KR20180010601A - Submarine hydrogen generator which maintains the pressure equalizing apparatus - Google Patents

Abstract

The present invention relates to an apparatus for generating hydrogen in an underwater state in which a pressure balance is maintained, and more particularly, to a hydrogen generator for generating hydrogen by reacting an electrolytic solution with a metal fuel in an underwater vessel such as a submarine, The present invention relates to an apparatus for generating hydrogen underwater in which pressure equilibrium is maintained such that active hydrogen equilibrium can be obtained by injecting or discharging compressed air into each device for pressure balance between supply devices.
The present invention is characterized in that a space for accommodating metal fuel is formed on the inner side and a reactor is connected to an electrolyte supply part for supplying an electrolyte from an electrolyte supply device for reacting with the metal fuel on one side, The pressure of the electrolyte supply device and the pressure of the reactor are adjusted so as to be balanced with each other.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hydrogen generator,

The present invention relates to an apparatus for generating hydrogen in an underwater state in which a pressure balance is maintained, and more particularly, to a hydrogen generator for generating hydrogen by reacting an electrolytic solution with a metal fuel in an underwater vessel such as a submarine, The present invention relates to an apparatus for generating hydrogen underwater in which pressure equilibrium is maintained such that active hydrogen equilibrium can be obtained by injecting or discharging compressed air into each device for pressure balance between supply devices.

In general, the use of fuel cells in batteries other than batteries as a means of storing energy in aquariums including submarines is greatly increasing.

The fuel cell converts the chemical energy generated by the oxidation of the fuel into direct electrical energy. The fuel cell continuously supplies the gas reactant such as hydrogen from the outside continuously to generate electricity, and the produced material is continuously discharged to the outside of the reaction system This is a kind of high-efficiency, pollution-free power generation equipment characterized by the fact that

Although the technology using hydrogen as fuel has been developed so far, the technology for safely producing, storing or moving hydrogen fuel is still required in the field of hydrogen fuel cell.

Therefore, much effort has been focused on the technology of generating and storing hydrogen, and there are already many prior art technologies for generating hydrogen using the corrosion reaction of metals. However, the technology for controlling or storing the hydrogen generation reaction is still difficult to develop and is not generalized.

In addition, in order to continuously generate hydrogen in the water and use it as a fuel cell, the metal fuel reacts continuously with the electrolyte solution and the metal fuel is discharged to the outside of the reactor, and new metal fuel is continuously supplied.

Particularly, for continuous hydrogen generation, it is important to regulate the reaction or to supply the electrolytic solution and the metal fuel, but more importantly, the pressure of the reactor and the electrolyte supply device must be balanced with each other to continuously generate hydrogen. .

1. Korean Patent No. 10-1030121 2. Korean Patent No. 10-1544534

SUMMARY OF THE INVENTION It is an object of the present invention to provide a hydrogen generator for generating hydrogen by reacting an electrolytic solution with a metal fuel in an underwater vessel such as a submarine, The present invention provides an apparatus for generating hydrogen in an underwater compartment in which pressure equilibrium is maintained so that active hydrogen equilibrium can be obtained by injecting or discharging compressed air into each device for equilibration.

According to an aspect of the present invention, there is provided a fuel cell system including a reactor having a space for receiving a metal fuel therein and connected to an electrolyte supply part for supplying an electrolyte solution from an electrolyte supply device for reacting with the metal fuel, The pressure of the electrolyte solution supply device and the pressure of the reactor are adjusted so that they are in equilibrium with each other when the pressures of the electrolyte solution supply device and the reactor are different from each other.

In one embodiment, the pressure balance is characterized by pressure balance by electronic control or direct control.

In one embodiment, the pressure balance through the electronic control may include a pressure measurement unit in each of the electrolyte supply device and the reactor, each of the pressure measurement units may be connected to each other, and a pressure balance control unit may be provided therebetween, The pressure is controlled by the pressure balance control unit so that the pressure of each of the electrolytic solution supply unit and the reactor is compared and if the pressure is smaller than or greater than a predetermined pressure, the internal pressure of the reactor and the electrolyte supply unit are parallel.

In one embodiment, the pressure balance through the direct control is characterized by equilibrating the pressure of the reactor and the electrolyte supply device by connecting a pressure equalization pipe to connect the reactor and the electrolyte supply device.

In one embodiment, the separator and the electrolyte supply unit further include a heat exchanger disposed between the separator and the electrolyte supply unit to cool the temperature of the electrolyte, which reacts with the metal fuel and is heated by the exothermic reaction.

In one embodiment, a filter composed of one or more layers is provided on the inside thereof, and the metal fuel, which is sequentially reduced in size by reacting with the electrolyte solution, is configured to drop downward.

In one embodiment, the filter is composed of three layers in total, and the permeation net is formed denser toward the lower part.

In one embodiment, the reactor further comprises a metal fuel supply for supplying metal fuel in the form of a ball to the upper surface of the uppermost filter.

In one embodiment, the PH measurement unit is connected to the outside of the reactor to adjust the reaction rate by controlling the concentration of the electrolyte, which is a catalyst inside the reactor.

In one embodiment, the electrolyte supply unit further includes a pump 180 provided between the heat exchangers to pump the electrolyte supplied to the reactor.

In one embodiment, further between the pump and the reactor is a control valve for regulating the amount of electrolyte inflow.

In one embodiment, the metal fuel is formed of any one of magnesium, a magnesium alloy, aluminum, and an aluminum alloy.

In one embodiment, the electrolytic solution is characterized by being composed of sodium hydroxide or potassium hydroxide.

According to the hydrogen generating apparatus of the present invention in which the pressure equilibrium is maintained, first, compressed air is injected into or discharged from each device for pressure balance between the reactor and the electrolyte supplying device for supplying the electrolyte, So that it is possible to produce stable hydrogen, thereby improving the hydrogen generation efficiency.

Secondly, since the pressure equilibrium is made to be pressure balanced by electronic control or direct control, it can be suitably used according to the environment, and can be selectively used in various environments, thereby increasing the range of use.

Thirdly, in the hydrogen generator, the metal fuel, which is not reacted due to the small volume when the electrolytic solution reacts with the metal fuel to generate hydrogen, is processed through the separator. Thus, in order to remove the metal fuel to be discarded, It is possible to continuously generate hydrogen.

Fourth, since the electrolytic solution and the metal fuel are continuously supplied as much as the electrolytic solution and the metal fuel discharged to the separator, there is an effect that continuous hydrogen generation is possible.

FIG. 1 is a schematic view schematically showing an apparatus for generating hydrogen underwater in which pressure equilibrium is maintained through electronic control of the present invention. FIG.
FIG. 2 is a schematic view schematically showing an apparatus for generating hydrogen underwater in which pressure equilibrium is maintained through direct control of the present invention. FIG.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings, in order to explain the hydrogen generating apparatus of the present invention in which the pressure balance is maintained.

FIG. 1 is a schematic view schematically showing a hydrogen generating apparatus of an underwater vessel in which pressure equilibrium is maintained through electronic control according to the present invention. FIG. 2 is a schematic diagram of a hydrogen generating apparatus for underwater humidification in which pressure balance is maintained through direct control of the present invention Fig.

1 and 2, an apparatus for generating hydrogen in an underwater compartment in which a pressure balance is maintained according to the present invention includes a space in which a metal fuel is received, and an electrolyte supply device 112 And an electrolytic solution supply unit 110 to which an electrolytic solution is supplied. When the pressures of the electrolyte solution supply device 112 and the reactor 100 are different from each other, the pressures of the electrolyte solution supply device 112 and the reactor 100 are adjusted to balance each other, To derive the condition.

Here, the reactor 100 is formed in a housing shape, and a space for the metal fuel and the electrolyte to react with each other is formed on the inner side. Here, the metal fuel may be any one of magnesium, a magnesium alloy, aluminum, and an aluminum alloy, and the electrolyte may be sodium hydroxide, potassium hydroxide, or the like.

Meanwhile, the hydrogen generating apparatus of the present invention in which the pressure balance is maintained can be divided into two embodiments, one of which is pressure balance by electronic control and the other is pressure balance by direct control For example.

First, the electronic pressure equilibrium will be described.

The pressure equilibrium through the electronic control is provided with pressure measurement units 111 and 171 in the electrolyte supply device 112 and the reactor 100 respectively and the pressure measurement units 111 and 171 are connected to each other do. A pressure balance control unit 113 is provided between the reactor 100 and the reactor 100 to compare the pressures of the electrolytic solution supply unit 112 and the reactor 100. When the pressure is smaller or larger than a preset pressure, The pressure is controlled by the pressure equalization control unit 113 so that the internal pressure of the device 112 becomes parallel.

A heat exchanger 140 is provided between the separator 120 and the electrolyte supply unit 110 to cool the temperature of the electrolyte that reacts with the metal fuel in the reactor 100 and is raised by the exothermic reaction. . That is, in the reactor 100, when the electrolytic solution and the metal fuel react with each other to generate hydrogen, an exothermic reaction occurs, so that the temperature of the electrolytic solution rises. Therefore, the heat exchanger 140 is provided to cool the reactor 100 when it is introduced into the reactor 100 again.

Meanwhile, the reactor 100 includes a filter 150 formed of at least one layer on its inner side so that the metal fuel, which is sequentially reduced in size, reacts with the electrolytic solution and drops down to the bottom. It is preferable that the filter 150 is configured so that the density of the filter 150 becomes smaller as it goes down. In the figure, the filter 150 is composed of three layers, and the permeation net is densely formed toward the lower part. However, the number of the filters 150 may vary depending on the capacity of the reactor 100, And can be appropriately configured and used.

Meanwhile, a metal fuel supply unit 160 for supplying metal fuel in a ball shape to the upper surface of the uppermost filter 150 is provided.

That is, since the metal fuel is supplied into the reactor 100 in the form of a ball, the metal fuels that have reacted with the electrolytic solution and have a reduced volume are passed through the filters 150 of each layer and finally introduced into the separator 120 And the amount of metal fuel used is continuously supplied from the metal fuel supply unit 160. At this time, the water supply unit 161 is provided so as to be connected to the line through which the metal fuel is supplied in order to supply the metal fuel together with water.

Meanwhile, the PH sensor 170 is connected to the outside of the reactor 100 to control the reaction rate by controlling the concentration of the electrolyte, which is a catalyst inside the reactor 100. That is, since the reactant reacts with the metal fuel according to the amount and concentration of the electrolyte, the amount of hydrogen generated through the PH measuring unit 170 is uniformly controlled. In addition, when the concentration of the electrolytic solution is lowered by the water supplied through the water supply unit 161, the PH measuring unit 170 senses the concentration of the electrolytic solution and controls the electrolytic solution to be supplied to the reactor 100 as much as it is.

The reactor 100 may further include a temperature measuring unit 172 for measuring a temperature generated when the electrolyte and the metal fuel react with each other in the reactor 100 according to the concentration of the electrolyte, . This is for generating hydrogen stably by measuring heat and pressure generated in the reactor 100 when the electrolyte and the metal fuel react with each other.

That is, the PH measuring unit 170 and the temperature measuring unit 172 may be configured to measure an exothermic reaction generated when the electrolyte and the metal fuel react with each other in the reactor 100, a pressure inside the reactor 100 And the concentration of the electrolytic solution generate hydrogen while measuring all three items, thereby generating hydrogen of higher purity and producing stable hydrogen.

The electrolyte supply part 110 is provided between the pump 180 and the reactor 100 between the heat exchanger 140 and the pump 180 for pumping the electrolyte supplied to the reactor 100, A control valve 181 for controlling the amount of the electrolytic solution introduced may be further provided.

Therefore, when the electrolyte solution cooled in the heat exchanger 140 flows into the reactor 100, the electrolyte solution is stably supplied according to the amount and concentration of the electrolyte solution in the reactor 100.

Hereinafter, the pressure balance by the direct control will be described.

The hydrogen generating apparatus of the underwater vessel in which pressure equilibrium is maintained through the direct control of the present invention is the same in all constitutions as the hydrogen generating apparatus of the underwater vessel in which pressure equilibrium is maintained through electronic control. The pressure balance through the direct control is performed by connecting the pressure equalizing pipe 114 to connect the reactor 100 and the electrolyte supplying device 112 to balance the pressure of the reactor 100 and the electrolyte supplying device 112 Is different. That is, a pressure equalizing pipe 114 communicating with the reactor 100 and the electrolyte supplying device 112 is provided. When the pressures of the reactor 100 and the electrolyte supplying device 112 are different from each other, The pressure on both sides becomes equilibrium through the valve 114.

Hereinafter, the operating state of the hydrogen generating apparatus of the present invention having the above-described structure of the pressure balance maintained underwater will be described.

When the electrolytic solution and ball-shaped metal fuel are injected into the reactor 100 and driven, the electrolytic solution in the reactor 100 and the metal fuel react with each other to generate hydrogen, (101) and used as a fuel for underwater storage.

As the electrolyte and the metal fuel react with each other in the reactor 100, the volume of the metal fuel becomes small and passes through the filter 150 of the uppermost layer, and then is seated on the upper portion of the lower filter 150. Then, when the size becomes smaller, it passes through the filter 150 of the lowest layer, and then flows into the separator 120 like the electrolytic solution. The metal fuel in the electrolyte and the metal fuel introduced into the separator 120 is transferred to the storage tank 130 and collected.

Meanwhile, the electrolyte solution flows into the interior of the reactor 100 and reacts with the newly introduced metal fuel. Since the electrolyte discharged from the separator 120 reacts with the metal fuel in the reactor 100 and the temperature of the electrolyte increases due to the exothermic reaction, the temperature of the electrolyte is lowered through the heat exchanger 140 to be returned to the reactor 100 .

The metal fuel discharged from the reactor 100 is supplied to the reactor 100 in proportion to the amount of the metal fuel discharged through the metal fuel supplier 160 and is supplied to the reactor 100 together with water discharged from the water supplier 161 Is supplied.

On the other hand, in the reactor 100, since a chemical reaction is performed to generate hydrogen, heat is generated in the reactor, thereby increasing or decreasing the pressure.

At this time, a pressure difference is generated between the hydrogen electrolyte supply device 112 and the reactor 100, and the pressure difference is adjusted to increase the hydrogen generation efficiency. The pressure difference can be controlled by electronic control and direct control.

As described above, in the pressure balance by the electronic control, a pressure balance control unit 113 is provided between the electrolyte solution supply unit 112 and the pressure measurement units 111 and 171 of the reactor 100, The pressure of each of the reactor 100 and the reactor 100 is compared and when the pressure is smaller or larger than a predetermined pressure, the pressure in the reactor 100 and the electrolyte supply device 112 are parallel to each other, So that the pressure is controlled.

The pressure equilibrium by the direct control is obtained by providing a pressure equalizing pipe 114 communicating between the reactor 100 and the electrolyte supplying device 112 and controlling the pressures of the reactor 100 and the electrolyte supplying device 112 The pressure on both sides becomes equilibrium through the pressure equalizing pipe 114.

Since the metal fuel is supplied to the reactor 100 through the metal fuel supply unit 160 as much as the metal fuel is reacted with the electrolytic solution, Since the exhaust of the hydrogen generator is not stopped due to exhaustion, the efficiency of hydrogen generation is increased.

The embodiment of the hydrogen generating apparatus of the present invention in which the pressure balance is maintained as described above is merely an example, You can see that examples are possible. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: Reactor 101: Hydrogen outlet pipe
110: electrolytic solution supply line 111: electrolytic solution supply part pressure measurement unit
112: electrolyte supply device 113: pressure balance control part
114: pressure equalization pipe 115: pressure supply part
120: separator 130: storage tank
140: heat exchanger 150: filter
160: metal fuel supply unit 161: water supply unit
170: PH measuring section 171: Reactor pressure measuring section
172: temperature measuring unit 180: pump
181: Regulating valve

Claims (13)

And a reactor 100 in which a space for accommodating the metal fuel is formed on the inner side and an electrolyte supply part 110 for supplying the electrolyte solution from the electrolyte supply device 112 for reacting with the metal fuel is connected to one side,
The pressure of the electrolyte solution supply device 112 and the pressure of the reactor 100 are controlled so that they are in equilibrium with each other when the pressures of the electrolyte solution supply device 112 and the reactor 100 are different from each other. Apparatus for generating hydrogen in water. The method according to claim 1,
The pressure balance,
Wherein the pressure equilibrium is achieved by electronic control or direct control. 3. The method of claim 2,
The pressure balance through the electronic control,
Each of the electrolyte solution supply unit 112 and the reactor 100 is provided with pressure measurement units 111 and 171. The pressure measurement units 111 and 171 are connected to each other,
A pressure equalization control unit 113 is provided between the reactor 100 and the reactor 100 to compare the pressures of the respective reactors 100 and 100 with each other. 112) is controlled by a pressure equalization control unit (113) so that the internal pressure of the hydrogen storage tank (112) becomes parallel. 3. The method of claim 2,
The pressure balance through the direct control,
Wherein the pressure equalization pipe (114) is connected to connect the reactor (100) and the electrolyte supply device (112) to equalize the pressure of the reactor (100) and the electrolyte supply device (112) Hydrogen generator. The method according to claim 1,
Between the separator 120 and the electrolyte supply part 110,
Further comprising a heat exchanger (140) provided in the reactor (100) for cooling the temperature of the electrolytic solution which reacts with the metal fuel and is raised in temperature by the exothermic reaction. Device. The method according to claim 1,
The reactor (100)
And a filter 150 composed of one or more layers is provided on the inner side of the filter 150 so that the metal fuel, which is sequentially reduced in size, reacts with the electrolyte solution and falls down to the bottom. . The method according to claim 6,
The filter (150)
Wherein the pressure net is formed in three layers, and the permeation net is formed denser toward the lower part. 8. The method of claim 1 or 7,
The reactor (100)
Further comprising a metal fuel supply unit (160) for supplying metal fuel in a ball shape to an upper surface of the uppermost filter (150). The method according to claim 1,
The reactor (100)
And the pH measuring unit 170 is connected to the outside of the reactor 100 to control the reaction rate by adjusting the concentration of the electrolyte, which is a catalyst, in the reactor 100. 6. The method according to claim 1 or 5,
The electrolyte solution supply unit 110 supplies the electrolyte solution,
The apparatus of claim 1, further comprising a pump (180) disposed between the heat exchanger (140) to pump the electrolyte supplied to the reactor (100). 11. The method of claim 10,
The apparatus of claim 1, further comprising a control valve (181) between the pump (180) and the reactor (100) to regulate the amount of electrolyte flowing therein. The method according to claim 1,
The metal fuel may include,
Magnesium, magnesium alloy, aluminum, and an aluminum alloy, wherein the pressure equilibrium is maintained. The method according to claim 1,
The electrolyte solution,
Wherein the pressure equilibrium is maintained by the addition of sodium hydroxide or potassium hydroxide.

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