WO2021086162A1

WO2021086162A1 - Hydrogen generation device having self-power generation function using centrifugal force

Info

Publication number: WO2021086162A1
Application number: PCT/KR2020/015175
Authority: WO
Inventors: 김재호
Original assignee: 김재호
Priority date: 2019-11-01
Filing date: 2020-11-02
Publication date: 2021-05-06
Also published as: CN114667368B; KR20210053255A; CN114667368A; KR102464682B1

Abstract

The present invention relates to a hydrogen generation device having a self-power generation function using centrifugal force, and more particularly, to a hydrogen generation device having a self-power generation function using centrifugal force, wherein the hydrogen generation device is provided with a self-power generation function using centrifugal force, and allows electric energy generated by self-power generation to be used during water electrolysis for generating hydrogen, so that the supply of external power for the electrolysis of water can be minimized, and accordingly, the cost of hydrogen generation can be drastically reduced.

Description

Hydrogen generator with self-power function using centrifugal force

The present invention relates to a hydrogen generating device having a self-generation function using a centrifugal force, and more particularly, a self-generation function using a centrifugal force is provided to use the electric energy generated by self-generation during the electrolysis of water to generate hydrogen. The present invention relates to a hydrogen generator having a self-generation function using a centrifugal force that minimizes the supply of external power for electrolysis of water, thereby reducing the cost required for hydrogen generation in an innovative manner.

Hydrogen is recognized as a clean energy source such as general fuel, hydrogen vehicles, hydrogen airplanes, fuel cells, and nuclear fusion energy because it is easy to burn, has a large heat of combustion, and does not generate pollutants.

As a general method of generating such hydrogen, there is a method of generating hydrogen by a reforming reaction for hydrocarbon compounds such as petroleum, natural gas, and coal.

However, such a conventional method has a problem that pollutants are generated because carbon generated in the process of generating hydrogen generates carbon dioxide, which is a substance that causes global warming.

In order to solve this problem, in recent years, hydrogen generators using electrolysis have been developed, which apply electrical energy to water containing an electrolyte, etc., and as the water molecules are decomposed, oxygen gas is generated on the anode side, and the cathode It is a device that generates hydrogen gas on the side.

That is, the hydrogen generator is generally provided with an inlet and an outlet through which water is introduced and discharged into a case made of a pair, a positive electrode plate and a negative electrode plate are disposed in the case, and an ion film is disposed between the positive electrode plate and the negative electrode plate. As water passes through the space formed on both sides of the case based on the ion film, the positive plate, and the negative plate, water molecules are decomposed by electric energy, and hydrogen and oxygen may be generated.

Hydrogen generators using the electrolysis method have the advantage of not generating pollutants, but more than 20% of the sales that can be obtained by generating hydrogen are used as electricity required for electrolysis, so the production of hydrogen requires a lot of cost. There is a problem.

The present invention was conceived to solve the problems of the prior art as described above, and an object of the present invention is to minimize the supply of external power for electrolysis of water by enabling the use of electric energy generated by self-generation during electrolysis of water. And, accordingly, it is to provide a hydrogen generator having a self-powered function using a centrifugal force that can innovatively reduce the cost for generating hydrogen.

The present invention for achieving the above object,

A support frame fixedly installed on the ground, a rotating part rotatably coupled to the supporting frame, and a rotating part including a plurality of power generation modules and a plurality of electrolysis modules, and connected to the rotating part to drive the rotation of the rotating part and to the hydrogen generating module. It characterized in that it comprises a control unit for controlling the water supply.

In this case, the rotating part includes a main shaft that is rotatably connected to the support frame, a pipe part connected to and installed between the main shaft and the electrolysis module, a fixed frame in which the power generation module and the electrolysis module are fixedly installed, and the It is connected to the support frame and characterized in that it comprises a ring-shaped fixed track for supporting the rotation of the power generation module.

In addition, the piping part is a water supply pipe that supplies water from the main shaft to the electrolysis module, a hydrogen discharge pipe that discharges hydrogen generated in the electrolysis module through the main shaft, and discharges water and oxygen from the electrolysis module through the main shaft. It characterized in that it comprises a water / oxygen discharge pipe.

And, at the outer end of the fixed frame, a ring-shaped installation frame in which a plurality of electrolysis modules are fixedly installed on an outer surface is installed, and a water inlet connected to a water supply pipe and a hydrogen discharge pipe are installed on the inner surface of the installation frame. The first and second electricity to supply the (+) electrode and the (-) electrode to the electrolysis module by being connected to the hydrogen outlet connected to the hydrogen outlet, the water/oxygen outlet connected to the water/oxygen discharge pipe, and the power generation module. It characterized in that the connection portion is provided.

In addition, the power generation module includes a roller that rotates in close contact with the inner surface of the fixed track, a roller auxiliary device that is installed under the roller to pressurize the roller to be in close contact with the fixed track, and the rotational force of the roller is converted into electric energy. It characterized in that it comprises a generator that converts and an electronic device fixedly installed on the fixed frame to charge power generated by the generator and to control driving of the generator.

In addition, the electrolysis module has a structure in which a plurality of units consisting of a pair of cells provided with a membrane therein are connected in series, and a first and a first and a negative electrode to which the (+) and (-) poles are grounded respectively at the upper end of the unit. A cell water inlet through which water is supplied to the second grounding part is formed, a cell hydrogen outlet through which hydrogen generated inside is discharged is formed on one side of the unit, and a cell water in which internal water and oxygen are discharged is formed in the lower part of the unit. / Characterized in that the oxygen outlet is formed.

In addition, a water injection part for supplying water to the electrolysis module and a water/oxygen discharge part for discharging water and oxygen discharged from the electrolysis module to the outside are formed at the rear end of the main shaft.

In addition, the control unit includes a motor providing power to rotate the main shaft, a power supply unit supplying power for driving the motor, a belt connected between the motor and the main shaft, and water supplied from the outside. It characterized in that it comprises a pump for supply to the electrolysis module.

According to the present invention, by providing a self-powered function using centrifugal force so that the electric energy generated by self-power generation can be used when water is electrolyzed to generate hydrogen, external power supply for electrolysis of water is minimized, and accordingly It has an excellent effect of innovatively reducing the cost required for hydrogen generation.

1 is a perspective view showing a whole hydrogen generator having a self-power function using a centrifugal force according to the present invention.

Figure 2 is a rear perspective view showing a hydrogen generating device having a self-power function using a centrifugal force according to the present invention.

Figure 3 is a perspective view showing a state of the electrolysis module installed on the rotating part of the present invention shown in Figure 2;

Figure 4 is a view showing in detail the appearance of the rear end of the main shaft coupled to the support frame of the present invention shown in Figure 2;

Figure 5 is a view showing in detail the appearance of the power generation module installed on the rotating part of the present invention shown in Figure 2;

Figure 6 is a view showing in detail the installation of the electrolysis module of the present invention shown in Figure 2;

Figure 7 is a view showing in detail the appearance of the piping portion of the hydrogen generating device having a self-power function using a centrifugal force according to the present invention.

Figure 8 is a view showing in detail the internal view of the main shaft of the hydrogen generating device having a self-power function using a centrifugal force according to the present invention.

9 and 10 are views showing in detail the appearance of the control unit of the hydrogen generating device having a self-power function using a centrifugal force according to the present invention.

11 is a view showing in detail the internal view of the electrolysis module of the hydrogen generating device having a self-power function using a centrifugal force according to the present invention.

Hereinafter, preferred embodiments of a hydrogen generator having a self-powered function using a centrifugal force according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the entire hydrogen generating device having a self-generation function using a centrifugal force according to the present invention, Figure 2 is a rear perspective view showing a hydrogen generating device having a self-generating function using a centrifugal force according to the present invention, Figure 3 Is a perspective view showing the appearance of the electrolysis module installed on the rotating part of the present invention shown in Figure 2, Figure 4 is a view showing in detail the appearance of the rear end of the main shaft coupled to the support frame of the present invention shown in Figure 2, 5 is a view showing in detail the appearance of the power generation module installed on the rotating part of the present invention shown in Figure 2, Figure 6 is a view showing in detail the installation of the electrolysis module of the present invention shown in Figure 2, Figure 7 It is a view showing in detail the appearance of the piping part of the hydrogen generating device having a self-power generation function using a centrifugal force according to the present invention, Figure 8 is a view of the interior of the main shaft of the hydrogen generating device having a self-power generation function using the centrifugal force according to the present invention. 9 and 10 are diagrams showing in detail the appearance of the control unit among the hydrogen generators having a self-generation function using centrifugal force according to the present invention, and FIG. 11 is a self-power generation using centrifugal force according to the present invention. It is a diagram showing in detail the internal appearance of an electrolysis module among hydrogen generating devices having a function.

The present invention minimizes the supply of external power for electrolysis of water by providing a self-powered function using centrifugal force so that the electric energy generated by self-generation can be used during the electrolysis of water to generate hydrogen, thereby generating hydrogen. It relates to a hydrogen generator (hereinafter referred to as a'hydrogen generator') having a self-powered function using a centrifugal force that can innovatively reduce the cost required for this, and the configuration is as shown in FIGS. 1 and 2 Likewise, it consists of a largely including the rotating unit (1), the control unit (2) and the support frame (3).

First, the support frame 3 serves to support the hydrogen generator according to the present invention so that it can be fixedly installed on the ground, etc. The pair of fixing portions may be integrally formed.

Next, the rotation unit 1 is rotatably coupled to the support frame 3, and comprises a plurality of power generation modules 10 and a plurality of electrolysis modules 110, the support frame 3 and the rotation unit ( 1) may be formed in the same shape as a rotating ferris wheel installed in an amusement park as a whole.

That is, the rotating part 1 includes a power generation module 10 and an electrolysis module 110, and the power generation module 10 converts kinetic energy generated by the rotation of the rotating part 1 into electrical energy. The electrolysis module 110 plays a role of generating hydrogen by electrolyzing water using power produced by the power generation module 10, and a number of heavy power generation modules 10 By installing the dog to be spaced apart from the center of the rotating part (1) by a certain distance or more, and by connecting and installing a plurality of electrolysis modules (110) made of heavy weight to the outer end of the power generation module (10), the overall weight and rotation radius are increased. It is configured to maximize power generation efficiency and has its characteristics.

In more detail, the rotating part 1 includes a main shaft 5, a piping part 120, a fixed frame 7, a fixed track 6, a power generation module 10, and an electrolysis module 110. First, the main shaft 5 is connected to the support frame 3 so as to be rotatable, and has a hollow shape, and water supplied to the electrolysis module 110 and hydrogen discharged from the electrolysis module 110, It can act as a passage for oxygen and water.

That is, the main shaft 5 is hinged between the fixing parts of the support frame 3 and is configured to rotate by driving the motor 23 of the controller 2 to be described later. A hydrogen discharge unit 21 is formed at the front end to allow the hydrogen generated by the electrolysis module 110 to be discharged to the outside, and at the rear end of the main shaft 5, water is transferred to the electrolysis module 110 from the outside. A water injection part 51 for supplying the water and a water/oxygen discharge part 52 for discharging water and oxygen discharged from the electrolysis module 110 to the outside are formed.

At this time, in FIGS. 4 and 9, the water injection part 51 and the water/oxygen discharge part 52 are formed at the rear end of the main shaft 5, that is, at the rear of the hydrogen generator according to the present invention, and the hydrogen The discharge part 21 is shown to be formed at the front end of the main shaft 5, that is, the front side of the hydrogen generator according to the present invention, but if necessary, the water injection part 51 and the water/oxygen discharge part 52 ) And the hydrogen discharge unit 21 may be selectively formed on the front or rear surface of the hydrogen generator.

In addition, inside the main shaft 5, as shown in FIG. 8, water supplied to the electrolysis module 110, hydrogen discharged from the electrolysis module 110, and water discharged from the electrolysis module 110 A hydrogen discharge pipe connection part 1221 and a water supply pipe in which passages through which oxygen and oxygen move are separated and are formed, and communicate with the hydrogen discharge part 21, the water injection part 51 and the water/oxygen discharge part 52. A connection part 1211 and a water/oxygen discharge pipe connection part 1231 are formed, respectively.

In addition, a bearing 30 may be inserted and installed in a coupling portion between the support frame 3 and the main shaft 5 for smooth rotation of the main shaft 5.

Next, the piping part 120 is connected and installed between the main shaft 5 and the electrolysis module 110 so that water supplied from the outside is supplied to the electrolysis module 110 and from the electrolysis module 110 It serves to discharge the discharged hydrogen, water, and oxygen to the outside through the main shaft 5, as shown in Figs. 7 and 8, the hydrogen discharge pipe 121, the water supply pipe 122 And a water/oxygen discharge pipe 123.

That is, the hydrogen discharge pipe 121 is connected and installed between the hydrogen outlet 112 of the electrolysis module 110 and the main shaft 5 to be described later, and is generated through the electrolysis of water in the electrolysis module 110. It serves to supply the hydrogen discharged through the hydrogen outlet 112 to the main shaft 5, and the water supply pipe 122 is the water inlet 111 and the main shaft of the electrolysis module 110 to be described later ( 5) It is connected and installed between and serves to supply water supplied through the main shaft 5 from the outside to the inside of the electrolysis module 110 through the water inlet 111, and the water/oxygen discharge pipe 123 is connected and installed between the water/oxygen outlet 113 of the electrolysis module 110 and the main shaft 5 to be described later, and discharged from the electrolysis module 110 through the water/oxygen outlet 113 It serves to supply water and oxygen to the main shaft (5).

Next, the fixing frame 7 is radially installed on the outer circumferential surface of the main shaft 5 so that the power generation module 10 and the electrolysis module 110 can be fixedly installed, and the outer end of the fixing frame 7 In the ring-shaped installation frame 8 is installed, a plurality of electrolysis modules 110 may be configured to be fixedly installed outside the installation frame 8.

In more detail, the installation frame 8 is connected in a vertical direction to the outer ends of a plurality of fixing frames 7 radially installed on the outer circumferential surface of the main shaft 5, as shown in FIG. It is installed in a ring shape to form a concentric circle shape with (5), and a water inlet 111 connected to a water supply pipe 122 and a hydrogen discharge pipe 121 connected to the inner surface of the installation frame (8) The hydrogen outlet 112 and the water/oxygen outlet 113 connected to the water/oxygen discharge pipe 123 are each provided, and the water supplied through the water supply pipe 122 is supplied through the water inlet 111. Hydrogen and water/oxygen are supplied to the inside of the cracking module 110 and discharged from the electrolysis module 110 through the hydrogen outlet 112 and the water/oxygen outlet 113, and the hydrogen discharge pipe 121 and water/oxygen It is configured to be supplied to the discharge pipe (123).

In addition, first and second

electrical connection parts

114 and 115 are provided on the inner side of the installation frame 8, and the first and second

electrical connection parts

114 and 115 are electrolysis module 110, which includes a (+) electrode and It serves to supply each of the (-) electrodes, so that the power charged in the electronic device 14 can be supplied to the electrolysis module 110 by connecting and installing it to the electronic device 14 of the power generation module 10 to be described later. Can be configured.

Next, the fixed track 6 is connected to the support frame 3 and serves to support the rotation of the power generation module 10 and is formed in a ring shape.

As shown in Fig. 2, the fixed track 6 is fixedly installed on the upper end of the support frame 3 by fastening means 4 such as bolts, and a plurality of radially formed toward the outside of the center. A power generation module 10 to be described later on the inside of the fixed track 6, that is, the inside of the ring-shaped part, comprising a ring-shaped member formed in a'L' shape at the outer end of the connecting member of The roller 12 is in close contact and the fixed track 6 is configured to rotate the roller 12.

In other words, the fixed orbit 6 is fixed to the support frame 3 independently of the rotation of the rotating part 1 to maintain a fixed state that does not rotate, and the rotating part 1 is rotated by the rotation of the main shaft 5. When is rotated, a rotational force is generated in the rollers 12 of the power generation module 10 in close contact with the fixed track 6, and the power generation module 10 is configured to generate power by the rotational force generated at this time. A more detailed description of the will be described later.

Next, the power generation module 10 is fixedly installed on a fixed frame 7 spaced a certain distance from the center of the rotating part 1 to convert and store kinetic energy generated by the rotation of the rotating part 1 into electrical energy. By doing so, a total of 10 or more power generation modules 10 may be installed in the rotating part 1.

In more detail, the power generation module 10 may include a roller 12, a roller auxiliary device 13, a generator 11 and an electronic device 14, as shown in FIG. 5, wherein the roller ( 12) plays a role of generating kinetic energy for generating electric power by rotating in close contact with the inner surface of the fixed track 6 fixedly installed in a ring shape when the rotating part 1 is driven to rotate.

That is, if each of the power generation module 10 and the electrolysis module 110 is 500 kg, when a total of 10 power generation modules 10 and the electrolysis module 110 are installed, the total weight of the rotating unit 1 is 10 tons. This is the case, and the rotation radius of the rotating unit 1 is also increased by the series installation of the power generation module 10 and the electrolysis module 110, so that the rotational force of the rotating unit 1 can be maximized.

In addition, in the case of the roller 12 supported by the fixed track 6 and rotating, the rotational rpm can be increased by several tens of times or more compared to the rotating unit 1, so that the power generation efficiency of the power generation module 10 can be increased. In this way, it is possible to minimize external power used for hydrogen generation in the electrolysis module 110 accordingly.

Next, the roller auxiliary device 13 is connected to the lower portion of the roller 12 and serves to pressurize the roller 12 so that it can be in close contact with the fixed track 6. The frictional force between the roller 12 and the fixed track 6 is increased by pressing, so that the rotational speed of the roller 12 may be increased.

At this time, a rack gear is formed on the inner surface of the fixed track 6, and the roller 12 may be configured as a pinion gear coupled to the rack gear, but friction and noise are severely generated during high-speed rotation, and due to wear It is not preferable because the durability may be reduced.

Next, the generator 11 is connected to the rotation shaft of the roller 12 and serves to convert the rotational force of the roller 12 into electric energy, and a detailed configuration description thereof is omitted since the existing generator configuration can be applied. I will do it.

In addition, although not shown, by installing a reducer made of a gear structure on the rotating shaft of the roller 12, the rotational speed transmitted to the generator 11 by the roller 12 according to the rotational speed of the rotating part 1 is kept at a constant ratio. Of course, it can be adjusted.

Next, the electronic device unit 14 is fixedly installed on the fixed frame 7, and is connected to the generator 11 so that the electric power generated by the generator 11 can be charged and the generator 11 is driven. It can play a role in controlling.

Next, the electrolysis module 110 is connected in series to the outer end of the power generation module 10 and serves to generate hydrogen by electrolyzing water using power supplied from the power generation module 10, It is configured to generate hydrogen by electrolyzing water supplied from the outside and discharge it to the outside.

In more detail, as shown in FIG. 11, the electrolysis module 110 includes a plurality of units consisting of a pair of cells 1101 formed with a space portion for receiving water inside to be connected in series and fixed. It can be made in a structure that is.

At this time, a membrane (not shown) for separating hydrogen may be installed inside the unit, and the first and second grounding portions 1105 to which the (+) and (-) electrodes are grounded, respectively, at the upper end of the unit. 1106) can be formed.

In addition, a cell water inlet 1102 for supplying water to the inside is formed at the upper end of the unit, and a cell hydrogen outlet 1103 for discharging the hydrogen generated therein is formed at one side of the unit, and at the bottom of the unit A cell water/oxygen outlet 1104 through which water and oxygen are discharged may be formed.

The number of units to be installed may be adjusted as necessary, and the water inlet 111, the hydrogen outlet 112, the water/oxygen outlet 113, and the first electrical connection 114 provided in the above-described installation frame 8 ) And the second electrical connection unit 115 and the fixtures formed integrally with each other may be configured to firmly fix a plurality of units.

At this time, as shown in Figure 2, in order to prevent the electrolysis module 110 from being damaged by an external shock, a cover member 9 may be installed outside the electrolysis module 110, which is not shown. However, it goes without saying that the electrolysis module 110 may be an electrolysis module of various shapes previously used.

Next, the control unit 2 is connected to the rotating unit 1 at the front or rear and serves to control the rotational drive of the rotating unit 1 and water supply to the hydrogen generating module. As shown, it may include a motor 23, a power supply 22, a belt 26, and a pump 24.

In more detail, first, the motor 23 serves to provide power to rotate the main shaft 5 of the rotating unit 1, and may be used such as an air motor using pneumatic or an electric motor driven by electricity. I can.

In addition, the power supply unit 22 serves to supply power for driving the motor 23, and when the air motor is used as the motor 23, pneumatic pressure is supplied to the motor 23, and the electric motor When using, it can be configured to supply electricity to the motor 23.

Next, the belt 26 is connected to and installed between the motor 23 and the main shaft 5 of the rotating unit 1, and transmits the rotational force of the motor 23 to the main shaft 5 to the main shaft 5 It plays the role of starting the rotation.

That is, when the motor 23 is driven to rotate the rotating unit 1, the rotational force of the motor 23 is transmitted to the main shaft 5 through the belt 26, so that the rotating unit 1 starts to rotate, When the rotation of the rotating part 1 starts, the rotation of the rotating part 1 is accelerated by the centrifugal force by the power generation module 10 and the electrolysis module 110 made of heavy weight, so that the rotating part 1 is continuously rotated with little force. You will be able to do it.

Next, the pump 24 is connected to the main shaft 5 and serves to supply water supplied from the outside to the electrolysis module 110, and the water injection unit ( Water supplied to the main shaft 5 through 51 may be supplied to the inside of the electrolysis module 110 through the water supply pipe 122 and the water inlet 111.

On the other hand, although not shown, the rotational speed of the rotating unit 1 through the control unit 2, the water supply rate to the electrolysis module 110, the amount of power supplied from the power generation module 10 to the electrolysis module 110, etc. Of course, it can also be configured so that it can be checked and controlled in real time.

Therefore, according to the hydrogen generating device having a self-generation function using centrifugal force according to the present invention as described above, the electric energy generated by self-generation during electrolysis of water to generate hydrogen by having a self-generation function using centrifugal force It has various advantages, such as minimizing external power supply for electrolysis of water by enabling the use of, and thus innovatively reducing the cost required for hydrogen generation.

Although the above-described embodiments have been described with respect to the most preferred examples of the present invention, it is obvious to those skilled in the art that various modifications are possible without departing from the technical spirit of the present invention, and are not limited to the above embodiments.

Claims

A support frame fixedly installed on the ground,

A rotating part rotatably coupled to the support frame and including a plurality of power generation modules and a plurality of electrolysis modules, and

And a control unit connected to the rotation unit to control the rotation of the rotation unit and supply of water to the hydrogen generation module.
The method of claim 1,

The rotating part includes a main shaft that is rotatably connected to the support frame, a piping part connected to and installed between the main shaft and the electrolysis module, a fixed frame in which the power generation module and the electrolysis module are fixedly installed, and the support frame Hydrogen generator having a self-powered function using centrifugal force, characterized in that it includes a ring-shaped fixed orbit connected to and installed to support the rotation of the power generation module.
The method of claim 2,

The piping unit includes a water supply pipe supplying water from the main shaft to the electrolysis module, a hydrogen discharge pipe discharging hydrogen generated in the electrolysis module through the main shaft, and water discharging water and oxygen from the electrolysis module through the main shaft. / Hydrogen generator having a self-generation function using centrifugal force, characterized in that it comprises an oxygen discharge pipe.
According to 3,

At the outer end of the fixed frame, a ring-shaped installation frame in which a plurality of electrolysis modules are fixedly installed on an outer surface is installed, and a water inlet connected to a water supply pipe and a hydrogen discharge pipe are connected to the inner surface of the installation frame. The first and second electrical connectors are connected to the hydrogen outlet, the water/oxygen outlet connected to the water/oxygen discharge pipe, and the power generation module to supply the (+) electrode and the (-) electrode respectively to the electrolysis module. Hydrogen generator having a self-power function using centrifugal force, characterized in that provided.
The method of claim 2,

The power generation module includes a roller that rotates in close contact with the inner surface of the fixed track, a roller auxiliary device that is installed under the roller to pressurize the roller to be in close contact with the fixed track, and converts the rotational force of the roller into electric energy. A hydrogen generator having a self-generation function using a centrifugal force, characterized in that it comprises a generator and an electronic device that is fixedly installed on the fixed frame to charge power generated by the generator and controls the drive of the generator.
The method of claim 2,

The electrolysis module has a structure in which a plurality of units consisting of a pair of cells with a membrane therein are connected in series, and the first and second electrodes to which the (+) and (-) poles are grounded respectively at the upper end of the unit. A cell water inlet through which water is supplied to the ground is formed, a cell hydrogen outlet through which hydrogen generated inside is discharged is formed on one side of the unit, and a cell water/oxygen through which internal water and oxygen are discharged at the bottom of the unit. Hydrogen generator having a self-power function using centrifugal force, characterized in that the outlet is formed.
The method of claim 2,

Self-generation using centrifugal force, characterized in that a water injection part for supplying water to the electrolysis module and a water/oxygen discharge part for discharging water and oxygen discharged from the electrolysis module to the outside are formed at the rear end of the main shaft. A hydrogen generator that has a function.
The method of claim 2,

The control unit electrolyzes a motor that provides power to rotate the main shaft, a power supply that supplies power for driving the motor, a belt connected between the motor and the main shaft, and water supplied from the outside. Hydrogen generator having a self-power function using a centrifugal force, characterized in that it comprises a pump for supplying to the module.