KR102656624B1 - Hydrogen Generator, Hydrogen Generation System and Hydrogen Supply System for Generator Cooling - Google Patents

Abstract

The present invention relates to a hydrogen generation device, a hydrogen generation system, and a hydrogen supply system for cooling a generator, including a cathode where hydrogen ions are converted into hydrogen gas when energized, and a cathode where water is converted into hydrogen ions, oxygen gas, and electric charge when energized. An ion exchange membrane located between the anode, the cathode, and the anode, which transfers hydrogen gas generated from the anode to the cathode, a cathode chamber formed on one side of the ion exchange membrane to embed the cathode, and an anode chamber formed on the other side of the ion exchange membrane to embed the anode, It includes a current distribution plate built into each of the cathode and anode chambers to transfer the charge to the cathode or receive the charge from the anode, and generates hydrogen gas by electrolyzing water (pure water), so it is a hydrogen generator (electrolysis device). If a problem occurs in the cell, it is easy to replace and maintain the hydrogen generating device, and an appropriate amount of hydrogen gas can be continuously supplied to the generator through the front-end pressure regulator and back-end pressure regulator. In particular, the three-way valve allows hydrogen gas to be supplied to the generator. Provided is a hydrogen generation device, a hydrogen generation system, and a hydrogen supply system for cooling a generator, which prevents explosions due to ignition of hydrogen gas by discharging hydrogen gas into the atmosphere when there is a possibility of leakage exceeding the appropriate level.

Description

Hydrogen generator, hydrogen generation system and hydrogen supply system for generator cooling {Hydrogen Generator, Hydrogen Generation System and Hydrogen Supply System for Generator Cooling}

The present invention relates to a hydrogen generation device, a hydrogen generation system, and a hydrogen supply system for cooling a generator. It generates hydrogen gas by electrolyzing pure water, thereby generating hydrogen that is safe and can continuously supply a uniform amount of hydrogen gas to the generator. It relates to devices, hydrogen generation systems and hydrogen supply systems for generator cooling.

In general, in the case of large power plants, generators are cooled during operation to prevent overheating, and hydrogen is used as a refrigerant. To increase cooling efficiency, hydrogen is supplied to the generator at a pressure above atmospheric pressure, for example, 2.0 - 5.0 bar.

A certain amount of hydrogen continues to leak from the generator, resulting in hydrogen loss. For efficient and stable operation of the generator, lost hydrogen must be continuously replenished. As a method for this, a method of supplying hydrogen gas using a cylinder or supplying hydrogen generated by electrolyzing alkali (KOH; potassium hydroxide) is known.

However, there is always a risk of explosion when distributing stored hydrogen and supplying it to each generator. In particular, careless actions when replacing or handling storage containers can cause very dangerous accidents.

Although a natural ventilation system that circulates atmospheric air can be applied to a storage container with dense hydrogen gas storage containers, the risk of hydrogen ignition when replacing or handling the storage container is not completely eliminated.

In addition, when hydrogen is generated by electrolyzing alkali (KOH; potassium hydroxide), the hydrogen generated through electrolysis is purified and then supplied to the generator using a compressor. However, if a problem occurs in the electrolytic cell where electrolysis occurs or the compressor that pressurizes purified hydrogen, it is difficult to replace the electrolytic cell and compressor due to the chemical characteristics of alkali (KOH; potassium hydroxide), and there is a risk of injury to workers. is high. Additionally, since the compressor is essential, power consumption is high.

Republic of Korea Patent Publication No. 10-2018-0085672 (2018.07.27.)

Accordingly, the purpose of the present invention, which was invented in consideration of the above points, is to reduce the risk of explosion due to hydrogen gas ignition, to continuously generate hydrogen gas from water (pure water) without using a separate electrolyte solution, and to provide uniformity. The aim is to provide a hydrogen generation device that can continuously supply a certain amount of hydrogen gas to a generator, a hydrogen generation system, and a hydrogen supply system for cooling the generator.

In order to achieve the above object, the hydrogen generating device of one embodiment of the present invention is located between the cathode where hydrogen ions are converted into hydrogen gas, the anode where water is converted into hydrogen ions, oxygen gas, and electric charge, and the cathode and the anode. An ion exchange membrane that transfers hydrogen ions generated from the anode to the cathode, a cathode chamber formed on one side of the ion exchange membrane to embed the cathode, and an anode chamber formed on the other side of the ion exchange membrane to embed the anode, and transfer charges to the cathode or It includes a current distribution plate built into each of the cathode and anode chambers to receive electricity from the anode.

In addition, the cathode chamber and the anode chamber are positioned to face each of one side and the other side of the ion exchange membrane, a box-shaped frame with openings on the upper and lower sides, and a separator plate covering one side of the frame that is open to seal the cathode chamber and the anode chamber; It includes packing installed between the frame and the separator plate to prevent leakage of water and gas present in the cathode and anode chambers, and the frame and packing are used to discharge water and hydrogen gas present in the cathode chamber or to the anode chamber. Holes may be formed to allow the existing water and oxygen gas to escape.

Additionally, the cathode chamber may further include a pressure pad that secures the current distribution plate located inside the cathode chamber.

Additionally, the area of the ion exchange membrane may be larger than the area of the current distribution plate, and the area of the current distribution plate may be larger than the areas of the cathode and anode.

Additionally, the current distribution plate built in the cathode chamber and the current distribution plate built in the anode chamber may be connected to each other outside the cathode chamber and the anode chamber.

Additionally, the current distribution plate built into the cathode chamber and the current distribution plate built into the anode chamber can be individually connected to an external power supply.

In order to achieve the above object, the hydrogen generation system of one embodiment of the present invention includes a hydrogen generation device, a first storage tank that supplies water to the anode chamber and recovers water and oxygen gas from the anode chamber. It further includes a second storage tank that recovers water and hydrogen gas from the cathode chamber, and a gas purifier that evaporates moisture from the hydrogen gas collected in the second storage tank.

In addition, a first pipe that supplies water to the first storage tank, a second pipe that connects the first storage tank and the anode chamber to supply water, and a second pipe that connects the first storage tank and the anode chamber to recover water and oxygen gas. 3 pipes, a fourth pipe connecting the second storage tank and the cathode chamber to recover water and hydrogen gas, and a fourth pipe connecting the second storage tank and the second pipe to supply water present in the second storage tank to the anode chamber. 5 pipe, a 6th pipe connecting the second storage tank and the gas purifier to supply the hydrogen gas collected in the second storage tank to the gas purifier, and a 6th pipe connecting the gas purifier to the gas purifier to deliver the hydrogen gas from which moisture has been removed from the gas purifier to an external device. It may further include a seventh pipe connected to the first storage tank and an eighth pipe connected to the first storage tank to transfer the oxygen gas collected in the first storage tank to an external device.

In order to achieve the above object, the hydrogen supply system for generator cooling of an embodiment of the present invention includes a hydrogen generator, a refrigerant supply line connecting the cathode chamber and the generator cooling line, and a cathode. A front-end pressure regulator provided at the front of the refrigerant supply line so that hydrogen gas generated in the room flows into the refrigerant supply line while maintaining an appropriate flow rate, and a refrigerant supply so that hydrogen gas flowing in the refrigerant supply line flows into the cooling line while maintaining an appropriate flow rate. It further includes a rear-end pressure regulator provided at the rear end of the line, and a three-way valve mounted on the refrigerant supply line to be positioned between the front-end pressure regulator and the rear-end pressure regulator.

Additionally, the downstream pressure regulator may discharge some of the hydrogen gas that has reached the downstream pressure regulator into the atmosphere when the amount of hydrogen gas that has reached the downstream pressure regulator through the refrigerant supply line exceeds an appropriate value.

Additionally, the three-way valve can discharge some of the hydrogen gas that has reached the three-way valve into the atmosphere when the amount of hydrogen gas flowing in the refrigerant supply line exceeds the appropriate value.

In addition, pressure sensors may be located at the front and rear of the front-end pressure regulator, a flow meter may be located between the front-end pressure regulator and the three-way valve, and a flow meter and pressure sensor may be located between the rear-end pressure regulator and the cooling line.

According to the hydrogen generation device, hydrogen generation system, and hydrogen supply system for generator cooling of an embodiment of the present invention configured as above, hydrogen gas is generated by electrolyzing water (pure water), so the hydrogen generation device (electrolytic cell) If a problem occurs, the hydrogen generating device is easy to replace and maintain, and an appropriate amount of hydrogen gas can be continuously supplied to the generator through the front-end pressure regulator and back-end pressure regulator. In particular, when there is a possibility of hydrogen gas leaking beyond the appropriate level due to the three-way valve, hydrogen gas is discharged into the atmosphere, thereby preventing explosions due to hydrogen gas ignition.

1 is an exemplary diagram of a hydrogen generating device according to an embodiment of the present invention.
Figure 2 is an exemplary diagram of a hydrogen generation system according to an embodiment of the present invention.
Figure 3 is an exemplary diagram of a hydrogen supply system for cooling a generator according to an embodiment of the present invention.
4 to 5 are graphs showing the ability to adjust the hydrogen supply flow rate and hydrogen supply pressure of the hydrogen supply system for cooling a generator according to an embodiment of the present invention.

Hereinafter, the hydrogen generation device 1000, the hydrogen generation system 2000, and the hydrogen supply system 3000 for cooling a generator according to an embodiment of the present invention will be described with reference to the attached drawings.

As shown in FIG. 1, the hydrogen generator 1000 of an embodiment of the present invention includes a cathode 1100 in which hydrogen ions are converted into hydrogen gas when energized, and water is converted into hydrogen ions, oxygen gas, and hydrogen ions when energized. An anode 1200 that is converted into electric charge, an ion exchange membrane 1300 located between the cathode 1100 and the anode 1200, and which transfers hydrogen ions generated in the anode 1200 to the cathode 1100, and a cathode ( A cathode chamber 1400 formed on one side of the ion exchange membrane 1300 to embed the anode 1100, an anode chamber 1500 formed on the other side of the ion exchange membrane 1300 to embed the anode 1200, and transfer charge to the cathode 1100. Alternatively, it includes a current distribution plate 1600 built into each of the cathode chamber 1400 and the anode chamber 1500 to receive charge from the anode 1200.

The cathode chamber 1400 and the anode chamber 1500 are positioned to face each of one side and the other side of the ion exchange membrane 1300, and include a box-shaped frame 1410 with open upper and lower surfaces, the cathode chamber 1400, and A separator plate 1420 covers one side of the frame 1410 that is opened to seal the anode chamber 1500, and a frame 1410 is formed to prevent leakage of water and gas present in the cathode chamber 1400 and the anode chamber 1500. ) and a packing 1430 mounted between the separation plate 1420. The cathode chamber 1400 includes a pressure pad 1440 that secures the current distribution plate 1600 located inside the cathode chamber 1400. Holes are formed in the frame 1410 and the packing 1430 to discharge water and hydrogen gas present in the cathode chamber 1400 or to discharge water and oxygen gas present in the anode chamber 1500.

The area of the ion exchange membrane 1300 is larger than the area of the current distribution plate 1600, and the area of the current distribution plate 1600 is larger than the areas of the cathode 1100 and the anode 1200. The current distribution plate 1600 built in the cathode chamber 1400 and the current distribution plate 1600 built in the anode chamber 1500 are connected to each other outside the cathode chamber 1400 and the anode chamber 1500. Alternatively, the current distribution plate 1600 built into the cathode chamber 1400 and the current distribution plate 1600 built into the anode chamber 1500 may be individually connected to an external power supply.

The hydrogen generation device 1000 of the present invention is a polymer solid electrolyte electrolyte cell that electrochemically decomposes pure water, and is a membrane electrode assembly (MEA) including a hydrogen ion exchange membrane.

Water (H2O) is supplied to the anode 1200, which is an oxygen electrode, and is decomposed into oxygen gas (O2), electrons (e-), and hydrogen ions (H+). Some of the water (H2O) flows out of the anode chamber 1500 along with oxygen gas (O2). The decomposed hydrogen ions (H+) pass through the ion exchange membrane 1300 and move to the cathode 1100, which is the hydrogen electrode.

The anode 1200 and the cathode 1100 are connected to conduct electricity by the current distribution plate 1600, and react with electrons (e-) moving along the current distribution plate 1600 to generate hydrogen gas ( H2). Water (H2O), accompanied by hydrogen gas (H2) and hydrogen ions (H+), passes through the ion exchange membrane 1300. At this time, the electrochemical reactions occurring at the anode 1200 and the cathode 1100, respectively, are expressed as Chemical Formulas 1 and 2.

To electrolyze water, a current density of approximately 0.05 A/cm2 - 4.3 A/cm2 and a voltage of approximately 1.48 volts - 3.0 volts are applied to the current distribution plate (1600).

The length of the ion exchange membrane 1300 located between the anode 1200 and the cathode 1100 is formed to be longer than the length of the anode 1200 and the cathode 1100, and the anode 1200 and the cathode are formed in the ion exchange membrane 1300. A frame 1410 is located at both left and right ends that are not interviewed with 1100.

The inside and outside of the cathode chamber 1400 and the anode chamber 1500 are separated by the frame 1410. The anode chamber 1500 and the cathode chamber 1400 are closed by packing 1430 between the frame 1410 and the separation plates 1420 located at both upper and lower ends.

Water always exists in the cathode chamber 1400 and the anode chamber 1500. The current distribution plate 1600 maintains a uniform distance from the cathode 1100, the anode 1200, and the separator. The current distribution plate 1600 serves as a path through which charges move between the cathode 1100 and the anode 1200.

A pressure pad 1440 is located between the current distribution plate 1600 and the separator plate 1420 of the cathode chamber 1400. The pressure pad 1440 moves the current distribution plate 1600 to its original position by water moving from the anode chamber 1500 to the cathode chamber 1400 through the ion exchange membrane 1300 and hydrogen gas generated in the cathode 1100. prevents it from deviating closer to the separator plate 1420.

According to the hydrogen generation device 1000 of an embodiment of the present invention configured as above, hydrogen gas can be continuously generated by electrolyzing water (pure water), so replacement and maintenance are easy when a problem occurs, and the operator There is no risk of injury from exposure to the solution.

Since the gap between the anode 1200 and the cathode 1100 manufactured in the form of MEA is very small, there are no bubbles, making operation at low voltage and high current possible. In addition, because the conductivity of the electrolyte is not used, water, which is a raw material, can be used at high purity, and thus high purity hydrogen and oxygen can be obtained.

As shown in Figure 2, the hydrogen generation system 2000 of one embodiment of the present invention supplies water to the hydrogen generating device 1000 of the present invention described above and the anode chamber 1500, and the anode chamber ( A first storage tank 2100 for recovering water and oxygen gas from the cathode chamber 1500), a second storage tank 2200 for recovering water and hydrogen gas from the cathode chamber 1400, and hydrogen gas collected in the second storage tank 2200. It includes a gas purifier (2300) that evaporates moisture from the gas.

The hydrogen generation system 2000 of an embodiment of the present invention includes a first pipe 2410 for supplying water to the first storage tank 2100, and a first storage tank 2100 and an anode chamber 1500 to supply water. A second pipe 2420 connecting the first storage tank 2100 and the anode chamber 1500 to recover water and oxygen gas, a third pipe 2430 connecting the anode chamber 1500, and a second storage tank to recover water and hydrogen gas A fourth pipe 2440 connecting the 2200 and the cathode chamber 1400, and a second storage tank 2200 and a second pipe ( A fifth pipe 2450 connecting the second storage tank 2200) and a sixth pipe connecting the second storage tank 2200 and the gas purifier 2300 to supply the hydrogen gas collected in the second storage tank 2200 to the gas purifier 2300. The pipe 2460, the seventh pipe 2470 connected to the gas purifier 2300 to transfer the hydrogen gas from which moisture has been removed from the gas purifier 2300 to an external device, and the oxygen gas collected in the first storage tank 2100 It further includes an eighth pipe (2480) connected to the first storage tank (2100) to transmit it to an external device.

Pure water of 1 Mega ohm cm or higher is used as the raw material, and pure water is supplied by controlling the automatic valve (2411) installed in the first pipe (2410). The operation of the automatic valve 2411_ is controlled by the level sensor 2110 for detecting the water level located in the first storage tank 2100 that separates oxygen and water and simultaneously stores water.

Water in the first storage tank 2100 passes through the circulation pump 2421 installed in the second pipe 2420 and flows into the anode chamber 1500. A heat exchanger 2422, a water quality detection sensor 2423, and an ion exchange filter 2424 are installed in the second pipe 2420.

The oxygen gas and water present in the anode chamber 1500 are moved to the first storage tank 2100 through the third pipe 2430. A temperature sensor 2431 is installed in the third pipe to monitor the temperature of water discharged from the anode chamber 1500.

The oxygen gas that moved from the anode chamber (1500) to the first storage tank (2100) is discharged to an external device or outside through the eighth pipe (2480), and the water that moved from the anode chamber (1500) to the first storage tank (2100) is recycled to the anode chamber 1500.

And the cathode chamber 1400 and the second storage tank 2200 are connected through a fourth pipe 2440. Hydrogen gas generated in the cathode chamber 1400 is moved to the second reservoir through the fourth pipe 2440 along with water moved from the anode chamber 1500 to the cathode chamber 1400 through the ion exchange membrane 1300. Hydrogen gas and water are separated in the second reservoir.

The second storage tank 2200 is connected to the second pipe 2420 through a fifth pipe 2450. The water separated from the hydrogen gas in the second storage tank 2200 is moved to the second pipe 2420 through the fifth pipe 2450 to be recirculated to the anode chamber 1500.

According to one example, the second storage tank 2200 is provided with a level sensor 2210 for detecting the water level. The water level of the second storage tank 2200 is adjusted according to the signal generated from the level sensor 2210 for water level detection. If the water level in the second storage tank 2200 is above a certain displacement, the automatic valve 2451 provided in the fifth pipe 2450 is opened to supply water in the second storage tank 2200 to the second pipe 2420. do.

Meanwhile, hydrogen gas separated from water in the second storage tank 2200 is supplied to the gas purifier 2300 through the sixth pipe 2460. In the gas purifier 2300, moisture contained in hydrogen gas is removed. The gas purifier 2300 may be equipped with a bed filled with a moisture absorbent. Moisture is released into the atmosphere.

High-purity hydrogen gas that has passed through the gas purifier 2300 is supplied to a generator requiring hydrogen gas through the seventh pipe 2470. At this time, the seventh pipe 2470 is provided with a pressure control valve 2471 that regulates the pressure of hydrogen gas supplied from the gas purifier 2300 to the generator. A pressure sensor 2472 that measures pressure is provided at the front and rear ends of the pressure control valve 2471. A check valve 2473 is provided on one side of the pressure control valve 2471 to keep the flow direction of hydrogen gas constant.

According to the hydrogen generation system 2000 of an embodiment of the present invention configured as above, hydrogen gas can be generated by electrolyzing water (pure water), and the oxygen gas and hydrogen gas generated during electrolysis can be converted into hydrogen gas through a hydrogen generating device ( 1000) can be appropriately moved to the first storage tank 2100 or the second storage tank 2200. Therefore, it is possible to continuously generate hydrogen gas, and when the amount of gas discharged from the second storage tank 2200 is controlled to be constant, a uniform amount of hydrogen gas can be supplied to the generator.

As shown in FIG. 3, the hydrogen supply system 3000 for generator cooling of an embodiment of the present invention connects the hydrogen generation system 2000 of the present invention described above, the cathode chamber 1400, and the generator cooling line. A refrigerant supply line 3100 and a front-end pressure regulator 3200 provided at the front of the refrigerant supply line 3100 to allow hydrogen gas generated in the cathode chamber 1400 to flow into the refrigerant supply line 3100 while maintaining an appropriate flow rate. and a rear-end pressure regulator 3300, a front-end pressure regulator 3200, and a rear-end pressure regulator provided at the rear of the refrigerant supply line 3100 so that the hydrogen gas flowing in the refrigerant supply line 3100 flows into the cooling line while maintaining an appropriate flow rate. It includes a three-way valve 3400 mounted on the refrigerant supply line 3100 to be located between the regulators 3300.

A pressure sensor 3210 is located at the front and rear of the front-end pressure regulator 3200, a flow meter 3220 is located between the front-end pressure regulator 3200 and the three-way valve 3400, and the rear-end pressure regulator 3300 A flow meter 3310 and a pressure sensor 3320 are located between the and cooling lines.

The shear pressure regulator 3200 operates to open when the pressure applied to the shear pressure regulator 3200 by hydrogen gas that has been purified in the gas purifier 2300 and reached the shear pressure regulator 3200 is above a threshold. Accordingly, a uniform amount of hydrogen gas flows into the refrigerant supply line 3100. By adjusting the operation timing of the front-end pressure regulator (3200) according to the signal measured from the pressure sensor (3210) at the front and back of the front-end pressure regulator (3200), hydrogen gas reversely moves due to the pressure difference between the front and rear ends of the front-end pressure regulator (3200). prevent.

The back-end pressure regulator 3300 maintains the pressure of hydrogen gas passing through the back-end pressure regulator 3300 and flowing into the cooling line constant. Since the pressure of hydrogen gas flowing into the cooling line is maintained constant by the rear-end pressure regulator 3300, the hydrogen gas flow rate is also maintained constant.

When the amount of hydrogen gas reaching the rear-end pressure regulator 3300 through the refrigerant supply line 3100 exceeds the appropriate value, the rear-end pressure regulator 3300 controls some of the hydrogen gas reaching the rear-end pressure regulator 3300. is released into the atmosphere.

When the amount of hydrogen gas flowing in the refrigerant supply line 3100 exceeds the appropriate value, the three-way valve 3400 discharges some of the hydrogen gas that has reached the three-way valve 3400 into the atmosphere.

According to the hydrogen supply system 3000 for cooling a generator according to an embodiment of the present invention configured as above, hydrogen gas is generated by electrolyzing water (pure water), so there is a problem in the hydrogen generating device 1000 (electrolytic cell). When this occurs, replacement and maintenance of the hydrogen generation device 1000 is easy, and an appropriate amount of hydrogen gas can be continuously supplied to the generator through the front-end pressure regulator 3200 and the back-end pressure regulator 3300. In particular, when there is a possibility of hydrogen gas leaking beyond the appropriate value due to the three-way valve 3400, hydrogen gas is discharged into the atmosphere, thereby preventing an explosion due to hydrogen gas ignition.

4 to 5 are graphs showing the ability to adjust the hydrogen supply flow rate and hydrogen supply pressure of the hydrogen supply system 3000 for cooling a generator according to an embodiment of the present invention.

The graph in FIG. 4 is the result of connecting the hydrogen supply system 3000 for cooling a generator of an embodiment of the present invention with a gas container for a static pressure test and confirming whether the hydrogen pressure in the gas container can be controlled.

Three currents of 60A, 70A, and 80A are applied to the hydrogen generator (1000) to produce hydrogen in an amount or pressure proportional to each current value, and the hydrogen pressure in the gas container increases from the initial 2.1 bar to 2.8 bar and 3.2 bar. It was filled to maintain pressure.

As a result of the test, the amount of hydrogen gas produced by the hydrogen generator 1000 increased by a certain amount as the current increased. Hydrogen is supplied while the gas container pressure rises from the initial 2.1 bar to the set pressure of 2.8 bar (see the solid black arrow in Figure 5), but when the set pressure of 2.8 bar is reached, the hydrogen supply is automatically stopped and the set pressure is maintained. (see black dashed arrow in Figure 5).

When the set pressure was raised to 3.2 bar again, the hydrogen supply resumed, but when the set pressure was reached, the hydrogen supply was stopped and the set pressure was maintained. The set pressure was maintained for all three currents of 60A, 70A, and 80A.

The graph in FIG. 5 is the result of a test conducted to directly connect the hydrogen supply system 3000 for cooling the generator of one embodiment of the present invention and the generator and check the generator pressure.

Set the pressure of the generator to 2.9 bar and connect the hydrogen supply system 3000 (hereinafter referred to as this system) for cooling the generator of an embodiment of the present invention to check whether 2.9 bar can be maintained and whether it can increase to 2.9 bar or more. It was.

In the case of a generator, it usually consumes about 1.5 bottles (120kg/cm2, 47L) of hydrogen per day. When converted to the amount of hydrogen produced by this system, it is about 5.8L/min, and when converted to current, about 95A is required. You can.

Based on this, the system and the generator were connected and the system was operated continuously for 6 hours at 80A, 6 hours at 90A, 6 hours at 100A, 5 hours at 110A, and 1 hour at 100A (total of 24 hours). As a result, it can be seen that after the generator to which this system is not applied is operated for 24 hours, the hydrogen pressure is maintained within a certain error compared to the change in the pressure of hydrogen existing inside the generator.

1000: Hydrogen generating device 1100: Cathode
1200: Anode 1300: Ion exchange membrane
1400: cathode chamber 1410: frame
1420: Separator plate 1430: Packing
1440: Pressure pad 1500: Anode chamber
1600: Current distribution plate 2000: Hydrogen generation system
2100: first storage tank 2200: second storage tank
2300: Gas purifier 2410: First pipe
2420: 2nd pipe 2430: 3rd pipe
2440: 4th pipe 2450: 5th pipe
2460: 6th pipe 2470: 7th pipe
2480: 8th pipe 3000: Hydrogen supply system for generator cooling
3100: Refrigerant supply line 3200: Front pressure regulator
3300: Rear-end pressure regulator 3400: Three-way valve

Claims (12)

an anode, where water is converted into hydrogen ions, oxygen gas, and electric charge;
a cathode where the hydrogen ions are converted into hydrogen gas;
an ion exchange membrane located between the cathode and the anode and transferring hydrogen ions generated at the anode to the cathode;
a cathode chamber formed on one side of the ion exchange membrane to house the cathode;
an anode chamber formed on the other side of the ion exchange membrane to accommodate the anode;
In the hydrogen supply system for cooling a generator including a hydrogen generating device including a current distribution plate built into each of the cathode chamber and the anode chamber to transfer charge to the cathode or receive charge from the anode,
A refrigerant supply line connecting the cathode chamber and the generator cooling line;
a shear pressure regulator provided at the front of the refrigerant supply line to allow hydrogen gas generated in the cathode chamber to flow into the refrigerant supply line while maintaining an appropriate flow rate;
a rear-end pressure regulator provided at the rear end of the refrigerant supply line to allow hydrogen gas flowing in the refrigerant supply line to flow into the cooling line while maintaining an appropriate flow rate; and
A hydrogen supply system for cooling a generator further comprising a three-way valve mounted on the refrigerant supply line to be positioned between the front-end pressure regulator and the back-end pressure regulator.
According to paragraph 1,
The cathode chamber and the anode chamber are,
a box-shaped frame positioned to face one side and the other side of the ion exchange membrane, respectively, and having upper and lower surfaces opened;
a separator plate covering one side of the frame that is opened to seal the cathode chamber and the anode chamber;
It includes a packing mounted between the frame and the separator plate to prevent leakage of water and gas present in the cathode chamber and the anode chamber,
In the frame and the packing,
Discharging water and hydrogen gas present in the cathode chamber,
A hydrogen supply system for cooling a generator in which a hole is formed to discharge water and oxygen gas present in the anode chamber.
According to paragraph 2,
The cathode chamber is,
A hydrogen supply system for cooling a generator further comprising a pressure pad for fixing the current distribution plate located inside the cathode chamber.
According to paragraph 1,
The area of the ion exchange membrane is larger than the area of the current distribution plate,
A hydrogen supply system for generator cooling in which the area of the current distribution plate is larger than the areas of the cathode and the anode.
According to paragraph 1,
The current distribution plate built in the cathode chamber and the current distribution plate built in the anode chamber are connected to each other outside the cathode chamber and the anode chamber.
According to paragraph 1,
A hydrogen supply system for cooling a generator in which the current distribution plate built in the cathode chamber and the current distribution plate built in the anode chamber are individually connected to an external power supply device.
According to paragraph 1,
a first storage tank that supplies water to the anode chamber and recovers water and oxygen gas from the anode chamber;
a second storage tank for recovering water and hydrogen gas from the cathode chamber;
A hydrogen supply system for cooling a generator further comprising a gas purifier that evaporates moisture from the hydrogen gas collected in the second storage tank.
In clause 7,
a first pipe supplying water to the first storage tank;
a second pipe connecting the first reservoir and the anode chamber to supply water;
a third pipe connecting the first storage tank and the anode chamber to recover water and oxygen gas;
a fourth pipe connecting the second storage tank and the cathode chamber to recover water and hydrogen gas;
a fifth pipe connecting the second storage tank and the second pipe to supply water present in the second storage tank to the anode chamber;
a sixth pipe connecting the second storage tank and the gas purifier to supply hydrogen gas collected in the second storage tank to the gas purifier;
a seventh pipe connected to the gas purifier to deliver hydrogen gas from which moisture has been removed from the gas purifier to an external device;
A hydrogen supply system for cooling a generator further comprising an eighth pipe connected to the first storage tank to transfer the oxygen gas collected in the first storage tank to an external device.
delete According to paragraph 1,
The downstream pressure regulator is,
A hydrogen supply system for generator cooling that discharges some of the hydrogen gas that has reached the downstream pressure regulator into the atmosphere when the amount of hydrogen gas reaching the downstream pressure regulator through the refrigerant supply line exceeds an appropriate value.
According to paragraph 1,
The three-way valve is,
A hydrogen supply system for generator cooling that discharges some of the hydrogen gas that has reached the three-way valve into the atmosphere when the amount of hydrogen gas flowing in the refrigerant supply line exceeds the appropriate value.
According to paragraph 1,
Pressure sensors are located at the front and rear ends of the front pressure regulator, respectively,
A flow meter is located between the shear pressure regulator and the three-way valve,
A hydrogen supply system for cooling a generator in which a flow meter and a pressure sensor are located between the downstream pressure regulator and the cooling line.