KR102699533B1 - Hydrogen gas production device and method for producing hydrogen gas using nitrogen glow discharge - Google Patents

Abstract

The hydrogen gas manufacturing device and the hydrogen gas manufacturing method using nitrogen glow discharge according to the present invention include a water molecule generating unit in which gaseous or gaseous water molecules are generated through vibration of an ultrasonic generator or a heating unit, a water molecule levitation tank filled with water inside, the water molecule generating unit being immersed in the filled water, and nitrogen gas being filled on the upper part, a nitrogen plasma generating unit connected to the water molecule levitation tank to generate nitrogen plasma through nitrogen glow discharge so that the generated gaseous water molecules and nitrogen gas are introduced therein to completely separate the unseparated water molecules into hydrogen gas and oxygen gas, and a liquid nitrogen separator connected to the nitrogen plasma generating unit to separate the separated hydrogen gas, oxygen gas, and nitrogen gas, so that hydrogen gas is generated in large quantities at low cost, thereby significantly increasing the production efficiency of hydrogen gas, while the hydrogen gas generated in large quantities is separated in a nitrogen atmosphere, so that the hydrogen gas is separated with high purity, and the hydrogen gas is maintained stably without the risk of explosion due to mixing with nitrogen gas. The production, storage, and transportation of hydrogen gas are greatly facilitated, and high-purity oxygen gas is produced as a by-product.

Description

Hydrogen gas production device and method for producing hydrogen gas using nitrogen glow discharge {Hydrogen gas production device and method for producing hydrogen gas using nitrogen glow discharge}

The present invention relates to a hydrogen gas manufacturing device using a nitrogen glow discharge and a method for manufacturing hydrogen gas. More specifically, the present invention relates to a hydrogen gas manufacturing device using a nitrogen glow discharge, which can separate water molecules in a vapor or gaseous state generated through vibration such as ultrasonic vibration or a heating process into hydrogen gas and oxygen gas by striking them through a nitrogen glow discharge, and the hydrogen gas and oxygen gas thus separated are captured in nitrogen gas, so that the production efficiency of hydrogen gas is significantly increased, and a large amount of hydrogen gas is separated in a nitrogen atmosphere, so that the hydrogen gas is separated with high purity, and the hydrogen gas is mixed with nitrogen gas and maintained stably without a risk of explosion, so that the hydrogen gas can be transported without a risk of explosion, so that the storage and transportation of the hydrogen gas are greatly facilitated, and it is possible to transport it in an inexpensive container, and high-purity oxygen gas can be manufactured as a byproduct.

Recently, measures for environmental and resource problems have become important, and as one of the measures, the development of fuel cells is being actively carried out. Among fuel cells, phosphoric acid fuel cells (PAFC) and polymer electrolyte fuel cells (PEFC) use hydrogen as fuel, so a reforming system that converts raw materials such as hydrocarbons and methanol into hydrogen is necessary, and its development is a particularly important technical task in the development of fuel cells.

Regarding fuel reforming of PEFC for automobiles, methanol, dimethyl ether (DME), ethanol, natural gas, propane, and gasoline are being studied, and among these, development on methanol reforming, which has the lowest reforming temperature, is progressing the most, and currently, three reforming methods are being adopted: steam reforming, partial oxidation reforming, and combined reforming using both.

Steam reforming is,

It is represented by the reaction formula CH3OH + H2O → CO2 + 3H2, is an endothermic reaction, and the reforming temperature is 200 to 300℃.

Partial oxidation reforming is performed when air is used as an oxidizing gas.

It is expressed by the reaction formula CH3OH + 1/2 O2 + 2N2 → CO2 + 2H2 + 2N2, is an exothermic reaction, and the reforming temperature is 200 to 600℃.

A representative example of combined modification is when air is used as an oxidizing gas.

It is expressed by the reaction formula CH3OH + 1/3 O2 + 4/3 N2 + 1/3 H2O → CO2 + 7/3 H2 + 4/3 N2, and about 1/3 of the heat generation of partial oxidation is achieved, and the reforming temperature is 400-600℃.

In addition, there is also an invention providing a hydrogen generation device with high thermal efficiency, which generates hydrogen using hydrocarbon fuels such as natural gas, LPG, gasoline, naphtha, kerosene, and water as raw materials and is used for supplying hydrogen to hydrogen-utilizing devices such as fuel cells. However, this is a hydrogen generation device having at least a "hydrocarbon fuel supply unit, a combustion unit for the fuel, a water supply unit, a gas mixing unit for mixing the fuel and water or steam to create a reformed gas, and a reforming unit charged with a reforming catalyst, and which generates a reformed gas containing hydrogen from the reformed gas by the catalytic action of the reforming catalyst, wherein at least the gas mixing unit and the reforming unit are directly heated through a partition by the combustion exhaust gas generated in the combustion unit," and therefore the reforming temperature was as high as about 700°C.

There was a problem that producing hydrogen gas in this way required many unnecessary processes and consumed a lot of energy.

Registered patent 10-1147917

The problem to be solved by the present invention is to solve such problems, and to provide a hydrogen gas manufacturing device using nitrogen glow discharge, which can separate water molecules in a vapor or gas state generated through vibration such as ultrasonic vibration or a heating process into hydrogen gas and oxygen gas by using nitrogen glow discharge, and the hydrogen gas and oxygen gas thus separated are captured in nitrogen gas, so that the production efficiency of hydrogen gas is significantly increased, and a large amount of hydrogen gas is separated in a nitrogen atmosphere, so that the hydrogen gas is separated with high purity, and the hydrogen gas is mixed with nitrogen gas and maintained stably without the risk of explosion, so that the hydrogen gas can be transported without the risk of explosion, so that the storage and transportation of the hydrogen gas are greatly facilitated, and it is possible to transport it in an inexpensive container, and it is possible to manufacture high-purity oxygen gas as a byproduct, and a method for manufacturing the manufactured hydrogen gas.

As a means for solving the above problems of the present invention, a hydrogen gas manufacturing device using nitrogen glow discharge and a manufacturing method of the manufactured hydrogen gas are proposed according to the present invention, which includes a water molecule generator that generates gaseous or gaseous water molecules through vibration of an ultrasonic generator or a heating device, a water molecule levitation tank filled with water inside, the water molecule generator being immersed in the filled water, and nitrogen gas being filled on top, a nitrogen plasma generator that is connected to the water molecule levitation tank and generates nitrogen plasma through nitrogen glow discharge so that the generated gaseous water molecules and nitrogen gas are introduced therein to completely separate the unseparated water molecules into hydrogen gas and oxygen gas, and a liquid nitrogen separator that is connected to the nitrogen plasma generator and separates the separated hydrogen gas, oxygen gas, and nitrogen gas.

As a means for solving the above problems of the present invention, a hydrogen gas manufacturing device using nitrogen glow discharge and a method for manufacturing hydrogen gas are proposed according to the present invention, which include a water molecule generator that generates gaseous or gaseous water molecules through vibration of an ultrasonic generator or a heating device, a water molecule levitation tank filled with water inside, the water molecule generator being immersed in the filled water, and nitrogen gas being filled on top, a nitrogen plasma generator that is connected to the water molecule levitation tank and generates nitrogen plasma through nitrogen glow discharge so that the generated gaseous water molecules and nitrogen gas are introduced therein to completely separate unseparated water molecules into hydrogen gas and oxygen gas, a liquid nitrogen separator that is connected to the nitrogen plasma generator and separates the separated hydrogen gas, oxygen gas, and nitrogen gas, and a hydrogen gas storage container that stores the separated hydrogen gas and nitrogen gas.

The present invention is characterized in that a low-temperature freezer is additionally installed to separate hydrogen gas from the hydrogen gas storage tank, thereby liquefying nitrogen and separating only high-purity hydrogen gas. A hydrogen gas production device and a hydrogen gas production method using nitrogen glow discharge according to the present invention are proposed.

The hydrogen gas manufacturing device and the hydrogen gas manufacturing method using nitrogen glow discharge according to the present invention include a water molecule generating unit in which gaseous or gaseous water molecules are generated through vibration of an ultrasonic generator or a heating unit, a water molecule levitation tank filled with water inside, the water molecule generating unit being immersed in the filled water, and nitrogen gas being filled on the upper part, a nitrogen plasma generating unit connected to the water molecule levitation tank to generate nitrogen plasma through nitrogen glow discharge so that the generated gaseous water molecules and nitrogen gas are introduced therein to completely separate the unseparated water molecules into hydrogen gas and oxygen gas, and a liquid nitrogen separator connected to the nitrogen plasma generating unit to separate the separated hydrogen gas, oxygen gas, and nitrogen gas, so that hydrogen gas is generated in large quantities at low cost, thereby significantly increasing the production efficiency of hydrogen gas, while the hydrogen gas generated in large quantities is separated in a nitrogen atmosphere, so that the hydrogen gas is separated with high purity, and the hydrogen gas is maintained stably without the risk of explosion due to mixing with nitrogen gas. It has the excellent effect of greatly facilitating the storage and transportation of hydrogen gas and producing high-purity oxygen gas as a by-product.

Figure 1 is a schematic configuration diagram of a hydrogen gas production device using nitrogen glow discharge according to the first embodiment of the present invention.
Figure 2 is a schematic cross-sectional view of a water molecule generating unit of a hydrogen gas production device using nitrogen glow discharge according to the first embodiment of the present invention.
Figure 3 is a schematic cross-sectional view of a water molecule generating unit of a hydrogen gas production device using nitrogen glow discharge according to a second embodiment of the present invention.
Figure 4 is a schematic cross-sectional view of a hydrogen gas flotation tank of a device for generating and transporting hydrogen gas using nitrogen according to the first embodiment of the present invention.
Figure 5 is a schematic cross-sectional view of a nitrogen plasma generating unit of a hydrogen gas production device using nitrogen glow discharge according to the first embodiment of the present invention.
Figure 6 is a schematic cross-sectional view of a liquid nitrogen separator of a hydrogen gas production device using nitrogen glow discharge according to the first embodiment of the present invention.
FIG. 7 is a schematic cross-sectional view of a hydrogen gas production device using nitrogen glow discharge according to the first embodiment of the present invention, in which a low-temperature refrigerator is additionally connected to a liquid nitrogen separator.

A method for producing hydrogen gas using nitrogen according to the present invention comprises a step in which water is generated as a gaseous state or gaseous water molecules by vibration or heating of an ultrasonic vibrator, a step in which the generated water molecules are captured in a gaseous state in a nitrogen gas atmosphere, a step in which the water molecules captured in a gaseous state are completely separated into hydrogen gas, oxygen gas, and nitrogen gas by a nitrogen plasma generating unit that generates nitrogen plasma through nitrogen glow discharge, a step in which the hydrogen gas, oxygen gas, and nitrogen gas thus separated are separated into liquid oxygen, hydrogen gas, and nitrogen gas in a liquid nitrogen separator, and a step in which the gas separated into hydrogen gas and nitrogen gas is stored in a hydrogen gas transport container.

In this way, since hydrogen gas and nitrogen gas are mixed and stored in a hydrogen gas transport container, the risk of hydrogen gas explosion is eliminated, making it possible to transport it in a general hydrogen gas transport container, and at the same time eliminating the risk of hydrogen explosion due to transporting hydrogen gas.

A hydrogen gas production device (A) using a nitrogen glow discharge according to a first embodiment of the present invention, as illustrated in FIG. 1, includes a water molecule generator (1) in which gaseous or gaseous water molecules are generated through vibration of an ultrasonic generator or a heating device, a water molecule levitation tank (2) filled with water inside, the water molecule generator (1) being immersed in the filled water, and nitrogen gas being filled on top, a nitrogen plasma generator (3) which is connected to the water molecule levitation tank (2) and into which the generated gaseous water molecules and nitrogen gas are introduced to completely separate unseparated water molecules into hydrogen gas and oxygen gas, and a liquid nitrogen separator (4) which is connected to the nitrogen plasma generator and separates the separated hydrogen gas, oxygen gas, and nitrogen gas.

As one embodiment of the water molecule generator (1) of the present invention, as shown in FIG. 2, an ultrasonic vibrator is shown, and as the ultrasonic vibrator vibrates, the vibrated water molecules come into contact and become gaseous, and as the water molecules float up, they exist in a gaseous state in the upper nitrogen gas filling portion (21) filled with nitrogen gas.

In this embodiment, an ultrasonic vibrator is used as the water molecule generator (1) above, but it is not limited thereto, and any device capable of generating water molecules in a gaseous or gaseous state may be included. As an example, as shown in FIG. 3, a water molecule generator (1) formed of a heat generating panel (1a) that collects sunlight at 900 to 1,300°C and the Si-C heating rod (1b) that transfers the generated heat may be included here, such as water molecules that heat water or water molecules evaporated by heating in a boiler.

As shown in Fig. 4, the above water molecule flotation tank (2) is formed with a water molecule generating unit (1) positioned in the middle, water filled inside, and a nitrogen gas filling unit (21) filled with nitrogen gas in the upper space.

A nitrogen gas inlet (22) for filling nitrogen gas is arranged at the top of the nitrogen gas filling section (21) of the above water molecule flotation tank (2), and a gas outlet (23) for releasing nitrogen gas and water molecules is arranged at the side.

The above nitrogen plasma generator (3) generates nitrogen plasma through a nitrogen glow discharge inside, and all combined elements that collide with the nitrogen plasma are separated and completely separated into a gaseous state. When water molecules collide with the nitrogen plasma through a nitrogen glow discharge, they are separated into hydrogen molecules and oxygen molecules that make up the water molecules, and the hydrogen molecules and oxygen molecules are completely separated. The above nitrogen glow discharge is generated when a current of 1 A or less at a direct current of 200 to 300 V is applied at a pressure of 1 atm or less in a nitrogen atmosphere container.

The above nitrogen plasma generating unit (3), as shown in Fig. 5, is connected to the water molecule levitation tank (2), so that the generated water molecules and nitrogen gas are introduced, and the nitrogen plasma is collided with the unseparated water molecules, thereby separating the unseparated water molecules into hydrogen gas and oxygen gas in a completely separated state.

The voltage, current, and internal pressure applied to the above nitrogen plasma generator (3) may vary depending on the capacity, but in this example, 200 V of voltage, 0.8 A of current, and 1 atm of internal pressure were used. The hydrogen gas, oxygen gas, and nitrogen gas almost completely separated in the nitrogen plasma generating unit (3) are transferred to the liquid nitrogen separator (4) through the gas discharge port (31).

Briefly describing the above nitrogen plasma generating unit (3), although not shown, the plasma electrode may be solid, and the plasma electrode increases the plasma volume generated by the plasma electrode, and enables direct contact between the plasma of the plasma discharge and the plasma electrode within the plasma generating vessel (30) of the nitrogen plasma generating unit (3), which can reduce energy consumption when decomposing the gas when separating hydrogen gas and oxygen gas from water molecules in a gaseous state. The plasma electrode may include, for example, special steel, brass, carbon, and/or aluminum.

The above liquid nitrogen separator (4), as illustrated in FIG. 6, is connected to a nitrogen plasma generator (3) and has a configuration in which a mixture of hydrogen gas, oxygen gas, and nitrogen gas is brought into contact with liquid nitrogen to separate the hydrogen gas and nitrogen gas and the oxygen gas is liquefied and separated into liquid oxygen. When the hydrogen gas, oxygen gas, and nitrogen gas introduced into the liquid nitrogen separator (4) through the gas discharge port (31) come into contact with the liquid nitrogen (N), the oxygen gas is liquefied and settles to the bottom of the liquid nitrogen (N) as liquid oxygen (O) due to its specific gravity, the hydrogen gas rises in a gaseous state from the liquid nitrogen (N) and exists in a gaseous state in the space (41) above the liquid nitrogen separator (4), and the nitrogen gas is liquefied and mixed into the interior of the liquid nitrogen (N) or rises in a gaseous state and exists in a gaseous state in the space (41) above the liquid nitrogen separator (4).

In this way, hydrogen gas and nitrogen gas that exist in a gaseous state in the space (41) above the liquid nitrogen separator (4) are discharged through the gas discharge pipe (42) and stored in the hydrogen gas storage container (5).

Since the above hydrogen gas storage container (5) stores hydrogen gas and nitrogen gas mixed inside, the risk of hydrogen gas explosion is greatly reduced, so there is no need for a hydrogen gas-only transport container that transports expensive hydrogen gas, and since transport is possible with a general container, transport and storage of hydrogen gas can be performed very conveniently.

In the case where only hydrogen gas is to be used in the above hydrogen gas storage container (5) in which hydrogen gas and nitrogen gas are mixed, if a low-temperature freezer (6) capable of lowering the temperature to a temperature at which nitrogen gas is liquefied is arranged to be connected to the gas outlet (51) of the hydrogen gas storage container (5) as shown in FIG. 7, when the mixed hydrogen gas and nitrogen gas pass through the low-temperature freezer (6), the nitrogen gas is liquefied and undergoes a phase change into a liquid, settling into the inside of the low-temperature freezer (6), and only the hydrogen gas is discharged through the hydrogen gas outlet (61), so that high-purity hydrogen gas can be selected and used very easily.

As described above, the hydrogen gas production device using nitrogen glow discharge according to the present invention and the hydrogen gas production method using nitrogen glow discharge include a water molecule generation unit (1) in which gaseous or gaseous water molecules are generated through vibration of an ultrasonic generator or a heating unit, a water molecule levitation tank (2) filled with water inside, in which the water molecule generation unit (1) is immersed in the filled water and nitrogen gas is filled on the top, a nitrogen plasma generation unit (3) connected to the water molecule levitation tank (2) to generate nitrogen plasma through nitrogen glow discharge so that the generated gaseous water molecules and nitrogen gas are introduced and the unseparated water molecules are completely separated into hydrogen gas and oxygen gas, and a liquid nitrogen separator (4) connected to the nitrogen plasma generation unit to separate the separated hydrogen gas, oxygen gas, and nitrogen gas, so that hydrogen gas is generated in large quantities at low cost, and the production efficiency of hydrogen gas is significantly increased while the hydrogen gas generated in large quantities is generated in large quantities. Since hydrogen gas is separated in a nitrogen atmosphere and separated with high purity, and the hydrogen gas is mixed with nitrogen gas and maintained stably without risk of explosion, the storage and transportation of hydrogen gas is greatly facilitated, and high purity oxygen gas can be manufactured as a by-product.

The device for manufacturing hydrogen gas using nitrogen glow discharge and the method for manufacturing hydrogen gas according to the present invention can be said to be an invention with industrial applicability since it is possible to repeatedly manufacture the same device and perform the same method repeatedly in a general hydrogen gas manufacturing industry.

1: Water molecule generator 2: Water molecule flotation tank
3: Nitrogen plasma generator 4: Liquid nitrogen separator
5: Hydrogen gas storage tank 6: Low-temperature freezer

Claims (6)

In a hydrogen gas production device (A) using nitrogen glow discharge,
The hydrogen gas production device (A) using the above nitrogen glow discharge comprises a water molecule generation unit (1) in which gaseous or gaseous water molecules are generated through vibration of an ultrasonic generator or a heating device,
A water molecule buoyancy tank (2) filled with water inside, the water molecule generator (1) immersed in the filled water, and nitrogen gas filled on top;
A nitrogen plasma generator (3) that generates nitrogen plasma through nitrogen glow discharge so that gaseous water molecules and nitrogen gas generated by being connected to the above water molecule floatation tank (2) are introduced and the unseparated water molecules are completely separated into hydrogen gas and oxygen gas,
It includes a liquid nitrogen separator (4) that is connected to the above nitrogen plasma generator and separates hydrogen gas, oxygen gas, and nitrogen gas.
A nitrogen gas inlet (22) for filling nitrogen gas is arranged at the top of the nitrogen gas filling section (21) of the above water molecule flotation tank (2), and a gas outlet (23) for flowing nitrogen gas and water molecules is arranged at the side.
The above nitrogen plasma generator (3) is a plasma electrode selected from special steel, brass, carbon and/or aluminum installed in a plasma generator (30), and hydrogen gas and oxygen gas of gaseous water molecules are separated through direct contact between the nitrogen plasma of the nitrogen plasma discharge and the plasma electrode within the plasma generator (30).
The above liquid nitrogen separator (4) is formed by filling the inside of the liquid nitrogen separation container (40) with liquid nitrogen (N), forming a gas discharge port (31) on one side of the liquid nitrogen separation container (40), forming a gas space (41) at the top, and forming a gas discharge pipe (42) on one side of the gas space (41), so that when hydrogen gas, oxygen gas, and nitrogen gas that flow into the liquid nitrogen separator (4) through the gas discharge port (31) come into contact with the liquid nitrogen (N), the oxygen gas is liquefied and settles to the bottom of the liquid nitrogen (N) as liquid oxygen (O) due to its specific gravity, and the hydrogen gas rises in a gaseous state from the liquid nitrogen (N) and exists in a gaseous state in the gas space (41) at the top of the liquid nitrogen separator (4), and the nitrogen gas is liquefied and mixed into the inside of the liquid nitrogen (N) or rises in a gaseous state and exists in a gaseous state in the upper part of the liquid nitrogen separator (4). A hydrogen gas production device using nitrogen glow discharge, characterized in that it exists in a gaseous state in a gas space (41).
In the first paragraph,
The above water molecule generator (1) is a hydrogen gas production device using nitrogen glow discharge, characterized in that it changes into a gaseous state or a gaseous state by an ultrasonic vibrator or solar heating means.
In the first paragraph,
A hydrogen gas production device using nitrogen glow discharge, characterized in that hydrogen gas and nitrogen gas existing in a gaseous state in the space (41) above the liquid nitrogen separator (4) are discharged through a gas discharge pipe (42) and stored in a hydrogen gas storage container (5) and transported so that they can be transported.
In the third paragraph,
A hydrogen gas production device using nitrogen glow discharge characterized in that, in the case where only hydrogen gas is to be used in a state where hydrogen gas and nitrogen gas are mixed in the above hydrogen gas storage container (5), a low-temperature freezer (6) capable of lowering the temperature to the point where nitrogen gas is liquefied is additionally installed.
In a method for producing hydrogen gas using nitrogen glow discharge,
The above method for producing hydrogen gas using nitrogen glow discharge comprises a step in which water contained in a water molecule generating unit (1) generates water molecules in a gaseous state or gaseous state by vibration or heating of an ultrasonic vibrator,
A step in which water molecules in a gaseous or gaseous state generated in the above water molecule generating unit (1) float upward and are captured in a gaseous or gaseous state in a nitrogen gas atmosphere in a nitrogen gas filling unit (21) filled with nitrogen gas in the upper space of the water molecule floatation tank (2),
The step of the water molecules captured in a gaseous state being transferred to a nitrogen plasma generating unit (3) and colliding with nitrogen plasma generated through nitrogen glow discharge to be separated into hydrogen gas, oxygen gas, and nitrogen gas,
The step of separating hydrogen gas, oxygen gas and nitrogen gas from the above nitrogen plasma generator (3) and coming into contact with liquid nitrogen in the liquid nitrogen separator (4) causes the oxygen gas to liquefy and settle as liquid oxygen, and the hydrogen gas and nitrogen gas to rise from the liquid nitrogen and separate into gaseous states;
A method for producing hydrogen gas using nitrogen glow discharge, characterized in that it includes a step of separating liquid oxygen, hydrogen gas, and nitrogen gas in the liquid nitrogen separator (4) and then storing the separated gas into hydrogen gas and nitrogen gas in a transport container. delete