, not to mention the dehumidifying device, the waste gas processing device communicating with the dehumidifying device should be protected from spreading radioactive contamination to the surroundings even if the selective permeable membrane is broken and the waste gas leaks out of the system. There is a problem in that it must be housed inside the obstacle structure and used.

[0008]

DISCLOSURE OF THE INVENTION The present invention solves the problems of the conventional dehumidifier used in the above-mentioned waste gas treatment apparatus and requires a high temperature section for removing moisture of waste gas including regeneration treatment. In addition, the dehumidifier does not have to have a complicated structure, can be made compact, can be operated at low cost, and even if it should be damaged, radioactive substances in the waste gas leak out of the waste gas treatment system. An object of the present invention is to provide a safe radioactive gas waste dehumidifying device that does not do so.

[0009]

Therefore, the radioactive gas waste dehumidifying device of the present invention has the following means. (1) Separate excess moisture above the saturated moisture contained in the waste gas (radioactive gas waste) and discharge it to the outside of the system of the waste gas treatment equipment to make the waste gas moisture-saturated waste gas. A moisture separator was provided. (2) A dehumidifier provided with a selective permeable membrane that selectively permeates residual water in the waste gas that has passed through the moisture separator and separates it from the waste gas to use as a processing gas. It should be noted that most of the permeation through the permselective membrane is water, but as can be understood from FIG. 2, H ₂ , N ₂ , X contained in the waste gas are contained.
Although e and Kr are also small in quantity, they are transmitted. The mixture of the waste gas components that have permeated these selective permeation membranes is called a processing gas. (3) The treated gas separated from the waste gas by the dehumidifier is
A circulation line was provided to circulate from the dehumidifier to the inlet side of the moisture separator.

[0010]

With the radioactive gas waste dehumidifying device of the present invention, excess moisture above the saturated moisture content in the waste gas is removed by the above-mentioned means.
Moisture that is separated from the waste gas by the moisture separator and discharged to the outside of the system of the waste gas treatment device, and the moisture remaining in the waste gas from which excess moisture has been removed is the selective permeable membrane installed in the dehumidifier. Are preferentially transmitted. As a result, the waste gas sent to the activated carbon type rare gas hold-up device for treating the waste gas can be sufficiently dried and the performance deterioration of the device can be prevented.

Further, although the moisture that has permeated the selective permeable membrane is a small amount, it also becomes a processing gas mixed with the gas in the waste gas that has permeated the selective permeable membrane, and passes through the circulation line to be removed from the dehumidifier. The moisture is sent to the inlet side of the moisture separator, and the excess moisture equal to or higher than the saturated moisture is separated by the moisture separator and discharged to the outside of the system. As a result, the processing gas that has permeated through the selective permeable membrane is completely prevented from leaking out of the system, and even if the selective permeable membrane is damaged, the waste gas that has passed through the damaged portion as it is is the same as the processing gas. , It is only circulated from the dehumidifier to the moisture separator through the circulation line,
It is possible to reliably prevent radioactive substances in the waste gas from leaking out of the system and to prevent radioactive contamination in the vicinity where the waste gas treatment device is installed.

Furthermore, neither the moisture separator nor the dehumidifier is heated to a high temperature, and there is no danger of explosion even when treating a waste gas containing a large amount of H _2, and no explosion-proof measures are required. In addition, since neither the moisture separator nor the dehumidifier needs an operation for regeneration, the device can be made very simple and compact. Further, as the selective permeable membrane capable of making the waste gas highly dry, it is possible to adopt the one having a track record of no maintenance for 5 years or more in the general industry, which can improve the maintainability and reduce the running cost. .

[0013]

EXAMPLES The radioactive gas waste dehumidifying device of the present invention will be described below based on examples. FIG. 1 is a flow chart showing a waste gas treatment device including an embodiment of the radioactive gas waste dehumidifying device of the present invention.

As shown in the figure, a waste gas AG from a nuclear power plant or the like, which contains moisture, contains N ₂ and H ₂ as main components, and contains a small amount of radioactive Xe and Kr, is pressurized by a compressor 1. It The pressurization of this waste gas AG is
The H ₂ O contained therein is necessary for permeating the selectively permeable membrane described later. In other words, the waste gas AG
If the pressure is not applied, the permselective membrane will not function. The waste gas AG pressurized by the compressor 1 and having a high temperature is cooled to a room temperature or lower by the waste gas cooler 2 and then constitutes a radioactive gas waste dehumidifying apparatus which is an embodiment of the present invention. , Is introduced into the moisture separator 3.

In the moisture separator 3, the waste gas cooler 2 cools the waste gas AG to remove excess moisture from the waste gas AG, which has been saturated with water. The moisture separator 3 may employ a structure similar to that conventionally used, for example, to pass a waste gas AG containing mist-like water and containing saturated or more water through a filter or the like. With this, waste gas A that captures mist-like water, removes excess moisture, and removes moisture below saturation
It may be one that can be changed to G. Further, the water separated by the moisture separator 3 is discharged from the moisture separator 3 by the drain line 10 from the system of the waste gas treatment device 20 and is treated by the separately provided liquid treatment system.

The moisture-saturated waste gas AG that has passed through the moisture separator 3 is separated by an air filter 4 from dust contained in the gas.
After removing dust and the like, it is sent to the dehumidifier 5 which constitutes the present embodiment. The dehumidifier 5 is composed of two systems provided with a spare dehumidifier 6 in case of emergency. In the dehumidifier 5, moisture separation is performed using a selective permeation membrane having different permeation performance for each gas contained in the waste gas AG. The dehumidifier 6 also performs the same moisture separation as the dehumidifier 5, but only the dehumidifier 5 will be described for the sake of simplicity.

FIG. 2 shows that the inventors of the present application have confirmed by tests that they can be used in a radiation environment such as a nuclear power plant (radiation resistance performance), and that H ₂ , N ₂ and a trace amount of radioactive Xe can be used. It has been confirmed that H ₂ O can be selectively taken out from a waste gas composed of Cr, Kr and H ₂ O. In a permselective membrane using a hollow fiber membrane made of polyimide, which is widely used in general industry, It is a graph which shows the permeation | transmission performance of a film | membrane and temperature for every gas. As shown in FIG. 2, in this selective permeable membrane, gases such as N ₂ , Xe, and Kr have a smaller permeation coefficient than H ₂ O, and it is very difficult to permeate the selective permeable membrane.

In the dehumidifier 5, the above-mentioned permselective membrane is stretched and partitioned to make it difficult for the permselective membrane to permeate.
It is divided into a primary side 51 in which waste gas having a high degree of dryness stays and a secondary side 52 in which waste gas (processing gas) containing a large amount of water that easily permeates the selective permeable membrane stays. Of the waste gas AG introduced into the dehumidifier 5, the waste gas having a high degree of dryness that stays on the primary side is sequentially sent to the activated carbon type rare gas hold-up device 8 provided on the downstream side, and the activated carbon type The waste gas AG is processed without deteriorating the performance of the activated carbon of the rare gas holdup device 8.

Further, H which is relatively easy to pass through the selectively permeable membrane
₂ 、 Radioactive Xe and Kr, which are transmitted even in trace amounts
And the secondary side where the processing gas containing a lot of water stays,
It is connected to the suction side of the compressor 1 by the circulation line 7 that constitutes the present embodiment, and the processing gas returns from the secondary side 52 of the dehumidifier 5 to the suction side of the compressor 1 through the circulation line 7 and from the nuclear power plant or the like. It is mixed with the waste gas AG that has been sent, and is circulated through the waste gas treatment device 20 for dehumidification in the same manner as described above.

Thus, the processing gas on the secondary side 52 is also abolished.
Since it does not leak outside the system of the gas processing device 20,
First, the selectively permeable membrane provided in the dehumidifier 5 is damaged, and the waste gas AG
H inside ₂, N₂, Xe, Kr are the secondary side 52 of the dehumidifier 5.
Even if the gas flows out to the circulation line 7,
Since it returns to the inlet of the compressor 1 and circulates, waste gas treatment
No contamination of the surrounding area where the device 20 is installed
It

In FIG. 1, 9 is an N ₂ gas purge line for purging the processing gas on the secondary side 52 of the dehumidifier 5 to the inlet of the compressor 1.

As described above, in the radioactive gas waste dehumidifying apparatus of this embodiment, the moisture separator 3, the dehumidifier 5 provided with the selective permeable membrane, and the processing gas that has passed through the selective permeable membrane of the dehumidifier 5 are By the circulation line 7 that circulates to the inlet of the compressor 1, which is the inlet side of the moisture separator 3,
Many advantages over dehumidifiers that use solid adsorbents,
Waste gas can be treated by the selective permeable membrane without concern about the occurrence of radioactive contamination in the surrounding area.

[0023]

As described above, according to the radioactive gas waste dehumidifying device of the present invention, the following effects can be obtained with the configuration shown in the claims.

(1) It is possible to dehumidify the waste gas by means of the selectively permeable membrane, which can make the apparatus very simple and compact without requiring explosion-proof measures. In addition, running costs and maintenance costs can be reduced.

(2) Even if the selective permeable membrane is damaged,
A waste gas does not leak out of the system, and a safe system can be realized.

[Brief description of drawings]

FIG. 1 is a flow chart showing an embodiment of a radioactive gas waste dehumidifying device of the present invention,

FIG. 2 is a diagram showing permeation performance for each gas of a selectively permeable membrane used in the dehumidifier shown in FIG.

[Explanation of symbols]

1 Compressor 2 Waste gas cooler 3 Moisture separator 4 Air filter 5 Dehumidifier 6 Preliminary dehumidifier 7 Circulation line 8 Activated carbon type rare gas hold-up device 9 N ₂ Gas purge line 10 Drain line 20 Waste gas treatment device

Front page continuation (72) Inventor Shigekazu Hatano 2-1-1, Niihama, Arai-cho, Takasago, Hyogo Prefecture Takasago Laboratory, Mitsubishi Heavy Industries, Ltd. (72) Setsuo Fujiwara 2-5-1 Marunouchi, Chiyoda-ku, Tokyo Hishi Heavy Industries Ltd.

Claims (1)

[Claims] 1. A radioactive gas waste dehumidifying device for removing water contained in the radioactive gas waste, which constitutes a waste gas processing device for processing radioactive gas waste generated from nuclear power facilities, wherein the radioactive gas is used. Dehumidification provided with a moisture separator that separates the moisture of the waste and makes it saturated, and a selective permeable membrane that selectively permeates and separates the moisture remaining in the radioactive gas waste introduced from the moisture separator. A radioactive gas waste dehumidifying device comprising: a dehumidifier and a circulation line for circulating the processing gas that has permeated through the selectively permeable membrane from the dehumidifier to the inlet side of the moisture separator.