KR20200064375A - Hydrogen production equipment and hydrogen vehicle using it - Google Patents

Abstract

The present invention relates to a hydrogen production device and a hydrogen vehicle using the hydrogen production device, whererin the hydrogen production device comprises: an alkali metal storage tank (100); a hydrogen gas generating part (300) in which a fluid containing water is built in, and alkali metal supplied from the alkali metal storage tank (100) reacts with the water to generate hydrogen gas; and a hydrogen gas storage part (400) receiving hydrogen gas from the hydrogen gas generating part. Therefore, the hydrogen production device can autonomously produce hydrogen when driving even if a large amount of high-pressure hydrogen gas or liquefied hydrogen gas is not stored, thereby being able to provide a safer hydrogen vehicle.

Description

HYDROGEN PRODUCTION EQUIPMENT AND HYDROGEN VEHICLE USING IT

The present invention relates to a hydrogen vehicle using a hydrogen production device and a hydrogen production device, and is a hydrogen vehicle using a hydrogen production device and a hydrogen production device configured to produce hydrogen in real time by placing the hydrogen production device inside the hydrogen vehicle.

Automobiles used by modern people are configured to run on the ground by using a prime mover equipped with a body, and currently used automobiles generally use internal combustion engines using gasoline or diesel as fuel.

In addition, recently, eco-friendly cars have been spotlighted due to problems such as environmental pollution caused by cars using gasoline or diesel, and the eco-friendly cars are hydrogen fueled cars using hydrogen and Hydrogen fuel cell vehicles (Hydrogen Fueled Cell Vehicle), and electric vehicles that use electricity as fuel.

Among them, a hydrogen fueled vehicle and a hydrogen fueled vehicle (hereinafter referred to as a'hydrogen vehicle') using hydrogen as a fuel are constructed by directly burning hydrogen to generate power or generating electricity with hydrogen as fuel to obtain power. In general, a hydrogen vehicle is made to store and drive high-pressure hydrogen therein. Accordingly, in the case of an accident due to a collision, the hydrogen vehicle is likely to explode in a series of high-pressure hydrogen, and has a problem that its safety is somewhat low.

In addition, the high-pressure hydrogen is liquefied and stored, but various technologies are currently disclosed in order to overcome the risk of accident or leakage through a safer tank structure. For this, Korean Patent Publication No. 10-0804789 ("Liquid for low pressure liquefaction") Hydrogen storage container", 2007.08.12. Announcement) and Korean Patent Publication No. 10-2006-0130846 ("How to configure a high pressure liquefied hydrogen storage tank", published on December 20, 2006).

However, even if the liquefied high-pressure hydrogen is stored in a safer and more robust tank as described above, since the hydrogen vehicle has a built-in hydrogen therein, the risk is lowered and there is still a problem.

KR 10-0804789 B1 ("Low pressure liquefied hydrogen storage container") 2007.08.12. Announcement KR 10-2006-0130846 A ("How to construct a high-pressure liquefied hydrogen storage tank") 2006.12.20. open

The present invention has been devised to solve the problems of the prior art, a hydrogen production device and hydrogen that is formed so as to be able to run even when a hydrogen vehicle is driven by generating hydrogen only in the required quantity, so that a high-pressure hydrogen tank or a liquefied hydrogen tank is not built in. It relates to a hydrogen vehicle using a production device.

Hydrogen production apparatus of the present invention for achieving the above object, the alkali metal storage tank 100; A hydrogen gas generator 300 in which a fluid containing water is built in, and the alkali metal supplied from the alkali metal storage tank 100 reacts with the water to generate hydrogen gas; And a hydrogen gas storage unit 400 receiving hydrogen gas from the hydrogen gas generation unit 300.

In this case, the present invention may further include a neutralization unit 600 for neutralizing the fluid of the hydrogen gas generating unit 300.

In addition, a pH sensor 320 for measuring the pH concentration of the fluid is formed in the hydrogen gas generating unit 300, and when the pH concentration of the fluid is higher than a reference value, the fluid is discharged to the neutralization unit 600. It can be characterized by.

In addition, the present invention further includes a neutralization solution storage tank for supplying a neutralization solution to the neutralization unit, wherein the neutralization solution is an acidic aqueous solution.

In addition, a capacitive deionization (CDI) electrode including a positive electrode and a negative electrode is formed in the neutralizing portion to remove spectator ions.

In addition, the present invention further includes; a raw water storage tank that receives the fluid discharged from the neutralization unit, and the fluid discharged from the neutralization unit may be distributed to the raw water tank and the hydrogen gas generator.

Herein, in the present invention, when the storage amount of the storage tank 700 of the aqueous hydrochloric acid solution is lower than a reference amount or when a power higher than the reference is used in the storage type desalination electrode of the neutralization unit, the fluid of the hydrogen gas generator 300 is the neutralization unit ( 600 may be stored in the hydrochloric acid aqueous solution storage tank 700, and the fluid of the raw water storage tank 200 may be supplied to the hydrogen gas generator 300.

In addition, the alkali metal of the present invention may be supplied in the form of a powder filled with an alkali metal in a porous mesoporous material.

The hydrogen vehicle using the hydrogen production apparatus of the present invention for achieving the above object, the hydrogen engine 500 that receives hydrogen from the hydrogen gas storage unit 400 to generate power; to be configured to further include Can be.

The hydrogen vehicle using the hydrogen production device and the hydrogen production device of the present invention according to the above configuration is configured to produce hydrogen gas in real time through alkali metal and water and supply it to the hydrogen engine, so that the driving environment of the hydrogen vehicle is more Provide it to be done safely.

In addition, the present invention is configured to control the increased pH concentration through the neutralization unit by reacting with an alkali metal and generating hydroxide ions. If an acid solution, which is a neutralization solution, is used for a certain amount or more, the solvent is stored through water stored in a raw water storage tank. It is configured to increase the amount of water to lower the pH concentration, so that neutralization can be performed more efficiently.

1 is a system configuration diagram of a hydrogen production apparatus according to an embodiment of the present invention.
2 is a schematic diagram of a hydrogen gas generating unit according to an embodiment of the present invention.
3 and 4 are views showing the operation flow of the hydrogen production apparatus according to an embodiment of the present invention.

Hereinafter, a hydrogen production apparatus and a hydrogen vehicle using the hydrogen production apparatus according to various embodiments of the present invention will be described in detail with reference to the accompanying drawings. The drawings introduced below are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art. Therefore, the present invention is not limited to the drawings presented below and may be embodied in other forms. In addition, the same reference numbers throughout the specification indicate the same components.

At this time, unless there are other definitions in the technical terms and scientific terms used, it has the meanings commonly understood by those skilled in the art to which this invention belongs, and the subject matter of the present invention is unnecessary in the following description and accompanying drawings Descriptions of well-known functions and configurations that may be blurred will be omitted.

1 relates to an embodiment of a hydrogen vehicle using the hydrogen production device and the hydrogen production device of the present invention, Figure 1 shows a system configuration of the hydrogen production device.

Referring to Figure 1, the present invention, the alkali metal storage tank 100, the fluid containing water is embedded, the alkali metal (M) and the water (H ₂ O) supplied from the alkali metal storage tank 100 ) May be made of a hydrogen gas generating unit 300 in which hydrogen gas is generated by reaction, and a hydrogen gas storage unit 400 receiving hydrogen gas from the hydrogen gas generating unit 300.

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At this time, in the hydrogen gas generator 300, alkali metal (M) and water (H ₂ O) react as shown in the above formula to generate alkali hydroxide (MOH) and hydrogen gas (H ₂ ), and the hydrogen gas is generated. Water is embedded in the unit 300 and may be configured to control the amount of hydrogen gas produced by controlling the supply amount of the alkali metal.

At this time, the alkali metal (M) is a Group 1 metal such as lithium (Li), sodium (Na), potassium (K), rubidium (Rb), cesium (Cs), and francium (Fr), or calcium (Ca) or magnesium ( Mg), may be selected from alloys containing the same, and may be more economically configured when selected from lithium (Li), sodium (Na), and potassium (K). Among the reaction schemes, sodium (Na) is typically selected, and the present invention is more clearly described.

An alkali metal supply unit 110 may be connected to the alkali metal storage tank 100, and the alkali metal supply unit 110 converts the alkali metal inside the alkali metal storage tank 100 to the hydrogen gas generator 300. It can be configured to supply. At this time, the supplying method may be configured by adjusting the self-weight and the opening amount of the damper, or may be configured by applying currently well-known methods such as supplying through a motor and a screw. In addition, an alkali metal may be provided through the alkali supply pipe L ₁ between the alkali metal supply unit 110 and the hydrogen gas generator 300.

In addition, the alkali metal embedded in the alkali metal storage tank 100 may be stored in a powder form filled with an alkali metal in a porous mesoporous material. At this time, the porous mesoporous material may be formed of silica gel or the like, wherein the alkali metal is configured to exist in the silica gel in a neutral state, or a mixture is prepared by mixing a group 1 metal and silica gel under exothermic conditions, or the The mixture may be formed in various forms, such as heating to form a composition.

In addition, a hydrogen gas supply pipe (L ₃ ) is provided between the hydrogen gas generator 300 and the hydrogen gas storage unit 400 so that the hydrogen gas generated inside the hydrogen gas generator 300 is the hydrogen gas storage unit. It may be configured to move to 400. At this time, a check valve CV is formed on the hydrogen gas supply pipe L ₃ to prevent hydrogen gas from flowing back from the hydrogen gas storage unit 400 to the hydrogen gas generator 300.

In addition, the present invention may be configured to further include a neutralization unit 600 for neutralizing the fluid inside the hydrogen gas generation unit 300, the neutralization unit 600 is the hydrogen gas generation unit 300 and the solution discharge pipe doedoe connected to (L _4), a first control valve (V ₁₎ on the solution outlet pipe (L ₄₎ are formed may be arranged to control the flow of fluid.

And the present invention may further include a neutralization solution storage tank 700 for supplying a neutralization solution to the neutralization unit 600. At this time, the neutralizing solution may be composed of an acidic substance that reacts with the alkali hydroxide, such as hydrochloric acid, sulfuric acid, etc., and the acidic substance may be composed of an aqueous solution. In addition, a flow control valve (F.V) is disposed between the neutralization unit 600 and the neutralization solution storage tank 700 to be configured to control the flow rate of the neutralization solution supplied from the neutralization solution storage tank 700. In addition, the basic fluid discharged from the hydrogen gas generating unit 300 and the acidic fluid provided from the neutralization solution storage tank 700 react with each other to be neutralized by generating water.

Wherein if the response to each other sodium (NaOH) and hydrochloric acid (HCl) hydroxide, sodium ion (Na ⁺⁾ and chlorine ion (Cl ^-) is the internal fluid of the spectator ions (spectator ion) as does not participate in the reaction scheme the central 600 Can remain on. At this time, it may be configured to purify more pure water through a device configuration that performs reverse osmosis membrane, evaporation, ion exchange, etc. to remove residual salt or ions. Furthermore, in the present invention, the neutralization unit 600 of the present invention is provided with a capacitive deionization (CDI) electrode including a positive electrode and a negative electrode, and configured to adsorb the sodium ions and chlorine ions. The fluid discharged from 600) may be formed to be closer to pure water.

At this time, the capacitive desalination electrode is operated as an electrode equipped with a positive electrode and a negative electrode, and a technology using a principle that a cationic material is a negative electrode and an anionic material is adsorbed and desalted as an electric field is formed between the positive electrode and the negative electrode. to be. The ions adsorbed on the electrode are desorbed and concentrated when the electric field is removed, and the ions are adsorbed when the electric field is again formed, making operation easy. Therefore, since adsorption and desorption can be repeatedly controlled by regulating the flow of electric current to form an electric field, no chemical is required for regeneration, and because it is operated at a relatively low voltage of about 1.5 V or less, where no water decomposition reaction occurs. When desalting a concentration below the radix, it has the advantage of low energy consumption compared to other desalination techniques. In addition, since adsorption and desorption are performed electrically, there is no disadvantage that the recovery rate due to a low flow rate is lowered during desorption, and thus has an excellent advantage that there is no restriction on the flow rate.

In addition, the capacitive desalination electrode may include a graphite layer capable of stably transferring electrons in water or a current collector including the same, and a carbon layer laminated on the graphite layer to improve ion adsorption rate. In addition, in order to improve the adsorption performance and current efficiency of the ions, an ion exchange membrane layer laminated on the surface of the carbon layer may be further included.

In the present invention, when the acidic solution such as hydrochloric acid (HCL) is composed of an aqueous solution, the amount of fluid discharged from the neutralization unit 600 is greater than the fluid discharged from the hydrogen gas generation unit 300. . Accordingly, the present invention may be made to further include a raw water storage tank 200 to receive a portion of the fluid discharged from the neutralization unit 600. And the other part of the fluid may be configured to be recovered to the hydrogen gas generator 300.

Here, the pipe through which the fluid discharged from the neutralization unit 600 flows can be connected to a three-way valve (TV), and from the three-way valve (TV) to the raw water storage tank 200 and the hydrogen gas generator 300 It can be configured to control the amount of fluid supplied. In addition, the neutralization unit 600 may be connected to the hydrogen gas generation unit 300 and the raw water storage tank 200, respectively.

Here, a second control valve V ₂ may be configured on a pipe through which the fluid discharged from the neutralization unit 600 flows, and the flow control of the fluid through the second control valve V2 is illustrated in FIGS. 3 and 3 described below. This will be described in more detail in 4.

In addition, when a hydrogen vehicle is configured using the hydrogen production apparatus of the present invention, the hydrogen engine 500 connected to the hydrogen gas storage unit 400 may be further included. In this case, the hydrogen engine 500 may be configured in various forms, such as a hydrogen fuel engine that generates power by directly burning hydrogen or a hydrogen fuel cell engine that generates power by generating electricity from hydrogen. In addition, various valves V, such as a check valve, a flow control valve, and a control valve, may be disposed between the hydrogen gas storage unit 400 and the hydrogen engine 500.

2 relates to an embodiment of a hydrogen vehicle using a hydrogen production device and a hydrogen production device of the present invention, Figure 2 shows a schematic diagram of a hydrogen gas generator.

Referring to FIG. 2, in the hydrogen gas generator 300 of the present invention, a water level sensor 310 and a pH sensor 320 may be disposed therein. At this time, the water level sensor 310 may measure the amount of fluid, and the pH sensor 320 may measure the pH concentration of the fluid.

Here, the water level sensor 310 is composed of a capacitive level sensor or an ultrasonic level sensor, and may be configured to measure the level of the fluid in the hydrogen gas generator 300. In addition, an alkali supply pipe (L ₁ ), a raw water supply pipe (L ₂ ), a hydrogen gas supply pipe (L ₃ ), and a solution discharge pipe (L ₄ ) may be connected to the hydrogen gas generator 300, as follows.

The alkali supply pipe L ₁ is configured such that the alkali metal M stored in the alkali metal storage tank 100 is transferred through the alkali metal supply unit 110 as described above, within the hydrogen gas generation unit 300. Can supply. And the alkali metal (M) may generate hydrogen gas (H ₂ ) in contact with the fluid (F). At this time, the hydrogen gas (H ₂ ) may be transported to the hydrogen gas storage unit 400 along the hydrogen gas supply pipe (L ₃ ).

In addition, the raw water supply pipe (L ₂ ) and the solution discharge pipe (L ₄ ) may be formed to supply fluid into the hydrogen gas generator 300 or discharge the fluid in the hydrogen gas generator 300, respectively.

At this time, the raw water supply pipe L ₂ may be connected to the raw water storage tank 200 or the neutralization unit 600 to receive a neutralized fluid, and the solution discharge pipe L ₄ may supply the internal fluid to the neutralization unit ( 600). At this time, whether or not the solution discharge pipe L ₄ is discharged may be opened or closed according to the fluid pH concentration inside the hydrogen gas generator 300 or the discharge flow rate may be adjusted.

To explain this additionally, the present invention generates hydrogen gas through the reaction of the alkali metal (M) with water in the fluid, and alkali hydroxide is generated to gradually increase the pH concentration of the fluid. Accordingly, the production efficiency of hydrogen gas is gradually lowered, and when the alkali hydroxide reaches the saturation state, a problem that the reaction is remarkably lowered may occur. Accordingly, the present invention can measure the pH concentration of the fluid in real time through the pH sensor 320, and can be configured to open the flow path toward the solution discharge pipe (L ₄ ) when the pH concentration exceeds a certain level. . Alternatively, the present invention is configured to continuously discharge a certain amount, but when the pH concentration is higher than a certain level, it can be configured by increasing the amount discharged to the solution discharge pipe (L ₄ ) by adjusting the opening amount, and the alkali supply pipe ( It may be configured to calculate the pH concentration through the amount of the alkali metal supplied from L ₁ ), or the amount of hydrogen gas supplied to the hydrogen gas supply pipe (L ₃ ).

In addition, the level of the fluid in the hydrogen gas generator 300 may be set lower than the alkali supply pipe L ₁ , and the pH sensor 320 may be configured to contact the fluid. Accordingly, the user may set the fluid level detected by the water level sensor 310 to be maintained between the pH sensor 320 and the first alkali supply pipe L ₁ , or may be set within the range. And the solution discharge pipe (L4) may be configured to be formed on the bottom surface of the hydrogen gas generating unit 300 to discharge the fluid on the lower side.

3 and 4 relates to an embodiment of the present invention hydrogen production apparatus and a hydrogen vehicle using the hydrogen production apparatus, Figures 3 and 4 show the operation flow diagram of the hydrogen production apparatus, respectively.

3 and 4, the present invention discharges the fluid of the hydrogen gas generator 300 to the neutralization unit 600 as described above, in the neutralization unit 600, the neutralization solution storage tank It may be configured to neutralize by receiving an acidic solution from (700). In addition, a portion of the fluid neutralized in the neutralization unit 600 is stored in the raw water storage tank 200, and the rest of the fluid may be configured to be recovered by the hydrogen gas generation unit 300. At this time, the amount discharged from the hydrogen gas generator 300 and the amount recovered may be configured to correspond to each other, and the amount of recovery may be adjusted to be maintained within a certain level according to a user setting.

Next, referring to FIG. 4, the present invention is a first controller 810 disposed between the neutralization unit 600 and the neutralization solution storage tank 700, the raw water storage tank 200, and a hydrogen gas generator 300 ) And a second controller 820 disposed between the neutralization unit 600.

When the amount of the acidic solution stored on the neutralization solution storage tank 700 is less than or equal to a predetermined level, the first controller 810 blocks the flow path from the neutralization solution storage tank 700 to the neutralization unit 600, It may be formed to open a flow path from the neutralization unit 600 to the neutralization solution storage tank 700. Accordingly, the fluid that has passed through the neutralization unit 600 may be stored on the neutralization solution storage tank 700.

In addition, the second control valve (V ₂ ) formed on the flow path from the neutralization unit 600 to the three-way valve (TV) blocks the flow path, but the second controller 820 is the raw water storage tank 200 In may be formed to open the flow path toward the hydrogen gas generating unit 300. Accordingly, the pH concentration control on the hydrogen gas generator 300 is neutralized by increasing the amount of the neutralized solvent after neutralization, and has the advantage of being more efficient while maintaining hydrogen gas generation for a long time. At this time, a power device such as a pump for allowing fluid to move on the flow path is not shown separately, but may be formed on the first controller 810 and the second controller 820 or the solution discharge pipe L ₄ , and the neutralization unit The capacitive desalination electrode in 600 may be formed to be detachable from the outside, and may be configured to be maintained when charging an alkali metal or neutralizing solution.

Here, the present invention may be configured to further include a control unit and a battery in which power is stored to control the first controller 810 and the second controller 820, valves, pumps, and sensors. In addition, the electric power controlled so that the alkali metal is supplied from the alkali metal storage tank 100 is supplied by operating the hydrogen engine 500 through hydrogen gas pre-stored in the hydrogen gas storage unit 400, or power stored in the battery. It may be made to supply.

As described above, in the present invention, specific matters such as specific components and the like have been described by the limited embodiment drawings, but these are provided only to help the overall understanding of the present invention, and the present invention is limited to the above-described one embodiment No, those skilled in the art to which the present invention pertains can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention is not limited to the described embodiments, and should not be determined, and all claims that are equivalent or equivalent to the scope of the present invention as well as the scope of the claims described below belong to the scope of the spirit of the present invention. will be.

CV: Check valve F: Fluid
FV: Flow control valve L ₁ : Alkaline supply pipe
L ₂ : Raw water supply pipe L ₃ : Hydrogen gas supply pipe
L ₄ : Solution discharge tube M: Alkali metal
TV: 3-way valve V1: 1st control valve
V2: Second control valve
100: alkali metal storage tank 110: alkali metal supply unit
200: raw water storage tank
300: hydrogen gas generator
310: water level sensor 320: pH sensor
400: hydrogen gas storage unit
500: hydrogen engine
600: Chinese Department
700: Neutralization solution storage tank
810: 1st controller 820: 2nd controller

Claims (9)

Alkali metal storage tanks;
A hydrogen gas generator in which a fluid containing water is built in, and the alkali metal supplied from the alkali metal storage tank reacts with the water to generate hydrogen gas; And
A hydrogen gas storage unit receiving hydrogen gas from the hydrogen gas generation unit;
Hydrogen production device comprising a.
According to claim 1,
A neutralization unit for neutralizing the fluid of the hydrogen gas generation unit;
Hydrogen production device further comprising.
According to claim 1,
A pH sensor for measuring the pH concentration of the fluid is formed in the hydrogen gas generator,
When the pH concentration of the fluid is higher than the reference value, the hydrogen production device, characterized in that for discharging the fluid to the neutralization unit.
According to claim 2,
A neutralization solution storage tank that supplies a neutralization solution to the neutralization unit;
Further comprising,
The neutralizing solution is a hydrogen production device, characterized in that the acidic aqueous solution.
The method of claim 4,
A hydrogen production device characterized in that a capacitive deionization (CDI) electrode including a positive electrode and a negative electrode is formed in the neutralizing portion to remove spectator ions.
The method of claim 4,
A raw water storage tank accommodating the fluid discharged from the neutralization unit;
Further comprising,
The fluid discharged from the neutralization unit,
Hydrogen production apparatus characterized in that it is distributed to the raw water tank and the hydrogen gas generator.
The method of claim 6,
If the storage amount of the storage tank of the hydrochloric acid aqueous solution is lower than the reference amount or when the electric power of the reference level or higher is used in the storage type desalination electrode of the neutralization unit
The hydrogen gas generating unit fluid is stored in the hydrochloric acid aqueous solution storage tank through the neutralization unit,
Hydrogen production apparatus, characterized in that the fluid of the raw water storage tank is supplied to the hydrogen gas generator.
According to claim 1,
The alkali metal is a hydrogen production device characterized in that the porous mesoporous material is supplied in the form of a powder filled with alkali metal.
For hydrogen cars,
The hydrogen production apparatus according to any one of claims 1 to 8; And
A hydrogen engine that receives hydrogen from the hydrogen gas storage unit to generate power;
Hydrogen vehicle comprising a.

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