JP2013036822A - Decontamination system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a decontamination system capable of decontaminating a human body contaminated by contaminants (human body contaminated by biological (B) substances or chemical (C) substances) more surely in a shorter time compared to a system of decontamination by water discharged from a water shower.SOLUTION: In a decontamination system 1 which decontaminates a human body contaminated by contaminants (for example, nuclear, biological and chemical (NBC) substances), the human body contaminated by the contaminants is immersed in an ozone water stored in a decontamination chamber 41 to be decontaminated.

Description

  The present invention relates to a technique of a decontamination system for decontaminating a human body contaminated with various contaminants.

Conventionally, the technique regarding the decontamination system which decontaminates the human body contaminated with various pollutants is known. Examples of the various contaminants include NBC (nuclear, biological, chemical) materials. The contamination with N (nuclear) substances includes radioactive contamination due to nuclear weapons or nuclear accidents. Contamination by B (biological) substances includes contamination of smallpox viruses, carbon bacteria, and the like by biological weapons. Contamination by C (chemical) substances includes sarin and mustard gas contamination by chemical weapons.
In such a decontamination system, a human body contaminated with a pollutant is decontaminated by applying water discharged from a shower arranged in the tent (see Patent Document 1). That is, in such a decontamination system, decontamination is performed by washing away the contaminants from the human body by the water stream.

JP 2002-250793 A

However, in such a decontamination system, in order to reliably decontaminate a human body contaminated with a pollutant, it is necessary to keep water on the human body for a long time.
Further, in such a decontamination system, the human body cannot be decontaminated unless water is applied to the contaminated part of the human body, but it is difficult to apply water to the contaminated part of the human body by shower without leaking. Therefore, there is a problem that the decontamination work is finished in a state where the human body is not sufficiently decontaminated.

  The present invention has been made in view of the above situation, and decontaminates a human body contaminated with a pollutant in a short time and more reliably than that decontaminated with water discharged from a water shower. It is an object to provide a decontamination system that can be used.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

  That is, in claim 1, a decontamination system for decontaminating a human body contaminated with a pollutant, wherein the human body contaminated with the pollutant is immersed in ozone water stored in a decontamination chamber. And decontaminating the human body contaminated with the pollutant.

  In Claim 2, it has an exhaust apparatus comprised so that the gas in the said decontamination chamber can be exhausted out of the said decontamination chamber.

  According to a third aspect of the present invention, the decontamination chamber is configured such that a person contaminated with the pollutant can walk in the decontamination chamber in which the ozone water is stored.

  According to a fourth aspect of the present invention, the decontamination chamber includes a water flow generating device that generates a water flow in the ozone water stored in the decontamination chamber.

  As effects of the present invention, the following effects can be obtained.

  That is, according to the present invention, the human body contaminated with the pollutant (the human body contaminated with the B substance or the C substance) in a shorter time and more reliably than the one decontaminated with the water discharged from the shower. Can be decontaminated.

The block diagram which showed the whole structure of the decontamination system which concerns on embodiment of this invention. The front schematic diagram which showed the decontamination part of the decontamination system which concerns on embodiment of this invention. Similarly, a schematic plan view. (1) Front schematic diagram, (2) Front schematic diagram, (3) Front schematic diagram. Similarly front schematic diagram. Similarly front schematic diagram. Similarly front schematic diagram. Similarly front schematic diagram. Similarly front schematic diagram. The perspective view which showed the person decontaminated. Similarly perspective view. The front schematic diagram which showed the decontamination part of the decontamination system which concerns on embodiment of this invention. FIG. The block diagram which showed the reproduction | regeneration part of the decontamination system which concerns on embodiment of this invention. The block diagram which showed the whole structure of the decontamination system which concerns on embodiment of this invention. The front schematic diagram which showed the decontamination part of the decontamination system which concerns on embodiment of this invention. The front schematic diagram which showed the decontamination part of the decontamination system which concerns on embodiment of this invention. The block diagram which showed the whole structure of the decontamination system which concerns on embodiment of this invention.

Next, the decontamination system 1 which concerns on embodiment of invention is demonstrated using FIGS. 1-18.
The decontamination system 1 decontaminates a human body contaminated with various pollutants. The various contaminants include NBC (nuclear, biologic, chemical) materials.
As shown in FIG. 1, the decontamination system 1 includes a tank 2, an ozone water generator 3, and a decontamination unit 4.

The tank 2 of the decontamination system 1 stores raw water (water). The raw water stored in the tank 2 is supplied to the ozone water generator 3.
The ozone water generator 3 of the decontamination system 1 is connected to the tank 2 via a pipe. The ozone water generator 3 generates ozone water from raw water supplied from the tank 2 via a pipe. Here, the ozone water is obtained by dissolving ozone (O3) in water.
The ozone water generated by the ozone water generator 3 is heated to a predetermined temperature so that the person who is put on the ozone water (the person to be decontaminated) does not feel too cold or too hot by the temperature control device. The temperature is adjusted (for example, raised or lowered to 26 to 40 degrees) and supplied to the decontamination unit 4.

In the decontamination unit 4 of the decontamination system 1, the human body contaminated with the pollutant is decontaminated. As shown in FIG. 2 or FIG. 3, the decontamination unit 4 includes a decontamination chamber 41 and an exhaust device 42.
The decontamination chamber 41 of the decontamination unit 4 in the decontamination system 1 is connected to the ozone water generation device 3 through a pipe, and ozone water whose temperature is adjusted by the temperature adjustment device is stored in the decontamination chamber 41. Configured as follows.
The decontamination chamber 41 of the decontamination unit 4 is configured so that a person contaminated with a pollutant can be immersed in ozone water up to the shoulder while standing in the decontamination chamber 41.

In this way, the decontamination system 1 is contaminated with the pollutant by immersing the human body contaminated with the pollutant up to its shoulder in the ozone water stored in the decontamination chamber 41 of the decontamination unit 4. Configured to decontaminate the human body. For this reason, in the decontamination system 1, ozone water can be more reliably brought into contact with a portion of the human body contaminated with the pollutant that is immersed in the ozone water stored in the decontamination chamber 41 of the decontamination unit 4. it can.
In the decontamination system 1, when the pollutant that pollutes the human body is a B (biological) substance, the B substance is sterilized by ozone water immersed in the person contaminated with the pollutant. . In the case where the pollutant that pollutes the human body is a C (chemical) substance, the C substance is decomposed by ozone water immersed in a person contaminated with the pollutant.
As described above, in the decontamination system 1, decontamination is performed by immersing in ozone water stored in the decontamination chamber 41 of the decontamination unit 4, the substance B is sterilized, and the substance C is decomposed. .
For this reason, according to the decontamination system 1, it is contaminated with the pollutant (the human body contaminated with the B substance or the C substance) in a shorter time and more reliably than the decontamination with the water discharged from the shower. The decontaminated human body can be decontaminated.

In the decontamination system 1, when the pollutant that pollutes the human body is an N (nuclear) substance, the N substance is aggregated after being separated from the human body by the action of aggregating the colloid in ozone water. For this reason, in the decontamination system 1, when filtering the drainage of the ozone water used for decontamination, the aggregated N substance can be easily collected without using a fine filter, The process which removes N substance from waste water can be performed more easily.
In the decontamination system 1, when the pollutant that pollutes the human body is a weakly resistant B substance, the B substance is sterilized and rendered harmless, so that the disinfection treatment of the B substance contained in the waste water becomes unnecessary. . When the pollutant that pollutes the human body is a highly resistant substance B, disinfection of the substance B proceeds in the process of draining the ozone water after the human body contaminated with the pollutant is immersed in the ozone water. Then, the subsequent disinfection treatment of the B substance contained in the waste water can be easily performed.
In the decontamination system 1, when the pollutant that pollutes the human body is an easily decomposable C substance, the C substance is decomposed and rendered harmless, so that the decomposition process of the C substance contained in the waste water is not required. When the pollutant that pollutes the human body is a persistent C substance, the decomposition of the C substance proceeds in the process of draining the ozone water after the human body contaminated with the pollutant is immersed in the ozone water. Subsequent decomposition treatment of the C substance contained in the waste water can be easily performed.
Therefore, according to the decontamination system 1, the N substance is agglomerated, the B substance is sterilized, and the C substance is decomposed, so that the waste water can be treated more easily than the decontamination with water. be able to.
In addition, since ozone returns to oxygen in a short time, in the decontamination system 1, the neutralization process of ozone with respect to the said waste_water | drain is unnecessary.

  First, the decontamination unit 4 of the decontamination system 1 causes a person contaminated with a contaminant to enter the decontamination chamber 41 of the decontamination unit 4 in a state where ozone water is not stored (see FIG. 4 (1)). Then, ozone water is supplied from the water supply hole 41a of the decontamination chamber 41, and the ozone water is accumulated in the decontamination chamber 41 to decontaminate the contaminants (see FIG. 4 (2)). When the decontamination is completed, the ozone water stored in the decontamination chamber 41 may be drained from the drain hole 41b of the decontamination chamber 41 (see FIG. 4 (3)).

  As shown in FIG. 5, the decontamination chamber 41 of the decontamination unit 4 in the decontamination system 1 is provided with a stool in the decontamination chamber 41 so that a person contaminated with a contaminant can sit on the stool in the decontamination chamber 41. You may comprise so that a shoulder can be immersed in ozone water to a shoulder.

  The exhaust device 42 of the decontamination unit 4 in the decontamination system 1 is configured to be able to exhaust the gas in the decontamination chamber 41 out of the decontamination chamber 41. As shown in FIG. 2 or FIG. 3, the exhaust device 42 of the decontamination unit 4 includes a duct 43, a suction fan 44, and an exhaust cylinder 45.

The duct 43 of the exhaust device 42 in the decontamination section 4 of the decontamination system 1 is disposed along the side wall of the decontamination chamber 41 so as to protrude outward from the side wall of the decontamination chamber 41. The duct 43 of the exhaust device 42 in the decontamination section 4 is configured such that the inside thereof communicates with a portion above the portion in the decontamination chamber 41 where ozone water is stored.
The suction fan 44 of the exhaust device 42 in the decontamination unit 4 is disposed so as to protrude outward from the duct 43. The suction fan 44 of the exhaust device 42 in the decontamination section 4 is configured to be able to suck the gas in the decontamination chamber 41 toward the duct 43 side.
The exhaust cylinder 45 of the exhaust device 42 in the decontamination section 4 is disposed so as to extend upward from the suction fan 44 outside the decontamination chamber 41.
In the exhaust device 42 of the decontamination unit 4 configured as described above, the suction fan 44 performs a suction operation, whereby the gas in the decontamination chamber 41 is sucked to the duct 43 side, and the duct 43 and the suction fan 44 are collected. It will be discharged | emitted from opening of the upper end of the exhaust pipe 45 via this.

As described above, the exhaust device 42 in the decontamination section 4 of the decontamination system 1 exhausts the gas in the decontamination chamber 41 to the outside of the decontamination chamber 41.
Therefore, according to the decontamination system 1, when decontaminating a human body contaminated with a pollutant, ozone gas is not normally diffused from the ozone water, but the ozone gas is temporarily removed from the surface of the ozone water. Even when scattered, the ozone gas can be exhausted out of the decontamination chamber 41 so that a person contaminated with the pollutant is not affected by sucking the ozone gas.

Further, the exhaust device 42 in the decontamination section 4 of the decontamination system 1 may be constituted by a duct 43 and an air supply fan 46 as shown in FIG.
The duct 43 of the exhaust device 42 in the decontamination section 4 of the decontamination system 1 is disposed along the side wall of the decontamination chamber 41 so as to protrude outward from the side wall of the decontamination chamber 41. The duct 43 of the exhaust device 42 in the decontamination section 4 is configured such that the inside thereof communicates with a portion above the portion in the decontamination chamber 41 where ozone water is stored. The duct 43 of the exhaust device 42 in the decontamination section 4 has an exhaust port penetrating the inside of the duct 43 on the outer surface (the side opposite to the decontamination chamber 41).
The air supply fan 46 of the exhaust device 42 in the decontamination unit 4 of the decontamination system 1 is disposed on the ceiling of the decontamination chamber 41. The air supply fan 46 of the exhaust device 42 in the decontamination section 4 can supply air from the outside of the decontamination chamber 41 into the decontamination chamber 41 and push the gas in the decontamination chamber 41 toward the duct 43. Configured as follows.
In the exhaust device 42 of the decontamination section 4 configured as described above, the air supply fan 46 performs the air supply operation, whereby the gas in the decontamination chamber 41 is pushed out to the duct 43 side, and the exhaust of the duct 43 is performed. It will be discharged from the mouth.

Further, the exhaust device 42 in the decontamination section 4 of the decontamination system 1 may be configured by a duct 43 and an exhaust fan 47 as shown in FIG.
The duct 43 of the exhaust device 42 in the decontamination section 4 of the decontamination system 1 is disposed along the side wall of the decontamination chamber 41 so as to protrude outward from the side wall of the decontamination chamber 41. The duct 43 of the exhaust device 42 in the decontamination section 4 is configured such that the inside thereof communicates with a portion above the portion in the decontamination chamber 41 where ozone water is stored. The duct 43 of the exhaust device 42 in the decontamination section 4 has an exhaust port penetrating the inside of the duct 43 on the outer surface (the side opposite to the decontamination chamber 41).
The exhaust fans 47 of the exhaust device 42 in the decontamination unit 4 of the decontamination system 1 are respectively arranged outside the two exhaust ports of the duct 43. The exhaust fan 47 of the exhaust device 42 in the decontamination unit 4 is configured to be able to suck the gas in the decontamination chamber 41 toward the duct 43 side.
In the exhaust device 42 of the decontamination unit 4 configured as described above, the exhaust fan 47 performs an exhaust operation, whereby the gas in the decontamination chamber 41 is sucked to the duct 43 side and the exhaust port ( The air is exhausted from the exhaust fan 47).

The exhaust device 42 in the decontamination unit 4 of the decontamination system 1 may be configured such that an ozone decomposition catalyst is provided at the opening at the upper end of the exhaust cylinder 45 or at the exhaust port of the duct 43. The ozone decomposition catalyst of the exhaust device 42 in the decontamination unit 4 can return ozone gas exhausted from the opening at the upper end of the exhaust cylinder 45 in the exhaust device 42 or ozone gas exhausted from the exhaust port of the duct 43 to oxygen. Configured to be able to.
With this configuration, in the decontamination system 1, when the ozone gas is exhausted outside the decontamination chamber 41 of the decontamination unit 4, the ozone gas is returned to oxygen.
Further, a hepa filter may be disposed at the exhaust tube 45 of the exhaust device 42 in the decontamination unit 4 or the exhaust port of the duct 43 of the exhaust device 42.

As shown in FIG. 8, the decontamination chamber 41 of the decontamination unit 4 in the decontamination system 1 is sized so that a person contaminated with contaminants can walk in the decontamination chamber 41 in which ozone water is stored. It may be configured.
In this way, the decontamination chamber 41 of the decontamination unit 4 is configured, and the pollutant is separated from the human body by causing a person contaminated with the pollutant to walk in the decontamination chamber 41 in which ozone water is stored. Can do.
In addition, by configuring the decontamination chamber 41 of the decontamination unit 4 in this way, it is possible to simultaneously decontaminate a plurality of human bodies contaminated with contaminants.

As shown in FIG. 9, the decontamination chamber 41 of the decontamination unit 4 in the decontamination system 1 may include a water flow generator 48 that generates a water flow in the ozone water stored in the decontamination chamber 41.
A plurality of water flow generators 48 are arranged on the inner wall of the decontamination chamber 41. The water flow generators 48, 48,... Are configured to generate a water flow in the ozone water by injecting bubbles into the ozone water stored in the decontamination chamber 41 or by injecting ozone water. The
In the decontamination chamber 41 of the decontamination unit 4 configured in this way, when a person contaminated with a pollutant is immersed in the ozone water in which the water stream is generated, the pollutant is separated from the human body by the water stream. .
Therefore, according to the decontamination system 1, it is possible to decontaminate a human body contaminated with a pollutant in a shorter time and more reliably than a decontamination method using water discharged from a shower.

The decontamination unit 4 in the decontamination system 1 may be configured to perform preliminary decontamination before decontaminating a human body contaminated with a contaminant in the decontamination chamber 41.
As a configuration for performing preliminary decontamination in the decontamination unit 4, for example, there is a configuration in which a water tank in which water is stored is provided, and bubbles are injected into the water stored in the water tank from the inner wall of the water tank, or water is injected. . In such a preliminary decontamination configuration, a person contaminated with a pollutant is immersed in the water stored in the water tank in which the water stream is generated, and a part of the pollutant is separated from the human body by the water stream.
As described above, the decontamination unit 4 in the decontamination system 1 is discharged from the shower by adopting a configuration in which preliminary decontamination is performed before decontamination of the human body contaminated with the contaminant in the decontamination chamber 41. The human body contaminated with the pollutant can be further decontaminated more reliably than the one decontaminated with water.

Contaminants may be decontaminated by the decontamination unit 4 of the decontamination system 1 in a state where the goggles 9 and the mouth mask 10 are respectively attached to a person contaminated with the contaminants (see FIG. 10). ).
In addition, a person contaminated with a contaminant may be decontaminated by the decontamination unit 4 of the decontamination system 1 with the gas mask 11 covering the face (see FIG. 11).
By doing in this way, ozone gas is not normally diffused from the ozone water, but even if ozone gas was diffused from the ozone water in the decontamination chamber 41 of the decontamination section 4, it was contaminated with pollutants. Contaminants can be decontaminated without being affected by, for example, inhalation of ozone gas.

As shown in FIG. 12, in the state where the membrane member 49 is floated on the surface of the ozone water stored in the decontamination chamber 41 of the decontamination unit 4 in the decontamination system 1, decontamination of the human body contaminated with the pollutant is performed. You may do it. At this time, the membrane member 49 is disposed around the person contaminated with the pollutant, and the ozone gas scattered from the surface of the ozone water stored in the decontamination chamber 41 of the decontamination unit 4 is contaminated with the pollutant. It is made to flow to the inner wall side of the decontamination chamber 41 away from the person who has left.
In this way, when decontaminating the human body contaminated with pollutants, ozone gas is not normally diffused from ozone water, but if ozone gas is diffused from the surface of ozone water, In addition, it is possible to decontaminate the pollutant by preventing the person contaminated with the pollutant from being affected by sucking the ozone gas.

As shown in FIG. 13, the decontamination chamber 41 of the decontamination unit 4 in the decontamination system 1 is in a state in which the upper part from the neck of the human body contaminated with the pollutant is disposed outside the decontamination chamber 41 You may comprise so that the human body contaminated with the pollutant may be decontaminated.
The decontamination chamber 41 of the decontamination unit 4 has, for example, an inlet 41c on the side and an opening 41d that allows a portion above the neck of a human body contaminated with a contaminant to be disposed outside the decontamination chamber 41. Constructed in a box-like shape at the top.
In such a configuration, a person contaminated with a contaminant enters the decontamination chamber 41 from the side inlet 41c in the decontamination chamber 41 of the decontamination unit 4, and decontaminates the head from the upper opening 41d. Take it out of the chamber 41. And in the state which sealed the inlet 41c of the side part in the decontamination chamber 41 of the decontamination part 4, ozone water is stored in the decontamination chamber 41, and the human body contaminated with the pollutant is decontaminated.
By configuring in this way, when decontaminating the human body contaminated with pollutants, ozone gas does not normally diffuse from ozone water, but if ozone gas diffuses from the surface of ozone water In this case, the pollutant can be decontaminated so that a person contaminated with the pollutant is not affected by sucking the ozone gas.

As shown in FIG. 1, the decontamination system 1 includes a regeneration unit 5.
In the regeneration unit 5 of the decontamination system 1, the waste water of ozone water used for decontamination in the decontamination unit 4 is regenerated into raw water. As shown in FIG. 14, the regeneration unit 5 includes a coarse filter 51, an activated carbon adsorption filter 52, a reverse osmosis membrane purification device 53, and a dirt sensor 54.

The coarse filter 51 of the regeneration unit 5 in the decontamination system 1 removes impurities having a large particle size (such as dust and the aggregated N substance) from the waste water.
The activated carbon adsorption filter 52 of the regeneration unit 5 is disposed on the downstream side of the coarse filter 51. The activated carbon adsorption filter 52 of the regeneration unit 5 removes impurities having small particle sizes that could not be removed by the coarse filter 51 from the waste water.
The reverse osmosis membrane purification device 53 of the regeneration unit 5 is disposed on the downstream side of the activated carbon adsorption filter 52. The reverse osmosis membrane purification device 53 of the regeneration unit 5 purifies the waste water from which impurities have been removed by the activated carbon adsorption filter 52 into water quality that can be reused as raw water.
The dirt sensor 54 of the regenerating unit 5 detects the degree of purification of the waste water purified by the reverse osmosis membrane purification device 53 (degree of dirt).

Thus, in the regeneration unit 5 of the decontamination system 1, impurities are removed from the waste water by the coarse filter 51 and the activated carbon adsorption filter 52 of the regeneration unit 5, and the impurities are removed by the reverse osmosis membrane purification device 53 of the regeneration unit 5. The drainage from which the water has been removed is purified, and the degree of purification (dirt degree) of the purified wastewater is detected by the dirt sensor 54 of the regeneration unit 5.
When the degree of purification of the wastewater detected by the dirt sensor 54 of the regeneration unit 5 satisfies a predetermined reference value, the wastewater is supplied to the tank 2 and reused as raw water.

As described above, in the decontamination system 1, the waste water is regenerated into raw material water in the regeneration unit 5, supplied to the tank 2, and reused.
For this reason, in the decontamination system 1, it is possible to decontaminate a human body contaminated with a pollutant without requiring a large amount of raw material water.
Therefore, according to the decontamination system 1, even if it is difficult to secure (supplement) the raw material water, it is possible to decontaminate a large amount of human bodies contaminated with the pollutants.

In addition, when the purification | cleaning degree of the waste_water | drain detected by the dirt sensor 54 of the reproduction | regeneration part 5 in the decontamination system 1 does not satisfy | fill a predetermined reference value, the said waste_water | drain is supplied to the waste water tank 6 as waste water.
Then, the wastewater supplied to the wastewater tank 6 is subjected to wastewater treatment in the wastewater treatment device 7 on the downstream side thereof and discarded.

Further, as shown in FIG. 15, the decontamination system 1 may be configured to include an accelerated oxidation treatment unit 8 that performs accelerated oxidation treatment on ozone water.
Since the decontamination system 1 increases the decontamination effect of the pollutants by the ozone water by using the configuration including the accelerated oxidation treatment unit 8 that performs the accelerated oxidation treatment on the ozone water, the water discharged from the shower The human body contaminated with the pollutant (B substance or C substance) can be decontaminated more easily than the one to be decontaminated.
In addition, by adopting a configuration including the accelerated oxidation treatment unit 8 that performs accelerated oxidation treatment on ozone water in this way, in the decontamination system 1, active species such as OH radicals are generated in the ozone water, and colloid due to the ozone water. The action of agglomerating is improved. For this reason, in the decontamination system 1, when the pollutant which pollutes a human body is N substance, N substance will aggregate more reliably, and when performing the waste water treatment by filtering the waste water, it is easier. It is possible to collect N substances and to easily remove the N substances from the waste water.

As a method of performing the accelerated oxidation treatment on the ozone water in the accelerated oxidation treatment unit 8 of the decontamination system 1, there is a method of adding an additive (for example, hydrogen peroxide or a surfactant) to the ozone water. In this way, when the accelerated oxidation treatment is performed on the ozone water in the accelerated oxidation treatment section 8, for example, the additive may be added to the ozone water stored in the decontamination chamber 41 of the decontamination section 4 by the addition device 81. (See FIG. 16).
In addition, as a method of performing the accelerated oxidation treatment on the ozone water in the accelerated oxidation treatment unit 8, there is a method of irradiating the ozone water with ultraviolet rays. In this way, when the accelerated oxidation treatment is performed on the ozone water in the accelerated oxidation treatment unit 8, for example, the ultraviolet lamps 82 and 82 are provided on the inner wall of the decontamination chamber 41 of the decontamination unit 4. The ozone water stored in the decontamination chamber 41 is irradiated with ultraviolet rays (see FIG. 17).

The decontamination system 1 may be configured to circulate and reuse ozone water.
As shown in FIG. 18, the decontamination system 1 includes a tank 2, an ozone water generation device 3, a decontamination unit 4, a filtration unit 60, and an ozone concentration measurement device 70, and a circulation pump (not shown). ) To circulate ozone water. The decontamination system 1 is provided with piping so as to extend from the drain hole 41b of the decontamination chamber 41 of the decontamination section 4 to the water supply hole 41a of the decontamination chamber 41 via the ozone water generating device 3. The ozone water discharged from 41 is supplied to the decontamination chamber 41 again via the ozone water generating device 3.

The filtration unit 60 of the decontamination system 1 is disposed on the downstream side of the decontamination unit 4 (decontamination chamber 41) and on the upstream side of the ozone water generator 3. The filtration unit 60 is configured to filter the ozone water drained from the drain hole 41b of the decontamination chamber 41 of the decontamination unit 4 and remove impurities from the ozone water. The filtration unit 60 includes a dust removal filter 61 and a particulate filter 62.
The dust removal filter 61 of the filtration unit 60 removes impurities such as dust having a large particle size from the ozone water drained from the drain hole 41 b of the decontamination chamber 41 of the decontamination unit 4.
The particulate filter 62 of the filtration unit 60 is disposed on the downstream side of the dust removal filter 61, and removes impurities having a small particle size that could not be removed by the dust removal filter 61 from the ozone water.
The ozone water from which impurities have been removed by the filtration unit 60 is supplied to the ozone water generator 3.

The ozone concentration measuring device 70 of the decontamination system 1 is connected to the decontamination chamber 41 and the ozone water generator 3 of the decontamination unit 4.
The ozone concentration measuring device 70 is configured to measure the ozone concentration of the ozone water stored in the decontamination chamber 41 of the decontamination unit 4 and transmit information related to the concentration of the ozone water to the ozone water generating device 3. The

The decontamination system 1 determines the concentration of ozone water supplied from the ozone water generator 3 to the decontamination chamber 41 of the decontamination unit 4 based on the information regarding the concentration of ozone water from the ozone concentration measuring device 70. Configured.
When the ozone concentration of the ozone water stored in the decontamination chamber 41 of the decontamination unit 4 is lower than a predetermined concentration, the ozone water generator 3 determines the concentration of the ozone water supplied through the filtration unit 60. It is configured to increase ozone water to the predetermined concentration and supply ozone water having the increased concentration to the decontamination chamber 41 of the decontamination unit 4.

As described above, the decontamination system 1 is configured to circulate and reuse ozone water.
For this reason, in the decontamination system 1, it is possible to decontaminate a human body contaminated with a pollutant without requiring a large amount of raw material water.
Therefore, according to the decontamination system 1, even if it is difficult to secure (supplement) the raw material water, it is possible to decontaminate a large amount of human bodies contaminated with the pollutants.

DESCRIPTION OF SYMBOLS 1 Decontamination system 2 Tank 3 Ozone water production | generation apparatus 4 Decontamination part 5 Reproduction | regeneration part 41 Decontamination chamber 42 Exhaust device

Claims (4)

A decontamination system for decontaminating a human body contaminated with a pollutant,
It is configured to decontaminate a human body contaminated with the pollutant by immersing the human body contaminated with the pollutant in ozone water stored in a decontamination chamber.
Decontamination system. An exhaust device configured to be able to exhaust the gas in the decontamination chamber to the outside of the decontamination chamber,
The decontamination system according to claim 1. The decontamination chamber is configured such that a person contaminated with the pollutant can walk in the decontamination chamber in which the ozone water is stored.
The decontamination system according to claim 1 or claim 2. The decontamination chamber includes a water flow generator that generates a water flow in ozone water stored in the decontamination chamber.
The decontamination system according to any one of claims 1 to 3.

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