KR102242012B1 - Hydrogen bubble generating device and hydrogen bubble generating method using it - Google Patents

Abstract

The present invention relates to a hydrogen bubble generator and a hydrogen bubble generation method using the same, and more specifically, water and hydrogen can be mixed in a bubble form and then sprayed, and water and hydrogen are mixed in a bubble form without disassembling the product. It is possible to replenish purified water in the hydrogen generation tank as well as the internal cleaning of the bubble tank, and use a single water pump to generate hydrogen bubbles, wash the bubble tank, and replenish purified water. will be. To this end, a hydrogen generation tank that generates hydrogen through electrolysis of purified water, a water pump that mixes and discharges hydrogen generated from the hydrogen generation tank with water supplied from a separate water source, and water and hydrogen discharged from the water pump It provides a hydrogen bubble generating apparatus including a bubble tank for mixing and then spraying the mixture in the form of a bubble, and a control unit for controlling the operation of the hydrogen generating tank and the water pump.

Description

Hydrogen bubble generating device and hydrogen bubble generating method using it

The present invention relates to a hydrogen bubble generator and a hydrogen bubble generation method using the same, and more specifically, water and hydrogen can be mixed in a bubble form and then sprayed, and water and hydrogen are mixed in a bubble form without disassembling the product. It is possible to replenish purified water in the hydrogen generation tank as well as the internal cleaning of the bubble tank, and use a single water pump to generate hydrogen bubbles, wash the bubble tank, and replenish purified water. will be.

In general, hydrogen has recently attracted great attention due to its various uses including a clean energy source, and methods for efficiently producing such hydrogen are being studied in various and in-depth not only domestically but also globally.

The main method of producing such hydrogen is to obtain fossil fuels such as methane gas through steam reforming, and then purify and use them.However, in recent years, hydroelectrolysis of water to overcome the finiteness and environmental problems of fossil fuels We are actively developing and applying a method of using.

Hydrogen produced in this way can be used for drinking water or washing water, or sprayed into water in a bathtub to clean the skin through hydrogen dissolved in the water or used for skin treatment purposes such as atopy. There is a limitation in that the effect is limited because the hydrogen dissolution rate in water is not high because it is sprayed directly into water in the form of

In addition, as the water electrolysis process is repeated, foreign substances accumulate inside the product, and the amount of water stored inside the product gradually decreases.There was a hassle of disassembling the product in order to remove such foreign substances and replenish water.

Therefore, there is an urgent need to improve these limitations.

The technical problem to be solved in the present invention is to provide a hydrogen bubble generating device capable of spraying after mixing water and hydrogen in a bubble form, and a hydrogen bubble generating method using the same.

In addition, a hydrogen bubble generator capable of replenishing purified water in a hydrogen generating tank as well as cleaning the inside of a bubble tank in which water and hydrogen are mixed in a bubble form without disassembling the product, and a hydrogen bubble generating method using the same are provided.

In addition, a hydrogen bubble generator capable of generating hydrogen bubbles, washing a bubble tank, and replenishing purified water using a single water pump, and a hydrogen bubble generating method using the same.

The hydrogen bubble generation apparatus according to the present invention for solving the above technical problem is a hydrogen generation tank that generates hydrogen through electrolysis of purified water, and the hydrogen generated in the hydrogen generation tank and water supplied from a separate water source are mixed. And a water pump to discharge, a bubble tank for mixing and then spraying water discharged from the water pump in a bubble form, and a control unit for controlling the operation of the hydrogen generating tank and the water pump.

In this case, a hydrogen supply pump may be provided between the hydrogen generation tank and the water pump to supply hydrogen generated in the hydrogen generation tank by pressurizing the hydrogen generated in the water pump.

In addition, when the amount of hydrogen generated in the hydrogen generation tank is relatively smaller than the suction amount of the hydrogen supply pump, the hydrogen generation tank may be provided with a quantitative suction nozzle that prevents vacuum pressure from being formed inside the hydrogen generation tank. I can.

In this case, when a vacuum pressure is formed in the hydrogen generating tank, the fixed-quantity suction nozzle may prevent vacuum pressure formation by introducing outside air or additional hydrogen into the hydrogen generating tank.

Alternatively, a purified water supply pump may further include a purified water supply pump that sucks purified water from the purified water storage unit and discharges it into the hydrogen generation tank so that purified water is supplied into the hydrogen generation tank.

At this time, a flow path for supplying purified water and a flow path for draining purified water are formed between the hydrogen generation tank and the purified water storage unit, and a line for supplying purified water to enable supply and drainage of purified water using a single purified water supply pump A flow path control valve and a branch valve may be provided for selectively communicating a line through which the and purified water is drained to the purified water supply pump.

In this case, the flow path control valve includes a first flow path control valve and a second flow path control valve, and the branch valve includes a first branch valve and a second branch valve, and when purified water is supplied, the purified water is After moving to the purified water supply pump through a flow path control valve and the first branch valve sequentially, the hydrogen generation tank may be supplied to the inside of the hydrogen generation tank while sequentially passing through the second branch valve and the second flow path control valve.

In addition, when the purified water is drained, the purified water is sequentially passed through the second flow path control valve and the first branch valve, moves to the purified water supply pump, and then sequentially passes through the second branch valve and the first flow path control valve. It can be drained to the purified water storage.

In this case, a safety valve for selectively communicating the hydrogen generation tank and outside air may be further included, and the control unit may be configured to temporarily open the safety valve after the operation of the hydrogen generation tank and the water pump is terminated.

In addition, an air pump for supplying cleaning air may be further included in the bubble tank.

Meanwhile, the hydrogen generation tank is in communication with the purified water storage unit, and the control unit may control the air pump so that purified water is introduced into the hydrogen generation tank by forming a vacuum pressure in the hydrogen generation tank.

In this case, an air line for supplying cleaning air and a tank line in communication with the hydrogen generation tank are connected to the air pump, and a supply valve for controlling the air line and the tank line to be selectively connected to the air pump is provided. It can be included more.

In this case, it is preferable that the control unit controls the supply valve to operate before the air pump.

In addition, a safety valve for selectively communicating the hydrogen generation tank and outside air may be further included, and the control unit may be configured to temporarily open the safety valve after the operation of the air pump is terminated.

In this case, it is preferable that the control unit controls the hydrogen generation tank to operate before the water pump.

Meanwhile, a pump valve for controlling whether or not water supplied to the water pump is supplied from a separate water source may be further included.

In this case, it is preferable that the control unit controls the pump valve to operate before the water pump.

In addition, a safety valve is further included so that the hydrogen generation tank and the cleaning air supply unit are selectively communicated, and the control unit closes the pump valve, and the cleaning air is supplied to the bubble tank through the hydrogen generation tank. It may be configured to control a valve and the water pump.

In addition, a tank line is provided so that the water pump and the hydrogen generating tank communicate with each other, and the tank line may include a first tank line through which hydrogen passes and a second tank line through which cleaning air passes.

In this case, a discharge valve for selectively opening the first tank line and the second tank line may be further included.

In addition, an air line for supplying cleaning air and a purified water line for replenishing purified water are connected to the safety valve, and the control unit controls the safety valve so that the air line and the purified water line are selectively communicated with the hydrogen generation tank. Can be configured to

In this case, it is preferable that the control unit controls the second tank line to be opened when the hydrogen generation tank and the purified water line are in communication.

In addition, the purified water line further includes an interruption valve for controlling whether or not the purified water is supplied, and the controller may control the water pump to operate before the interruption valve.

In this case, it is preferable that the control unit controls the water pump so that purified water flows into the hydrogen generation tank by forming a vacuum pressure inside the hydrogen generation tank.

In addition, it is preferable that the control unit controls the safety valve so that the air line is temporarily communicated with the hydrogen generation tank after the operation of the water pump is finished.

On the other hand, one method for generating hydrogen bubbles according to the present invention includes the steps of generating hydrogen through electrolysis of purified water accommodated in the hydrogen generation tank, and water pumping hydrogen generated in the hydrogen generation tank and water supplied from a separate water source. And mixing and discharging the water and hydrogen discharged from the water pump, and mixing the water and hydrogen discharged from the water pump in a bubble tank in a bubble shape and then spraying the mixture.

At this time, after the step of mixing water and hydrogen in the bubble tank and then spraying, the operation of the hydrogen generation tank and the water pump is terminated, and the safety valve is temporarily turned off so that the hydrogen generation tank and outside air communicate. It may further include the step of opening.

In addition, after the step of temporarily opening the safety valve, the step of operating the air pump to supply the washing air to the bubble tank may be further included.

In addition, after the air pump operation step, the step of terminating the operation of the air pump and waiting may be further included.

At this time, after the step of waiting, it is preferable to further include the step of operating the air pump in a state in which the air pump, the hydrogen generating tank and the purified water storage unit are in communication so that purified water is introduced into the hydrogen generating tank. .

In addition, after the step of introducing the purified water, it is preferable to further include a step of temporarily opening the safety valve so that the hydrogen generating tank and outside air communicate with each other.

Another method for generating hydrogen bubbles according to the present invention includes generating hydrogen through electrolysis of purified water contained in a hydrogen generating tank, operating a pump valve to supply water supplied from a separate water source to the water pump, and Supplying the hydrogen generated in the hydrogen generating tank and water supplied from a separate water source to the water pump, mixing and discharging the water, and mixing the water and hydrogen discharged from the water pump in a bubble tank in a bubble tank and then spraying It includes the step of.

At this time, after the step of mixing water and hydrogen in the bubble tank and then spraying, the operations of the hydrogen generation tank and the pump valve are terminated, and the cleaning air is transferred to the bubble tank through the hydrogen generation tank. It may further include the step of continuously operating the water pump to be supplied.

In addition, after the operation of the water pump, the step of terminating the operation of the water pump and waiting may be further included.

In addition, after the step of waiting, the step of operating the water pump while the water pump, the hydrogen generating tank and the purified water storage unit are in communication with each other to allow purified water to flow into the hydrogen generating tank may be further included.

At this time, after the step of introducing the purified water, it is preferable to further include temporarily opening the safety valve so that the hydrogen generating tank and the cleaning air supply unit communicate with each other.

The hydrogen bubble generation device of the present invention having the above configuration and the hydrogen bubble generation method using the same can be sprayed after mixing water and hydrogen in a bubble form, so that the hydrogen dissolution rate in water is high, and drinking water or washing water and skin treatment are possible. It has the advantage of obtaining excellent effects when used for purposes.

In addition, since it is possible to replenish purified water in the hydrogen generating tank as well as cleaning the inside of the bubble tank in which water and hydrogen are mixed in a bubble form without disassembling the product, there is an advantage in that the convenience according to use is improved.

In addition, since it is possible to generate hydrogen bubbles, wash the bubble tank and replenish purified water using a single water pump, the configuration is simple, so maintenance and repair are easy, and manufacturing costs are reduced.

1 is a view showing a hydrogen bubble generating apparatus according to an embodiment of the present invention.
2 is a view showing a process of generating hydrogen bubbles using the hydrogen bubble generator according to an embodiment of the present invention.
3 is a view showing a process of cleaning the hydrogen bubble generating device according to an embodiment of the present invention.
4 is a view showing a process of replenishing purified water in the hydrogen bubble generator according to an embodiment of the present invention.
5 is a view showing a process of draining purified water accommodated in the hydrogen bubble generator according to an embodiment of the present invention.
6 is a view showing a hydrogen bubble generating apparatus according to another embodiment of the present invention.
7 is a diagram illustrating a process of generating hydrogen bubbles using a hydrogen bubble generator according to another embodiment of the present invention.
8 is a view showing a process of cleaning the hydrogen bubble generating device according to another embodiment of the present invention.
9 is a diagram illustrating a process of replenishing purified water in a hydrogen bubble generator according to another embodiment of the present invention.
10 is a view showing a hydrogen bubble generating apparatus according to another embodiment of the present invention.
11 is a view showing a process of generating hydrogen bubbles using the hydrogen bubble generator according to another embodiment of the present invention.
12 is a view showing a process of cleaning the hydrogen bubble generating device according to another embodiment of the present invention.
13 is a diagram illustrating a process of replenishing purified water in a hydrogen bubble generator according to another embodiment of the present invention.
14 is a view showing whether the hydrogen bubble generating apparatus according to another embodiment of the present invention is operated for each process.
15 is a flow chart showing a hydrogen bubble generation process according to another embodiment of the present invention.
16 is a flow chart showing a bubble tank cleaning process according to another embodiment of the present invention.
17 is a flowchart illustrating a process of replenishing purified water according to another embodiment of the present invention.
18 is a view showing whether the hydrogen bubble generating apparatus according to another embodiment of the present invention is operated for each process.
19 is a flow chart showing a hydrogen bubble generation process according to another embodiment of the present invention.
20 is a flow chart illustrating a bubble tank cleaning process according to another embodiment of the present invention.
21 is a flow chart showing a process of replenishing purified water according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. The present invention may be implemented in various different forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and the same reference numerals are assigned to the same or similar components throughout the specification.

In the present specification, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of the presence or addition. In addition, when a part such as a layer, film, region, plate, etc. is said to be "on" another part, this includes not only the case where the other part is "directly above", but also the case where there is another part in the middle. Conversely, when a part of a layer, film, region, plate, etc. is said to be "below" another part, this includes not only the case where the other part is "directly below" but also the case where there is another part in the middle.

1 is a view showing a hydrogen bubble generating device according to an embodiment of the present invention, Figure 2 is a view showing a process of generating a hydrogen bubble using the hydrogen bubble generating device according to an embodiment of the present invention 3 is a view showing a process of cleaning the hydrogen bubble generator according to an embodiment of the present invention, Figure 4 is a diagram showing a process of replenishing purified water to the hydrogen bubble generator according to an embodiment of the present invention 5 is a view showing a process of draining purified water accommodated in a hydrogen bubble generating device according to an embodiment of the present invention, and FIG. 6 is a view showing a hydrogen bubble generating device according to another embodiment of the present invention. 7 is a diagram showing a process of generating hydrogen bubbles using a hydrogen bubble generating device according to another embodiment of the present invention, and FIG. 8 is a diagram showing a process of generating hydrogen bubbles according to another embodiment of the present invention. FIG. 9 is a view showing a process of replenishing purified water to a hydrogen bubble generator according to another embodiment of the present invention, and FIG. 10 is a hydrogen bubble generator according to another embodiment of the present invention. FIG. 11 is a view showing a process of generating hydrogen bubbles using a hydrogen bubble generator according to another embodiment of the present invention, and FIG. 12 is a diagram illustrating hydrogen according to another embodiment of the present invention. A diagram showing a process of cleaning the bubble generating device, FIG. 13 is a diagram illustrating a process of replenishing purified water to a hydrogen bubble generating device according to another embodiment of the present invention, and FIG. 14 is another embodiment of the present invention. FIG. 18 is a view showing whether the hydrogen bubble generator is operated for each process, and FIG. 18 is a view showing whether the hydrogen bubble generator according to another embodiment of the present invention is operated for each process.

1, 6, and 10, a hydrogen generation tank 100 for generating hydrogen through electrolysis of purified water is provided. A water electrolysis unit is provided in the hydrogen generation tank 100 to enable electrolysis of purified water. Such a water electrolytic unit is provided with a polymer electrolyte membrane having an oxygen electrode catalyst layer and a hydrogen electrode catalyst layer formed thereon, and an anode electrode plate is stacked and disposed on one side of the polymer electrolyte membrane via an oxygen electrode catalyst layer, and the other side of the polymer electrolyte membrane via a hydrogen electrode catalyst layer. Thus, the cathode electrode plate is stacked and disposed.

Purified water inside the hydrogen generation tank 100 passes through the polymer electrolyte membrane and reaches the surface of the oxygen electrode catalyst layer interposed between the anode electrode plate and the polymer electrolyte membrane, and then oxygen and electrons are generated and released through an oxidation reaction. The ions move toward the cathode electrode plate through the polymer electrolyte membrane.

In this case, the hydrogen ions move in a hydrated state, and hydrogen is generated through the reduction reaction of the hydrogen ions and electrons that reach the surface of the hydrogen electrode catalyst layer, and the generated hydrogen passes through the cathode electrode plate to generate a hydrogen generation tank ( 100) It moves to the top.

In addition, as shown in FIG. 1, the hydrogen that has moved to the top of the hydrogen generation tank 100 is mixed with water supplied from a separate water source by the water pump 200, is discharged, and then flows into the bubble tank 300. .

In this case, a hydrogen amount control valve 30 may be provided in a flow path connecting the hydrogen generation tank 100 and the water pump 200 to control the amount of moving hydrogen.

In addition, a bubble generator may be provided inside the bubble tank 300. Such a bubble generator is a hollow pipe having a height slightly smaller than the total length of the inside so as to be installed in the bubble tank 300, and a mesh-shaped spiral is inserted into the pipe, and a nozzle hole is formed at the top of the pipe. Water and hydrogen flowing into the bubble tank 300 pass through such a bubble generator, and water and hydrogen are mixed in the form of bubbles, thereby increasing the hydrogen dissolution rate in the water, and when used for drinking water, washing water, and skin treatment purposes. There is an advantage that you can get an excellent effect.

In addition, a control unit 400 for controlling the operation of the hydrogen generation tank 100 and the water pump 200 is provided, and the operation of the control unit 400 will be described later.

At this time, as shown in FIG. 1, between the hydrogen generation tank 100 and the water pump 200, hydrogen generated in the hydrogen generation tank 100 is pressurized by the water pump 200 to supply hydrogen. A pump 110 may be provided.

In this way, when a separate hydrogen supply pump 110 is provided, it is possible to supply a constant amount of hydrogen regardless of the operation of the water pump 200.

At this time, when the amount of hydrogen generated in the hydrogen generation tank 100 is relatively smaller than the suction amount of the hydrogen supply pump 110 in the hydrogen generation tank 100, the vacuum pressure is formed inside the hydrogen generation tank 100. A fixed amount suction nozzle 120 to prevent may be provided.

That is, as described above, the suction amount of the hydrogen supply pump 110 is determined so that the amount of hydrogen can be supplied through the hydrogen supply pump 110 at a constant level. The amount of may be relatively less than this suction amount, and in this case, a vacuum pressure may be formed in the inside of the hydrogen generation tank 100. However, since such vacuum pressure may be affected in the process of replenishing or draining purified water, which will be described later, it is preferable to maintain the vacuum pressure so that the inside of the hydrogen generation tank 100 is not formed through the quantitative suction nozzle 120.

When the vacuum pressure is formed in the hydrogen generating tank 100, the quantitative suction nozzle 120 may introduce outside air or additional hydrogen into the hydrogen generating tank 100 to prevent the vacuum pressure from forming.

That is, when the vacuum pressure is formed by communicating the fixed amount suction nozzle 120 with the outside air, the outside air is introduced to relieve the vacuum pressure, or the hydrogen is supplied by communicating with a separate source of hydrogen to relieve the vacuum pressure. It is also possible.

That is, as shown in FIG. 2, the hydrogen generated in the hydrogen generating tank 100 is supplied to the water pump 200 through the hydrogen supply pump 110 and then mixed with water to the bubble tank 300. It is moved, and water and hydrogen are discharged in a mixed state in the form of a bubble in the bubble tank 300.

In addition, as shown in FIG. 3, after the hydrogen generation process is finished, it is preferable to configure the inside of the bubble tank 300 to be cleaned using the air pump 600.

A purified water supply pump 1100 for sucking purified water from the purified water storage unit 20 and discharging the purified water into the hydrogen generating tank 100 so that purified water is supplied into the hydrogen generating tank 100 may be further included.

With this configuration, purified water can be effectively replenished according to the amount of purified water inside the hydrogen generating tank 100, and an upper limit measuring sensor and a lower limit measuring sensor capable of measuring the amount of purified water are provided inside the hydrogen generating tank 100. Can be.

At this time, as shown in FIGS. 4 and 5, a flow path for supplying purified water and a flow path for draining purified water are formed between the hydrogen generation tank 100 and the purified water storage unit 10, and a single purified water supply pump ( A flow path control valve 1110 and a branch valve 1120 for selectively communicating the purified water supply line and the purified water discharge line to the purified water supply pump 1100 are provided to enable supply and drainage of purified water using 1100. Can be.

In other words, if it is necessary to replenish purified water during the hydrogen generation process, purified water is replenished into the interior of the hydrogen generation tank 100 using the purified water supply pump 1100, but when hydrogen generation is finished, the interior of the hydrogen generation tank 100 is replenished. Maintaining dryness is advantageous in terms of product durability and hygiene, so purified water is drained, but it is configured to be drained using the above-described purified water supply pump 1100, and for this purpose, as described above, purified water is supplied. A flow path control valve 1110 and a branch valve 1120 for selectively communicating the line and the line through which the purified water is discharged to the purified water supply pump 1100 are provided.

At this time, the flow path control valve 1110 includes a first flow control valve 1111 and a second flow control valve 1112, and the branch valve 1120 includes a first branch valve 1121 and a second branch valve. Including 1122, and as shown in FIG. 4, when purified water is supplied, the purified water is moved to the purified water supply pump 1100 through the first flow path control valve 1111 and the first branch valve 1121 in sequence. Subsequently, the second branch valve 1122 and the second flow path control valve 1112 may be sequentially passed through and supplied to the inside of the hydrogen generation tank 100.

In addition, when the purified water is drained, the purified water moves to the purified water supply pump 1100 by sequentially passing through the second flow path control valve 1112 and the first branch valve 1121, as shown in FIG. 5, and then the second branch valve. It may be drained into the purified water storage unit 10 while passing through 1122 and the first flow path control valve 1111 in sequence.

As shown in FIG. 7, a safety valve 500 for selectively communicating the hydrogen generation tank 100 and outside air is further included. When the process of generating hydrogen bubbles ends, the control unit 400 temporarily opens the safety valve 500. That is, the process of generating hydrogen in the hydrogen generation tank 100, and the hydrogen is mixed with water through the water pump 200 and then introduced into the bubble tank 300, and the hydrogen bubbles inside the bubble tank 300. When the process of spraying is completed after mixing in the form of a furnace, a vacuum pressure is formed in the hydrogen generation tank 100 due to the suction power of the water pump 200. At this time, the safety valve 500 is temporarily opened to generate hydrogen. This vacuum pressure can be eliminated by allowing the tank 100 to communicate with the outside air.

As the process of generating hydrogen bubbles is repeated, foreign substances are accumulated in the bubble tank 300, and an air pump 600 for supplying cleaning air is provided for cleaning the inside of the bubble tank 300. In order to supply the cleaning air to the air pump 600, the cleaning air supply unit 20 is connected.

In the flow path connecting the air pump 600 and the bubble tank 300, a check valve 40 for preventing reverse flow of the cleaning air and a pressure check unit 50 for checking and controlling the pressure of the cleaning air are provided. I can.

As shown in FIG. 8, while the air for cleaning is injected at high pressure into the bubble tank 300 through the air pump 600, foreign substances in the bubble tank 300 are washed. In addition, the high-pressure cleaning air is discharged to the outside of the bubble tank 300 after washing foreign substances. The foreign matter discharge passage of the bubble tank 300 may be formed in the same manner as the passage through which hydrogen bubbles are injected. With this configuration, hydrogen bubbles can be injected and foreign substances can be discharged using a single flow path, thereby simplifying the configuration. If necessary, a flow path through which hydrogen bubbles are injected and a flow path through which foreign substances are discharged may be separately formed.

In addition, if the air pump 700 and the cleaning air supply unit 20 are used to clean the inside of the bubble tank 300, cleaning can be performed without disassembling the product to remove foreign substances. Improves.

In addition, since the bubble tank 300 is initialized to a state without water and hydrogen through the cleaning process, there is an effect that hydrogen bubbles can be normally generated in the initial state when generating hydrogen bubbles again later.

When the hydrogen generation process is repeated inside the hydrogen generation tank 100, the amount of purified water in the hydrogen generation tank 100 decreases. At this time, the hydrogen generation tank 100 and the purified water storage unit 10 are used to replenish the purified water. Is configured to communicate with each other. In addition, the control unit 400 controls the air pump 600 so that a vacuum pressure is formed in the hydrogen generation tank 100, as shown in FIG. 9, and the vacuum pressure is formed in the hydrogen generation tank 100 in this way. Then, the purified water discharged from the purified water storage unit 10 moves to the hydrogen generation tank 100. As described above, if purified water is replenished by using the vacuum pressure inside the hydrogen generating tank 100 while the hydrogen generating tank 100 and the purified water storage unit 10 are in communication, the purified water is stored in the hydrogen generating tank 100 without disassembling the product. Since it can be supplemented, there is an effect of improving convenience according to use.

To this end, an air line AL for supplying cleaning air and a tank line TL in communication with the hydrogen generation tank 100 are connected to the air pump 600. At this time, the air line AL and the tank line TL ) Is provided with a supply valve 700 for controlling to be selectively connected to the air pump 600. That is, when the bubble tank 300 is washed, the air pump 600 communicates with the air line AL, and when replenishing purified water, the air pump 600 communicates with the tank line TL. By switching to, since both the washing process and the purified water replenishment process can be performed using a single air pump 600, the configuration is simple, and maintenance and repair are facilitated.

At this time, it is preferable that the control unit 400 controls the supply valve 700 to operate before the air pump 600. This is because when the air pump 600 is operated when the flow path of the supply valve 700 is switched, only a part of the flow path of the supply valve 700 is changed due to the suction force of the air pump 600, or the entire flow path is not changed. Because it can. Therefore, it is preferable that the control unit 400 controls the air pump 600 to operate after the flow path of the supply valve 700 is completely switched, and the control unit 400 includes a flow path change time of the supply valve 700. It is desirable that the related specifications are input and configured to be controlled by reflecting these specifications.

When the supply valve 700 has a size that may not be affected by the suction power of the air pump 600 or has an internal structure, the control unit 400 may control the air pump 600 and the supply valve 700 at the same time. Do.

As shown in FIG. 9, a safety valve 500 for selectively communicating the hydrogen generation tank 100 and outside air is further included. When the process of replenishing purified water through the air pump 600 ends, the control unit 400 temporarily opens the safety valve 500. That is, as described above, the air pump 600 is operated to replenish purified water to form a vacuum pressure inside the hydrogen generation tank 100. Even when the operation of the air pump 600 is terminated, the hydrogen generation tank 100 The vacuum pressure formed inside is not resolved. If this condition persists, a phenomenon in which purified water is arbitrarily replenished from the purified water storage unit 10 may occur. This may be advantageous in terms of replenishing purified water, but causes another problem in that the amount of purified water in the hydrogen generation tank 100 cannot be adjusted. Since it is necessary to secure an optimal volume for generating hydrogen inside the hydrogen generation tank 100, it is necessary to configure the purified water not to be replenished arbitrarily, and for this purpose, the purified water replenishment process through the air pump 600 is terminated. Then, by temporarily opening the safety valve 500 to communicate with the hydrogen generation tank 100 and outside air, this vacuum pressure can be eliminated.

The hydrogen that has moved to the top of the hydrogen generation tank 100 for hydrogen bubble injection is mixed with water supplied from a separate water source by the water pump 200 and then discharged and introduced into the bubble tank 300. The hydrogen generation tank Since the amount of hydrogen generated in the hydrogen generating tank 100 is not large at the moment when 100 starts operation, if the water pump 200 is operated in this state, only water supplied from a separate water source is passed through the water pump 200. There may be a problem flowing into the bubble tank 300. In order to prevent such a problem from occurring, the controller 400 may control the hydrogen generation tank 100 to operate before the water pump 200. When configured in this way, the water pump 200 is operated while the hydrogen generating tank 100 first operates and a certain amount of hydrogen is generated in the hydrogen generating tank 100. It can be introduced into the bubble tank 300 through 200).

In this case, as shown in FIGS. 10 and 11, a pump valve 800 may be provided to control whether or not water supplied to the water pump 200 is supplied from a separate water source. This basically uses the water pump 200 in the process of supplying water and hydrogen to the bubble tank 300, but in addition, in the process of washing the bubble tank 300 or replenishing purified water in the hydrogen generating tank 100, a separate It is to close the supply of water from the water source and to use only the suction power of the water pump 200, and the operation of the water pump 200 will be described later.

In this case, it is preferable that the control unit 400 controls the pump valve 800 to operate before the water pump 200. This is because when the water pump 200 is operated while the pump valve 800 closes the flow path of water supplied from a separate water source, only a part of the flow path of the pump valve 800 is closed due to the suction force of the water pump 200, This is because there may be a problem that the entire flow path is not closed. Therefore, it is preferable that the control unit 400 controls the water pump 200 to operate after the flow path of the pump valve 800 is completely closed, and the control unit 400 requires the flow path of the pump valve 800 to be closed. It is desirable that the specifications for the time to be entered are configured to reflect these specifications to be controlled.

When the pump valve 800 has a size that may not be affected by the suction power of the water pump 200 or has an internal structure, the control unit 400 may control the water pump 200 and the pump valve 800 at the same time. Do.

As shown in FIG. 11, in the hydrogen bubble generation process, hydrogen generated in the hydrogen generation tank 100 and water supplied from a separate water source are mixed through the water pump 200 and then introduced into the bubble tank 300, In this case, a hydrogen amount control valve 30 may be provided in a flow path connecting the hydrogen generation tank 100 and the water pump 200 to control the amount of moving hydrogen.

As shown in FIG. 12, a safety valve 500 is further included so that the hydrogen generation tank 100 and the cleaning air supply unit 20 are selectively communicated, and at this time, the control unit 400 controls the pump valve 800. It is possible to perform the cleaning process of the bubble tank 300 by closing the safety valve 500 and the water pump 200 so that the cleaning air is supplied to the bubble tank 300 through the hydrogen generating tank 100. .

That is, while the flow path of the pump valve 800 is closed, the washing process of the bubble tank 300 is performed using the suction force of the water pump 200. When configured in this way, since an additional driving source for supplying the cleaning air is not required, the configuration is simplified and manufacturing cost is reduced.

At this time, as shown in FIG. 12, a tank line TL is provided so that the water pump 200 and the hydrogen generation tank 100 communicate with each other, and this tank line TL is a first tank line through which hydrogen passes ( It includes TL1) and a second tank line TL2 through which cleaning air passes.

As described above, a hydrogen amount control valve 30 is provided to control the amount of hydrogen supplied from the hydrogen generation tank 100 during the hydrogen bubble generation process, and the hydrogen amount control valve 300 The size and structure of the internal flow path are limited so that the amount can be finely adjusted.If the cleaning air is configured to pass through the hydrogen amount control valve 30 even in the cleaning process, the amount of cleaning air that moves is small, so the bubble tank ( 300) A problem that takes a lot of time may occur during washing. In order to prevent such a problem from occurring, a second tank line TL2 through which the cleaning air passes is separately provided. In the second tank line TL2, it is preferable to set the size of the flow path so that the cleaning process can be effectively performed. In addition, since hydrogen passes through the first tank line TL1, a hydrogen amount control valve 30 is provided to control the amount of hydrogen.

In this case, a discharge valve 900 is provided to selectively open the first tank line TL1 and the second tank line TL2. In the discharge valve 900, basically, one of the flow paths is always open, and when the discharge valve 900 is operated, one flow path may be closed and the other flow path may be opened. That is, basically, the first tank line TL1 is kept open to allow hydrogen to pass therethrough, and when the discharge valve 900 is operated, the first tank line TL1 is closed, and the second tank line ( TL2) is configured to be open.

When configured in this way, it is possible to smoothly open and close the first tank line TL1 and the second tank line TL2.

12 and 13, the above-described safety valve 500 is connected to an air line AL for supplying cleaning air and a purified water line WL for replenishing purified water, and the controller 400 The safety valve 500 is controlled so that the air line AL and the purified water line WL are selectively communicated with the hydrogen generation tank 100.

That is, the control unit 400 controls the air line AL and the hydrogen generation tank 100 to communicate with each other during the washing process of the bubble tank 300, and the purified water line WL to communicate with each other during the process of replenishing purified water.

In addition, as shown in FIG. 12, the control unit 400 controls the second tank line TL2 to be opened when the hydrogen generation tank 100 and the air line AL communicate with each other, as well as shown in FIG. As described above, even when the hydrogen generation tank 100 and the purified water line WL are in communication, it is preferable to control the second tank line TL2 to be opened. This is because the size of the flow path is set so that the cleaning process or the purified water replenishment process can be effectively performed in the second tank line TL2.

The purified water line WL is provided with an intermittent valve 1000 that controls whether or not purified water is supplied, and in the process of replenishing purified water, the control unit 400 preferably controls the water pump 200 to operate before the intermittent valve 1000. Do. That is, when the water pump 200 first operates in a state in which the intermittent valve 1000 is closed, a vacuum pressure is formed in the hydrogen generation tank 100 and the purified water line WL due to the suction force of the water pump 200, When vacuum pressure is formed in the hydrogen generation tank 100 as described above, the purified water flowing out of the purified water storage unit 10 moves to the hydrogen generation tank 100 through the purified water line WL. As described above, if purified water is replenished by using the vacuum pressure inside the hydrogen generating tank 100 while the hydrogen generating tank 100 and the purified water storage unit 10 are in communication, the purified water is stored in the hydrogen generating tank 100 without disassembling the product. Since it can be supplemented, there is an effect of improving convenience according to use.

In addition, when the vacuum pressure is formed in the hydrogen generation tank 100 using the water pump 200 as described above, the hydrogen bubble generation process, the washing process, and the purified water replenishment process can all be performed using a single water pump 200. Therefore, there is an effect that the configuration is simple, and maintenance and repair are easy.

It is preferable that the control unit 400 controls the safety valve 500 so that the air line AL temporarily communicates with the hydrogen generation tank 100 after the operation of the water pump 200 is terminated. In the process of replenishing purified water, the water pump 200 is operated to form a vacuum pressure in the hydrogen generating tank 100. Even when the operation of the water pump 200 is terminated, the vacuum pressure formed in the hydrogen generating tank 100 is eliminated. It will not be. If this condition persists, a phenomenon in which purified water is arbitrarily replenished from the purified water storage unit 10 may occur, which causes a problem in that the amount of purified water in the hydrogen generation tank 100 cannot be adjusted. To this end, when the process of replenishing purified water through the water pump 200 is finished, the safety valve 500 is controlled so that the air line AL is temporarily communicated with the hydrogen generating tank 100 to It is possible to eliminate the pneumatic pressure.

A hydrogen bubble generation method using such a hydrogen bubble generation device is as follows.

14 and 15, generating hydrogen through electrolysis of purified water contained in the hydrogen generation tank 10, hydrogen generated in the hydrogen generation tank 100 and water supplied from a separate water source After supplying the water to the water pump 200, mixing and discharging the same, and mixing the water and hydrogen discharged from the water pump 200 in the bubble tank 300 in a bubble form and spraying the mixture.

In this case, as shown in FIG. 14, the hydrogen generation tank 100 and the water pump 200 may be operated at the same time.

After the step of mixing water and hydrogen in a bubble form and then spraying the bubble tank 300, as shown in FIGS. 14 and 15, the operation of the hydrogen generating tank 100 and the water pump 200 is terminated, It further includes temporarily opening the safety valve 500 to communicate with the hydrogen generation tank 100 and outside air.

In addition, after the step of temporarily opening the safety valve 500, as shown in FIG. 16, the bubble tank ( 300) Carry out washing.

After the operation of the air pump 600, the step of terminating the operation of the air pump 600 and waiting is further included.

After this waiting step, as shown in FIG. 17, by operating the air pump 600 in a state in which the air pump 600, the hydrogen generation tank 100, and the purified water storage unit 10 are in communication, the hydrogen generation tank ( 100) Purified water replenishment step of allowing purified water to flow into the interior is further included.

After the step of introducing purified water, a step of temporarily opening the safety valve 500 so that the hydrogen generating tank 100 and outside air communicate with each other is further included to relieve the vacuum pressure inside the hydrogen generating tank 100.

Alternatively, as shown in FIGS. 18 and 19, first operating the hydrogen generation tank 100 to generate hydrogen through electrolysis of purified water accommodated in the hydrogen generation tank 100, the water pump 200 Operating the pump valve 800 so that water supplied from a separate water source is supplied, supplying hydrogen generated in the hydrogen generation tank 100 and water supplied from a separate water source to the water pump 200, and then mixing them. Discharging and mixing the water and hydrogen discharged from the water pump 200 in a bubble form in the bubble tank 300 and then spraying.

In addition, after the step of spraying water and hydrogen in the bubble form from the bubble tank 100, as shown in FIG. 20, the operation of the hydrogen generating tank 100 and the pump valve 800 is terminated, and the cleaning air is The process of washing the bubble tank 300 is performed by continuously operating the water pump 200 to be supplied to the bubble tank 300 through the hydrogen generating tank 100.

After the operation of the water pump 200, the step of ending and waiting for the operation of the water pump 200 is further included.

After the standby step, as shown in FIG. 21, the water pump 200 is operated while the water pump 200, the hydrogen generating tank 100, and the purified water storage unit 10 are in communication. ) Further comprising the step of replenishing the purified water so that the purified water is introduced into the interior.

After the step in which the purified water is introduced, the safety valve 500 is temporarily opened so that the hydrogen generation tank 100 and the cleaning air supply unit 20 communicate with each other, so that the vacuum pressure formed in the hydrogen generation tank 100 can be relieved. .

Through the above-described process, hydrogen bubble generation, washing, and replenishment of purified water can be effectively performed.

Although an embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiment presented in the present specification, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same idea. It will be possible to easily propose other embodiments by changing, deleting, adding, etc., but it will be said that this is also within the scope of the present invention.

10: purified water storage unit 20: air supply unit for washing
30: hydrogen amount control valve 40: check valve
50: pressure check unit 100: hydrogen generation tank
110: hydrogen supply pump 120: fixed amount suction nozzle
200: water pump 300: bubble tank
400: control unit 500: safety valve
600: air pump 700: supply valve
800: pump valve 900: discharge valve
1000: intermittent valve 1100: purified water supply pump
1110: flow path control valve 1111: first flow path control valve
1112: second flow path control valve 1120: branch valve
1121: first branch valve 1122: second branch valve
AL: Air line TL: Tank line
TL1: first tank line TL2: second tank line
WL: Purified water line

Claims (13)

A hydrogen generation tank for generating hydrogen through electrolysis of purified water;
A water pump for mixing and discharging hydrogen generated in the hydrogen generating tank and water supplied from a separate water source;
A bubble tank for mixing water and hydrogen discharged from the water pump in a bubble form and then spraying it; And
A control unit for controlling the operation of the hydrogen generation tank and the water pump;
Including,
A hydrogen supply pump is provided between the hydrogen generation tank and the water pump to supply hydrogen generated in the hydrogen generation tank by pressurizing it with the water pump,
In the hydrogen generation tank, when the amount of hydrogen generated in the hydrogen generation tank is relatively smaller than the suction amount of the hydrogen supply pump, a hydrogen bubble having a quantitative suction nozzle that prevents the formation of vacuum pressure inside the hydrogen generation tank Generating device. delete delete The method of claim 1,
When a vacuum pressure is formed in the hydrogen generating tank, the quantitative suction nozzle prevents the formation of vacuum pressure by introducing outside air or additional hydrogen into the hydrogen generating tank. The method of claim 4,
A hydrogen bubble generating device further comprising a purified water supply pump for sucking purified water from the purified water storage unit and discharging the purified water into the hydrogen generating tank so that purified water is supplied into the hydrogen generating tank. The method of claim 5,
A flow path for supplying purified water and a flow path for draining purified water are formed between the hydrogen generation tank and the purified water storage unit,
Hydrogen bubble generation provided with a flow path control valve and a branch valve that selectively communicates the purified water supply line and the purified water drainage line to the purified water supply pump to enable supply and drainage of purified water using a single purified water supply pump Device. The method of claim 6,
The flow path control valve includes a first flow path control valve and a second flow path control valve,
The branch valve includes a first branch valve and a second branch valve,
When purified water is supplied, the purified water sequentially passes through the first flow path control valve and the first branch valve, moves to the purified water supply pump, and then sequentially passes through the second branch valve and the second flow path control valve to generate the hydrogen. A hydrogen bubble generator that is supplied to the inside of the tank. The method of claim 7,
When the purified water is drained, the purified water is sequentially passed through the second flow path control valve and the first branch valve, moves to the purified water supply pump, and then sequentially passes through the second branch valve and the first flow path control valve to store the purified water. A hydrogen bubble generator that is drained to the part. The method of claim 1,
A safety valve for selectively communicating the hydrogen generation tank and outside air is further included,
And the control unit temporarily opens the safety valve after the operation of the hydrogen generation tank and the water pump is terminated. The method of claim 1,
Hydrogen bubble generation apparatus, characterized in that further comprising an air pump for supplying the cleaning air to the bubble tank. The method of claim 1,
Wherein the control unit controls the hydrogen generation tank to operate before the water pump. Generating hydrogen through electrolysis of purified water accommodated in the hydrogen generating tank;
Supplying hydrogen generated in the hydrogen generation tank and water supplied from a separate water source to a water pump, mixing them, and discharging them; And
Mixing water and hydrogen discharged from the water pump into a bubble in a bubble tank and then spraying;
Including,
The step of supplying hydrogen generated in the hydrogen generation tank and water supplied from a separate water source to a water pump, mixing and discharging the same,
The hydrogen generation tank is supplied by pressurizing hydrogen with a hydrogen supply pump provided between the hydrogen generation tank and the water pump, but when the amount of hydrogen generated in the hydrogen generation tank is relatively smaller than the suction amount of the hydrogen supply pump A hydrogen bubble generating method comprising the step of supplying by pressurizing hydrogen with the hydrogen supply pump while preventing a vacuum pressure from being formed in the hydrogen generating tank through a quantitative suction nozzle provided in the. Generating hydrogen through electrolysis of purified water accommodated in the hydrogen generating tank;
Operating a pump valve to supply water supplied from a separate water source to the water pump;
Supplying hydrogen generated in the hydrogen generation tank and water supplied from a separate water source to the water pump, mixing them, and discharging them; And
Mixing water and hydrogen discharged from the water pump into a bubble in a bubble tank and then spraying;
Including,
The step of supplying hydrogen generated in the hydrogen generation tank and water supplied from a separate water source to a water pump, mixing and discharging the same,
The hydrogen generation tank is supplied by pressurizing hydrogen with a hydrogen supply pump provided between the hydrogen generation tank and the water pump, but when the amount of hydrogen generated in the hydrogen generation tank is relatively smaller than the suction amount of the hydrogen supply pump A hydrogen bubble generating method comprising the step of supplying by pressurizing hydrogen with the hydrogen supply pump while preventing a vacuum pressure from being formed in the hydrogen generating tank through a quantitative suction nozzle provided in the.

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