JP2004033497A - Carbon dioxide sustained-release device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a carbon dioxide sustained-release device equipped with a container, a lid for hermetically closing the container, a flow channel opened in the container at one end thereof and opened to the outside of the container at the other end thereof, an on-off valve for opening and closing the flow channel, and a pressure means for pressurizing the hermetically closed container which is constituted of the container and the lid with gas and constituted so as to efficiently supply generated carbon dioxide to a local part of a human body to impart a blood circulation improvement effect to the patient. <P>SOLUTION: This carbon dioxide sustained-release device comprises the water storage container and the lid for hermetically closing the container, and a foaming chemical agent generating carbon dioxide is charged in the water stored in the hermetically closed container and a mechanism for gradually releasing carbon dioxide through water and a gas-liquid separation film is provided. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention utilizes the effects of carbon dioxide gas such as vasodilatory action and blood viscosity lowering action,
The present invention relates to a carbon dioxide sustained release device that gives a human body a blood circulation promoting effect by exposing a human body to carbon dioxide gas.
[0002]
[Prior art]
A carbon dioxide gas generator that is attached to a part of the human body surface and supplies carbon dioxide to the enclosed space through a simple cover and a flow passage that forms a closed space together with the human body surface, Japanese Patent Application Laid-Open No. 7-171189, which discloses a mist generator for supplying a mist to a closed space and injecting carbon dioxide generated by the carbon dioxide generator to a local part of a human body to promote blood circulation. Is disclosed.
In addition, the reaction vessel and the container for storing the liquid and a conduit connecting the two, is configured to store one component of the carbon dioxide gas generation source in a liquid state reaction container, the other component is stored in the container, Japanese Patent Application Laid-Open No. 8-143308 discloses a gas supply device for supplying carbon dioxide generated when both are mixed.
[0003]
[Problems to be solved by the invention]
Each of the gas supply apparatuses disclosed in JP-A-7-171189 and JP-A-8-143308 injects and supplies the generated high-concentration carbon dioxide gas outside the apparatus. In fact, when carbon dioxide is percutaneously absorbed into the human skin, if a high concentration of carbon dioxide is filled around the human skin, the rate of carbon dioxide absorption into the skin is constant. However, since these gas supply devices are not provided with a mechanism for controlling the injection amount of the generated carbon dioxide gas, the carbon dioxide gas is consumed uselessly, and it is difficult to efficiently absorb the carbon dioxide gas through the skin. The present invention has been made in view of the above problems, and aims to provide a mechanism for gradually releasing generated gas, to efficiently supply carbon dioxide to a local part of the human body, and to have a sufficient blood circulation promoting effect. It is an object of the present invention to provide a carbon dioxide sustained-release device capable of providing the following.
[0004]
[Means for Solving the Problems and Functions / Effects]
In order to solve the above problem, a container, a lid for sealing the container, a flow path having one end opened inside the container and the other end opened outside the container, an on-off valve for opening and closing the flow path, the container and the lid And a pressurizing means for pressurizing the inside of the closed container with a gas, wherein the water is sealed with a pair of gas-liquid separation membranes that allow only gas to pass through the flow path. A room was set up.
Here, the gas-liquid separation membrane through which only gas can pass is a hollow fiber, activated carbon, polytetrafluoroethylene, or polyvinylidene fluoride, polyethylene, polypropylene or the like subjected to a water-repellent treatment.
[0005]
In the carbon dioxide gas sustained release device according to the present invention, as a mechanism for gradually releasing carbon dioxide gas, a property that the solubility of carbon dioxide gas in a liquid varies depending on pressure is used. Generally, the solubility of carbon dioxide gas in water increases as the pressure increases. Accordingly, the pressurized carbon dioxide gas in the container is dissolved under pressure into the water in the water-filled chamber via the gas-liquid separation membrane inside the container in the flow path. Here, since the pressure outside the container is at atmospheric pressure, the carbon dioxide gas dissolved under pressure in the water in the water filling chamber is subjected to pressure and atmospheric pressure from the gas-liquid separation film provided outside the container. It is gradually released by the lower solubility difference. Utilizing this property, high-concentration gas in the container can be released at once, and the required minimum amount can be released gradually, without wasteful consumption of carbon dioxide gas. Gas can be supplied efficiently, and a sufficient blood circulation promoting effect can be obtained.
[0006]
In a preferred aspect of the present invention, a container, a lid for sealing the container, a flow path having one end opened inside the container and the other end opened outside the container, an on-off valve for opening and closing the flow path, the container and the lid In a carbon dioxide gas sustained release device comprising a pressurizing means for pressurizing and dissolving gas in stored water stored in a closed container constituted by a gas-liquid separation membrane that allows only gas to pass through the flow path, A portion of the flow path extending in the container had a flexible tube, and a weight was provided near a distal end of the tube forming the one end of the flow path.
The provision of the weight near the distal end of the tube here means that the weight may form the side surface near the distal end of the tube instead of the distal end of the tube if the distal end of the tube forming the one end of the flow path is submerged. Alternatively, the tube itself may have the function of a weight by forming the tube with a material having a specific gravity greater than that of water. When the weight is formed at the forefront of the tube, the weight is composed of a porous ceramic, a porous material such as a high specific gravity resin sintered body, a combination of a resin sintered body and a heavy material, a fine mesh, etc. You.
[0007]
The carbon dioxide gas sustained release device according to the present invention is a carbon dioxide gas sustained release device in which pressurized carbon dioxide gas and stored water are sealed in a container. Similar to the first aspect of the present invention, the mechanism for gradually releasing carbon dioxide gas by utilizing the difference in solubility of carbon dioxide gas in a liquid is used. Since the weight is provided near the distal end of the tube forming the one end of the flow path, the flow path opened in the container is always submerged in the water stored in the container. For this reason, even if the carbon dioxide sustained release device is used in any direction, the pressurized carbon dioxide gas in the container is not ejected out of the container at once because the flow path that opens in the container is submerged, A user-friendly carbon dioxide sustained-release device can be provided.
[0008]
In a preferred aspect of the present invention, a container, a lid for sealing the container, a flow path having one end opened inside the container and the other end opened outside the container, an on-off valve for opening and closing the flow path, the container and the lid And a pressurizing means for pressurizing and dissolving gas in stored water stored in an airtight container constituted by: a carbon dioxide sustained release device, wherein the amount of water flowing through the flow path in the flow path is automatically adjusted to be substantially constant. A constant flow valve, a tank that communicates with the container through the flow path, and stores the stored water discharged from the container again, and a ventilation flow path that has one end opened inside the tank and the other end opened outside the tank. .
[0009]
In the carbon dioxide sustained release apparatus according to the present invention, the pressurized stored water in the container is sent to the tank via the constant flow valve. At this time, only the stored water discharged from the constant flow valve is reduced to the atmospheric pressure in the tank. Here, only the carbon dioxide gas which has been decompressed and cannot be dissolved is discharged to the outside of the container. Therefore, since the amount of gas to be discharged can be adjusted by setting the constant flow valve and the pressure in the container, the gas can be stably released at a user's desired amount for a long period of time in a stable manner.
[0010]
In a preferred aspect of the present invention, a portion of the ventilation channel extending in the tank has a flexible tube, and a floating body is attached near a tip of a tube forming the one end of the ventilation channel. .
[0011]
The carbon dioxide sustained release device according to the present invention discharges only the carbon dioxide generated in the tank. Therefore, when the water stored in the tank enters the ventilation flow path, the water accumulates in the ventilation flow path, which makes it difficult to discharge carbon dioxide gas, and also changes the sustained release amount of carbon dioxide gas. Here, a portion of the ventilation channel extending in the tank has a flexible tube, and one end of the tube is submerged because the floating body is attached near the tip of the tube forming one end of the ventilation channel. Can be prevented, and the stored water does not enter the ventilation flow path, so that the carbon dioxide gas can be reliably discharged at a constant flow rate.
[0012]
In a preferred aspect of the present invention, the on-off valve and the constant flow valve are provided in the flow path, and the on-off valve is provided downstream of the constant flow valve.
In the carbon dioxide sustained release apparatus according to the present invention, the supplied carbon dioxide is generated by reducing the pressure of the stored water. In addition, at the time of water discharge, the on-off valve and the constant flow valve are the main pressure reducing sections. Here, when the on-off valve is located on the upstream side of the constant flow valve, the carbon dioxide gas and the stored water generated near the on-off valve due to the pressure reducing effect pass through the constant flow valve. When a mixture of carbon dioxide and stored water passes through the constant flow valve, the constant flow function of the constant flow valve does not work well due to the influence of bubbles of the carbon dioxide gas. Here, by providing the on-off valve on the downstream side of the constant flow valve, the stored water mixed with carbon dioxide gas does not flow through the constant flow valve. it can.
[0013]
In a preferred aspect of the present invention, a gas-liquid separation membrane is provided at the end of the flow path that is open outside the container, and a cover that covers the gas-liquid separation membrane is provided. Adjustable.
In the carbon dioxide gas sustained release device according to the present invention, the carbon dioxide gas is discharged through the gas-liquid separation membrane in contact with the water in the water filling chamber and the water in the container. It changes depending on the area of the passing membrane. Therefore, by providing a cover for covering the gas-liquid separation membrane, and by adjusting the position of the cover to adjust the gas passage membrane area, it is possible to control the sustained release amount of the gas, so that the user can control the gas in a desired mode. Can be supplied.
[0014]
In a preferred aspect of the present invention, a membrane protective plate is provided on the gas-liquid separation membrane on the downstream side of the flow path and the ventilation flow path.
In the carbon dioxide sustained release device according to the present invention, the pressurized carbon dioxide is gradually released through the gas and liquid separation membrane with the water and the stored water, and the gas and liquid separation membrane corresponds to the pressure in the container. It takes weight. Here, since the membrane protection plate was provided on the downstream side of the flow path and the ventilation flow path of the gas-liquid separation membrane, even if pressure was applied to the gas-liquid separation membrane, the membrane was not damaged, so the pressure was increased at once. It is possible to safely and stably supply the carbon dioxide gas without releasing the carbon dioxide gas or the stored water.
[0015]
In a preferred aspect of the present invention, a dish-shaped gas holding portion is provided at the other end of the flow path and the ventilation flow path.
Normally, even when a device that directly injects high-concentration carbon dioxide gas onto the skin is used, it is difficult to efficiently absorb carbon dioxide gas through the skin because the periphery of the skin is open. By providing a dish-shaped gas holding portion at the other end of the flow path and the ventilation flow path, the supplied carbon dioxide gas fills the gas holding portion, so that the concentration of carbon dioxide gas in the vicinity of the affected part where blood circulation in the gas holding portion is desired to be promoted Dramatically higher. Therefore, the blood circulation of the affected part can be efficiently promoted with a small amount of sustained release of carbon dioxide gas.
[0016]
In a preferred aspect of the present invention, the tank is mounted on a local portion of the surface of the human body, has a shape that forms a closed space together with the surface of the human body, and is formed of a member having higher thermal conductivity than the container and the lid. .
In general, apart from the method of percutaneously absorbing carbon dioxide, a method of promoting blood circulation by warming an affected part to expand blood, lower blood viscosity, and the like is known. In the carbon dioxide sustained release device according to the present invention, the tank is configured to be attached to a local portion of the surface of the human body, and is made of a member having a high thermal conductivity. Heat is conducted, and the blood circulation promotion effect can be further enhanced by the synergistic effect of the blood circulation promotion effect by carbon dioxide gas and the blood circulation promotion effect by warm heat.
[0017]
In a preferred aspect of the present invention, a plurality of flexible projections are provided near the other ends of the flow path and the ventilation flow path.
As a result, the affected part is stimulated by the flexible projection, and therefore the blood circulation can be more efficiently promoted by the synergistic effect of the blood circulation promoting effect by percutaneous absorption of carbon dioxide and the blood circulation promoting effect by the stimulation of the protrusion. .
[0018]
In a preferred aspect of the present invention, the pressurizing means is a foaming agent that reacts with stored water to generate gas.
The sustained release amount of carbon dioxide gas of the carbon dioxide sustained release device according to claims 2 to 10 is determined mainly by the gas passing area of the gas-liquid separation membrane and the pressure in the container. By using a foaming agent as the pressurizing means in the container, the pressure in the container can be easily adjusted by changing the amount of the foaming agent to be charged, so that the controlled release amount of carbon dioxide can be easily adjusted. It becomes possible. Therefore, the user can inject the carbon dioxide gas into the affected part in a preferred mode. Also, unlike gas cylinders, it is only necessary to pressurize the inside of the container immediately before using the device.Therefore, there is no risk of the container etc. exploding due to impact, etc. A gas sustained release device can be provided.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the embodiments shown in the drawings. FIG. 1 is a sectional view showing a first embodiment of a carbon dioxide sustained release device of the present invention, and FIG. FIG. 3 is a cross-sectional view showing a third embodiment of the present invention, and FIG. 4 is a cross-sectional view showing a fourth embodiment of the present invention. FIG. 5 is a sectional view of a nozzle tip according to a fourth embodiment of the present invention, FIG. 6 is a front view of a nozzle tip according to a fourth embodiment of the present invention, and FIG. 7 is an embodiment of the present invention. It is a perspective view of the tip part of the nozzle with which the carbon dioxide gas sustained release device is provided.
[0020]
FIG. 1 illustrates a carbon dioxide gas sustained release apparatus according to a first embodiment of the present invention.
As shown in FIG. 1, the local body gas device according to the present embodiment includes a container 1 and a lid 2 that forms a closed space in cooperation with the container 1. Filled with carbon dioxide. An opening / closing valve 4 for opening / closing a portion of the flow passage 3 extending inside the lid 2, the opening / closing valve 4 having one end opening inside the container 1 and the other end opening outside the lid 2; An operation switch 5 for manually operating the cover 4 is attached to the lid 2. In addition, a water-filled chamber 7 is provided in the flow path 3 and partitioned by a pair of gas-liquid separation membranes 6 through which only gas can pass, and water is filled in the water-filled chamber 7. Further, a membrane protection plate 8 for preventing breakage of the gas-liquid separation membrane 6 is provided downstream of the flow path 3 of the gas-liquid separation membrane 6, and a dish-shaped gas holding portion 9 is provided at the other end of the flow path 3. .
[0021]
Next, the operation of the carbon dioxide gas sustained release device will be described.
In the carbon dioxide sustained release apparatus according to the present invention, carbon dioxide is pressurized and filled in a closed container formed by the lid 2 and the container 1. The user points the gas holding unit 9 to a desired body part and presses the operation switch 5 to open the on-off valve 4. Then, the pressurized and filled carbon dioxide gas flows into the flow path 3, passes through the gas-liquid separation membrane 6 provided in the flow path 3, and is dissolved in the water stored in the water sealing chamber 7. Here, it is known that the solubility of carbon dioxide gas in water is determined by the pressure on water, and the higher the pressure, the higher the solubility in water. Therefore, the amount of carbon dioxide gas corresponding to the gas pressure of the carbon dioxide gas filled in the closed vessel via the gas-liquid separation membrane 6 disposed on the upstream side of the water sealing chamber 7 is added to the water in the water sealing chamber 7. Dissolves. Further, the downstream side of the water filling chamber is open to the atmosphere via the flow path 3, the on-off valve 4, and the gas holding unit 9, and the solubility of carbon dioxide gas in water is lower at atmospheric pressure than under pressure of the container than under pressure of the container. Has become. Therefore, carbon dioxide gas that cannot be completely dissolved under the atmospheric pressure corresponding to the pressure difference between the pressure in the closed vessel and the atmospheric pressure is gradually released from the gas-liquid separation membrane 6 disposed downstream of the water filling chamber 7. In this way, by utilizing the difference in the solubility of carbon dioxide in water according to the pressure, the required minimum amount is gradually released without jetting a high-concentration gas in the container at once, and the carbon dioxide gas is wasted. Can be obtained, and the effect of promoting blood circulation in the body part can be obtained.
Further, since the gas holding portion 9 is provided at the opening outside the container of the flow path 3, the gradually released carbon dioxide gas fills the inside of the gas holding portion. Therefore, the concentration of carbon dioxide in the vicinity of the body part where blood circulation is desired to be promoted in the gas holding part can be dramatically increased, and the blood circulation in the body part can be promoted more efficiently with a small sustained release amount of carbon dioxide gas.
Here, in the carbon dioxide gas sustained-release device according to the present invention, the pressurized carbon dioxide gas is gradually released through the gas-liquid separation membrane 6 with water and stored water. However, since the membrane protection plate 8 is provided on the downstream side of the flow path 3 of the gas-liquid separation membrane 6, the gas-liquid separation membrane 6 may be damaged by the pressure in the container 1. And pressurized carbon dioxide can be supplied safely and at a constant flow rate.
[0022]
FIG. 2 illustrates a carbon dioxide sustained release apparatus according to a second embodiment of the present invention.
As shown in FIG. 2, the carbon dioxide sustained release apparatus according to the present embodiment includes a container 1 for storing water and a lid 2 forming a closed space in cooperation with the container 1. An opening / closing valve 4 for opening / closing a portion of the flow passage 3 extending inside the lid 2, the opening / closing valve 4 having one end opening inside the container 1 and the other end opening outside the lid 2; An operation switch 5 for manually operating the cover 4 is attached to the lid 2. In addition, a gas-liquid separation membrane 6 that allows only gas to pass through the flow path 3, and a membrane protection plate 8 that prevents damage to the gas-liquid separation membrane 6 is provided downstream of the flow path 3 of the gas-liquid separation membrane 6. Has been. Further, a portion of the flow path 3 extending inside the container 1 has a flexible tube 10. In the vicinity of one end of the tube 10 forming the one end of the flow path 3, a porous body such as a porous ceramic or a high-density resin sintered body, a combined body of a resin sintered body and a heavy material, a fine wire mesh, or the like. Is attached. The other end of the tube 10 is fixed to the lid 2 and communicates with a portion of the water passage 3 extending inside the lid 2.
[0023]
Next, the operation of the carbon dioxide gas sustained release device will be described.
The user removes the lid 2 from the container 1, fills the container 1 with water, and then puts a foaming agent for generating gas into the container 1, covers the container 1 with the lid 2, and seals the container 1. The foaming agent reacts with water to generate carbon dioxide. The carbon dioxide gas joins the air layer in the container 1, increases the pressure of the air layer, pressurizes the inside of the container 1, and dissolves in the water in the container 1. When the carbon dioxide is sufficiently dissolved in the water in the container 1, the user directs the tip of the nozzle to a desired body part and presses the operation switch 5 to open the on-off valve 4. Then, the container is opened to the atmosphere by opening the on-off valve 4. Here, under atmospheric pressure, the solubility of carbon dioxide gas in water is lower than under container pressurization. For this reason, the carbon dioxide gas that cannot be completely dissolved under the atmospheric pressure corresponding to the pressure difference between the pressure in the container 1 and the atmospheric pressure via the gas-liquid separation membrane 6 disposed in the flow path 3 is removed from the water in the container 1. Sustained release. In this way, utilizing the difference in the solubility of carbon dioxide in water according to the pressure, the required minimum amount is slowly released without blowing out the carbon dioxide in the container at once, and the effect of promoting blood circulation in the body part Can be obtained.
In addition, a portion of the flow path 3 extending inside the container 1 has a flexible tube 10, and a weight 11 is provided near the tip of the tube 10 forming the one end of the flow path 3, so that The channel 3 which is opened at the time is always immersed in the water in the container 1. Therefore, no matter which direction the carbon dioxide sustained release device is used, the flow path 3 opened in the container 1 is submerged, so that the pressurized carbon dioxide in the container is blown out of the container 1 at a time. Therefore, it is possible to provide a carbon dioxide sustained release device that is easy to use for the user.
[0024]
FIG. 3 illustrates a carbon dioxide gas sustained release apparatus according to a third embodiment of the present invention.
As shown in FIG. 3, the carbon dioxide sustained release apparatus according to the present embodiment includes a container 1 for storing water and a foaming agent, and a lid 2 forming a closed space in cooperation with the container 1. Also, in the lid 2
A flow path 3 is provided, one end of which is open in the container 1 and the other end of which is open in a tank 12 for storing the stored water discharged from the container again. The on-off valve 4 is provided downstream of the constant flow valve 13. In addition, a vent passage 14 is provided, one end of which is open in the tank 12 and the other end is open outside of the tank 12, and a portion of the vent passage 14 extending in the tank 12 has a flexible tube. A floating body 15 is mounted near one end of a tube forming the one end of the passage 14. Here, the tank 12 is mounted on a local portion of the surface of the human body, has a shape that forms a closed space together with the surface of the human body, and is formed of a member having higher thermal conductivity than the container 1 and the lid 2.
[0025]
Next, the operation of the carbon dioxide gas sustained release device will be described.
The user removes the lid 2 from the container 1, fills the container 1 with water, and then puts a foaming agent for generating gas into the container 1, covers the container 1 with the lid 2, and seals the container 1. Then, the foaming agent reacts with water to generate carbon dioxide gas. The carbon dioxide gas dissolves in the water in the container 1 and joins the air layer in the container 1 to increase the pressure of the air layer and pressurize the inside of the container 1. When a sufficient pressure is obtained inside the container 1, the tank 12 is pressed against a desired body part, and the operation switch 5 is pressed to open the on-off valve 4. The pressurized water flows into the flow path 3, passes through the constant flow valve 13, is adjusted to a substantially constant flow rate, and flows into the tank 12. Here, since the inside of the tank 12 communicates with the outside of the tank 12 through the ventilation passage 14, the water in the tank 12 is decompressed and gas is generated. This gas is gradually released to a desired body part through the ventilation channel 14.
[0026]
Here, only the water discharged from the constant flow valve 13 is depressurized in the tank 12, and only the gas generated from the depressurized water is discharged. To supply the gas. In addition, since the floating body 15 is attached near one end of the tube extending in the tank 12 forming the ventilation channel 14, the tip of the ventilation channel 14 in the tank 12 is surely not submerged in water. The generated gas can be discharged.
Further, in the carbon dioxide gas sustained-release device according to the present invention, the supplied carbon dioxide gas is generated by reducing the pressure of the water in the container 1. The on-off valve 4 and the constant flow valve 13 serve as a main pressure reducing unit, and bubbles of carbon dioxide gas are generated near the on-off valve 4 and the constant flow valve 13. Here, when the on-off valve 4 is on the upstream side of the constant flow valve 13, carbon dioxide gas and water generated near the on-off valve 4 due to the pressure reducing effect pass through the constant flow valve 13. When a mixture of carbon dioxide and water passes through the constant flow valve 13, the constant flow function of the constant flow valve 13 does not work well due to the influence of bubbles of the carbon dioxide gas. In the carbon dioxide gas sustained release device according to the present invention, the on-off valve 4 is provided on the downstream side of the constant flow valve 13, so that the water mixed with carbon dioxide gas does not flow through the constant flow valve 13, Carbon dioxide gas can be supplied at a flow rate.
In addition to the method of percutaneously absorbing carbon dioxide gas, a method of promoting blood circulation by heating a diseased part to expand blood or lower the viscosity of blood is generally known. In the carbon dioxide sustained release device according to the present invention, the tank is configured to be attached to a local portion of the surface of the human body, and is made of a member having a high thermal conductivity. Heat is conducted, and the blood circulation promotion effect can be further enhanced by the synergistic effect of the blood circulation promotion effect by carbon dioxide gas and the blood circulation promotion effect by warm heat.
[0027]
FIG. 4 illustrates a carbon dioxide gas sustained release apparatus according to a fourth embodiment of the present invention.
As shown in FIG. 4, the carbon dioxide sustained release device according to the present embodiment includes a container 1 for storing water and a foaming agent, and a lid 2 forming a closed space in cooperation with the container 1. The lid includes an on-off valve 4 and an operation switch 5, and a flow path 3 having one end opened inside the container 1 and the other end opened outside the lid 2. The flow path 3 has a portion extending outside the container 1, and the extending portion includes a flexible elastic member 16 and a nozzle 17. As shown in FIGS. 5 and 6, a gas-liquid separation film 6 and a cover 18 that covers the gas-liquid separation film 6 are provided at the tip of the nozzle 17. The cover 18 is provided with a cover opening 19 and can rotate around a screw 20 provided for connection with the tip of the nozzle 17. Thus, by rotating the cover 18, the opening area 21 of the gas-liquid separation film 6 can be freely adjusted.
[0028]
Next, the operation of the carbon dioxide gas sustained release device will be described.
The user removes the lid 2 from the container 1, fills the container 1 with water, and then puts a foaming agent for generating gas into the container 1, covers the container 1 with the lid 2, and seals the container. Then, the foaming agent reacts with water to generate carbon dioxide gas. The generated carbon dioxide gas dissolves in the water in the container 1 and joins the air layer in the container 1 to increase the pressure of the air layer and pressurize the inside of the container 1. Next, the cover 18 at the tip of the nozzle 17 is rotated to determine the opening area 21 of the gas-liquid separation film 6. When sufficient pressure is obtained inside the container 1, the user directs the cover opening 19 at the tip of the nozzle 17 to a desired body part, and presses the operation switch 5 to open the on-off valve 4. Then, the pressurized water flows into the gas-liquid separation membrane 6 in the nozzle 17 via the flow path 3. Here, the opening area of the gas-liquid separation film 6 determined by the cover 18 is a carbon dioxide gas that cannot be dissolved under the atmospheric pressure corresponding to the pressure difference between the pressure in the container 1 and the atmospheric pressure via the gas-liquid separation film 6. At 21, it is released from the cover opening 19. Here, it has been described above that the carbon dioxide gas is gradually released by the pressure in the container 1 and the atmospheric pressure difference pressure. However, since the carbon dioxide gas is gradually released via water, It is determined by the area of the gas-liquid separation membrane in contact. The carbon dioxide sustained release apparatus according to the present invention is provided with a cover 18 for covering the gas-liquid separation film 6 provided at the tip of the nozzle 17 as shown in FIGS. Since the passage membrane area can be adjusted, it is possible to provide an easy-to-use carbon dioxide gas sustained release device that allows the user to freely control the gas supply amount.
[0029]
As shown in FIG. 7, a plurality of flexible projections 22 having a conical shape, a brush shape, or any other shape may be attached to the tip of the nozzle 17 and near the cover opening 19. The cover opening 19 may be provided at the tip of the flexible projection 22. When blood circulation of the scalp is promoted by using the carbon dioxide gas sustained release device, the scalp is stimulated by the flexible projections 22, so that the blood circulation of the scalp can be promoted by the synergistic effect of the carbon dioxide gas and the scalp stimulation. Further, when the cover opening 19 is disposed at the tip of the flexible projection 22, the cover opening 19 approaches the scalp, so that carbon dioxide is easily transcutaneously absorbed into the scalp.
[0030]
Also, as described above, the carbon dioxide gas sustained release amount of the carbon dioxide gas sustained release device is determined mainly by the gas passing area of the gas-liquid separation membrane and the pressure in the container. Since the pressure in the container can be easily adjusted by changing the amount of the foaming agent to be charged, it is possible to easily adjust the sustained release amount of carbon dioxide gas. Therefore, the user can inject the carbon dioxide gas into the affected part in a preferred mode. Also, unlike gas cylinders, it is only necessary to pressurize the inside of the container immediately before using the device.Therefore, there is no danger of the container etc. exploding due to impact, etc. A gas sustained release device can be provided.
[0031]
The components of the foaming agent that generates carbon dioxide include carbonates and organic acids. Examples of carbonates and organic acids are listed below.
Carbonates: carbonates or bicarbonates of alkali metals such as sodium, potassium, lithium, rubidium
Organic acid: an organic acid such as citric acid, malic acid, tartaric acid, succinic acid, fumaric acid, or a mixture thereof. Other acids, including sodium or potassium acid phosphate, or mixtures thereof may be used.
【The invention's effect】
[0032]
As can be seen from the above, the carbon dioxide gas sustained release device according to the present invention is inexpensive because it has a simple mechanism for slowly releasing carbon dioxide generated in the container via water and a gas-liquid separation membrane, and is inexpensive. The present invention can provide a carbon dioxide sustained-release device capable of efficiently supplying carbon dioxide to a local part of the subject and providing a sufficient blood circulation promoting effect.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a first embodiment of a carbon dioxide sustained release device of the present invention.
FIG. 2 is a cross-sectional view showing a second embodiment of the carbon dioxide sustained release device of the present invention.
FIG. 3 is a sectional view showing a third embodiment of the carbon dioxide gas sustained release apparatus according to the present invention.
FIG. 4 is a cross-sectional view showing a fourth embodiment of the carbon dioxide sustained release device of the present invention.
FIG. 5 is a sectional view of a nozzle tip portion according to a fourth embodiment of the present invention.
FIG. 6 is a front view of a nozzle tip portion according to a fourth embodiment of the present invention.
FIG. 7 is a perspective view of a distal end portion of a nozzle provided in the carbon dioxide sustained release device according to the embodiment of the present invention.
[Explanation of symbols]
1 container
2 lid
3 Channel
4 On-off valve
5 Operation switch
6. Gas-liquid separation membrane
7 Water filling room
8 Membrane protection plate
9 Gas holding unit
10 tubes
11 weight
12 tanks
13 Constant flow valve
14 Ventilation channel
15 Floating body
16 Elastic member
17 nozzle
18 Cover
19 Cover opening
20 screws
21 Opening area
22 Flexible projection

Claims (11)

A container, a lid for sealing the container, a flow path having one end opened inside the container and the other end opened outside the container, an on-off valve for opening and closing the flow path, and the inside of the closed container formed by the container and the lid. And a pressurizing means for pressurizing with gas, wherein a water-filling chamber is provided in the flow path, in which water is sealed by a pair of gas-liquid separation membranes that can pass only gas. Carbon dioxide sustained release device. A container, a lid for sealing the container, a flow path having one end opened in the container and the other end opened outside the container, an on-off valve for opening and closing the flow path, and a closed container formed by the container and the lid. In a carbon dioxide gas sustained release device comprising a pressurizing means for pressurizing and dissolving a gas in stored water, a gas-liquid separation membrane that allows only gas to pass through the flow path, An extended portion has a flexible tube, and a weight is provided near a distal end of the tube forming the one end of the flow path, wherein the carbon dioxide sustained release device is provided. A container, a lid for sealing the container, a flow path having one end opened in the container and the other end opened outside the container, an on-off valve for opening and closing the flow path, and a closed container formed by the container and the lid. In a carbon dioxide sustained release device comprising a pressurizing means for pressurizing and dissolving a gas in stored water, a constant flow valve for automatically adjusting the amount of water flowing through the flow path to substantially constant in the flow path; A tank that communicates with the container by a channel and stores the discharged water discharged from the container again, and a ventilation flow path having one end opened inside the tank and the other end opened outside the tank. Release device. The portion of the ventilation channel extending in the tank has a flexible tube, and a floating body is attached near a tip of a tube forming the one end of the ventilation channel. The carbon dioxide sustained release device according to the above. The carbon dioxide gas sustained release device according to claim 3, wherein the on-off valve and the constant flow valve are provided in the flow path, and the on-off valve is provided downstream of the constant flow valve. Gas-liquid separation membrane at the end of the flow path opened outside the container, a cover that covers the gas-liquid separation membrane is provided, and by adjusting the position of the cover, the gas passage membrane area can be adjusted, The carbon dioxide gas sustained release device according to claim 1 or 2, wherein The carbon dioxide gas sustained release device according to claim 1, wherein a membrane protection plate is provided on the gas-liquid separation membrane downstream of the flow path and the ventilation flow path. The carbon dioxide sustained release device according to claim 1, wherein a dish-shaped gas holding portion is provided at the other end of the flow path and the ventilation flow path. 4. The carbonic acid according to claim 3, wherein the tank is mounted on a local portion of a human body surface, has a shape that forms a closed space together with the human body surface, and is made of a member having higher thermal conductivity than the container and the lid. Gas sustained release device. The carbon dioxide sustained release device according to claim 1, wherein a plurality of flexible protrusions are provided near the other end of the flow path and the ventilation flow path. The carbon dioxide sustained release device according to claim 2, wherein the pressurizing unit is a foaming agent that reacts with stored water to generate a gas.

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