JP2013151400A - Hydrogen gas generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain highly-pure hydrogen gas having no contamination of impurities in the produced gas, and having no risk of explosion when producing brown gas containing hydrogen gas.SOLUTION: A portion over the liquid surface of raw material water supplied from a raw material water supply means 1 is heated by a heating means 8 in a superheated steam heating tank 2 to generate superheated steam, and the superheated steam is heated up to a temperature of 600°C-700°C, to thereby generate brown gas containing hydrogen gas. Then, a mixed fluid containing the brown gas and the superheated steam is allowed to flow out from a space over the liquid surface of the superheated steam heating tank 2 through a steam flow pipe 11, and the other end of the steam flow pipe 11 is sent into a gas-liquid separation tank to separate the brown gas from the superheated steam, and the brown gas is taken out into a brown gas outflow pipe 13 and cooled by a cooling means.

Description

  The present invention relates to a hydrogen gas generator that generates hydrogen gas from saturated steam and enables the hydrogen gas to be taken into the human body.

  Reactive oxygen species in the human body cause lesions and dysfunction, and it is effective to inhale hydrogen in order to exert an antioxidant action to remove the active oxygen species. When water is electrolyzed, hydrogen gas is generated together with oxygen gas, and the hydrogen gas generated in this manner is disclosed in Patent Document 1, for example. Here, hydrogen gas, which is a reducing gas, acts on active oxygen present in the body. As a result, a substance containing active oxygen is inactivated and removed from the body. In addition, various wastes and the like exist in the body, and therefore, it is necessary to cause an oxidative reaction, and it is beneficial to take oxygen gas into the body.

  By electrolyzing water, a mixed gas of hydrogen gas and oxygen gas is generated. For this purpose, a pair of electrodes are inserted into an electrolytic cell containing an electrolytic solution made of water, and power is supplied to both electrodes. Will be supplied. Therefore, by electrolyzing the aqueous solution, hydrogen gas and oxygen gas are generated at a ratio of approximately 2: 1. This mixed gas is called brown gas or oxyhydrogen gas. Relates to the brown gas generator.

JP 2004-204347 A

  By the way, when water is electrolyzed, reaction heat is generated. Although hydrogen gas is generated by this reaction, it is necessary to cool the electrolytic cell because an explosion may occur when the electrolytic cell becomes hot. Moreover, in order to exert a physiologically good effect on the human body, it is necessary to prevent impurities from being mixed in the brown gas generated by the reaction. The possibility of contamination cannot be denied.

  The present invention has been made in view of the above points, and the object of the present invention is to produce a gas without generating a danger of explosion when generating a brown gas containing hydrogen gas. The purpose is to make the hydrogen gas of high purity free from impurities.

  In order to achieve the above-described object, the present invention includes a raw water supply means for supplying raw water, and raw water supplied from the raw water supply means, and a portion above the liquid surface is heated by a heating means. A superheated steam heating tank that generates superheated steam by heating under normal pressure and generates a brown gas containing hydrogen gas from the superheated steam, and an upper space above the liquid level of the superheated steam heating tank, the superheated steam heating A steam circulation pipe for allowing a mixed fluid containing brown gas and superheated steam to flow out of the tank; and the other end of the steam circulation pipe is connected to separate the brown gas and superheated steam from the mixed fluid; A gas-liquid separation tank for condensing water, a brown gas outflow pipe connected to the liquid level of the gas-liquid separation tank, for extracting brown gas separated from superheated steam in the gas-liquid separation tank, and in the brown gas outflow pipe Blau By being configured and a cooling means for cooling the gas is to its features.

  Brown gas which is a mixed gas of hydrogen gas and oxygen gas is generated by generating superheated steam from the raw water and heating the superheated steam to a higher temperature. This brown gas is taken into the human body, and by incorporating the hydrogen gas contained in this brown gas into the human body, it exhibits an antioxidant action against active oxygen, thereby promoting health. Further, not only hydrogen gas but also oxygen gas is produced as a secondary in Brown gas. The oxygen gas may be separated and removed from the brown gas, but oxygen gas is also useful for causing not only a reduction reaction for wastes and the like in the body but also an oxidation reaction.

  The raw water can be used as it is without special treatment of, for example, general tap water. However, since it is absorbed by the human body, for example, various germs and the human body can be absorbed by a reverse osmosis membrane (RO membrane). It is desirable to remove impurities such as harmful organic substances and inorganic substances in advance. Moreover, the mixing ratio of hydrogen gas and oxygen gas in the generated Brown gas can be adjusted. For example, active hydrogen water may be used to increase the amount of hydrogen gas that is a reducing gas. The active hydrogen water reacts with a reducing metal such as magnesium to produce hydrogen water rich in hydrogen.

  Various methods have been developed as a method for generating brown gas. When raw water is heated in a superheated steam heating tank to generate superheated steam, and this superheated steam is further heated under normal pressure, specifically 600 ° C. When heated to the above, brown gas is generated. Heating in the superheated steam heating tank is most desirable when electromagnetic induction heating means using an electromagnetic induction coil is used because heating efficiency is high and energy loss is small. The heating temperature is 600 ° C. or more for generating brown gas, but if the temperature is too high, energy loss occurs, so the heating temperature is about 600 ° C. to 700 ° C.

  In order to perform strictly the temperature in the superheated steam heating tank, it is necessary to make the liquid level in the superheated steam heating tank constant. Since superheated steam is continuously generated in the tank, the liquid level always changes. Therefore, it is desirable to provide a liquid level adjustment means between the raw water supply means and the superheated steam heating tank so that the liquid level of the superheated steam heating tank is always managed. As a specific configuration of the liquid level height adjusting means, a liquid level height adjusting tank is provided, the raw water supply means is connected to the liquid level height adjusting tank by a water supply pipe, and an open / close valve is connected to this pipe. The replenishment flow rate can be controlled by opening and closing the on-off valve. In addition, it is good also as a structure which connects a pump to an on-off valve as needed. The liquid level height adjustment tank is equipped with a liquid level sensor that detects the liquid level height, and when the liquid level height by the liquid level sensor falls below a predetermined level, the liquid level height The adjustment means is operated so that the raw material water is supplied to the liquid level adjustment tank. And a liquid level height adjustment tank and a superheated steam heating tank are connected under each liquid level.

  By heating the inside of the superheated steam heating tank with heating means such as electromagnetic induction, the raw water is heated and superheated steam is generated. When the superheated steam is further heated, brown gas is generated, and a mixed fluid of the brown gas and superheated steam is generated. The mixed fluid is taken out by a steam flow pipe opened at the upper position of the superheated steam heating tank and guided to the gas-liquid separation tank, and the brown gas is separated from the superheated steam in the gas-liquid separation tank. Here, the brown gas is stabilized in a gaseous state, and the superheated steam before the brown gas is separated condenses when the temperature decreases. Condensed water stays in the gas-liquid separation tank. If the end of the high-pressure steam pipe is immersed under the surface of the staying water, the superheated steam is mixed with the staying water. Will rise as a bubble. As a result, water containing condensate from the steam stays in the lower part of the gas-liquid separation tank, and the upper part of the gas-liquid separation tank is filled with brown gas, so that gas-liquid separation is performed.

  Therefore, if a brown gas outflow pipe is connected to the upper part of the gas-liquid separation tank, only the brown gas is taken out. However, since the brown gas is in a high temperature state in this state, it is cooled using a cooling means. As the cooling means, either an air cooling type or a water cooling type can be used. The brown gas cooled to a temperature at which it can be sucked into the human body by the cooling means in this way flows into the nasal cannula or the like through the suction means, and can be sucked into the human body.

  As described above, by generating Brown gas from superheated steam, there is no risk of explosion, and the generated gas is a high-purity hydrogen gas that does not contain impurities.

It is composition explanatory drawing of the brown gas generator which shows one embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In FIG. 1, reference numeral 1 denotes a raw water tank as raw water supply means. The raw water tank 1 stores water as a raw material for brown gas. Brown gas is a mixed gas containing hydrogen (H ₂ ) gas and oxygen (O ₂ ) gas in a ratio of approximately 2: 1, and is also called oxyhydrogen gas.

  As the raw water, general tap water can be used as it is, but since it is supplied to the human body, necessary treatments such as removing germs and impurities, especially organic and inorganic substances harmful to the human body, etc. It is desirable to perform processing. If various filters are used, impurities and the like can be removed from tap water. For example, a reverse osmosis membrane (RO membrane) is preferably used as the filter, and a carbon filter or the like can be used in combination with the reverse osmosis membrane (RO membrane). Furthermore, it becomes possible to remove radioactive substances using a hollow fiber membrane filter.

  Here, the raw water supplied from the raw water tank 1 is for generating brown gas. The brown gas is generated by heating the raw water to generate superheated steam, and is a stable gas that does not cause an explosion or the like. The raw material water becomes steam when the temperature reaches 100 ° C., and when this heating degree is increased, the raw water becomes superheated steam and brown gas is generated. When the superheated steam is further heated, specifically, when heated to 600 ° C. to 700 ° C., hydrogen and oxygen are separated and brown gas is generated. Moreover, in this superheated steam heating tank 2, the superheated steam which is a stage before brown gas is also mixed, and therefore, a mixed fluid of brown gas and superheated steam is generated in the superheated steam heating tank 2. become.

  Thus, raw water is supplied from the raw water tank 1 to the superheated steam heating tank 2, and this mixed fluid is taken out from the superheated steam heating tank 2. Here, the heating of the raw material water is concentrated on the liquid surface and the region on the liquid surface in order to suppress the energy consumption as low as possible. For this reason, it is necessary to keep the liquid level of the raw water in the superheated steam heating tank 2 substantially constant. For this reason, the superheated steam heating tank 2 is interposed between the raw water tank 1 and the superheated steam heating tank 2. The liquid level height adjusting means for adjusting the liquid level height is provided. This liquid level adjustment means is constituted by connecting the raw water tank 1 and the superheated steam heating tank 2 with a water supply pipe 3 and connecting the liquid level adjustment tank 4 to the other end of the water supply pipe 3. Has been. An on-off valve 5 is provided in the middle of the water supply pipe 3, and a liquid level sensor 6 for detecting the liquid level is provided in the liquid level adjustment tank 4. The liquid level adjustment tank 4 and the superheated steam heating tank 2 communicate with each other through a communication pipe 7.

  In the state where the on-off valve 5 is closed, the liquid level adjustment tank 4 and the superheated steam heating tank 2 communicated by the communication pipe 7 have the same height, and the liquid level sensor 6 provides the liquid level adjustment tank. When the liquid level in 4 drops below a predetermined level, the on-off valve 5 is opened, whereby the raw water is supplied to the liquid level adjustment tank 4 and the superheated steam heating tank 2 communicated therewith. When the liquid level detected by the liquid level sensor 6 reaches a predetermined level, the on-off valve 5 is closed. Therefore, the liquid level adjustment tank 4, the on-off valve 5 and the liquid level sensor 6 constitute liquid level height adjusting means in the superheated steam heating tank 2. As a result, the liquid level adjustment tank 4 and the superheated steam heating tank 2 The liquid level is always kept at a substantially constant level.

  The superheated steam heating tank 2 is equipped with heating means 8 composed of an electromagnetic induction coil, and the inside of the superheated steam heating tank 2 is heated by the heating means 8. Here, the superheated steam heating tank 2 has a liquid region 9 at the lower position and a vapor region 10 at the upper side, and steam is generated from the liquid region 9 by heating the water on the liquid surface. . Although the liquid in the liquid region 9 is reduced by this evaporation, the liquid level in the superheated steam heating tank 2 is always managed to be substantially constant. The reason why the liquid level adjustment means 3 is provided on the upstream side of the superheated steam heating tank 2 is to keep the liquid level in the superheated steam heating tank 2 substantially constant. When lowered, water is replenished from the raw water tank 1. In this way, the liquid level slightly rises and falls, but the heating means 8 is always located in the vapor region 10 in the superheated steam heating tank 2 and is not immersed in the liquid region 9.

In the superheated steam heating tank 2, the heating means 8 heats the space of the steam region 10, and the liquid level in the liquid region 9 is also heated with this. As a result, steam is generated in the steam space 10, and the steam space 10 is filled with superheated steam. The steam filling the steam area 10 is heated by the heating means 8 to generate superheated steam. When the superheated steam is heated to 600 ° C. to 700 ° C. in the steam region 10, a brown gas composed of molecular hydrogen (H ₂ ) gas and oxygen (O ₂ ) gas is generated from the superheated steam. Will be. Therefore, in the vapor | steam area | region 10 in the superheated steam heating tank 2, the mixed fluid of brown gas and the superheated steam which is not gasified is filled in the high temperature state.

  A steam circulation pipe 11 is connected to the superheated steam heating tank 2, and the steam circulation pipe 11 is connected to an upper position of the superheated steam heating tank 2. Accordingly, an upward flow of a mixed fluid of superheated steam and brown gas is generated in the superheated steam heating tank 2, and this mixed fluid flows into the steam flow pipe 11. The other end of the steam flow pipe 11 is connected to a gas-liquid separation tank 12. Water of a predetermined liquid level is stored inside the gas-liquid separation tank 12, and the other end of the steam flow pipe 11 is positioned below the liquid level in the gas-liquid separation tank 12 in the gas-liquid separation tank 12. It is open.

  The gas-liquid separation tank 12 is not provided with heating means, and is in a temperature state sufficiently lower than the superheated steam heating tank 2 heated by the heating means 8. For this reason, the mixed fluid of the superheated steam and the brown gas generated in the superheated steam heating tank 2 flows into the gas-liquid separation tank 12 from the steam flow pipe 11. The water stored in the gas-liquid separation tank 12 has a boiling point or less, and the mixed fluid is cooled when passing through the steam flow pipe 11, and the steam component is condensed. As a result, the brown gas fills the upper region in the gas-liquid separation tank 12, and the condensed water stays on the lower side so that the gas-liquid is separated.

  The brown gas separated from the vapor as described above flows into the brown gas outflow pipe 13. A cooling means 14 is provided in the middle of the brown gas outflow pipe 13, and the brown gas flowing through the brown gas outflow pipe 13 is cooled by the cooling means 14. Here, the illustrated cooling means 14 is an air-cooled type constituted by a meandering pipe 13a connected to the brown gas outflow pipe 13 and a cooling fan 14b for supplying cooling air toward the meandering pipe 14a. On the other hand, water is stored inside the gas-liquid separation tank 12, and the internal liquid level rises as the superheated steam condenses. Therefore, when the liquid level in the gas-liquid separation tank 12 exceeds a predetermined level, the gas-liquid separation tank 12 is discharged to the outside through the discharge pipe 15. Thereby, the liquid level inside the gas-liquid separation tank 12 is always maintained at a constant level.

  The brown gas is for sucking the human body, and for this purpose, for example, a nasal cannula 16 is used as a suction means. A suction pump 17 is connected to the end of the meandering pipe 14a, and the nasal cannula 15 is detachably connected to the suction pump 17. Thus, the brown gas from which the superheated vapor is separated can be supplied to the human body through the nasal cannula 15. In the stage before being supplied to the nasal cannula 15, the cooling means 14 cools the brown gas to a temperature that is not dangerous to the human body, for example, about 20 ° C.

DESCRIPTION OF SYMBOLS 1 Raw material water tank 2 Superheated steam heating tank 4 Liquid level adjustment tank 5 On-off valve 6 Liquid level sensor 8 Heating means 11 Steam distribution pipe 12 Gas-liquid separation tank 13 Brown gas outflow pipe 14 Cooling means 17 Suction pump

Claims (5)

Raw water supply means for supplying raw water;
The raw water supplied from the raw water supply means is flowed in, and the portion above the liquid surface is heated under normal pressure by the heating means to generate superheated steam, and the brown gas containing hydrogen gas is generated from this superheated steam. A superheated steam heating tank,
A steam circulation pipe that opens to the upper space of the liquid surface of the superheated steam heating tank and allows a mixed fluid containing brown gas and superheated steam to flow out of the superheated steam heating tank;
A gas-liquid separation tank connected to the other end of the steam flow pipe, separating the Brown gas and superheated steam from the mixed fluid, and condensing the superheated steam;
A brown gas outflow pipe connected to the liquid level of the gas-liquid separation tank and for extracting brown gas separated from superheated vapor in the gas-liquid separation tank;
A hydrogen gas generator comprising: cooling means for cooling the brown gas in the brown gas outflow pipe.   2. The hydrogen gas generator according to claim 1, wherein the raw water supplied from the raw water supply means is sterilized through at least a reverse osmosis membrane.   The raw water supply means and the superheated steam tank are connected by a water supply pipe, and a liquid level height adjusting tank is provided in the middle of the connecting pipe. A liquid level sensor for detecting the height of the liquid level is mounted, and the liquid detected by the liquid level sensor is provided between the raw water supply means and the liquid level height adjustment tank in the connection pipe. An on-off valve is provided that opens when the surface height drops to a predetermined level, and the liquid level height adjustment tank and the superheated steam heating tank are communicated with each other under the respective liquid levels by a communication pipe. The hydrogen gas generator according to claim 1, wherein:   The hydrogen gas generator according to any one of claims 1 to 3, wherein the superheated steam heating tank heats the liquid surface vicinity of the raw water from 600 ° C to 700 ° C by electromagnetic induction heating means. .   5. The hydrogen gas generation according to claim 1, wherein a suction pump is connected to a pipe constituting the cooling means, and a nasal cannula is detachably connected to an output side of the suction pump. apparatus.

Images