KR20150028763A - Chlorine dioxide processing structure, chlorine dioxide processing apparatus, sterilization apparatus and environment purification apparatus - Google Patents

Abstract

It takes a long time to make chlorine dioxide gas, which has worked to purify the surrounding environment, to a low concentration that is safe for humans.
A chlorine dioxide gas treating structure (20) for reducing chlorine dioxide gas in the air to be treated including chlorine dioxide gas, comprising a space for circulating the air to be treated, a fan (23), a contact layer and an ultraviolet ray irradiation means, The fan 23 circulates the air to be treated in the space so that the contact layer in the circulation path is irradiated with the ultraviolet ray irradiation means 24 The air to be treated is brought into contact with the contact layer in a state of irradiating ultraviolet rays.

Description

TECHNICAL FIELD [0001] The present invention relates to a chlorine dioxide processing structure, a chlorine dioxide gas processing apparatus, a sterilization apparatus, and an environmental purification apparatus,

The present invention relates to a chlorine dioxide gas treatment structure, a chlorine dioxide gas treatment device, a sterilization device, and an environmental purification device that reduce the chlorine dioxide gas that has worked to purify the surrounding environment to a safe concentration in a human body in a short time.

The space in which a person lives includes, for example, various kinds of fine particles including minute particles such as dust and cigarette smoke, organic volatile gases from chemical substances such as various air pollutants, floating fungi, and paints, and odors such as human bodies and various products , Gas, mold, and harmful bacteria.

In order to reduce these harmful bacteria and the like in the human body, purification treatment such as sterilization and deodorization is performed. Chlorine dioxide gas has been known to be extremely excellent in cleaning action such as sterilization and deodorization. However, chlorine dioxide gas has irritating odor such as chlorine or ozone at normal temperature and normal pressure, and is unstable to light or heat. Thus, stabilized chlorine dioxide has been developed by stabilizing chlorine dioxide gas with pure water in an alkali so that chlorine dioxide gas can be used in a stable state without any danger. A technique has been proposed in which chlorine dioxide gas is activated by activating stabilized chlorine dioxide in a gel state, a liquid state, or a solid state, and is brought into contact with an object to be purified in the space to purify the inside of the space widely.

According to the conventional purifying treatment with chlorine dioxide gas, the residual chlorine dioxide gas contained in the treated gas is filtered and absorbed by water or activated carbon to be low concentration. In addition, although the photodegradation action of the chlorine dioxide gas is unclear, it has been known that the chlorine dioxide gas is decomposed by ultraviolet rays (Patent Document 1: paragraph 0004). Thus, the chlorine dioxide gas which has been subjected to the purifying treatment has been diffused as it has become low in concentration as described above and then released into the atmosphere.

In the case of an air conditioner in which an exhaust duct is installed so that chlorine dioxide gas can be directly discharged outdoors, chlorine dioxide gas discharged from an exhaust duct can be discharged to a large amount of air to be diluted. However, in a sterilization apparatus that cleans medical equipment used in hospitals, the chlorine dioxide gas after sterilization is less than a predetermined concentration safe for the human body and is being dissipated around the apparatus. According to the OSHA standards, the concentration of chlorine dioxide in the human body is 8 hours per day or 40 hours per day, which is less than 0.1 ppm in terms of the time load average (TWA). In addition, according to the standards of the American Industrial Hygienists Association (ACGIH), the short-term exposure limit (STEL) of 0.3 ppm is always required for 15 minutes, and it is necessary to maintain chlorine dioxide gas in this low concentration range continuously. However, according to the method of reducing chlorine dioxide gas according to the conventional adsorption to activated carbon or the like, since the concentration becomes lower than the predetermined concentration and then the adsorption action becomes gentle, it takes a long time until the chlorine dioxide gas becomes low concentration did.

On the other hand, there is also proposed a technique of releasing a high concentration of chlorine dioxide gas into the space to purify the space environment. For example, in Patent Document 2, it is possible to contain dissolved chlorine dioxide at a high concentration by a pure water chlorine gas liquid agent, and to adjust the concentration from a high concentration to a low concentration (Patent Document 2: paragraph 0072). In addition, Patent Document 3 discloses a technique of fumigating a space or object contaminated with chlorine dioxide at a higher concentration than in the prior art. According to Patent Document 3, it is also disclosed to remove at least chlorine dioxide over 5 to 6 hours (Patent Document: paragraph 0024)

As described in Patent Document 2 or Patent Document 3, when chlorine dioxide at a high concentration is used, it takes a long time to remove chlorine dioxide, and the spread of environmental purification using chlorine dioxide gas at a high concentration is prevented. In addition, since the chlorine dioxide gas affects the external environment according to the amount of the chlorine dioxide gas even at a low concentration, a processing structure and apparatus for efficiently reducing the chlorine dioxide gas in a short time have been desired.

The inventors of the present invention conducted various experiments while irradiating chlorine dioxide gas with ultraviolet rays to reduce chlorine dioxide gas in a short period of time. In order to reduce chlorine dioxide gas in a short time, It has been found that the chlorine dioxide gas can be reduced or eliminated to a safe low concentration in the human body in a short period of time by repeated contact.

Patent Document 1: JP-A-4-300201 Patent Document 2: JP-A-11-278808 Patent Document 3: Specification No. 2005-528930

It takes a long time to lower the concentration of chlorine dioxide gas, which has been applied to the purification of the surrounding environment, to a safe concentration in the human body.

A first invention of the present invention is a chlorine dioxide gas treating structure for reducing chlorine dioxide gas in a processing apparatus air containing a chlorine dioxide gas. The chlorine dioxide gas treating structure includes a space in which the air to be treated is circulated, Wherein the contact layer is a contact layer in which water is impregnated in a steel wool in which a thin wire made of iron is bundled in a cotton shape, the airflow generating means circulates the air to be treated in the space, The air to be treated is repeatedly brought into contact with the contact layer in a state where ultraviolet rays are irradiated to the contact layer in the circulation path of the air to be treated.

Here, the air to be treated refers to air containing chlorine dioxide gas that is acted upon by sterilization, deodorization, mold removal, etc. in the space where various fine particles, gas, mold, harmful bacteria and the like are present. For example, air in the sterilization apparatus. The circulating space may be a space in which the air to be treated circulates and contacts the contact layer repeatedly. Also, the concentration of the chlorine dioxide gas is not limited.

The wavelength of the ultraviolet ray is most preferably the ultraviolet ray having a wavelength of 254 nm to 270 nm which is said to have a high absorbance against the chlorine dioxide gas by absorption spectrum analysis at the time of extinction, but is not limited thereto (see FIG. 8). 8 is a graph of the measurement result obtained by diluting 100 ppm of stabilized chlorine dioxide at 500 ppm of pure water with an absorption spectrum analysis at the time of ultraviolet irradiation and shows the absorbance on the vertical axis and the ultraviolet wavelength on the horizontal axis .

When chlorine dioxide gas is irradiated with ultraviolet rays, chlorine dioxide gas tends to react. As a result, the chlorine dioxide gas, which is easy to react with the contact layer in which water is drenched in the steel wool having the steel fine wire bundled into a cotton shape, is circulated and contacted by the air flow generating means to oxidize the iron, There is an advantageous effect that the chlorine dioxide gas in the air to be treated is reduced in a short time even at the low concentration which becomes gentle. Here, the intensity of the ultraviolet ray is not limited, and the effect of reducing the chlorine dioxide gas according to the intensity of the ultraviolet ray is shown (see FIG. 9). The graph of FIG. 9 is a graph in which the tendency of the concentration of the chlorine dioxide gas to decrease was examined by irradiating the chlorine dioxide gas in a cubic container composed of an acrylic plate with each side of 1 m shielded from external light, by changing the intensity of ultraviolet rays. It was confirmed that the effect of lowering the concentration of chlorine dioxide gas was higher for the case of doubling the intensity of the ultraviolet rays (the broken line indicated by?) And the other side (the broken line indicated by?) In all the time zones.

The airflow generating means may be a well-known fan that generates a flow of air. A fan having an appropriate blowing ability can be selected in accordance with the amount of the air to be treated and the number of contact of the air to be treated with the contact layer. Further, since the steel wool is oxidized to chlorine dioxide gas and the effect of reducing chlorine dioxide gas is lowered, the steel wool is optimal when it is accommodated in a bag through which the air to be treated passes and can be exchanged.

A second invention of the present invention is characterized in that, in the chlorine dioxide gas treating structure of the first invention, the diameter of the fine wire is 0.02 mm to 0.04 mm. Even if the weight of the steel wool is the same, the smaller the diameter of the fine wire is, the larger the surface area becomes, and the contact area of the chlorine dioxide gas becomes larger. On the other hand, if the diameter of the fine wire becomes too small, the fine wire breaks and becomes easy to be scattered. Steel wool having a diameter of 0.02 mm to 0.04 mm in diameter is optimum for increasing the surface area even if the weight of the same steel wool is used.

A third invention of the present invention is characterized in that, in the chlorine dioxide gas treating structure of the first or second invention, an ultraviolet ray reflecting surface is provided on the inner surface of the space to which ultraviolet rays are irradiated from the ultraviolet ray irradiating means. It is optimal that a thin film or sheet of aluminum material having high reflectance of ultraviolet rays is adhered to the inner surface of the space. According to the third invention, strong ultraviolet rays can be irradiated using the same ultraviolet lamp.

The fourth invention of the present invention is characterized in that in the chlorine dioxide gas treating structures of the first to third inventions, the steel wool is equipped with wetting means for wetting the water. The wetting means may bring the steel wool into and out of the water tank in which the water is stored to make the steel wool wet, or spray the water with the sprayer to wet the steel wool. By the provision of the wetting means, the wetting at the beginning and the steel wool disposed in the space are not dried, so that the effect of the contact layer continues.

A fifth invention of the present invention is a chlorine dioxide gas treating apparatus for reducing chlorine dioxide gas contained in air to be treated after air purification by chlorine dioxide gas, And the first to fourth inventions include either of the chlorine dioxide processing structures, the first processing means is provided with the first air stream generating means and the activated carbon filter, the first air stream generating means is provided with the air to be treated And the chlorine dioxide gas contained in the air to be treated after the first treatment is reduced by the chlorine dioxide gas treating structure .

According to the fifth invention, the technique of the conventional activated carbon filter adsorption treatment is set to a desired concentration, for example, in the range of 2.5 ppm to 5.0 ppm by the first treatment means, and then the chlorine dioxide gas of the first to fourth inventions The concentration of the chlorine dioxide gas is lowered to a safe concentration in the human body by the treatment structure. According to the adsorption treatment by the activated carbon filter of the prior art, the adsorption action becomes gentle after the chlorine dioxide gas reaches the desired concentration. For this reason, it takes a long time to make the chlorine dioxide gas to have a desired concentration, for example, less than 0.1 ppm. However, according to the present invention, the chlorine dioxide gas is reduced by the activated carbon filter up to the concentration at which the high abatement efficiency of the conventional activated carbon filter is maintained, and the chlorine dioxide gas treatment structure of the first to fourth inventions reduces the concentration of chlorine dioxide gas The time required until the desired low concentration, which is safe for the human body, is shortened.

Further, since the steel wool is reacted with the chlorine dioxide gas at a low concentration, the use amount of the steel wool may be reduced. Also, the frequency of replacement of steel wool is reduced.

A sixth invention of the present invention is a chlorine dioxide gas treating apparatus for reducing chlorine dioxide gas contained in air to be treated after air purification by chlorine dioxide gas, And the chlorine dioxide gas treating structure according to any one of the first to fourth inventions, wherein the first treating means comprises a first air flow generating means, an ultraviolet ray irradiating means, and a steel wool A first process for treating chlorine dioxide in the target air by circulating the chlorine dioxide gas in the target air to the contact layer by the first airflow generating means while the ultraviolet ray is irradiated to the contact layer by the ultraviolet ray irradiation means, The chlorine dioxide gas contained in the air to be treated after the first treatment is reduced by the chlorine dioxide gas treating structure Key is characterized in that.

In the sixth invention of the present invention, in place of the adsorption action of the activated carbon filter of the fifth invention treatment means, means for bringing the still water layer as a contact layer and bringing the air to be treated into contact with the contact layer while irradiating ultraviolet rays And is used as a primary treatment means for chlorine dioxide gas. It was confirmed that even when the steel wool was irradiated with ultraviolet rays and brought into contact with the air to be treated, almost the same effect as that of the activated carbon filter was exhibited as shown in (Evaluation Result 2-1) and (Evaluation Result 2-2) described later. Here, the diameter of the thin wire of the steel wire is optimum from 0.02 mm to 0.04 mm.

A seventh invention of the present invention is characterized in that the sterilization apparatus for sterilizing a medical device by bringing it into contact with chlorine dioxide gas is equipped with the chlorine dioxide gas treatment structure of any one of the first to fourth inventions. By having the first to fourth chlorine dioxide gas treatment structures of the present invention, the time required for reducing the concentration of chlorine dioxide gas at a high concentration, which acts on sterilization, to a desired concentration, for example, a concentration of 0.1 ppm is shortened, It becomes possible to sterilize the medical device in a short time cycle by the sterilizing device, and the sterilizing device can be effectively utilized.

An eighth invention of the present invention is an environmental purification apparatus for introducing chlorine dioxide gas into a closed environment in which an air purification apparatus is installed and purifying the chlorine dioxide gas by bringing the chlorine dioxide gas into contact with an object in the environment, And the chlorine dioxide gas treatment structure. By the provision of the chlorine dioxide processing structure of any one of the first to fourth aspects of the present invention, chlorine dioxide gas at a high concentration can be supplied at a desired concentration, for example, 0.1 ppm , The time to be taken is shortened, and the object to be cleaned by the chlorine dioxide gas is expanded. For example, even in areas where there are many residential buildings, the entire house is covered with a sheet, and all the items in the house are removed and sterilized by chlorine dioxide gas to reduce the chlorine dioxide gas in a short period of time. .

According to the first invention of the present invention, chlorine dioxide gas, which is easy to react with, is circulated and brought into contact with the contact layer in which water is wetted by steel wool which has been formed by rolling steel fine wires into a cotton- There is an advantageous effect that the chlorine dioxide gas in the air to be treated is reduced in a short time even in a low concentration where the reduction is gentle.

According to the second invention of the present invention, the surface area of iron reacting with chlorine dioxide gas at the same weight is increased, and the fine line is not broken and scattered.

According to the third invention of the present invention, strong ultraviolet rays can be irradiated even if the same ultraviolet lamp is used.

According to the fourth invention of the present invention, by providing the wetting means, the effect of the contact layer is maintained without wetting the steel wool disposed in the space at the beginning.

According to the fifth aspect of the present invention, in the concentration at which the reduction efficiency of the activated carbon filter is kept high, the concentration of chlorine dioxide gas is reduced by the activated carbon filter and the tendency of reduction by the activated carbon filter becomes gentle, By reducing the concentration of chlorine dioxide gas by the chlorine gas processing structure on the side of the substrate, the time required until the desired low concentration, which is safe for the human body, is shortened.

According to the sixth invention of the present invention, as in the fifth invention, the concentration of the chlorine dioxide gas which irradiates ultraviolet rays to the contact layer of the steel wool becomes gentle and the chlorine dioxide gas treatment structure of any one of the first to fourth inventions By reducing the concentration of the chlorine dioxide gas, the time required until the desired low concentration, which is safe for the human body, is shortened.

According to the seventh invention of the present invention, it is possible to sterilize the medical device by the sterilization device in a short cycle by shortening the time until the chlorine dioxide gas is brought to a desired concentration, for example, a concentration of 0.1 ppm, So that it can be utilized effectively.

According to the eighth invention of the present invention, the time required until the concentration of a high concentration of chlorine dioxide gas at a desired concentration, for example, a concentration of 0.1 ppm, which acts on environmental purification such as mold removal, is shortened and purification by chlorine dioxide gas The subject is enlarged.

1 is a schematic diagram of a configuration of a chlorine dioxide gas processing apparatus (Embodiment 1).
2 is a graph showing an evaluation result graph of a chlorine dioxide gas treatment structure (Example 1).
Fig. 3 is a view showing an evaluation graph of a small chlorine dioxide gas treating structure (Example 1). Fig.
4 is a schematic diagram of the configuration of a chlorine dioxide gas processing apparatus (Example 2).
5 is a graph showing a result of evaluation of the first processing means (Example 2).
6 is a schematic diagram of the configuration of a chlorine dioxide gas processing apparatus (Embodiment 3).
7 is a process chart of the sterilization apparatus (Example 4).
8 is a graph showing an experiment graph of absorption spectrum analysis at the time of extinction.
9 is a graph showing a graph of the intensity of ultraviolet rays and the tendency of reducing chlorine dioxide gas.

The purpose of lowering the chlorine dioxide gas to a safe concentration in the human body in a short time is to lower the concentration of the chlorine dioxide gas to a desired low concentration by the first treatment means and further lower the concentration to a safe low concentration in the body by the chlorine dioxide treatment structure It was realized by thing.

The chlorine dioxide gas treating apparatus 100 of the first embodiment will be described with reference to Fig. Fig. 1 is a schematic diagram showing a configuration of a chlorine dioxide gas treating apparatus 100 according to the first embodiment. The chlorine dioxide gas is adsorbed by the activated carbon filter 11 so that the concentration of the chlorine dioxide gas in the introduction air 30 before the treatment with a high concentration of the chlorine dioxide gas is changed from 2.0 ppm to 5.0 ppm as the intermediate treatment air 40 And a chlorine dioxide gas treatment structure 20 that treats the primary treatment means 10 and the intermediate treatment air 40 at a concentration lower than 0.1 ppm which is a safe concentration of chlorine dioxide gas in the human body and discharges it as the discharge air 50 The chlorine dioxide gas processing apparatus 100 schematically shows the main components.

The first processing means 10 of the first embodiment is housed in a cubic container 12 made of an acrylic plate of 1 m in each side. It is needless to say that the shape and size of the container 12 are not limited to be. A fan (13) for circulating the introduction air (30) is provided in the container (12). The airflow generated by the fan 13 is introduced into the activated carbon filter 11 provided in front of the fan 13 through the introduction air 30 as indicated by the arrow 14 shown in the first processing means 10 The chlorine dioxide gas contained in the air (30) is adsorbed to the activated carbon filter (11).

The air volume of the fan 13 and the size and thickness of the activated carbon filter 11 and the capacity of the activated carbon can be appropriately selected according to the concentration and amount of the chlorine dioxide gas contained in the introduction air 30 introduced into the container 12 do. Here, the activated carbon filter 11 may be optimally used if it is an activated carbon filter 11 capable of adsorbing an acid gas, and may be powdery carbon or granular carbon. It goes without saying that an activated carbon layer for a neutral gas and an activated carbon layer for a basic gas may be used in combination.

The first processing means 10 is provided with a detection inlet 15 capable of opening and closing in the vicinity of the outlet of the intermediate processing air 40 so that the detection inlet 15 can be opened and closed, The air is sucked into the detection tube 16 for the chlorine dioxide gas and the concentration of the chlorine dioxide gas is measured so that the configuration of the first treatment means 10 is simplified. The detection tube 16 for chlorine dioxide gas can be a gas concentration detection tube of GASTEC (registered trademark). On the other hand, a well-known detection means (refer to Japanese Unexamined Patent Application Publication No. 2007-68612) may be provided as a means for detecting chlorine dioxide gas concentration, which is not shown, to measure the concentration of chlorine dioxide gas.

It is detected that the chlorine dioxide gas concentration of the introduced air 30 having a high concentration of the chlorine dioxide gas which has been subjected to the air purification becomes the desired low concentration by the first treatment means 10, Is led to the chlorine dioxide gas treatment structure (20) in the primary treatment means (10).

The chlorine dioxide gas treating structure 20 is also housed in a cubic container 22 made up of an acrylic plate having a length of 1 m. Needless to say, the shape and size of the container 22 are not limited. The container 22 includes a fan 23, ultraviolet irradiation means 24, and a steel wool 21 in a wet state. An aluminum foil 28 is adhered to the inner surface of the container 22. The aluminum material is optimum so that the ultraviolet rays irradiated by the ultraviolet ray irradiating means 24 do not leak to the outside and the ultraviolet rays are reflected in the container and the intensity of the ultraviolet rays is enhanced. However, even if the thin film is a foil, It may be.

The air flow generated by the fan 23 installed in the chlorine dioxide gas treating structure 20 is applied to the contact layer of the steel wool 21 laid out as shown by the arrow 25 in the chlorine dioxide treating structure 20 of FIG. It is circulated as contact. The steel wool 21 installed in the chlorine dioxide gas treating structure 20 is immersed in water and irradiated with ultraviolet rays by the ultraviolet ray irradiation means. The intermediate processing air 40 is brought into contact with the steel wool 21 so that the chlorine dioxide gas contained in the intermediate processing air 40 is processed into the low concentration discharge air 50 safe for the human body.

Here, the steel wool 21 constituting the contact layer uses 325 g of steel wool having a diameter of 0.02 to 0.04 mm in diameter. When the steel wool 21 is installed in the chlorine dioxide gas treating structure 20, it is pre-wetted with water by spraying about 50 mL of water. The steel wool (21) may be provided with a water palette (26) in which water is stored at the bottom, and may be suitably extended and retracted by an unillustrated appearance means to maintain the wet state.

As the ultraviolet ray irradiating means 24, six ultraviolet lamps GPL9 having a wavelength of 254 nm manufactured by Sankyo Denki Co., Ltd. and six GPL 27s were used, and an ultraviolet lamp having a total output of 216 W was used. The ultraviolet illuminance was measured at 0.345 mW / cm ² at the position where the contact layer was set according to measurement by ultraviolet intensity meter of Kasutamu Co., The room temperature was measured at room temperature in a stable room temperature environment at 20 占 폚.

The concentration of the chlorine dioxide gas in the intermediate treatment air is detected by the concentration detecting means for the chlorine dioxide gas provided at the concentration detecting position 27 at the position near the discharge orifice so that the concentration of the chlorine dioxide gas is not more than 0.1 ppm, And then dissipated to the outside air by the discharge air 50. In Embodiment 1, the introduction air 30 having a chlorine dioxide concentration of 50 ppm is treated with the intermediate treatment air 40 of 3.6 ppm at the time point of 8 minutes after the start of the treatment by the first treatment means and the chlorine dioxide treatment structure 20 ), The chlorine dioxide concentration becomes 0.1 ppm or less, which is more safe than the intermediate treatment air 20 after 6 minutes from the start of the treatment, and the chlorine dioxide gas is not detected 14 minutes after the initiation of the first treatment And is in a state suitable for the discharge air 50.

(Evaluation Experiment 1)

Here, in order to evaluate the effect of the main components of the chlorine dioxide gas treating structure 20 of the embodiment 1, the chlorine dioxide gas treating structure 20 of the embodiment 1 lowers the concentration of the chlorine dioxide gas, Experiments were conducted to confirm the effect of the main components by comparing the gas treatment structure 20 excluding the main components (Evaluation Experiment 1). The result will be described with reference to Fig. 2 is a graph showing the evaluation results of the chlorine dioxide gas treatment structure and the graph of the comparison results. (Evaluation Result 1-1) shows that when the chlorine dioxide gas treating structure 20 is operated (Comparative Result 1-1), when ultraviolet rays are irradiated in a state in which the steel wool of the contact layer is not wetted (Comparative Example 1 -2 shows a tendency of the chlorine dioxide gas concentration of each intermediate treatment air 40 to decrease when the steel wool is removed and only ultraviolet rays are irradiated. The concentration of the chlorine dioxide gas was detected by a gas detection tube of GASTEC (registered trademark).

(Evaluation result 1-1)

Evaluation results of the chlorine dioxide gas treatment structure (□ line graph of the indication): The intermediate treatment air (40) was introduced into the chlorine dioxide gas treatment structure (20) of a container having a volume of 1 m ³ composed of an acrylic plate at a room temperature of 20 ° C The chlorine dioxide gas was treated with the composition of the chlorine dioxide gas treating structure 20 of Example 1 at the concentration of chlorine dioxide gas of 3.6 ppm. The lowering of the concentration of the chlorine dioxide gas is indicated by a broken line graph in which the symbol is marked. The concentration of the chlorine dioxide gas was about 0.12 ppm at the elapsed time of 4 minutes after the initiation of the treatment at 3.6 ppm and became 0.00 ppm at the elapsing time of 6 minutes. ), The concentration of chlorine dioxide gas was reduced to a safe concentration in a short time.

(Comparison result 1-1)

Comparative Example (Bounded line graph with? Mark) in the case where only the ultraviolet rays are irradiated without wetting the steel wool 21 with water: The steel wool 21 of the contact layer of the chlorine dioxide gas treating structure 20 of Example 1 ) Was immersed in water so that the intermediate treatment air 40 was introduced to treat the chlorine dioxide gas in a state where the concentration of the chlorine dioxide gas was 2.76 ppm. The lowering of the concentration of the chlorine dioxide gas is represented by a broken line graph with? The concentration of the chlorine dioxide gas is 0.24 ppm at the time point of 6 minutes after starting the treatment at about 2.76 ppm, and about 0.01 ppm at the time of 10 minutes from the start of the treatment.

(Comparison result 1-2)

(A broken line graph marked with a circle): The contact layer of the steel wool of the chlorine dioxide gas treating structure 20 of Example 1 was removed, and the intermediate treatment Air 40 was introduced to treat the chlorine dioxide gas at a concentration of chlorine dioxide gas of 2.52 ppm. The lowering of the concentration of the chlorine dioxide gas is indicated by a broken line graph with a mark & cirf & The concentration of chlorine dioxide gas was 0.45 ppm at 2.52 ppm after 6 minutes from the initiation of treatment, but it was 0.36 ppm even after 10 minutes, and it was not a safe concentration to human body because it was 0.1 ppm.

(Evaluation Experiment 2)

Next, a cubic sterilizing device having a side of 65 cm is assumed, and the capacity of the chlorine dioxide gas treating structure of Example 1 is set to 0.25 m ³ , so that the effect is exhibited even with a small chlorine dioxide gas treating structure regardless of the size of the capacity Evaluation Experiment 2 was conducted to confirm that there was a difference between the two. The result will be described with reference to FIG. 3 is a graph showing the evaluation result graph of the small chlorine dioxide gas treating structure of the evaluation experiment 2. Fig. (Evaluation result 2-1) shows that when the chlorine dioxide gas treating structure 20 is operated (comparison result 2-1), when the ultraviolet rays are irradiated without wetting the steel wool of the contact layer (comparison result 2-2 Shows a tendency of the chlorine dioxide gas concentration of each intermediate treatment air to decrease when the steel wool is removed and only ultraviolet rays are irradiated. As the ultraviolet ray irradiating means 24, six ultraviolet lamps GPL9 of 254 nm wavelength manufactured by Sankyo Denki Co., Ltd. were used and a total of 54 W ultraviolet rays were used. The steel wool which constitutes the contact layer was the same as Evaluation Experiment 1. Aluminum foil was attached to the inner surface of the container, and conditions at room temperature were the same.

(Evaluation result 2-1)

Evaluation results of the small chlorine dioxide gas treatment structure (broken line graph at the □ mark): The intermediate treatment air 40 is introduced into the chlorine dioxide gas treating structure 20 of the small container at room temperature of 20 ° C, Was treated at a concentration of 2.52 ppm with chlorine dioxide gas in the above-described configuration. The lowering of the concentration of the chlorine dioxide gas is indicated by a broken line graph in Fig. 3. The concentration of the chlorine dioxide gas was 0.30 ppm at 2.52 ppm, 2 minutes after the start of the treatment, and 0.00 ppm at the time of 4 minutes. It was confirmed that the tendency of the chlorine dioxide gas to be reduced as in Example 1 with a large capacity can be obtained by appropriately determining the intensity of the ultraviolet rays irrespective of the capacity of the chlorine dioxide gas treating structure. The concentration of the chlorine dioxide gas can be lowered to a safe concentration in a short period of time as compared with (comparison result 2-1) and (comparison result 2-2) shown below.

(Comparison result 2-1)

Comparative example (a line graph with? Mark) in the case where only the ultraviolet rays are irradiated without wetting the steel wool: In a small chlorine dioxide gas treatment structure, the steel wool of the contact layer is not wetted with water, Air 40 was introduced to treat the chlorine dioxide gas with the concentration of chlorine dioxide gas at 2.16 ppm. The lowering of the concentration of the chlorine dioxide gas is indicated by a graph in which a mark & cir & The concentration of chlorine dioxide gas was 0.78 ppm at the elapsed time of 2 minutes after starting the treatment at 2.16 ppm and 0.30 ppm at the elapse of 4 minutes.

(Comparison result 2-2)

(A broken line graph marked with a circle): The contact layer of the steel wool was removed in the small structure of the chlorine dioxide gas treatment, the intermediate treatment air 40 was introduced, The chlorine dioxide gas was treated at a chlorine gas concentration of 2.10 ppm. The lowering of the concentration of the chlorine dioxide gas is indicated by a broken line graph with a mark & cirf & The concentration of chlorine dioxide gas was 1.08ppm at 2.10ppm after 2 minutes of treatment and 0.48ppm at 4 minutes after initiation of treatment.

The chlorine dioxide gas treating apparatus 200 of the second embodiment will be described with reference to FIG. 4 is a schematic diagram of the configuration of the chlorine dioxide gas processing apparatus 200. As shown in Fig. The chlorine dioxide gas of the introduction air 30 having a high concentration of the chlorine dioxide gas is brought into contact with the steel wool irradiated with the ultraviolet rays in place of the first treatment means 10 of the first embodiment, And the first processing means 60 serving as the processing air 40 are provided. The chlorine dioxide gas treating structure 20 that treats the intermediate treatment air 40 at a concentration lower than 0.1 ppm, which is a safe chlorine dioxide concentration in the human body, to produce the discharge air 50 is the same as that of Embodiment 1, And the description thereof will be omitted.

The first processing means 60 of the second embodiment is housed in a cubic container 62 composed of an acrylic plate of 1 m in each side. Like the first embodiment, the shape and size of the container 62 It goes without saying that it is not limited. The vessel (62) is provided with a fan (63) for circulating the introduction air (30). An airflow is generated by the fan 63 as indicated by the arrows indicated by the first processing means 60. [ On the front side of the fan 63, there is provided a steel wool 61 in a state in which ultraviolet rays are irradiated by the ultraviolet ray irradiating means 64. The introduction air 30 passes through the steel wool 61 and the chlorine dioxide gas contained in the introduction air 30 comes into contact with the steel wool 61 irradiated with the ultraviolet rays emitted from the ultraviolet ray irradiation means, So that the concentration becomes intermediate treatment air 40 having a desired concentration.

(Evaluation Experiment 3)

5, the results of Evaluation Experiment 3 for evaluating the primary treatment means for reducing the concentration of chlorine dioxide in the introduction air 30 having a high concentration of chlorine dioxide and making the intermediate treatment air 40 are shown. (Evaluation Result 3-1) is the first treatment means of Example 1 in which chlorine dioxide gas is adsorbed on the activated carbon filter. (Evaluation Result 3-2) In the evaluation result 3-2, chlorine dioxide gas (Comparative Example 3-1) shows experimental results in the case where the concentration of chlorine dioxide gas is lowered by irradiating only ultraviolet rays. As ultraviolet ray irradiation means, ultraviolet ray of total 54W was used by using 6 pieces of ultraviolet lamp GPL9 having a wavelength of 254 nm of Sankyo Electric Co., Ltd. The steel wool which constitutes the contact layer was the same as Evaluation Experiment 1. Aluminum foil is attached to the inner surface of the container, and conditions at room temperature are the same.

(Evaluation result 3-1)

Evaluation results of the first treatment means of Example 1 in which chlorine dioxide gas of the introduced air was adsorbed to the activated carbon filter (a broken line graph marked with?): The first treatment means of Example 1 was used to treat the activated carbon filter with high- The introduction air containing the chlorine gas was contacted to adsorb the chlorine dioxide gas to the activated carbon filter and the concentration of the chlorine dioxide gas was lowered. The lowering of the concentration of the chlorine dioxide gas is indicated by a broken line graph in Fig. After 5 minutes from the initiation of the treatment, the concentration decreased from 50 ppm to 6.24 ppm, and it was 1.20 ppm at the elapse of 10 minutes. After that, the concentration decreases gradually, and the concentration becomes 0.12 ppm at the time of 20 minutes, and it takes 25 minutes after the start of the treatment until the concentration becomes 0.1 ppm.

(Evaluation result 3-2)

Evaluation results of the first treatment means of Example 2 (chlorine dioxide gas of the introduced air) were brought into contact with the steel wool while irradiating ultraviolet rays (a broken line graph marked with?): In the first treatment means of Example 2, The introduction air 30 containing a high concentration of chlorine dioxide gas was brought into contact with the ultraviolet ray irradiated with ultraviolet rays to lower the concentration of the chlorine dioxide gas. The lowering of the concentration of the chlorine dioxide gas is indicated by a line graph in which a mark & cir & After 10 minutes from the start of the treatment, the concentration dropped from 40 ppm to 2.30 ppm. After that, the concentration of the chlorine dioxide gas dropped slowly, and it took 20 minutes after the start of the treatment until the concentration became 0.1 ppm. However, the chlorine dioxide gas was not detected at the time of 20 minutes after the start of the treatment. Compared with the first treatment means of Example 1, the activated carbon filter of Example 1 exhibited a somewhat excellent reduction effect until 10 minutes elapsed, but it took a long time to reach a safe concentration of 0.1 ppm. On the other hand, until the concentration of chlorine dioxide reaches a low concentration of 2.5 ppm, both the first treatment means of Example 2 and the first treatment means of Example 1 require about 10 minutes, and as the first treatment means, It was evaluated as appropriate.

(Comparison result 3-1)

Comparative Example 1 (Curved line graph marked with □): A chlorine dioxide gas of high concentration was contained in the same size container under the same temperature condition as in Example 1 The introduced air 30 was irradiated with ultraviolet rays by ultraviolet irradiation means to lower the concentration of the chlorine dioxide gas. The lowering of the concentration of the chlorine dioxide gas is represented by a broken line graph in which the symbol is marked in Fig. After a lapse of 20 minutes from the start of the treatment, the concentration decreased from 50 ppm to 47.5 ppm, but the tendency to decrease was gradual. On the other hand, there was a tendency to reduce the chlorine dioxide gas at the same rate at any irradiation time.

In Embodiment 3, an embodiment in which the first processing means and the chlorine dioxide processing structure are provided in the same vessel 70 will be described with reference to Fig. 6 is a schematic diagram of the configuration of the chlorine dioxide gas processing apparatus 300. The same constituent parts as those of the first embodiment are denoted by the same reference numerals and the description thereof is omitted. The introduction air 30 having a high concentration of the chlorine dioxide gas introduced into the vessel 70 is first introduced into the activated carbon filter 11 of the first treatment means 71 in a state in which the chlorine dioxide gas treatment structure 72 is stopped So that the concentration of chlorine dioxide gas is lowered. When it is detected by the detection means that the chlorine dioxide gas concentration of the air to be treated in the container becomes smaller than the desired concentration, the first treatment means 71 is stopped, and the chlorine dioxide gas treatment structure 72 irradiates ultraviolet rays The air to be treated is brought into contact with the steel wool 21 in a wet state while circulating ultraviolet rays by the irradiation means 24. This makes it possible to reduce the concentration of chlorine dioxide gas in a single container in a short time.

In Embodiment 4, an embodiment of a sterilizing apparatus for medical instruments will be described with reference to Fig. 7 (A) and FIG. 7 (B) show a process of generating a high concentration of chlorine dioxide gas. After sterilizing the medical instrument, a high concentration of chlorine dioxide gas is supplied to a desired concentration , For example, from 2.0 ppm to 5.0 ppm, and FIG. 7 (C) is an explanatory diagram showing a step of lowering the chlorine dioxide gas reduced to a desired concentration to a safe concentration in the human body in advance.

The sterilizing apparatus 400 includes a chlorine dioxide generating means 81, a first treating means 82 and a chlorine dioxide treating structure 83 in contact with the medical instrument receiving portion 80. In the chlorine dioxide gas generating means 81, the stabilized chlorine dioxide water 85 in gel or liquid phase is supplied to the medical instrument receiving portion 80 by the ultraviolet irradiating means 86 Ultraviolet rays are irradiated and chlorine dioxide gas of high concentration is sent by the fan 87 to the medical instrument receiving portion 80 as shown by the arrows in Fig. 7 (A) and circulated. The vent 84 may be closed and the fan 87 may be stopped after the concentration of the chlorine dioxide gas in the medical instrument receiving portion 80 reaches a predetermined concentration (see also Fig. 7 (A)).

After the medical instrument is sterilized, the vent hole 88 of the first treatment means 82 is opened with the vent hole 84 of the chlorine dioxide gas generating means 81 being closed, The gas in the mechanism accommodating portion 80 is circulated to the activated carbon filter 90 as indicated by the arrows in FIG. 7 (B) so that the chlorine dioxide gas is adsorbed and reduced to a desired concentration. Here, the desired concentration may be from 2.0 ppm to 5.0 ppm, but is not limited to the concentration in this range (see also Fig. 7 (B)).

After the concentration of chlorine dioxide gas in the medical instrument receiving portion 80 reaches a desired concentration by the first treatment means, the vent 88 of the first treatment means is closed and the chlorine dioxide gas treatment means and the medical instrument receiving portion The low concentration of chlorine dioxide gas in the state in which the vent hole 91 is opened and the steel wool 92 in the wet state is irradiated with the ultraviolet ray by the ultraviolet ray irradiation means 93, So that the concentration of the chlorine dioxide gas is lowered (see also Fig. 7 (C)).

The processing time of the chlorine dioxide gas generating means 81, the processing time of the first processing means 82 and the processing time of each of the chlorine dioxide gas processing structures 83 are determined according to the size of the medical instrument receiving section 80 The chlorine dioxide gas concentration detecting means (not shown) may be provided in the medical instrument receiving portion 80 of the sterilizing device. The chlorine dioxide gas generating means 81, The primary treatment means 82 and the chlorine dioxide gas treatment structure 83 may be operated in order. The output of the ultraviolet irradiation means, the capacity of the activated carbon filter, and the mass of the steel wool may be selected appropriately.

(Other)

Although specific dimensions, outputs, and positions have been shown and described in the above embodiments, the present invention is not limited thereto, and it goes without saying that the present invention may be modified within the scope not departing from the gist of the present invention.

In the above embodiment, the chlorine dioxide gas is generated by the stabilized chlorine dioxide, but it is not limited thereto.

The embodiments disclosed herein are to be considered in all respects as illustrative and not restrictive. The technical scope of the present invention is not limited to the above description, and is intended to include all modifications within the meaning and scope equivalent to the claims.

100, 200, 300 chlorine dioxide gas treatment system
400 sterilization apparatus 10 Primary treatment means
20 chlorine dioxide gas treatment structure 30 introduction air
40 Intermediate treatment air 50 Emission air
11 Activated carbon filter 12 containers
13 Fan 14 Arrows
15 Detection inlet 16 Detection tube for chlorine dioxide gas
21 Steel wool 22 containers
23 Fan 24 UV Irradiation Means
25 Arrow 26 Water palette
27 Concentration detection position 28 Aluminum foil
60 Primary treatment means 61 Steel wool
62 containers 63 fans
64 Ultraviolet irradiation means 70 container
71 Primary treatment means 72 Chlorine dioxide gas treatment structure
80 Medical instrument receptacle 81 Chlorine dioxide gas generating means
82 Primary treatment means 83 Structure of chlorine dioxide gas treatment
84 Vents 85 Stabilized chlorine dioxide
86 Ultraviolet irradiation means 87 Fan
88 Vents 89 Fans
90 Activation filter 91 Vent
92 Steel Wool

Claims (8)

A chlorine dioxide gas treating structure for reducing chlorine dioxide gas in a target air containing chlorine dioxide gas,
A space in which the air to be treated is circulated, an airflow generating means, a contact layer, and an ultraviolet irradiation means,
Wherein the contact layer is a contact layer in which water is impregnated in a steel wool in which iron fine wires are gathered in a cotton-
The airflow generating means circulates the air to be treated in the space,
The ultraviolet ray irradiation means irradiates ultraviolet rays to the contact layer in the circulation path of the air to be treated,
And the air to be treated is repeatedly brought into contact with the contact layer. The method according to claim 1,
Wherein the fine wire has a diameter of 0.02 mm to 0.04 mm. 3. The method according to claim 1 or 2,
And the ultraviolet ray reflecting surface is provided on the inner surface of the space to which the ultraviolet ray emitted from the ultraviolet ray irradiating means is irradiated. 4. The method according to any one of claims 1 to 3,
And a wetting means for wetting said water in said steel wool. In a chlorine dioxide gas processing apparatus for reducing chlorine dioxide gas contained in air to be treated after air purification by chlorine dioxide gas,
A first treatment means for lowering the chlorine dioxide gas to a desired concentration,
A chlorine dioxide gas treating structure as set forth in any one of claims 1 to 4,
The first processing means is provided with the first air flow generating means and the activated carbon filter,
Wherein the chlorine dioxide gas contained in the air to be treated after the first treatment is subjected to the first treatment to adsorb chlorine dioxide gas in the air to be treated in the activated carbon filter by the first airflow generating means, Wherein the chlorine dioxide gas is reduced by the treatment structure. In a chlorine dioxide gas processing apparatus for reducing chlorine dioxide gas contained in air to be treated after air purification by chlorine dioxide gas,
A first treatment means for lowering the chlorine dioxide gas to a desired concentration,
A chlorine dioxide gas treating structure as set forth in any one of claims 1 to 4,
The first processing means is provided with the first air stream generating means, the ultraviolet ray irradiating means and the steel wool,
In a state in which ultraviolet rays are irradiated to the contact layer by the ultraviolet ray irradiation means,
Wherein the chlorine dioxide gas contained in the air to be treated after the first treatment is subjected to a first treatment for causing the chlorine dioxide gas in the treated air to circulate and contact the contact layer by the first airflow generating means, Wherein the chlorine dioxide gas treatment structure reduces the chlorine dioxide gas by the chlorine dioxide gas treatment structure. A sterilization apparatus for sterilizing a medical device by contacting with a chlorine dioxide gas,
A sterilization apparatus characterized by comprising the chlorine dioxide gas treatment structure according to any one of claims 1 to 4. There is provided an environmental purification apparatus for introducing chlorine dioxide gas into a closed environment in which an air purification apparatus is installed and purifying the chlorine dioxide gas by bringing the chlorine dioxide gas into contact with an object in the environment,
An environmental purification apparatus comprising the chlorine dioxide gas treatment structure according to any one of claims 1 to 4.

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