JP7562121B2 - Gas Generator - Google Patents

Description

The present invention relates to a gas generating device that generates a specific gas.

Conventionally, gas generators that generate chlorine dioxide by chemically reacting sodium chlorite with citric acid as an oxidizing agent have been known (see, for example, Patent Document 1).

JP 2009-256141 A

In the above chemical reaction, in addition to chlorine dioxide, which is necessary for sterilization, unwanted reactants such as sodium citrate are also produced. When sodium hypochlorite (a chlorine agent) is used for sterilization, the sodium in the chemical reacts with organic matter, which may result in the production of unwanted substances.

In order to eliminate the unexpected effects of the generation of unwanted substances, there is a demand to obtain only the necessary chlorine dioxide by chemically reacting sodium chlorite with citric acid. In addition, since the chlorine dioxide generated is a gas, it disperses quickly in the air and is therefore not very convenient to use for sterilization, etc.

The above demands also arise when chlorine dioxide is generated using citric acid or a substance other than citric acid, or when a gas other than chlorine dioxide is generated. For example, the same demand arises when it is desired to obtain only the fragrance components from a substance such as a fragrance.

The objective of the present invention is to provide a gas generator that can obtain the required gas (gas that does not contain impurities) and can improve the usability of the obtained gas.

The present invention has a first container that contains a plurality of kinds of substances in an internal space and allows gas generated by a chemical reaction of the plurality of kinds of substances to pass through and be released to the outside,
The first container is adapted to be contained in a second container having an opening and containing a dissolved liquid in which the gas released from the first container is dissolved, the dissolved liquid being water, and a third container is contained in an internal space of the first container, a first chemical is contained in the internal space of the third container, and a second chemical is contained in the internal space of the first container, which is a space outside the internal space of the third container, and the gas generator is configured such that, when the third container is destroyed, the first chemical and the second chemical undergo a chemical reaction in the first container to generate the gas, the first chemical is sodium chlorite, the second chemical is citric acid, and the gas is chlorine dioxide, the first container is made of a synthetic resin that is elastic and allows only gas to pass through, and the synthetic resin is polypropylene, polyethylene, or silicone, or a mixture of at least two materials selected from the group consisting of polypropylene, polyethylene, and silicone .

The invention described in claim 2 is the gas generation device described in claim 1, wherein the sodium chlorite is contained in the internal space of the third container in the form of an aqueous solution, and the citric acid is contained in the internal space of the first container and in the space outside the internal space of the third container in the form of a powder or tablet, or the sodium chlorite is contained in the internal space of the third container in the form of a powder or tablet, and the citric acid is contained in the internal space of the first container and in the space outside the internal space of the third container in the form of an aqueous solution, or the sodium chlorite is contained in the internal space of the third container in the form of an aqueous solution, and the citric acid is contained in the internal space of the first container and in the space outside the internal space of the third container in the form of an aqueous solution .

The invention described in claim 3 has a first container that contains multiple types of substances in an internal space and allows gas generated by a chemical reaction of the multiple types of substances to pass through and release it to the outside, the first container is configured to be contained in a second container that has an opening and contains a dissolved liquid in which the gas released from the first container is dissolved, the dissolved liquid is water, and a third container is provided in the internal space of the first container, a first chemical is contained in the internal space of the third container, and a second chemical is contained in the internal space of the first container, which is a space outside the internal space of the third container, The gas generating device is configured such that, when the third container is destroyed, the first chemical and the second chemical undergo a chemical reaction in the first container to generate the gas, the first chemical is citric acid, the second chemical is sodium chlorite, and the gas is chlorine dioxide, the first container is made of a synthetic resin that is elastic and allows only gas to pass through, and the synthetic resin is polypropylene, polyethylene, or silicone, or a mixture of at least two of the materials polypropylene, polyethylene, and silicone .

The invention described in claim 4 is the gas generation device described in claim 3 , wherein the citric acid is contained in the internal space of the third container in the form of an aqueous solution, and the sodium chlorite is contained in the internal space of the first container in the form of a powder or tablet, and the sodium chlorite is contained in the internal space of the first container in the form of an aqueous solution, and the sodium chlorite is contained in the internal space of the third container in the form of an aqueous solution, and the sodium chlorite is contained in the internal space of the first container in the form of an aqueous solution, and the sodium chlorite is contained in the internal space of the third container in the form of an aqueous solution .

The invention described in claim 5 is a gas generating device described in any one of claims 1 to 4, wherein the opening of the first container is covered with a lid, the lid is configured to include a lid body and a gas permeable membrane, and the gas permeable membrane is configured to allow gas to pass through but block liquid .

The present invention has the effect of providing a gas generator that can obtain the required gas (gas that does not contain impurities) and can improve the usability of the obtained gas.

1 is a cross-sectional view showing a schematic configuration of a gas generation device according to an embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a gas generation device according to a modified example. 1A and 1B are diagrams showing a schematic configuration of a gas generation device according to a reference example, and FIG. 1B is a cross-sectional view taken along line IIIB-IIIB in FIG. 1A to 1C are diagrams showing the schematic configuration of a gas generation device according to a reference example, where (a) is a front view, (b) is a side view, and (c) is a diagram showing the IVC-IVC cross section in (b).

The gas generating device 1 according to the embodiment of the present invention is a device that generates a gas such as chlorine dioxide by a chemical reaction or the like, and is configured with a first container 3 as shown in FIG. 1. The first container 3 is adapted to be housed within a second container 5.

The first container 3 contains multiple types of substances in an internal space 7 that is separated from the outside. The multiple types of substances include a first chemical 17 and a second chemical 21, the details of which will be described later. The first container 3 is also made of a material that allows only a specific gas to pass through. This allows the first container 3 to allow only the gas generated by the chemical reaction of the multiple types of substances to pass through and be released to the outside of the first container 3.

The second container 5 is made of a material that is impermeable to neither gas nor liquid. The second container 5 has an opening 9. The second container 5 contains the first container 3 and a dissolved liquid 11 that dissolves the gas released from the first container 3. When the first container 3 and the dissolved liquid 11 are contained in the second container 5, the entire first container 3 is submerged in the dissolved liquid 11. Note that, although FIG. 1 shows a wide-mouthed bottle as the second container 5, this is not limiting and various shapes may be used as the second container 5. For example, a bathtub or a fish tank may be used as the second container 5.

The gas generator 1 is also provided with a third container 13. The third container 13 is, for example, an ampoule, and is housed in the internal space 7 of the first container 3.

The internal space 15 of the third container 13 contains a first drug 17, and the internal space 7 of the first container 3, which is a space 19 outside the internal space 15 of the third container 13, contains a second drug 21.

The third container 13 is configured to be broken, for example, by an applied force, causing a chemical reaction between the first chemical 17 and the second chemical 21 in the first container 3, generating gas. This gas permeates the flesh of the first container 3 and dissolves in the dissolved liquid 11 in the second container 5. The gas dissolved in the dissolved liquid 11 is gradually released from the dissolved liquid 11.

The first container 3 is made of synthetic resin such as polypropylene , polyethylene, silicone, etc., which is elastic and chemical resistant and allows only gas to pass through. The second container 5 and the third container 13 are made of synthetic resin, glass, etc., which is chemical resistant and does not allow gas or liquid to pass through.

Chlorine dioxide is listed as the gas produced by the above chemical reaction. Water (e.g., pure water) is listed as the dissolved liquid 11. When chlorine dioxide is listed as the gas, the first chemical 17 contained in the internal space 15 of the third container 13 contains a chlorine-based compound. When chlorine dioxide is listed as the gas, the second chemical contained in the internal space 7 of the first container 3, that is, in the space 19 outside the internal space 15 of the third container 13, contains an acid.

In any case, the first chemical 17 and the second chemical 21 undergo a chemical reaction, so that only chlorine dioxide is produced as a gas at room temperature and pressure.

More specifically, the first chemical 17 contains sodium chlorite (e.g., an aqueous solution of sodium chlorite), and the second chemical 21 contains citric acid (e.g., citric acid in powder or tablet form).

The first chemical 17 and the second chemical 21 may be interchanged. That is, citric acid may be contained in the internal space 15 of the third container 13, and sodium chlorite may be contained in the internal space 7 of the first container 3, that is, in the space 19 outside the internal space 15 of the third container 13.

The first chemical 17 may be an aqueous solution of sodium chlorite and the second chemical 21 may be an aqueous solution of citric acid, or the first chemical 17 may be a powder or tablet of sodium chlorite and the second chemical 21 may be an aqueous solution of citric acid.

When the third container 13 breaks, a chemical reaction occurs between the sodium chlorite and citric acid in the first container 3, producing chlorine dioxide, sodium citrate, sodium _chloride , and water. This reaction is expressed as " _15NaClO2 + 4C( _OH )( _CH2COOH ) _2COOH → _12ClO2 + _4C6H5Na3O7 + 3NaCl _{+ 2H2O} ".

Only the chlorine dioxide permeates the wall of the first container 3 and dissolves in the water 11 stored in the second container 5.

The opening 9 of the second container 5 of the gas generating device 1 shown in FIG. 1 is fitted with a lid 23. The lid 23 is composed of a lid body 25 and a gas permeable portion (gas permeable membrane) 27. The gas permeable membrane 27 is designed to allow gas to pass through but block liquid.

This allows only the chlorine dioxide that was dissolved in the dissolved liquid 11 and that has emerged as a gas from the dissolved liquid 11 to pass through the gas permeable membrane 27 and exit the gas generator 1, and prevents the dissolved liquid 11 from spilling outside the gas generator 1 even if the gas generator 1 is accidentally tipped over.

Next, we will explain how to use the gas generator 1.

In the initial state, the lid 23 is removed from the second container 5, and the first container 3 is outside the second container 5. The third container 13 and the second drug 21 are stored in the internal space 7 of the first container 3, and the first drug 17 is stored in the internal space 15 of the third container 13.

In the above initial state, a force is applied to the first container 3 to elastically deform the first container 3 and destroy the third container 13, after which the first container 3 is immediately placed into the dissolved liquid 11 in the second container 5 and the lid 23 is placed on the second container 5.

As a result, only the chlorine dioxide generated by the chemical reaction in the first container 3 passes through the wall of the first container 3 and dissolves in the dissolved liquid 11 in the second container 5. After this, the chlorine dioxide dissolved in the dissolved liquid 11 is gradually released from the dissolved liquid 11 and passes through the gas permeable membrane 27 of the lid 23 to the outside of the gas generator 1.

The gas generating device 1 includes a first container 3 that contains multiple types of substances in an internal space 7 and allows only the gas generated by the chemical reaction of the multiple types of substances to pass through and be released to the outside, and a second container 5 that has an opening 9 and contains the first container 3 and a dissolved liquid 11 in which the gas released from the first container 3 is dissolved.

As a result, only the chlorine dioxide coming out of the first container 3 is dissolved in the dissolved liquid 11 in the second container 5. Then, by taking out the dissolved liquid 11 containing only chlorine dioxide from the opening 9 of the second container 5, it is possible to obtain only the required chlorine dioxide.

In addition, since chlorine dioxide is dissolved in the dissolved liquid 11, the dispersion speed of chlorine dioxide is slowed down, making chlorine dioxide easier to use. For example, if the dissolved liquid 11 containing only chlorine dioxide is sprayed in the form of a mist onto a table to be sterilized, the chlorine dioxide is gradually released from the dissolved liquid 11, and the sterilizing effect can be sustained.

In addition, the gas generator 1 is configured so that when the third container 13 is destroyed, the first chemical 17 and the second chemical 21 undergo a chemical reaction in the first container 3, generating chlorine dioxide, so that chlorine dioxide can be obtained when a necessary situation arises, that is, in response to an appropriate demand.

In the gas generating device 1, as shown in FIG. 2, a relief valve 31 may be installed at the opening 9 of the second container 5 so as to close the opening 9 of the second container 5. Furthermore, instead of the relief valve 31, a spray head (not shown) or a throttle valve (not shown) may be installed.

By installing the relief valve 31, when the pressure inside the second container 5 reaches or exceeds a predetermined pressure, the chlorine dioxide inside the second container 5 passes through the relief valve 31 and comes out of the second container 5. In addition, the relief valve 31 is capable of changing the predetermined pressure and maintaining the changed state.

In addition, by installing the spray head, the dissolved liquid (dissolved liquid containing dissolved chlorine dioxide) 11 stored in the second container 5 is sprayed, for example in the form of a mist, from the nozzle of the spray head to the outside of the second container 5 by simply pulling the lever of the spray head without using any power source such as electricity or compressed air.

In addition, a throttle valve (flow rate control valve) is installed so that the chlorine dioxide in the second container 5 passes through the throttle valve and slowly comes out of the second container 5. The throttle valve can also change the flow rate of the chlorine dioxide passing through the throttle valve and maintain this changed state.

As shown in FIG. 2, the gas generator 1 may be provided with a temperature adjustment unit 29 that adjusts the temperature of the dissolved liquid 11 in the second container 5 (the temperature of the gas generator 1). The temperature adjustment unit 29 includes, for example, a Peltier element or a heater, and covers the second container 5. The temperature adjustment unit 29 is capable of setting and changing the temperature.

According to the gas generator 1 shown in FIG. 2, a relief valve 31, a spray head, or a throttle valve is installed at the opening of the second container 5, so that the dissolved liquid 11 in the second container 5 containing the dissolved chlorine dioxide coming out of the first container 3 can be taken out in an appropriate form, making it easy to use.

For example, by using a spray head, the dissolved liquid 11 containing dissolved chlorine dioxide can be sprayed uniformly onto the object to be sterilized. In addition, by using a relief valve 31 or a throttle valve, the amount of chlorine dioxide (chlorine dioxide gas emerging from the dissolved liquid 11) discharged from the second container 5 can be appropriately controlled.

The gas generator 1 shown in FIG. 2 has a temperature control unit 29 that adjusts the temperature of the dissolved liquid 11 in the second container 5, so the permeation rate of chlorine dioxide (the amount of chlorine dioxide that permeates the flesh of the first container 3 per unit time) can be adjusted. That is, the permeation rate of chlorine dioxide can be increased by increasing the temperature, and decreased by decreasing the temperature. In addition, the amount of chlorine dioxide produced in the first container 3 and the amount of chlorine dioxide discharged from the second container 5 (chlorine dioxide gas coming out of the dissolved liquid 11) can be appropriately controlled.

The permeation rate of chlorine dioxide can be adjusted by appropriately changing the material of the first container 3.

However, the gas generating device 1 may be a device that generates gas without chemical reaction. This gas generating device 1 is also configured with a first container 3 and a second container 5.

However, the first container 3 contains a substance (e.g., a fragrance) that generates a specific gas (e.g., a fragrance component) in the internal space 7, and is designed to allow only the specific gas generated by this substance to pass through and be released to the outside.

The second container 5 has an opening 9 and contains the first container 3 and a dissolved liquid 11 that dissolves the specified gas released from the first container 3.

This allows you to obtain only the fragrance components you need, just like with chlorine dioxide, and also slows down the rate at which the fragrance components disperse, making it easier to use.

Next, the gas generating device 51 according to the reference example will be described with reference to FIG. 3.

The gas generating device 51 shown in FIG. 3 is configured with a first container 53 and a second container 55. The first container 53 is configured similarly to the second container 5 shown in FIG. 1. The second container 55 is configured similarly to the third container 13 shown in FIG. 1.

The second container 55 contains a mixture of citric acid powder and baking soda (sodium bicarbonate) powder. The space inside the first container 53 and outside the second container 55 contains sodium chlorite liquid (e.g., an aqueous solution of sodium chlorite).

When the second container 55 is destroyed, the mixture of citric acid powder and baking soda powder comes into contact with the sodium chlorite liquid, causing a chemical reaction that produces chlorine dioxide and other substances.

The chlorine dioxide produced passes through a constriction (e.g., a choke) 57 formed at the upper end of the first container 53 and exits the second container 55.

The mixture of citric acid powder and baking soda powder may be replaced with sodium chlorite liquid. That is, sodium chlorite liquid may be contained inside the second container 55, and the mixture of citric acid powder and baking soda powder may be contained in the space inside the first container 53 and outside the second container 55.

In addition, instead of a mixture of citric acid powder and baking soda powder, a mixture of citric acid tablets and baking soda tablets may be used.

Furthermore, citric acid (aqueous solution of citric acid), baking soda liquid (e.g., an aqueous solution of baking soda), and sodium hypochlorite liquid (e.g., an aqueous solution of sodium hypochlorite) may be combined to cause a chemical reaction and produce chlorine dioxide, etc. In this case, a third container (not shown) similar to the second container 55 is provided within the first container 53.

That is, citric acid (aqueous solution of citric acid) may be contained in the second container 55, baking soda liquid (e.g., an aqueous solution of baking soda) may be contained in the third container, and sodium chlorite liquid (e.g., an aqueous solution of sodium chlorite) may be contained in the first container 53 outside the second container 55 and the third container.

Then, when the second container 55 and the third container are destroyed, a chemical reaction may occur to generate chlorine dioxide.

Even in this case, the citric acid solution, the baking soda solution, and the sodium chlorite solution contained in the second container 55, the third container, and the first container 53, and in the space outside the second container 55 and the third container, may be replaced as appropriate.

Next, the gas generating device 71 according to the reference example will be described with reference to FIG.

The gas generator 71 shown in FIG. 4 differs from the gas generator 51 shown in FIG. 3 in that the amount of throttling can be changed by the throttling section 57 and that the chlorine dioxide flow path 73 is elongated, but in other respects it is configured in the same way as the gas generator 51 shown in FIG. 3.

To explain further, the first container 53 of the gas generating device 71 shown in FIG. 4 comprises a container body 75 and a flow path forming section 77. The upper end of the container body 75 is closed. The second container 55 and the like are housed inside the container body 75.

The flow path 73 for chlorine dioxide is formed by the flow path forming portion 77. The chlorine dioxide flow path 73 is elongated in the vertical direction, and the lower end of the chlorine dioxide flow path 73 and the lower end of the container body portion 75 are connected to each other. When a chemical reaction is occurring, the position of the liquid level in the container body portion 75 and the position of the liquid level in the chlorine dioxide flow path 73 are the same. The constriction portion 57 is installed at the upper end of the chlorine dioxide flow path 73.

In the throttle section 57, turning the knob 79 changes the gap between the valve body 81 and the opening at the upper end of the flow path 73, thereby changing the amount of throttling.

The gas generating device 71 according to the reference example shown in Figures 3 and 4 may be the gas generating device 1 according to a modified example of the present invention. In this case, the first container 53 is the second container 5, and the second container 55 is the first container 3. The third container 13 is stored inside the first container 3.

REFERENCE SIGNS LIST 1 Gas generator 3 First container 5 Second container 7 Internal space 9 Opening 11 Dissolved liquid 13 Third container 15 Internal space 17 First chemical 19 Outer space 21 Second chemical 29 Temperature control section 31 Relief valve

Claims (5)

a first container that contains a plurality of kinds of substances in an internal space and that allows gas generated by a chemical reaction of the plurality of kinds of substances to pass therethrough and is released to the outside;
The first container is adapted to be accommodated in a second container having an opening and accommodating a dissolved liquid in which the gas released from the first container is dissolved;
The dissolved liquid is water,
a third container housed in an internal space of the first container;
A first drug is accommodated in the internal space of the third container, and a second drug is accommodated in the internal space of the first container and in a space outside the internal space of the third container;
The third container is configured to break, so that the first chemical and the second chemical react with each other in the first container to generate the gas,
the first agent is sodium chlorite, the second agent is citric acid, and the gas is chlorine dioxide;
A gas generating device characterized in that the first container is made of a synthetic resin that is elastic and allows only gas to pass therethrough, and the synthetic resin is polypropylene, polyethylene, or silicone, or a mixture of at least two of the materials polypropylene, polyethylene, and silicone . 2. The gas generating device according to claim 1,
The sodium chlorite is contained in the internal space of the third container in the form of an aqueous solution, and the citric acid is contained in the internal space of the first container in the form of a powder or tablet, in a space outside the internal space of the third container;
Alternatively, the sodium chlorite is contained in the internal space of the third container in the form of a powder or tablet, and the citric acid is contained in the form of an aqueous solution in the internal space of the first container, which is a space outside the internal space of the third container;
Alternatively, the sodium chlorite is contained in the internal space of the third container in the form of an aqueous solution, and the citric acid is contained in the internal space of the first container, which is a space outside the internal space of the third container, in the form of an aqueous solution . a first container that contains a plurality of kinds of substances in an internal space and that allows gas generated by a chemical reaction of the plurality of kinds of substances to pass therethrough and is released to the outside;
The first container is adapted to be accommodated in a second container having an opening and accommodating a dissolved liquid in which the gas released from the first container is dissolved;
The dissolved liquid is water,
a third container housed in an internal space of the first container;
A first drug is accommodated in the internal space of the third container, and a second drug is accommodated in the internal space of the first container and in a space outside the internal space of the third container;
The third container is configured to break, so that the first chemical and the second chemical react with each other in the first container to generate the gas,
the first agent is citric acid, the second agent is sodium chlorite, and the gas is chlorine dioxide;
A gas generating device characterized in that the first container is made of a synthetic resin that is elastic and allows only gas to pass therethrough, and the synthetic resin is polypropylene, polyethylene, or silicone, or a mixture of at least two of the materials polypropylene, polyethylene, and silicone . 4. The gas generating device according to claim 3,
The citric acid is contained in the internal space of the third container in the form of an aqueous solution, and the sodium chlorite is contained in the form of a powder or tablet in the internal space of the first container, which is a space outside the internal space of the third container;
Alternatively, the citric acid is contained in the internal space of the third container in the form of a powder or tablet, and the sodium chlorite is contained in the form of an aqueous solution in the internal space of the first container, which is a space outside the internal space of the third container;
Alternatively, the citric acid is contained in the internal space of the third container in the form of an aqueous solution, and the sodium chlorite is contained in the internal space of the first container, which is a space outside the internal space of the third container, in the form of an aqueous solution . The gas generating device according to any one of claims 1 to 4,
A gas generating device characterized in that a lid is placed on the opening of the first container, the lid being composed of a lid body and a gas-permeable membrane, the gas-permeable membrane being configured to allow gas to pass through but block liquid .

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