KR20150005916A - Apparatus for generating chlorine dioxide gas and sterilization box for medical instrument - Google Patents

Abstract

The surface area of the stabilized chlorine dioxide water 10 stored in the storage tank 20 and irradiated with ultraviolet rays 71 is enlarged by the surface area enlarging means 30 to quickly generate chlorine dioxide gas, To the outside of the container. Stable chlorine dioxide gas can be stably released by irradiating ultraviolet rays to the liquid phase stabilized chlorine dioxide. The concentration of the chlorine dioxide gas can be adjusted by adjusting the concentration of the chlorine dioxide water 10 and the output of the ultraviolet ray 71. Chlorine dioxide gas, which has a low concentration that is safe for humans, can be sterilized to every corner of the room by releasing it directly to the room where the person lives. When the concentration is high, the medical instrument in the sterilization box for the medical device can be sterilized.
Thereby, it is possible to provide a chlorine dioxide gas generating apparatus capable of rapidly and continuously generating chlorine dioxide gas and facilitating the concentration control of chlorine dioxide gas.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chlorine dioxide gas generator and a sterilization box for a medical device,

The present invention relates to a chlorine dioxide gas generator for generating chlorine dioxide gas in a space and purifying air in the space, and a sterilizing box for a medical device. More particularly, the present invention relates to a chlorine dioxide gas generator for increasing the surface area of stabilized chlorine dioxide water stored in a chlorine dioxide gas generator and irradiating ultraviolet rays to generate chlorine dioxide gas, and a sterilizing box for a medical device.

Viruses such as influenza virus, fungi such as fungi, other bacteria, and germs are likely to be mixed in the air in a living space where a person works or lives. Recently, there has been a concern about the influences of the new influenza, such as the influenza, and the health effects such as allergies caused by mold. In order to cope with such a problem, various air cleaners such as household, business, medical, and the like are provided.

Further, as a means for sterilizing viruses, bacteria and the like in the air, a method using chlorine dioxide gas is known. Chlorine dioxide gas is a kind of chemical substance having a strong oxidizing power and has an action of changing proteins such as viruses and bacteria by the oxidation action thereof. It is known that this action changes the structure of viruses, bacteria, and the like, and has a function of virus removal, eradication, deodorization, prevention of mold and the like from decreasing its function. However, since chlorine dioxide gas has high reactivity, it is likely to react with other substances and generate a high concentration of chlorine gas, which is not suitable for long-term storage, and thus it is difficult to use chlorine dioxide as it is.

Thus, in order to stabilize and use chlorine dioxide gas, a stabilized chlorine dioxide water having been stabilized by dissolving chlorine dioxide gas in an alkaline aqueous solution has been developed. Since the chlorine dioxide gas is dissolved in the stabilized chlorine dioxide water, the chlorine dioxide gas is not released into the air unless an external stimulus is applied, thereby enabling long-term preservation and eliminating the risk that chlorine gas is generated by reacting with other substances do. On the other hand, chlorine dioxide gas is not generated in the stabilized chlorine dioxide water without external stimulation, and the sterilizing effect can not be exerted in the state as it is.

As a method of activating the stabilized chlorine dioxide water and releasing the chlorine dioxide gas, a method of irradiating ultraviolet rays, a method of heating, a method of adding an acidic substance, and the like are known. Among these methods, when a method of adding an acidic substance is used, it is possible to generate a high concentration of chlorine dioxide gas, but it is difficult to adjust the generation concentration of the chlorine dioxide gas and to maintain the generation continuity, It has been pointed out that it is difficult to apply it unless it is treated (Patent Document 1, paragraph 0009). In the case of the method of heating, it is necessary to control the temperature, and it takes time to return to the original temperature after raising the temperature, so that it is difficult to manage the generation of the chlorine dioxide gas.

On the other hand, when the ultraviolet ray is irradiated to a substance containing stabilized chlorine dioxide water, stabilized chlorine dioxide water is activated by irradiation of ultraviolet rays, and chlorine dioxide from stabilized chlorine dioxide water The generation of gas can be stopped.

Patent Document 2 discloses an apparatus for purifying air by chlorine dioxide gas, and Patent Document 2 discloses a technique for purifying air and chlorine dioxide gas collected in the apparatus by gas-liquid contact. Specifically, the circulating water to which an appropriate amount of chlorine dioxide gas is added and the air to be cleaned are brought into gas-liquid contact in the apparatus, the stabilized chlorine dioxide water is activated by irradiating ultraviolet rays, and the air is sterilized, A technique of an air purification device for deodorizing air is disclosed. The concentration of chlorine dioxide gas in the air after purification was within a desired concentration range by controlling the irradiation state of the ultraviolet ray irradiation means according to the concentration detected by the chlorine dioxide gas concentration detection means.

However, the method according to this technology is required to purify the air in the apparatus, to require a chlorine dioxide gas concentration detection means and the like, and the concentration of the chlorine dioxide gas in the purified air A mechanism for adjusting the concentration of the chlorine dioxide gas by controlling the ultraviolet ray irradiation means is required so as to keep the concentration of the chlorine dioxide gas within the desired concentration range. On the other hand, there was a need for a simple sterilizing device for use in a small number of living rooms.

Patent Document 3 discloses an indoor small-sized air cleaning apparatus. The technique is to clean the air collected in a container containing water by washing it with the sprayed water. In this technique, the floor fan is rotated by a drive mechanism to suck air from the intake duct to the inside of the container, and the air is cleaned and deodorized by water in a shower state by a water sprinkling device, And discharges it from the discharge side duct. Therefore, the object to be cleaned and deodorized was limited to the air sucked in the container.

In Patent Document 4, there is disclosed a small air purifying apparatus technology in which a photocatalyst is provided inside a port for storing water, and the photocatalyst is irradiated with light to activate the photocatalyst to purify the air. According to this technology, the organic radicals in the port are absorbed by carbon dioxide or water, scattered by the OH radicals generated by the irradiation of light to the photocatalyst, and the bacteria included in the air drawn into the water It is said that the sterilizing effect is exerted. However, according to the technique of Patent Document 4, there is a problem in that a long time is required for all the air in the entire room to be sucked into the air purifying device and sterilized since the air in the room is drawn into the water and the sterilizing effect is exerted there was.

In addition, as an air purifier using chlorine dioxide gas for countermeasures against general household bacteria and viruses, an air purifier in which stabilized chlorine dioxide is contained in a gel or tablet is circulated. When the concentration of stabilized chlorine dioxide contained in the gel body is low, the stabilized chlorine dioxide in the form of a gel has a problem that chlorine dioxide gas is not released even when ultraviolet rays are irradiated due to the wavelength of ultraviolet rays (see Experiment (3)). On the other hand, in the case of the purified product, since it is used by being melted in water, there is a problem that it is impossible to generate a chlorine dioxide gas at a very high concentration, especially at the beginning of use.

According to the OSHA standards, the concentration of chlorine dioxide gas is within a period of 8 hours a day or 40 hours a week, so that the average value of the time load (TWA) is 0.1 ppm or less have. In addition, in accordance with the American Council of Industrial Hygienists (ACGIH) standards, it is always necessary to maintain a short-term exposure limit (STEL) of 15 ppm for 0.3 ppm, and chlorine dioxide gas to remain in this low concentration range . On the other hand, in order to sterilize a medical instrument in a sterilization box for medical use in a short time, it is optimal to set the concentration of the chlorine dioxide gas to 30 ppm or more.

Patent Document 1: JP-A-11-278808 Patent Document 2: JP-A 2007-68612 Patent Document 3: JP-A-2011-19646 Patent Document 4: Japanese Patent Application Laid-Open No. 2011-19647

SUMMARY OF THE INVENTION It is an object of the present invention to provide a chlorine dioxide gas generating apparatus capable of quickly and continuously generating chlorine dioxide gas to facilitate concentration control of chlorine dioxide gas. According to the technique of the present invention, it is possible to directly discharge low-concentration chlorine dioxide gas, which is safe to human body, in a human-occupied space and to continuously maintain the concentration of chlorine dioxide gas. Further, It is possible to generate chlorine gas quickly and to keep it continuously for a desired time.

A first invention of the present invention is a chlorine dioxide gas generator for generating chlorine dioxide gas, comprising: a storage tank for storing a stabilized chlorine dioxide water having a desired concentration; a chlorine dioxide gas generating space for generating chlorine dioxide gas; An ultraviolet ray irradiating means and a venting means, wherein ultraviolet rays outside the chlorine dioxide gas generating device are blocked in the storage tank, and the chlorine dioxide gas generating space is provided in the storage tank And the ultraviolet ray irradiation means emits ultraviolet rays to the surface of the stabilized chlorine dioxide water expanded by the surface area enlarging means in the chlorine dioxide gas generating space, From the chlorine gas generating space, chlorine dioxide Thereby releasing the gas.

In the first invention, the concentration of the chlorine dioxide gas to be released is not limited. Concentrations of 30 ppm or more are best when releasing chlorine dioxide gas in a medical sterilization box, and concentrations less than 0.1 ppm are best when it is released directly into a human room. It is optimal that the stabilized chlorine dioxide water is diluted with pure water to obtain a desired concentration of stabilized chlorine dioxide water at a high concentration. Since the ultraviolet rays from the outside of the apparatus are blocked in the storage tank, the stabilized chlorine dioxide water is maintained in a stable state. Here, the material of the storage tank is not limited such as metal quality, resin quality and glass quality, and ultraviolet rays from the outside of the apparatus should be shielded. It is possible to adjust the concentration of the chlorine dioxide gas generated by adjusting the concentration of the stabilized chlorine dioxide water used and adjusting the ultraviolet output of the ultraviolet ray irradiation means. It is optimal if the surface area of the stabilized hydrochloric acid salt is enlarged by using water droplets, bubbles, means for generating mist, or vibration means in the chlorine dioxide gas generating space in the chlorine dioxide generating device.

The ultraviolet ray irradiation means is not limited to the type of the ultraviolet lamp or the ultraviolet LED and the wavelength thereof. If it is intended to generate chlorine dioxide gas at a high concentration, an ultraviolet lamp having a wavelength of 254 nm to 270 nm which is said to have a high absorbance against chlorine dioxide gas can be used. On the other hand, if chlorine dioxide gas having a low concentration is generated, An ultraviolet LED of 400 nm or the like may be used. The ultraviolet ray output from the ultraviolet ray irradiation means is appropriately adjusted in accordance with the size of the chlorine dioxide gas generating space and the concentration of stabilized chlorine dioxide. The position where the ultraviolet ray irradiating means is installed is set to a position irradiated on the surface of a wide range of stabilized chlorine dioxide water including the surface of the storage tank and the surface of the stabilized chlorine dioxide water expanded by the surface area enlarging means in the chlorine dioxide gas generating space . The ventilation means may be a well-known fan, and its shape and blowing amount are not limited. So long as it releases chlorine dioxide gas generated in the chlorine dioxide gas generator.

According to the first aspect of the present invention, chlorine dioxide gas is rapidly and more readily generated by the action of the ultraviolet ray irradiation means and the surface area enlargement means within the space for generating chlorine dioxide gas, And the emission of the chlorine dioxide gas is stopped by the irradiation of ultraviolet rays and the stop of the ventilation means. Thereby, it becomes possible to rapidly and continuously discharge the chlorine dioxide gas at a desired concentration, and at the same time to stop the discharge of the chlorine dioxide gas, and it becomes possible to manage the discharge of the chlorine dioxide gas.

The chlorine dioxide gas generating apparatus of the second invention of the present invention is the chlorine dioxide gas generating apparatus of the first invention which releases chlorine dioxide gas directly into a room where a person resides, The water is converted into stabilized chlorine dioxide water having a concentration of 100 ppm to 10,000 ppm and the ventilation means introduces the room air into the chlorine dioxide gas generating space to release the generated chlorine dioxide gas into the room .

The stabilized chlorine dioxide water stored in the chlorine dioxide generating device of the second invention is optimum when it is diluted with pure water and has a concentration ranging from 100 ppm to 10,000 ppm. It is possible to prevent the generation of a high concentration of chlorine dioxide gas by using a low concentration of stabilized chlorine dioxide water, and if the concentration of chlorine dioxide gas is low, it does not generate irritating odor. The ventilation means is optimum when an inlet for introducing indoor air and an outlet for discharging chlorine dioxide gas are installed apart from each other. The wavelength and the output of the ultraviolet irradiation means may be determined according to the concentration of stabilized chlorine dioxide and the concentration of chlorine dioxide released into the room. It goes without saying that, if the wavelength of the ultraviolet LED is changed from 254 nm to 270 nm, it is applicable to a stabilized chlorine dioxide having a lower concentration.

According to the second invention, the enlarged surface of the low concentration of stabilized chlorine dioxide water is irradiated with ultraviolet rays to continuously discharge a low concentration of chlorine dioxide gas into the room where the person lives. As a result, it is possible to uniformly spread the chlorine dioxide gas at a safe concentration throughout the room in which the person lives.

The third invention of the present invention is characterized in that in the chlorine dioxide gas generator of the first or second invention, the stabilized chlorine dioxide water is diluted with pure water and adjusted in concentration.

When diluted with water containing impurities, for example, drinking water or the like, a stabilized chlorine dioxide water is generated in a small amount and it is difficult to control the concentration of chlorine dioxide gas at a low concentration. However, when diluted with pure water, chlorine dioxide gas is not generated and the stable state is maintained without external activation factors such as irradiation with ultraviolet rays. By stopping the ultraviolet ray irradiation means and the surface area enlarging means on the stabilized chlorine dioxide water, the chlorine dioxide gas is not generated, and the concentration of chlorine dioxide gas is easily managed.

A fourth invention of the present invention is characterized in that, in the first to third inventions, a deep portion is provided from the stabilized chlorine dioxide water surface of the storage tank. The shape of the storage tank is not limited, and the bottom portion may be curved, or the bottom portion may be inclined to partially deeper, or a depression may be provided in the bottom portion to deepen a portion.

If the scooping inlet of the scooping portion of the surface area enlarging means described later is provided at a portion where the depth is deep, the scoop height will not be sufficient and the scoop will not be stagnated. Further, if a bubble generating means described below is provided at a deep part of the water depth, the bubble is not exposed and bubbles are continuously generated. Thereby, even if the amount of the stabilized chlorine dioxide water is limited, there is an advantageous effect that the surface area of the stabilized chlorine dioxide water can be widened and the function of the surface area enlarging means can be maintained.

A fifth invention of the present invention is the chlorine dioxide generator according to any one of the first to fourth aspects of the present invention, characterized in that it comprises an inner lid having an opening inwardly around the upper part of the storage tank, And a second storage space for storing the stabilized chlorine dioxide water in the storage tank between the partition wall and the wall of the storage tank in a state in which the chlorine dioxide generating device is tilted sideways.

According to the fifth invention, it is possible to generate chlorine dioxide gas by irradiating ultraviolet rays in a short distance by attaching stabilized chlorine dioxide water to the partition wall of the chlorine dioxide generating device. In addition, even when placed upside down, the stabilized chlorine dioxide water stored in the storage tank located at the bottom portion is stored in the second storage space defined by the partition wall, the wall of the storage tank, the inner lid and the bottom plate of the storage tank. As a result, the amount of chlorine dioxide gas generated is increased, and even when the chlorine dioxide gas generator of the present invention is placed upside down, the stabilized chlorine dioxide does not leak out of the chlorine dioxide generator.

In a sixth aspect of the present invention, in the chlorine dioxide gas generator of any one of the first to fifth aspects, the surface area enlarging means includes a droplet droplet and a rotating means, the rotating means includes rotation driving means and power source means, Wherein the droplet droplet body is hollow and has a substantially inverted conical shape along the inner wall thereof and has a root portion along its inner wall and its lower end is opened to be immersed in the storage tank, And the stabilized chlorine dioxide water is raised along the root portion to disperse the water droplet droplet in the water droplet state in the chlorine dioxide gas generating space around the droplet droplet.

According to the sixth aspect of the present invention, the stabilized chlorine dioxide water that has fallen inside the droplet droplet scattered by the open bottom end of the droplet droplet is rotated together with the root of the droplet droplet, And is scattered as a water droplet on the upper side of the droplet droplet. The surface area of the stabilized chlorine dioxide is enlarged by the surface area of the scattered water droplet surface area and the water droplet falling directly on the water surface of the storage tank and the number of stabilized chlorine dioxide is trickling. Also, stabilized chlorine dioxide water is attached to the wall portion constituting the chlorine dioxide gas generating space, and the water surface area of the stabilized chlorine dioxide is enlarged. Whereby the generation of chlorine dioxide gas can be promoted.

A seventh aspect of the present invention is the chlorine dioxide generator according to the sixth aspect of the present invention, wherein the ventilation means includes a fan, the fan is rotated by the rotation means, and the rotation drive means and the power source means, Is provided upstream of the air flow of the air flow by the means.

According to the seventh invention, the rotary drive means and the power source means are not exposed to the chlorine dioxide gas generated in the chlorine dioxide gas generating space. Thereby, even when the chlorine dioxide generating device is used over a long period of time, the metal parts of the rotation driving means and the power source means are not corroded.

According to an eighth aspect of the present invention, in the chlorine dioxide gas generator of any one of the first to fifth aspects of the invention, the surface area enlarging means includes bubbling means, wherein the foaming means introduces air into the tube, And is characterized by expanding the surface area of stabilized chlorine dioxide water by foaming a large number of bubbles in the storage tank.

According to the eighth aspect of the present invention, the introduced air generates a large number of bubbles in the storage tank, the surface area of the stabilized chlorine dioxide water is expanded by the expansion of the bubbles, and the water droplets of the small stabilized chlorine dioxide water Thereby enlarging the surface area of the stabilized chlorine dioxide water. Thereby making it possible to promote the generation of chlorine dioxide gas

The ninth invention of the present invention resides in the chlorine dioxide gas generator of any one of the first through fifth aspects of the present invention, wherein the surface area enlarging means includes a mist generating means composed of an ultrasonic vibrator, Thereby generating a fine stabilized chlorine dioxide water in a fog state on the water surface of the stabilized chlorine dioxide water to increase the surface area of the stabilized chlorine dioxide water.

According to the ninth invention, the stabilized chlorine dioxide water is generated in a foggy manner in the chlorine dioxide gas generating space by the mist generating means, thereby enlarging the surface area of the stabilized chlorine dioxide water in the chlorine dioxide gas generating space. Whereby the generation of chlorine dioxide gas can be promoted.

The tenth invention of the present invention is characterized in that, in the chlorine dioxide generating apparatus of the first to ninth inventions, the concentration of the chlorine dioxide gas emitted into the room is in a range of 0.01 ppm to 0.1 ppm.

In the tenth aspect of the present invention, the concentration of the chlorine dioxide gas emitted into the room is set to a concentration greater than 0.01 ppm and less than 0.1 ppm. As a result, even in a space where a person stays for a long period of time, the chlorine dioxide gas does not directly affect the human body, and the generation of germs and fungi with low vitality can be suppressed or eliminated.

An eleventh invention of the present invention is a sterilizing box for a medical device sterilizing a medical instrument, comprising a chlorine dioxide gas generating means and a medical instrument receiving portion, wherein the chlorine dioxide gas generating means comprises a storage tank for storing stabilized chlorine dioxide water of a desired concentration , A chlorine dioxide gas generating space for generating chlorine dioxide gas, a surface area increasing means for increasing the surface area of the stabilized chlorine dioxide water in the storage tank, and ultraviolet ray irradiating means, wherein ultraviolet rays from the outside of the chlorine dioxide gas generator Wherein the chlorine dioxide gas generating space is disposed on the upper side of the storage tank in contact with the storage tank and the ultraviolet ray irradiating means is disposed in the chlorine dioxide gas generating space so that the surface of the stabilized chlorine dioxide water expanded by the surface- When ultraviolet light of 254 nm to 270 nm is irradiated, chlorine dioxide Is a chlorine dioxide gas generating generates characterized in that the inlet to the portion receiving the medical device.

According to the eleventh invention, the chlorine dioxide gas at a concentration that sterilizes the medical instrument by the surface area enlarging means is quickly and continuously generated in the ultraviolet irradiating means. This makes it possible to sterilize the medical instrument housed in the sterilization box to every corner in a short time. Further, the positional relationship between the chlorine dioxide gas generating means and the medical instrument receiving portion is not limited. As the ultraviolet ray irradiation means, an ultraviolet ray lamp having a wavelength of 254 nm to 270 nm is most suitable for the stabilized chlorine dioxide water. Also, the concentration of the stabilized chlorine dioxide water and the output of the ultraviolet ray may be determined according to the concentration of the chlorine dioxide gas to be generated.

According to the first aspect of the present invention, chlorine dioxide gas of a desired concentration can be rapidly and continuously released and the emission of chlorine dioxide gas can be stopped by the action of the surface area enlarging means, the ultraviolet ray irradiating means and the venting means, It becomes possible to manage the release of the gas.

According to the second invention, it becomes possible to uniformly distribute the chlorine dioxide gas at a safe concentration throughout the room in which the person lives.

According to the third invention, by stopping the ultraviolet ray irradiation means and the surface area enlarging means for the stabilized chlorine dioxide water, the chlorine dioxide gas is not generated, and the concentration of the chlorine dioxide gas is easily managed.

According to the fourth invention, even if the amount of stabilized chlorine dioxide is limited, it is easy to widen the surface area and to maintain the function of the surface area enlarging means.

According to the fifth invention, the amount of chlorine dioxide generated is increased, and even when the chlorine dioxide gas generator of the present invention is placed upside down, the stabilized chlorine dioxide does not leak outside the chlorine dioxide generator.

According to the sixth, eighth, ninth, and tenth inventions, generation of chlorine dioxide gas can be promoted.

According to the seventh invention, even when the chlorine dioxide generating device is used for a long time, the metal parts of the rotation driving means and the power source means are not corroded.

According to the eleventh invention, it becomes possible to sterilize the medical instrument housed in the sterilizing box to every corner in a short time.

1 is a cross-sectional view showing a state before and after the operation of the surface area enlarging means (Embodiment 1).
Fig. 2 is an explanatory diagram of a second storage space (Embodiment 1). Fig.
FIG. 3 is an explanatory diagram of a chlorine dioxide gas generator in which a stirring body is provided outside the end portion of a droplet discharge body (Example 2).
4 is an explanatory diagram of a chlorine dioxide gas generator equipped with an air pump (Example 3).
5 is an explanatory diagram of a chlorine dioxide gas generator equipped with an underwater pump and a dissipator (Example 4).
6 is an explanatory diagram of a chlorine dioxide gas generator equipped with an ultrasonic vibrator (Example 5).
7 is an explanatory diagram of a chlorine dioxide gas generator equipped with a vibrator (Example 6).
8 is an explanatory diagram of a sterilizing box for a medical device (Example 7).
[FIG. 9] Experimental graph of low concentration of chlorine dioxide generating gas (experiment 1 at low concentration).
[FIG. 10] Experiment graph of high concentration of chlorine dioxide generating gas (Experiment 2 at high concentration).

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The chlorine dioxide gas generating apparatuses according to the first to the first to the following embodiments are chlorine dioxide gas generating apparatuses which generate chlorine dioxide gas at a low concentration in a room where a person lives. Each of the chlorine dioxide gas generators is equipped with a stabilized chlorine dioxide storage tank in the lower part, and releases chlorine dioxide gas from the upper part into the room. In each of the embodiments, another means is adopted as the surface area increasing means for enlarging the surface area of the stabilized chlorine dioxide water.

First, in the first embodiment, a droplet droplet scattering body 30 having a funnel shape with an enlarged upper part and chlorine dioxide gas having surface area enlarging means composed of a rotating mechanism rotating the droplet scattering body 30 around the central axis 31 The generator 1 will be described with reference to Figs. 1 and 2. Fig. The chlorine dioxide gas generator 1 of the first embodiment has a height of 15 cm, a diameter of 15 cm, a lower portion of a substantially cylindrical shape, and a hemispherical top cover 60 on the upper portion thereof. Fig. 1 (A) is an explanatory diagram of a vertical section of the state before the operation of the drive motor 62, and Fig. 1 (B) is an explanatory diagram of a vertical section of the state in which it is in operation. Fig. 2 (A) and Fig. 2 (B) are views for explaining a vertical cross section of the chlorine dioxide gas generator 1 upside down. Fig. 2 Fig. Fig. 2 illustrates the amount of stabilized chlorine dioxide.

The chlorine dioxide gas generator 1 of the first embodiment is provided with a storage tank 20 for storing the stabilized chlorine dioxide water 10 below. The bottom of the water droplet scattering body 30 is immersed in the stabilized chlorine dioxide water 10 stored in the depression 21 at the central portion of the storage tank 20. An opening 22 is provided at the upper center of the storage tank 20 and an inner lid 40 having a partition wall 42 facing downward from the top plate 41 is attached to the opening 22. The stabilized chlorine dioxide water 10 is stored in the storage tank 20 up to a height exceeding the depression 21 by being inserted into the opening 22 at the upper side.

The second storage space 50 is a storage space for temporarily storing the stabilized chlorine dioxide water 10 stored in the storage tank 20 to prevent the chlorine dioxide gas 10 from flowing out to the outside when the chlorine dioxide generating device 1 is placed upside down. (Refer to Fig. 2). Here, the second storage space 50 is a space between the top plate 41 of the inner lid 40, the side wall 23 of the storage tank 20, and the bottom plate of the storage tank (see FIG. 2 (B) . The capacity for storing the stabilized chlorine dioxide water 10 in the second storage space 50 is larger than the amount of the stabilized chlorine dioxide water 10 stored in the storage tank 20. Thereby, even if the chlorine dioxide generating device 1 is inverted, the stabilized chlorine dioxide 10 of the storage tank 20 is accumulated in the second storage space 50 and does not flow out to the outside (see FIG. 2).

Here, the stabilized chlorine dioxide water 10 used has a low concentration of 100 ppm to 10,000 ppm. By activating a low concentration of stabilized chlorine dioxide water (10), a human-safe chlorine dioxide gas at a concentration of 0.1 ppm or less is released into the room.

The canopy 60 is provided with a fan 61, a drive motor 62 thereof, and a power supply means 63. A drive motor 62 is disposed at the center of the canopy 60. A fan 61 is mounted on the drive shaft 64 extending downward from the drive motor 62 and a center shaft 31 A droplet spray body 30 is mounted. In the first embodiment, the driving motor 62 serves as a rotating mechanism for rotating the fan 61 and the droplet scattering body 30. [ In addition, the canopy 60 is provided with an air introduction path 65 for entraining the air in the room and a discharge path 66 for discharging chlorine dioxide gas generated in the chlorine dioxide generating device to the room.

An ultraviolet LED 70 for generating an ultraviolet ray 71 is provided below the canopy 60 so as to directly face the water surface 13 of the stabilized chlorine dioxide water 10 of the storage tank 20. The ultraviolet LED 70 is connected to the power supply means 63 by an electric supply path (not shown). The wavelength of the ultraviolet LED 70 is an LED for irradiating ultraviolet rays 71 having a wavelength of 400 nm distributed in the market. By using the ultraviolet ray irradiating means as a commercially available ultraviolet LED 70, the chlorine dioxide generating apparatus 1 can be downsized and at the same time, it can be provided at a low price.

The space between the storage tank 20 and the canopy 60 is a chlorine dioxide gas generating space 80. The air in the room is introduced into the chlorine gas generating space 80 by the fan 61 and the chlorine dioxide gas generated in the chlorine dioxide gas generating space 80 is discharged directly to the room from the discharge path 66. [

The water droplet scattering body 30 is hollow and has an expanded funnel shape and is provided with an opening 32 at the lower end and the opening 32 is formed by the stabilized chlorine dioxide water 10 in the depression 21, Lt; / RTI > In addition, the water droplet scattering body (30) is provided with a projecting root portion (33) extending in the vertical direction along the inner wall thereof. The root portion may be formed in a groove shape.

Further, a plate body 34 is mounted on the upper side of the droplet scattering body 30. This plate body 34 prevents the stabilized stabilized chlorine dioxide water 10 from adhering to the ultraviolet LED 70 or the fan 61. Dispersion holes (35) penetrating the inside and outside of the water droplet scattering body (30) are provided at mounting portions of the plate bodies (34) and the water droplet scatter bodies (30).

When the water droplet scattering body 30 is rotated by the drive motor 62 and centrifugal force is generated in the stabilized chlorine dioxide water 10 in the droplet scattering body 30, The stabilized chlorine dioxide water 10 pumped up is dispersed in the chlorine dioxide gas generating space 80 as the water drops 11 (see Fig. 1 (B)), B)). The surface area of the stabilized chlorine dioxide water surface is enlarged due to the slack of the water surface 13 of the stabilized chlorine dioxide water 10 so that the stabilized chlorine dioxide water 10 adheres to the lower portion 24 of the side wall of the storage tank 20 , The surface area of the stabilized chlorine dioxide water 10 is increased. The surface area of the stabilized chlorine dioxide water 10 facing the chlorine dioxide gas generating space 80 is also increased by the fact that the dispersed water droplets 11 adhere to the partition wall 42 of the inner lid. The surface area of the water droplet dispersion body 30 and the surface of the droplets 12 of the stabilized chlorine dioxide water 10 falling from the partition wall 42 also make the surface area of the stabilized chlorine dioxide water 10 in the chlorine dioxide gas generating space 80 .

1 (B) shows a state in which the droplet droplet scattering body 30 is in operation, as compared with the flat water surface 13 (see also Fig. 1 (A)) of the stabilized chlorine dioxide water in which the water droplet dispersion body 30 is not operated ), The surface area of the stabilized chlorine dioxide water 10 is remarkably enlarged as described above, and the generation of the chlorine dioxide gas is promoted.

The operation of the ultraviolet ray irradiation means or the chlorine dioxide gas surface area enlarging means may be controlled by control means not shown. The ultraviolet ray irradiation means and the chlorine dioxide gas surface area enlarging means may be operated together for a predetermined time from the start of operation so that the chlorine dioxide gas surface area enlarging means may be stopped after a predetermined time elapses. The concentration of the chlorine dioxide gas in the room can be controlled by turning on and off the surface area enlarging means, the ultraviolet ray irradiating means, and the fan depending on factors such as the size of the room where the chlorine dioxide generating device is installed and the temperature of the installation site. As a result, it is possible to quickly generate a chlorine dioxide gas at a safe concentration in the room, and then to lower the concentration of the chlorine dioxide gas, thereby sterilizing bacteria and viruses.

(Low concentration experiment 1)

In order to confirm the effect of the surface area enlarging means of the present invention, the concentration of chlorine dioxide gas generated in the test vessel was compared with ultraviolet rays irradiated with stabilized chlorine dioxide as a gel or liquid at a room temperature of 18 degrees Celsius. The concentration of chlorine dioxide gas was measured after 30 minutes and 60 minutes after the operation of the comparative example of the chlorine dioxide gas generator of the embodiment 1 and the concentrations of the chlorine dioxide gas are shown in Tables 1 and 9 .

The generation of chlorine dioxide gas at a low concentration was confirmed by experiments in which a chlorine dioxide gas generator of the embodiment 1 was kept in an acrylic box of 1 m ³ in which no external influences of ultraviolet light existed. Stabilized stabilized chlorine dioxide water of 10,000 ppm was stored in a storage tank having a surface area of 100 cm ² of chlorine dioxide water, and the concentration of chlorine dioxide gas generated inside the acrylic box was compared. As the ultraviolet ray irradiation means, one ultraviolet LED having a wavelength of 400 nm and an output of 0.2 W was used. The concentration of the chlorine dioxide gas was determined by aspirating the gas inside the hole provided on the top plate of the acrylic box and measuring the concentration thereof by a detector tube of Gas Tech (registered trademark).

Experiment (1) shows the concentration of chlorine dioxide gas in the case of operating the apparatus for enlarging the chlorine dioxide gas according to Example 1 by operating the fan and surface area enlarging means and irradiating ultraviolet rays.

Experiment (2) shows the concentration of chlorine dioxide gas when the surface area enlarging means and the fan are removed and only ultraviolet rays are irradiated.

Experiment (3) shows the concentration of chlorine dioxide gas in the case of changing into liquid and irradiating only the ultraviolet rays to the same concentration of the gel body.

Experiment (4) shows the concentration of chlorine dioxide gas in a state where the chlorine dioxide gas generating apparatus of Example 1 was left inactive.

In FIG. 9, the experimental results are shown in a graph. The vertical axis represents the concentration of chlorine dioxide and the horizontal axis represents the elapsed time. A broken line with a circled line represents the concentration of Experiment (1), a broken line with a pentagon represents the concentration of Experiment (2) Is the concentration of experiment (3), and the broken line with triangles represents the concentration of experiment (4).

Elapsed time
Experimental conditions Chlorine dioxide gas concentration [ppm] 30 minutes later After 60 minutes Experiment (1) 0.1 0.1 Experiment (2) 0.05 0.05 Experiment (3) 0.0 0.0 Experiment (4) 0.0 0.0

In Experiment (1), it was found that chlorine dioxide gas was stably detected at a concentration of 0.1 ppm even after a lapse of 30 minutes and after 60 minutes. In Experiment (2), it was found that chlorine dioxide gas at a concentration of 0.05 ppm was stably detected at any of the elapsed times described above. In Experiment (3), chlorine dioxide gas was not detected even when ultraviolet rays were irradiated to a low-concentration gel body. In the comparison between Experiment (1) and Experiment (3), when the stabilizing chlorine dioxide is set to a low concentration, chlorine dioxide gas is not generated even when the gel body is irradiated with ultraviolet rays, and chlorine dioxide gas . In Experiment (4), chlorine dioxide gas was not detected.

From the results shown in Table 1 and FIG. 9, it was confirmed that when the means for enlarging the surface area of the stabilized chlorine dioxide water was used, chlorine dioxide gas was emitted quickly, stably, and stably as compared with the case where only ultraviolet rays were irradiated. Further, it has been confirmed that when the stabilized chlorine dioxide water is left in a standing state, chlorine dioxide gas is not generated and it is easy to prevent the stabilized chlorine dioxide from being consumed and stored.

In Embodiment 2, referring to Fig. 3, the chlorine dioxide gas generating apparatus in which the surface area enlarging means is added with the stirring body 36 in Embodiment 1 will be described. 3 is a cross-sectional view of a chlorine dioxide generating device 2 equipped with an agitator 36 for agitating the water surface outside the end portion of the droplet scattering body 30. As shown in Fig. In the second embodiment, the configuration other than the configuration in which the agitator 36 is provided is the same as that of the first embodiment, and the same reference numerals are given to the drawings and the description is omitted.

The stabilized chlorine dioxide water 10 is vigorously stirred by the rotation of the stirring body 36 so that the water surface 13 sweeps up and down to enlarge the surface area and at the same time, The chlorine number 10 is increased. As a result, the surface area of the stabilized chlorine dioxide water 10 irradiated with the ultraviolet rays 71 is further increased as compared with the first embodiment, and the generation of the chlorine dioxide gas is promoted.

In Embodiment 3, referring to Fig. 4, a chlorine dioxide gas generating apparatus 3 in which surface area enlarging means is used as foaming means will be described. 4 is a cross-sectional view illustrating the chlorine dioxide gas generator 3 equipped with the air pump 90. Fig. Hereinafter, the surface area enlarging means constituted by the foaming means which is the main part of the constitution of the third embodiment will be described. The foaming means has an air pump (90) and a pipe (91). Portions that are the same as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

The air pump 90 is disposed in the canopy 60 and is connected to a pipe 91 disposed in the storage tank 20. The end of the pipe 91 is optimal when it is disposed in the depression 21 of the storage tank 20. Here, the air pump 90 only needs to introduce air into the chlorine dioxide generating space 80, and there may be a known air sending means.

Air is introduced into the stabilized chlorine dioxide water (10) by the foaming means, and bubbles are generated in the water of the stabilized chlorine dioxide water (10). The air bubbles 92 float on the water surface 13 of the stabilized chlorine dioxide water 10 and the air bubbles 92 are expanded so that the water surface 13 is undulated and the surface area of the water surface 13 is enlarged. In addition, the bubble 92 is ruptured so that the water droplet 11 is scattered and the scattered water droplet 11 is attached to the lower portion 24 of the side wall. As a result, the surface area of the stabilized chlorine dioxide water 10 irradiated with the ultraviolet rays 71 is enlarged, and the generation of the chlorine dioxide gas is promoted.

Here, the air pump 90 serves as a means for enlarging the surface area, and at the same time, a means for introducing air. The air pump 90 is operated so that the air is introduced from the air introduction path 65 and passes through the pipe 91 extending from the air pump 90 to become the bubble 92 and the chlorine dioxide gas generating space 80, . The air introduced into the chlorine dioxide gas generating space 80 is released in the discharge path 66 together with the generated chlorine dioxide gas.

In Embodiment 4, referring to Fig. 5, a chlorine dioxide gas generating device 4 in which the surface area enlarging means is stabilized chlorine dioxide water dissipating means is described. 5 is an explanatory diagram for explaining the chlorine dioxide gas generating apparatus 4 in which the stabilized chlorine dioxide water dissipating means is an underwater pump 100 and a dissipating unit 103, in cross section. The surface area enlarging means constituted by the stabilized chlorine dioxide water dissipating means which is a crucial part of the constitution of the fourth embodiment will be described below. Portions which are the same as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted.

The underwater pump 100 is disposed in the depression 21 of the storage tank 20 and is equipped with a water inlet 101 and a pouring pipe 102. The scooping pipe 102 is provided with a spreading part 103 which extends upward from the water surface 13 and has a plurality of small holes toward the stabilized chlorine dioxide water at the end thereof. The stabilized chlorine dioxide water 10 is pumped up by the underwater pump 100 from the water intake port 101 provided in the depression and dissipated toward the water surface 13 of the stabilized chlorine dioxide water 10 from the diffusion part 103. It is sufficient if the underwater pump 100 is capable of pumping the stabilized chlorine dioxide water 10 and the dissipating unit 103 dissipates the stabilized chlorine dioxide water 10 as the water droplets 11 downward.

The water droplets 11 of the stabilized chlorine dioxide water 10 dispersed in the chlorine dioxide gas generating space 80 in the dissipating part 103 fall down to the water surface 13 and the water droplet 14 splashes out from the water surface 13, The surface area of the stabilized chlorine dioxide water 10 is enlarged. Also, the scattered water spray 14 is attached to the lower portion 24 of the side wall in a wide range. As a result, the surface area of the stabilized chlorine dioxide water (10) irradiated with the ultraviolet ray (71) is enlarged, and the generation of chlorine dioxide gas is promoted.

In Embodiment 5, referring to Fig. 6, an embodiment in which the surface area enlarging means includes the fogging means is described. 6 is a cross-sectional view illustrating the chlorine dioxide generating device 5 equipped with the ultrasonic vibrator which is the mist generating means. Hereinafter, the means for enlarging the surface area, which is the essential part of the constitution of the fifth embodiment, will be described.

The ultrasonic vibrator 110 is disposed in the depression 21 of the storage tank 20 and is entirely immersed in the stabilized chlorine dioxide water 10. [ Here, the chlorine dioxide gas generating apparatus 5 of the fifth embodiment may be a medium to large-sized chlorine dioxide generating apparatus. The stabilized chlorine dioxide water 10 is fogged by the ultrasonic vibration 111 of the ultrasonic vibrator 110 and the area of the stabilized chlorine dioxide water 10 is enlarged. The stabilized chlorine dioxide water 10 is also adhered to the side wall 23 of the storage tank 20 by the fog 15 as the mist 15 is generated. The surface area of the stabilized chlorine dioxide water 10 irradiated with the ultraviolet rays 71 is expanded by the stabilized chlorine dioxide water 10 attached to the mist 15 and the side wall 23 to promote the generation of chlorine dioxide gas . The same components as those in the first embodiment are denoted by the same reference numerals as those in FIG.

In the embodiment, referring to Fig. 7, a description will be given of an embodiment in which the surface area enlarging means serves as the vibrator 120 contacting the outside 25 of the storage tank. 7 is a cross-sectional view of the chlorine dioxide gas generator 6 of the sixth embodiment. The surface area enlarging means by the vibrator 120 which is the essential part of the configuration of the sixth embodiment will be described below.

The vibrator 120 is disposed in contact with the outer surface 25 of the storage tank. The oscillator 120 vibrates the storage tank 20 and vibrations are transferred to the stabilized chlorine dioxide water 10 stored in the storage tank 20. The water surface 13 of the oscillated stabilized chlorine dioxide water 10 sags vertically so that the water surface 14 rises in the water surface 13 and the surface area of the stabilized chlorine dioxide water 10 is enlarged. In addition, the stabilized chlorine dioxide water 10 is attached to the lower portion 24 of the side wall of the storage tank 20 by the wave generated by the vibration. As a result, the surface area of the stabilized chlorine dioxide water (10) irradiated with the ultraviolet ray (71) is enlarged, and the generation of chlorine dioxide gas is promoted. The same components as those in the first embodiment are denoted by the same reference numerals as those in FIG.

The sterilization box 7 for a medical device according to the seventh embodiment is a sterilization box for sterilizing the medical instrument 130 with chlorine dioxide gas having a high concentration. Hereinafter, the sterilizing box 7 for a medical instrument will be described with reference to Fig. 8 is a perspective view of a sterilization box 7 for a medical device according to the seventh embodiment. The sterilization box 7 for a medical instrument is provided with a chlorine dioxide gas generating space 80 below and a medical instrument receiving portion 81 above the medical instrument 130.

A storage tank 20 is provided in the chlorine dioxide generating space 80 and a vibrator 120 is disposed in contact with the outside of the storage tank 20 below the storage tank 20. In addition, an ultraviolet lamp 72 is disposed above the storage tank 20 so as to face the stabilized chlorine dioxide water surface. The inside of the chlorine dioxide generating space is also shown by a broken line. The chlorine dioxide gas generating space 80 and the medical instrument receiving portion 81 communicate with each other through the vent hole 82 and the generated chlorine dioxide gas flows into the medical instrument receiving portion 81. The surface area enlarging means is not limited to the surface area enlarging means by the vibrator 120, and the surface area enlarging means described in Embodiments 1 to 6 can be applied.

(Experiment 2 of high concentration)

An experiment was conducted to confirm that the concentration of chlorine dioxide gas in the acrylic box reached a concentration of 30 ppm or more required for sterilizing bacteria and the like by chlorine dioxide gas. The experimental environment was the same as Experiment 1 of the above-mentioned low concentration. Stabilized Stabilized Chlorine dioxide water having a surface area of 450 cm ² in a static state was adjusted to 50,000 ppm of stabilized chlorine dioxide water in an amount of 3 cm from the top of the pipe to the stabilized chlorine dioxide water surface using the foaming means shown in Example 3 The experiment was carried out. Three ultraviolet lamps with a wavelength of 254 nm and an output power of 9 W were used as ultraviolet light irradiation means. The surface area of the stabilized chlorine dioxide water was expanded by foaming the stabilized chlorine dioxide water at the ends of four tubes using four gas pumps of 2.5 L / min as the surface area increasing means.

The concentrations of chlorine dioxide gas after 30 minutes, 60 minutes, 90 minutes, and 120 minutes after the operation were measured, and the results are shown in Table 2 and FIG. Experiment (5) shows the concentration of chlorine dioxide gas in the case of irradiating ultraviolet rays while the surface area of the stabilized chlorine dioxide water is enlarged by the surface area enlarging means.

Experiment (6) shows the concentration of chlorine dioxide gas when only the ultraviolet rays are irradiated to the stabilized chlorine dioxide water without applying the surface area enlarging means.

In FIG. 10, the experimental results are shown in a graph. The vertical axis shows the concentration of chlorine dioxide and the horizontal axis shows the elapsed time. A broken line with a circle indicates the concentration of the experiment (5), and a broken line with the square table shows the concentration of the experiment (6).

Elapsed time
Experimental conditions Chlorine dioxide gas concentration [ppm] 30 minutes 60 minutes 90 minutes 120 minutes Experiment (5) 27.5 50.0 75.0 97.5 Experiment (6) 20.0 25.0 37.5 42.5

From the results shown in Table 2 and FIG. 10, it was confirmed that chlorine dioxide gas at a high concentration was generated at a high rate in the case of applying the surface area enlarging means by the foaming means. It goes without saying that when the sterilizing box for a medical device is made smaller than the above-mentioned acrylic box, the concentration reaches a higher level sooner.

(Etc)

In the first to fourth embodiments, the embodiment of the small-size chlorine dioxide generating device is described, but the size is not limited. It goes without saying that the depression is not necessarily formed.

In the above embodiment, an ultraviolet ray is irradiated only from the upper side. An ultraviolet ray reflecting plate, for example, a stainless steel plate is disposed on the bottom surface of the storage tank, the upper side ultraviolet ray is reflected by the stainless steel plate, It is a matter of course that a high concentration of chlorine dioxide gas is generated.

The concentration of the stabilized chlorine dioxide water and the output of the ultraviolet ray have been specifically described in the above embodiment, but it may be determined according to the concentration of the chlorine dioxide gas to be released.

The presently disclosed embodiments 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 it is intended that all modifications are included within the meaning and scope equivalent to the claims.

1, 2, 3, 4, 5, 6 chlorine dioxide gas generator
7 Sterilization box for medical device 10 Stabilized chlorine dioxide
11 Twelve drops of water
13 Water 14 Spray
15 Fog 20 Storage tank
21 depression 22 opening
23 side wall 24 lower portion of side wall
25 Outside of storage tank 30 Water droplet scattering body
31 central axis 32 opening
33 root 34 plate
35 Dispersion Blower 36 Stirring Blower
40 inner lid 41 top plate
42 partition 50 second storage space
60 thousand 61 fans
62 drive motor 63 power supply means
64 drive shaft 65 air introduction path
66 Emission path 70 Ultraviolet LED
71 Ultraviolet light 72 Ultraviolet lamp
80 Chlorine dioxide gas generating space 81 Medical instrument receiving section
82 vent hole 90 air pump
91 Pavilion 92 Bubble
100 submersible pump 101 withdrawal port
102 Percent raise 103 Dissemination Department
110 Ultrasonic vibrator 111 Ultrasonic vibration
120 Oscillators 130 Medical Instruments

Claims (11)

A chlorine dioxide gas generator for generating chlorine dioxide gas,
A storage tank for storing the stabilized chlorine dioxide water at a desired concentration; a chlorine dioxide gas generating space for generating chlorine dioxide gas; a surface enlargement means for enlarging the surface area of the chlorine dioxide water; an ultraviolet irradiation means; ,
In the storage tank, ultraviolet rays are shielded from the outside of the chlorine dioxide gas generator,
Wherein the chlorine dioxide gas generating space is disposed above the storage tank in contact with the storage tank,
The ultraviolet ray irradiation means irradiates the surface of the stabilized chlorine dioxide water expanded by the surface area enlarging means in the chlorine dioxide gas generating space with ultraviolet rays,
Wherein the ventilation means releases chlorine dioxide gas from the chlorine dioxide gas generating space to the outside of the chlorine dioxide gas generating device. The method according to claim 1,
A chlorine dioxide gas generator for directly discharging chlorine gas to a room where a person is living,
The stabilized chlorine dioxide water becomes a stabilized chlorine dioxide water having a concentration of 100 ppm to 10,000 ppm,
Wherein the ventilation means introduces the air in the room into the chlorine dioxide generating space and releases the generated chlorine dioxide gas to the room. 3. The method according to claim 1 or 2,
Wherein the stabilized chlorine dioxide water is diluted with pure water to adjust the concentration. 4. The method according to any one of claims 1 to 3,
Wherein a portion deep in the water depth from the stabilized chlorine dioxide water surface of the storage tank is provided. 5. The method according to any one of claims 1 to 4,
An inner lid having an opening inwardly of the upper part of the algae tank, a partition wall descending from the inside of the inner lid toward the storage tank,
And a second storage space for storing the stabilized chlorine dioxide water in the storage tank between the partition wall and the wall of the storage tank in a state in which the chlorine dioxide generating device is tilted sideways. 6. The method according to any one of claims 1 to 5,
Wherein the surface area enlarging means includes a droplet scattering body and a rotating means,
Wherein the rotating means has rotation driving means and power supply means,
The water droplet scattering body has a hollow inside and has a generally inverted conical shape and has a root portion along the inner wall and is opened at its lower end portion to be immersed in the storage tank,
The rotation driving means rotates the droplet droplet body around its central axis and raises the stabilized chlorine dioxide water along the root portion and disperses the water droplet droplet droplet in the water droplet state in the chlorine dioxide gas generating space around the droplet droplet Wherein the chlorine dioxide gas generating device is characterized by: The method according to claim 6,
Said venting means comprising a fan,
Wherein the fan is rotated by the rotation means, and the rotation drive means and the power source means are provided upstream of an air flow of air by the air supply means. 6. The method according to any one of claims 1 to 5,
Wherein the surface area enlarging means includes a foaming means,
Wherein the foaming means introduces air into the tube and foams a large number of bubbles in the storage tank to expand the surface area of the stabilized chlorine dioxide water. 6. The method according to any one of claims 1 to 5,
Wherein the surface area enlarging means includes a mist generating means composed of an ultrasonic vibrator,
Wherein the mist generating means generates fine mist stabilized chlorine dioxide water on the surface of the stabilized chlorine dioxide water by the ultrasonic vibrator submerged in the storage tank and increases the surface area of the stabilized chlorine dioxide water, Device. 10. The method according to any one of claims 1 to 9,
Wherein the concentration of the chlorine dioxide gas emitted into the room is in a range of 0.01 ppm to 0.1 ppm. A sterilization box for a medical device sterilizing a medical instrument,
A chlorine dioxide gas generating means and a medical instrument accommodating portion,
A storage tank for storing the stabilized chlorine dioxide water at a desired concentration of chlorine dioxide gas generating means, a chlorine dioxide gas generating space for generating chlorine dioxide gas, a surface area enlarging means for enlarging the surface area of the stabilized chlorine dioxide water in the storage tank, Comprising:
The ultraviolet rays from the outside of the chlorine dioxide gas generator are blocked in the storage tank,
Wherein the chlorine dioxide gas generating space is disposed above the storage vessel in contact with the storage vessel,
The ultraviolet ray irradiation means irradiates the surface of the stabilized chlorine dioxide water expanded by the surface area enlarging means in the chlorine dioxide gas generating space with ultraviolet rays having a wavelength of 254 nm to 270 nm to generate chlorine dioxide gas,
And the generated chlorine dioxide gas is introduced into the medical instrument receiving portion.

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