JP6934317B2 - Free-standing hydrogen power generation and drinking water supply system - Google Patents

Description

The present invention relates to a hydrogen power generation and drinking water supply system that can independently supply power and drinking water without requiring a commercial power source in the event of a disaster such as an earthquake, and particularly adsorbs moisture in the atmosphere.・ By collecting and collecting water, it is possible to supply drinking water even in places where there is no water source, and it is possible to supply drinking water regardless of the water quality such as the hardness of the water. The present invention relates to a self-sustaining hydrogen power generation and drinking water supply system capable of effectively utilizing surplus power generated when the amount of power generated by a renewable energy power generation device exceeds the power required for the operation of this system.

If a disaster such as an earthquake occurs and the lifeline is stopped, it is expected that it will take a considerable amount of time for the lifeline to spread. At present, each local government has an urgent need to set up an emergency shelter in the event of a disaster. It has been pointed out that it becomes difficult to secure tap water and power supply due to the suspension of lifelines in the event of a disaster. In particular, one of the problems in emergency evacuation centers is that the procurement and distribution of drinking water is a serious problem.
Schools and public halls are often designated as emergency evacuation centers set up in various parts of the country. Such facilities may have a pool as ancillary equipment. Many of these pools store water all year round. If the water stored in such a pool can be utilized as drinking water, it can be expected to solve the problem of drinking water in the emergency evacuation center to which the pool is attached.
In order to supply safe drinking water in such an emergency shelter, a water treatment device is indispensable. Currently, various water treatment devices for drinking water are known, but securing a power source is a major problem in all of them. Therefore, especially in the event of a disaster, it is an issue to operate a water treatment device without using a commercial power source to secure drinking water.

The invention disclosed in Patent Document 1 is known as a system for securing a power source without using a commercial power source. Patent Document 1 discloses a power supply system having a direct methanol fuel cell and a secondary battery.
For example, FIG. 5 is a schematic diagram showing an example of a conventional power supply system. As shown in FIG. 5, the conventional power supply system 30 needs to input the electricity stored in the secondary battery 37 in two steps. One is to generate electricity from a charging mechanism using natural energy such as a solar panel 31 and store it in a secondary battery 37. The other is that electricity is directly generated by the methanol fuel cell 33 and stored in the secondary battery 37. By using such a power supply system 30, it is considered that continuous driving for a long time becomes possible, and for example, a device 35 such as a water treatment system can be continuously operated in the event of a disaster. Here, as a water treatment system, the one disclosed in Patent Document 2 is known.
However, although the power supply system 30 includes a fuel tank 34 for storing methanol as a fuel, it does not have a means for independently producing fuel. That is, since it is necessary to replenish methanol directly according to the operating status of the methanol fuel cell 33, it is predicted that it will be difficult to stably supply electric power for a long period of time when the system is examined as a single unit.

As another problem, if the source of raw water used for water treatment is located away from the power supply system and the drinking water supply device, access to the raw water is expected to become a problem.
In addition, when the secondary battery is charged with the electricity generated from the renewable energy power generation device to supply power, or when the power is generated using fossil fuel such as gasoline and the power is supplied for a long period of time, the secondary battery is used. It is necessary to use a battery with a large storage capacity. Further, since it is necessary to increase the storage amount of fossil fuel, there is a problem that not only the size of the device is increased but also the weight of the device constituting the system is increased.
Another problem is that drinking water and the like cannot be supplied at all in places where there is no water source. In addition, when using this system using rivers and tap water in areas with high water hardness, and pool water stored in pools as raw water, calcium, magnesium, etc., which are abundant in raw water, are deposited and scale adheres to pipes, etc. It may cause a failure.
Furthermore, systems that use natural energy such as solar panels can be used for water treatment systems, but the amount of power generated by fuel cells, renewable energy power generators, and fuel cells exceeds the power required to operate this system, resulting in surplus. Power may be generated. Effective utilization of such surplus electricity has also been pointed out as a problem.
The present inventor examined the problems of the power supply system in the prior art, created a system that enables a stable supply of drinking water for a long period of time without using a commercial power source, and further, even in a place without a water source. Self-supporting hydrogen that can supply drinking water, etc., can supply drinking water regardless of water quality such as water hardness, and can effectively utilize surplus electricity from fuel cells and solar panels. Developed a power generation and drinking water supply system.

Japanese Unexamined Patent Publication No. 2014-187856 Japanese Unexamined Patent Publication No. 2013-212470

The present invention is a self-sustaining hydrogen power generation and drinking water supply system that enables power generation and drinking water supply by itself, does not require a commercial power source, and can stably supply electricity and drinking water for a long period of time. The purpose is to provide.
In addition to being able to treat pool water and well water as raw water, the present invention is a self-supporting type that can supply drinking water and domestic water by adsorbing, collecting and collecting water in the atmosphere. The purpose is to provide a hydrogen power generation and drinking water supply system.
Another object of the present invention is to provide a system for continuously circulating a plurality of processes such as hydrogen supply, fuel cell operation, water treatment, and water collection.

In addition, a self-supporting hydrogen power generation and beverage that can be configured so that multiple devices can be separated, the system unit including the water collecting device can be transported to a place with high humidity, and the system unit including the water treatment device can be transported to the water source. The purpose is to provide a water supply system.
The purpose is to supply drinking water regardless of the water quality such as the place where there is no water source or the hardness of the water.
Another object of the present invention is to provide a self-sustaining hydrogen power generation and drinking water supply system that can effectively utilize surplus electric power of fuel cells and solar panels. A further object of the present invention is to provide a self-sustaining hydrogen power generation and drinking water supply system that can be made smaller and lighter than a system that generates power using fossil fuels and the like.

The present inventor has adopted the following configuration in order to solve the above problems.
(1) A hydrogen power generation and drinking water supply system having a hydrogen generation device and a drinking water supply device, wherein the hydrogen generation device has a secondary battery and a hydrogen production device that produces hydrogen by reacting water. , The drinking water supply device has a fuel cell, a hydrogen storage device, and a water treatment device, and further has a water collection device for supplying water to the hydrogen production device and \ or the water treatment device. However, it has an adsorbent that adsorbs water contained in the outside air or a collector that collects water, and has a water collecting tank that receives the water adsorbed and collected by the adsorbent. Type hydrogen power generation and drinking water supply system.
As described above, the water collecting device according to the present invention has at least an adsorbent or a collecting agent, and a water collecting tank. If it can be suitably used for the present invention, it is included in the scope of the present invention even if it has other configurations.

Here, the collecting agent can be made by using natural fibers such as cotton, hemp, wool, silk and other natural fibers and chemical fibers, and cellulosic regenerated fibers typified by rayon and cupra. Examples thereof include natural fibers and regenerated fibers processed into filaments and staples, woven, knitted, and non-woven fabrics using them, and further processed to have fine surface properties. With such a configuration, moisture in the atmosphere can be collected as water droplets on the surface of the collecting agent without requiring electric power, and water can be collected by receiving the water droplets as they are in the water collecting tank. It becomes.
Further, the adsorbent is a substance having many fine pores on the surface and having a porous surface. Examples thereof include substances such as silica gel, activated carbon, activated alumina, zeolite, aluminum oxide, molecular sieve, allophane, and clay.

Further, the hydrogen production apparatus uses water electrolysis, steam reforming, partial oxidation reforming, methanol / ethanol reforming, etc., or a chemical reaction between water or an alkaline solution and a reaction substance. It is a device that produces hydrogen by means of this. The water used is preferably purified water, but drinking water or tap water sold on the market can be used as long as it can generate hydrogen. When a renewable energy power generation device is used, a method of producing hydrogen by electrolysis of water, which can produce hydrogen by using electricity generated from the device, is preferable. Further, as the hydrogen production apparatus by a chemical reaction, a method of reacting water with aluminum or a method of producing hydrogen by reacting an alkaline solution with aluminum can be used. In addition, the hydrogen production apparatus according to the present invention can generate hydrogen by using, for example, a method of reacting silicon nanoparticles (Si nanoparticles) treated in the form of powder of 10 nm or less with water.
Further, the fuel cell in the present invention is a fuel cell in which hydrogen is supplied to the anode (anode) and oxygen is supplied to the cathode (cathode), so that hydrogen and oxygen are supplied and reacted in a normal temperature or high temperature environment to continuously generate electric power. It is a power generation device that can take out. For example, a polymer electrolyte fuel cell that generates electricity by supplying an oxidizing agent to the positive electrode and hydrogen as a reducing agent across an ion exchange membrane is known.

Further, as the hydrogen storage device in the present invention, hydrogen storage alloys, organic hydrites, liquid hydrogen tanks, high-pressure hydrogen tanks and the like are currently known. Of these, a hydrogen storage alloy having a high hydrogen filling density is preferable. Further, a hydrogen storage alloy cylinder may be used. As hydrogen storage alloys, AB2 type, AB5 type, BCC solid solution type, Ti—Fe type, V type, Mg alloy, Pd type, and Ca type alloy are currently known.
Further, the water treatment device in the present invention is a device that produces drinking water from a pool, a pond, or the like. In the present invention, it is preferable that the pump and the filtration device are composed of the pump and the filtration device.
Here, as the filtration device, an activated carbon filter, a metal filter using stainless steel, aluminum, bronze, copper, titanium, nickel, etc., polypropylene, polyvinyl chloride, polyvinylidene chloride, polyethylene, polyamide, etc. , Cartridge type filtration device using a resin filter or the like using a fluorine-based resin or the like, sand filtration device, diatomaceous earth type filtration device and the like.

The hydrogen generation device used in the present invention has at least a secondary battery for storing electricity and a hydrogen production device. If necessary, other parts such as a pure water production apparatus may be provided. For example, a solar panel or the like. When using a type of device that electrolyzes water as a hydrogen production device, a step of producing water is required. In the present invention, as the water to be electrolyzed, pure water obtained by further passing the drinking water purified by the drinking water supply device of the present invention through the pure water production device may be used.
The drinking water supply device used in the present invention has at least a fuel cell, a hydrogen storage device, and a water treatment device. Other parts may be provided if necessary. For example, a charging box for a mobile phone. The hydrogen produced in the hydrogen generation device will be stored in the hydrogen storage device in such a drinking water supply system.
Then, the stored hydrogen can be used to operate the fuel cell, and to supply electricity as a power source for operating a household AC power source, a pump for purifying drinking water, and a filtration device. Further, the fuel cell can be used as it is without storing the hydrogen generated in the hydrogen generation device in the hydrogen storage device.

(2) A heater in which the water collecting device further heats the adsorbent or the collecting agent and desorbs the water adsorbed and collected by the adsorbent or the collecting agent as water vapor, and condensing the water vapor. The self-supporting hydrogen power generation and drinking water supply system according to (1) above, wherein the water generated by the container and the condenser is received in the water collecting tank.
In addition, the heater heats the taken-in outside air, aerates the adsorbent that has adsorbed the moisture or the collecting agent that has collected the moisture, and desorbs the moisture adsorbed by the adsorbent or the collecting agent. It is incorporated for the purpose of obtaining hot and humid air. For example, a steam heater or an electric heater can be used, but it is also possible to substitute a heat source in which the heat generated from the hydrogen storage device built in the drinking water supply device is transferred by a heat pipe.
The condenser is a heat exchanger that cools the hot and humid outside air obtained by the heater and generates water droplets by dew condensation.
The water collecting tank is a container that collects water by receiving the water droplets adsorbed and collected by the adsorbent as they are. The collected water is supplied as the raw water of the pure water production device or the hydrogen production device of the hydrogen generation device, or is supplied to the water treatment device of the drinking water supply device, and after filtration, is further supplied to the drinking water or the hydrogen production device. It is also possible to supply.
Such a water collecting device may be built in a hydrogen generating device or a drinking water supply device, or may be divided into a hydrogen generating device or a drinking water supply device and configured as a single unit. For example, a steam heater or an electric heater can be used, but it is also possible to substitute a heat source in which the heat generated from the hydrogen storage device built in the drinking water supply device is transferred by a heat pipe.
The condenser is a heat exchanger that cools the hot and humid outside air obtained by the heater and generates water droplets by dew condensation. A water collecting tank is a container that collects water by receiving water droplets generated by dew condensation. (3) The self-sustaining hydrogen power generation and drinking water supply system according to (1) or (2) above, wherein the water collecting device further has an air supply fan that takes in outside air.
Here, the air supply fan is a device for the purpose of taking in the outside air into the self-sustaining hydrogen power generation and drinking water supply system according to the present invention. The taken-in outside air is supplied to the adsorbent, and after collecting and adsorbing the contained moisture, it is released to the atmosphere. Further, the taken-in outside air is heated by the heater and supplied to the adsorbent or the collecting agent, and the moisture collected and adsorbed by the adsorbent or the collecting agent can be desorbed.
(4) The self-sustaining hydrogen power generation and drinking water supply system according to any one of (1) to (3) above, wherein the hydrogen production apparatus produces hydrogen by electrolysis of water. ..

(5) The hydrogen generating device further includes a renewable energy power generation device, and the secondary battery stores electricity generated by the renewable energy power generation device (1) to (1) to the above. The self-sustaining hydrogen power generation and drinking water supply system according to any one of (4).
Here, the renewable energy power generator is constantly or repeatedly replenished by solar power, wind power, wave power, small hydropower, running water, tidal power, geothermal power, biomass, etc., or a combination of these natural forces. It is a power generation device that generates electricity based on energy resources. In the present invention, since it has a hydrogen storage device used for drinking water and a household AC power supply device, it has a certain power generation efficiency and can be operated on a small scale and in a distributed manner. Therefore, solar cells are used as solar cells. Photovoltaic power generation, which directly converts electricity into electricity, is preferable. Further, the hydrogen generating device in the present invention has a secondary battery. By adopting such a configuration, it is possible to appropriately electrolyze water by storing electricity generated by renewable energy in a secondary battery. For example, it is possible to use the electricity generated by the solar panel during the day at night.

(6) The hydrogen generating apparatus further includes a pure water producing apparatus, and receives the water produced by the water collecting device and / or the water produced by the water collecting device (1). The self-sustaining hydrogen power generation and drinking water supply system according to any one of (5).
By adopting such a structure, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention can also generate hydrogen using the produced pure water. Further, as the pure water in the present invention, water generated by the water collecting device or pure water produced by filtration by the water treatment device can also be used.
For example, hydrogen and aluminum hydroxide can be generated by reacting crushed aluminum with purified water purified by a pure water production apparatus as shown in the following formula.
Chemical formula 2Al + 6H ₂ O2Al (OH) ₃ + 3H ₂

(7) The self-sustaining hydrogen power generation and drinking water supply system according to any one of (1) to (6) above, wherein the hydrogen storage device is a hydrogen storage alloy.
(8) One of the above (1) to (7), wherein the fuel cell and \ in the drinking water supply device or the secondary battery in the hydrogen generation device supply electricity as a household AC power source. The self-sustaining hydrogen power generation and drinking water supply system described.
Here, the household AC power source is an AC power of about 100 to 200 V for driving home appliances and the like.
This system is an invention relating to an operation method of a system that independently supplies electric power and drinking water without requiring a commercial power source in the event of a disaster. However, this system can also be used in normal times, etc., not during a disaster. At that time, it is also possible to use it together with a commercial power source. The electricity obtained from the commercial power source can be used to operate the water treatment device, and can also be stored in the secondary battery. For example, in normal times other than a disaster, this system can be operated in combination with a commercial power source, and in the event of a disaster, the system can be operated by switching to a self-sustaining power supply or drinking water supply. can.

(9) The water collecting device is configured to be separated from the hydrogen generating device and the drinking water supply device, and wheels are attached below the water collecting device, the hydrogen generating device and the drinking water supply device to move. The self-sustaining hydrogen power generation and drinking water supply system according to any one of (1) to (8) above, which is capable of being formed.
By adopting such a configuration, it is possible to use the functions of each device according to the application. For example, if only the drinking water supply device is moved to the raw water storage area, the raw water supply source used for water treatment will be moved to the raw water even if it is located away from the power supply system and the drinking water supply device. Can solve the access problem. Further, by moving only the water collecting device to a place with high humidity, efficient water collecting becomes possible.
That is, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention may be configured by dividing the water collecting device, the hydrogen generating device and the drinking water supply device into three units, or the hydrogen generating device and the drinking water supply device. The device may be configured as one unit, and only the water collecting device may be separately configured. Further, the water collecting device, the hydrogen generating device and the drinking water supply device may be configured as one unit, or the function of the water collecting device may be built in either the hydrogen generating device or the drinking water supply device. ..

The self-sustaining hydrogen power generation and drinking water supply system according to the present invention enables power generation and drinking water supply by itself, does not require a commercial power source, and can stably supply power and drinking water for a long period of time. And.
Further, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention can treat pool water and well water as raw water, and also adsorbs and collects atmospheric moisture to collect water for drinking water and daily life. It makes it possible to supply water.
Further, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention has an effect of constructing a system for continuously circulating a plurality of processes such as hydrogen supply, operation of a fuel cell, water treatment, and water collection. There is.

Further, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention has a plurality of devices separably configured so that a single system including a water collecting device can be transported to a place with high humidity, and also includes a water treatment device. It has the effect of enabling the system itself to be transported to the water source.
Further, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention has an excellent effect of supplying drinking water regardless of the water quality such as a place without a water source and the hardness of water.
Further, the self-sustaining hydrogen power generation and drinking water supply system according to the present invention has an effect of providing a self-sustaining hydrogen power generation and drinking water supply system capable of effectively utilizing surplus power of a fuel cell or a solar panel.
Further, since the self-sustaining hydrogen power generation and drinking water supply system according to the present invention uses the hydrogen produced by the hydrogen production apparatus to generate electricity by the fuel cell, the renewable energy power generation apparatus stores electricity in the secondary battery. Compared to the case of power supply or the case of generating electricity using fossil fuel such as gasoline to supply power, the device can be miniaturized and the weight can be reduced when securing the same power supply amount. It can be suppressed and can be made suitable for portability.

It is a conceptual diagram which shows an example of the self-sustaining hydrogen power generation and drinking water supply system which concerns on Embodiment 1 of this invention. (A) is a drinking water supply device. (B) is a hydrogen generator. (C) is a water collecting device. It is a conceptual diagram which shows an example of the self-sustaining hydrogen power generation and drinking water supply system which concerns on Embodiment 2 of this invention. (A) is a drinking water supply device. (B) is a hydrogen generator. (C) is a water collecting device. It is a conceptual diagram which shows an example of the hydrogen production apparatus which concerns on Embodiment 3 of this invention. It is a perspective view which shows the use example of the self-supporting hydrogen power generation and drinking water supply system which concerns on Embodiment 4 of this invention. (A) is a drinking water supply device. (B) is a hydrogen generator. (C) is a water collecting device. It is a conceptual diagram which shows an example of the conventional power supply system.

An example of an embodiment of the self-sustaining hydrogen power generation and drinking water supply system of the present invention will be described with reference to the drawings. However, the following description is an example of an embodiment of the self-sustaining hydrogen power generation and drinking water supply system of the present invention, and does not limit the scope of the present invention. Embodiment 1
FIG. 1 is a conceptual diagram showing an example of the configuration of a self-supporting hydrogen power generation and drinking water supply system according to the first embodiment. As shown in FIG. 1, the hydrogen power generation and drinking water supply system according to the first embodiment includes a drinking water supply device (a), a hydrogen generation device (b), and a water collecting device (c).
The hydrogen generation device (b) includes a secondary battery 2 for storing electricity and a hydrogen production device 3. Further, the self-supporting hydrogen power generation and drinking water supply system according to the first embodiment has a pure water purification device 4. Further, the self-sustaining hydrogen power generation and drinking water supply system according to the first embodiment has a renewable energy power generation device 5. In the first embodiment, photovoltaic power generation using a solar panel is used. In the renewable energy power generation according to the second embodiment, sunlight is received from the solar panel 5 and electricity is generated by applying the photovoltaic effect to which a solar cell is connected. The generated electricity is stored in the secondary battery 2 in the hydrogen generator (b). The electricity stored in the secondary battery 2 can be used as electric power used when the purified water purified by the pure water purification apparatus 4 is electrolyzed to obtain hydrogen.

The hydrogen production device 3 has an electrode, and by passing electricity charged in the secondary battery 2, electrons react with the pure water purified by the pure water purification device 4 at the cathode, and hydrogen is generated. appear. The decomposed oxygen can be discharged into the atmosphere. The hydrogen generator (b) in the first embodiment requires 500 W of electric power by supplying power from the solar panel, and the amount of hydrogen generated is 1.0 L / min (0.35 MPa Max). The actual dimensions of the hydrogen generator (b) in the first embodiment are width 500 mm × depth 350 mm × height 900 mm. As described above, the hydrogen generator (b) according to the first embodiment is characterized in that it can operate independently without requiring fossil fuel from the outside because it electrolyzes water by solar power generation to generate hydrogen. Has.
The drinking water supply device (a) includes a hydrogen storage device 7 capable of taking in and storing hydrogen generated by the hydrogen generation device (b), a fuel cell 8, and a water treatment device 9. A hydrogen storage alloy is used as the hydrogen storage device 7 in the first embodiment. The drinking water supply device (a) can supply hydrogen stored in the hydrogen storage device 7 to the fuel cell 8 and take out electric energy by an electrochemical reaction with oxygen to use it as electric power.

The electricity obtained by the fuel cell 8 can be used as electricity supplied to the household AC power source E1. The electricity supplied by the household AC power supply E1 is 100 to 200 V. Such a home AC power source E1 can be used as a power source for a mobile terminal required in the event of a disaster or as a power source for home appliances such as a home television.
The electricity obtained by the fuel cell 8 can be supplied as electricity for storing in the secondary battery 2 in the hydrogen generator (b) in addition to the electricity supplied to the household AC power source E2.
The main purpose of the drinking water supply device (a) of the first embodiment is to operate the water treatment device 9. The water treatment device 9 includes a pump, a filtration device, and the like. The water treatment device 9 of the first embodiment can pump the pool water with a pump, filter the pool water with the filtration device, and purify the filtered water W1 for drinking. However, it is not essential that the water treatment device 9 in the first embodiment uses pool water. This is because the water generated by the water collecting device (c) described later may be used. Further, the water purified by the water treatment device 9 can store the drinking water W1 in a drinking water tank (not shown). At the same time, the purified water W2 can be supplied to the pure water purification device 4 in the hydrogen generation device (b). Purified water W2 can also be stored in a purified water tank (not shown).

The drinking water supply device (a) in the first embodiment can supply electric power of 100 W Max for 6 hours, and the water supply amount is 1.0 L / min (Max 3.0 L / min). The actual dimensions of the drinking water supply device (a) in the first embodiment are width 500 mm × depth 350 mm × height 900 mm.
With such a configuration, it is possible to construct a system that continuously circulates a plurality of processes such as hydrogen supply, fuel cell operation, and water treatment. The self-sustaining hydrogen power generation and drinking water supply system of the first embodiment enables power generation and drinking water supply by itself by the above-described configuration, does not require a commercial power source, and stabilizes power and drinking water for a long period of time. In addition, pool water and well water can be treated as raw water to supply drinking water and domestic water.

Further, the self-supporting hydrogen power generation and drinking water supply system of the first embodiment has a water collecting device (c). The water generated by the water collecting device (c) is supplied to the water treatment device 9 in the drinking water supply device (a).
The water collecting device (c) used in the self-sustaining hydrogen power generation and drinking water supply system of the first embodiment has a collecting agent 32 and a water collecting tank 15.
The outside air taken into the water collecting device (c) according to the first embodiment is supplied to the collecting agent 32, and after collecting the contained water, it is released to the atmosphere.

As the collecting agent 32 according to the first embodiment, a non-woven fabric made of rayon as a raw material is used. By using such a non-woven fabric, moisture can be collected from the taken-in outside air to the fine rayon fibers arranged on the surface of the collecting agent 32. In the first embodiment, it is also possible to use an adsorbent instead of the collecting agent.
Then, the water collected by the collecting agent 32 can be collected as water droplets in the water collecting tank 15. The collected water is supplied as the raw material water of the pure water purification device 4 constituting the hydrogen generation device (b), or is supplied to the water treatment device 9 constituting the drinking water supply device (a), and is used for drinking after filtration. It can be further supplied to the water or pure water production apparatus 4. The water collecting device (c) according to the self-sustaining hydrogen power generation and drinking water supply system of the first embodiment is divided into a drinking device (a) and a hydrogen generating device (b) and is configured as a single unit.

Embodiment 2
FIG. 2 is a conceptual diagram showing an example of the configuration of the self-supporting hydrogen power generation and drinking water supply system according to the second embodiment. As shown in FIG. 2, the hydrogen power generation and drinking water supply system of the present invention includes a drinking water supply device (a), a hydrogen generation device (b), and a water collecting device (c). Hereinafter, in the description of the drawings, the same members as those in the first embodiment will be described using the same reference numerals.
The hydrogen generation device (b) includes a secondary battery 2 for storing electricity and a hydrogen production device 3. Further, the self-supporting hydrogen power generation and drinking water supply system according to the second embodiment has a pure water purification device 4. Further, the self-sustaining hydrogen power generation and drinking water supply system according to the second embodiment has a renewable energy power generation device 5. In the second embodiment, photovoltaic power generation using a solar panel is used. Photovoltaic power generation receives sunlight from the solar panel 5 and generates electricity by applying the photovoltaic effect to which a solar cell is connected. The generated electricity is stored in the secondary battery 2 in the hydrogen generator (b). The electricity stored in the secondary battery 2 can be used for two kinds of purposes. One can be used as electric power used when the purified water purified by the pure water purification apparatus 4 is electrolyzed to obtain hydrogen. The other can also be used as electricity supplied to the household AC power supply E1.

The hydrogen production device 3 has an electrode, and by passing electricity charged in the secondary battery 2, electrons react with the pure water purified by the pure water purification device 4 at the cathode, and hydrogen is generated. appear. The decomposed oxygen can be discharged into the atmosphere. The hydrogen generator (b) in the second embodiment requires 500 W of electric power by supplying power from the solar panel, and the amount of hydrogen generated is 1.0 L / min (0.35 MPa Max). The actual dimensions of the hydrogen generator (b) in the first embodiment are width 500 mm × depth 350 mm × height 900 mm. As described above, the hydrogen generator (b) according to the second embodiment is characterized in that it can operate independently without requiring fossil fuel from the outside because it electrolyzes water by solar power generation to generate hydrogen. Has.
The drinking water supply device (a) includes a hydrogen storage device 7 capable of taking in and storing hydrogen generated by the hydrogen generation device (b), a fuel cell 8, and a water treatment device 9. A hydrogen storage alloy is used as the hydrogen storage device 7 in the second embodiment. The drinking water supply device (a) can supply hydrogen stored in the hydrogen storage device 7 to the fuel cell 8 and take out electric energy by an electrochemical reaction with oxygen to use it as electric power.

The electricity obtained by the fuel cell 8 can be used for four kinds of applications. One can be used as electricity supplied to the household AC power supply E2. The electricity supplied by the household AC power supply E2 is 100 to 200 V. Such a household AC power source E2 can be used as a power source for a mobile terminal required in the event of a disaster or as a power source for home appliances such as a home television. The other is used as electric power to operate the water treatment device 9.
The electricity obtained by the fuel cell 8 can be supplied as electricity for storing in the secondary battery 2 in the hydrogen generator (b) in addition to the electricity supplied to the household AC power source E2. It can also be used as electric power for the heater 11 in the water collecting device (c).
The main purpose of the drinking water supply device (a) of the second embodiment is to operate the water treatment device 9. The water treatment device 9 includes a pump, a filtration device, and the like. The water treatment device 9 of the second embodiment can pump the pool water with a pump, filter the pool water with the filtration device, and purify the filtered water W1 for drinking. However, it is not essential that the water treatment device 9 in the second embodiment uses pool water. This is because the water generated by the water collecting device (c) described later may be used. Further, the water purified by the water treatment device 9 can store the drinking water W1 in a drinking water tank (not shown). At the same time, the purified water W2 can be supplied to the pure water purification device 4 in the hydrogen generation device (b). Purified water W2 can also be stored in a purified water tank (not shown).

The drinking water supply device (a) in the second embodiment can supply electric power of 100 W Max for 6 hours, and the water supply amount is 1.0 L / min (Max 3.0 L / min). The actual dimensions of the drinking water supply device (a) in the second embodiment are width 500 mm × depth 350 mm × height 900 mm.
With such a configuration, it is possible to construct a system that continuously circulates a plurality of processes such as hydrogen supply, fuel cell operation, and water treatment. The self-sustaining hydrogen power generation and drinking water supply system of the second embodiment enables power generation and drinking water supply by itself by the above-described configuration, does not require a commercial power source, and stabilizes power and drinking water for a long period of time. In addition, pool water and well water can be treated as raw water to supply drinking water and domestic water.

Further, the self-supporting hydrogen power generation and drinking water supply system of the second embodiment has a water collecting device (c). The water generated by the water collecting device (c) is supplied to the water treatment device 9 in the drinking water supply device (a).
The water collecting device (c) used in the self-sustaining hydrogen power generation and drinking water supply system of the second embodiment includes an air supply fan 10, a heater 11, an adsorbent 12, a condenser 14, and a water collecting tank 15. have.
Here, the air supply fan 10 used in the second embodiment is a blower fan having a function of taking in outside air into the water collecting device. The outside air taken in by the blower fan is supplied to the adsorbent 12, collects and adsorbs the contained moisture, and then releases it to the atmosphere. Further, when obtaining hot and humid air, the taken-in outside air is heated by the heater 11 to supply the adsorbent 12 and desorb the moisture adsorbed by the adsorbent. As a power source for operating such a blower fan, it is also possible to utilize the electricity supplied from the solar panel 5 or the electricity generated by the fuel cell 8 of the drinking water supply device (a).

Silica gel is used as the adsorbent 12 used in the second embodiment. By using the porous silica gel, moisture can be taken out from the outside air taken in by the blower fan on the surface of the adsorbent 12 and adsorbed on the adsorbent 12. In the second embodiment, it is also possible to use a collecting agent instead of the adsorbent.
Here, the heater 11 used in the second embodiment has a function of heating the outside air taken in by the blower fan. By aerating the heated outside air through the adsorbent 12, the moisture adsorbed on the adsorbent 12 can be desorbed to obtain hot and humid air. In the second embodiment, an electric heater is used as the heater 11.
Next, the condenser 14 used in the second embodiment is a heat exchanger, which can cool the hot and humid outside air obtained by the heater 11 and generate water droplets by dew condensation. The outside air from which the moisture has been taken out is released into the atmosphere from the water collecting device (c).
Then, water is collected by receiving the water droplets generated by the dew condensation of the condenser 14 in the water collecting tank 15. The collected water is supplied as raw water for the pure water purification device 4 constituting the hydrogen generating device (b), or is supplied to the water treatment device 9 constituting the drinking water supply device (a), and is used for drinking after filtration. It can be further supplied to the water or hydrogen purification apparatus 4.
The water collecting device (c) according to the self-sustaining hydrogen power generation and drinking water supply system of the second embodiment is divided into a drinking device (a) and a hydrogen generating device (b) and configured as a single unit.

Embodiment 3
FIG. 3 is a conceptual diagram showing an example of the hydrogen generating apparatus 20 according to the third embodiment. As shown in FIG. 3, the hydrogen generation device 20 according to the third embodiment includes a reaction aluminum storage unit 21 that functions as a hydrogen production device, a pure water production device 24, and a secondary battery 22. In the third embodiment, purified water produced by the pure water production apparatus 24 is supplied to the reaction aluminum storage unit 21, and the reaction aluminum and water are reacted to produce hydrogen. The hydrogen generating section in the third embodiment is the reaction aluminum storage section 21. The purified water used in the reaction is discharged after the reaction without being recycled (D). The reaction aluminum used in the reaction is taken out and discarded without being recycled, and new reaction aluminum is appropriately replenished in the reaction aluminum storage section 21.
In the hydrogen generating apparatus 20 according to the third embodiment, there is no limitation on the form of the reaction aluminum stored in the reaction aluminum storage unit 21, and the size and shape of the reaction aluminum can be charged into the reaction aluminum storage unit 21. , Fragment, etc. can be arbitrarily selected.

Embodiment 4
Next, another usage example of the self-sustaining hydrogen power generation and drinking water supply system of the present embodiment will be described with reference to FIG.
FIG. 4 is a perspective view showing an example of use of the self-supporting hydrogen power generation and drinking water supply system according to the fourth embodiment. In the self-sustaining hydrogen power generation and drinking water supply system according to the fourth embodiment, the drinking water supply device (a), the hydrogen generation device (b), and the water collecting device (c) can be used separately. The drinking water supply device (a) and the hydrogen generation device (b) store the hydrogen generated by the hydrogen generation device (b) in the hydrogen storage device in the drinking water supply device (a), and therefore are for supply (not shown). It is connected by a pipe. Further, the water collecting device (c), the drinking water supply device (a), and the hydrogen generating device (b) are connected by a supply pipe (not shown) in order to distribute water. Since the articulated pipe is detachably configured, the drinking water supply device (a) can be transported to a water source such as a pool P to operate the water treatment device.

In particular, since the hydrogen generating device (b) and the water collecting device (c) according to the fourth embodiment have a renewable energy power generation device, it is necessary to arrange them in the vicinity of equipment such as a solar panel 50 and connect them with a cable. be. However, since the hydrogen generator (b) can also be charged by a secondary battery, it may be configured to be transportable by providing an axle and wheels at the bottom. Similarly, the water collecting device (c) can be configured to be transportable by installing a secondary battery.
As shown in FIG. 4, the drinking water supply device (a) is conveyed to the vicinity of the water supply duct 52, and the pool water P is filtered by the filtration device by connecting the water supply duct 52 and the drinking water supply device (a). , Drinking water can be obtained. A water supply duct may be added to the drinking water supply device (a). In that case, the pool water P can be directly filtered by the drinking water supply device (a) without providing the water supply duct 52.
By adopting such a configuration, the self-sustaining hydrogen power generation and drinking water supply system according to the fourth embodiment can be used by transporting a plurality of single systems to a water source away from the renewable energy power generation device. can.

(A) Drinking water supply device (b) Hydrogen generation device (c) Water collection device 2,12,22 Secondary battery 4,14,24 Pure water purification device 5 Renewable energy power generation device 7 Hydrogen storage device 8 Fuel cell 9 Water treatment equipment 21 Aluminum storage for reaction 10 Air supply fan 11 Heater 12 Adsorbent 14 Condenser 15 Water collecting tank 32 Collecting agent

Claims (8)

A hydrogen power generation and drinking water supply system having a hydrogen generator and a drinking water supply device.
The hydrogen generator has a secondary battery and a hydrogen production apparatus that reacts water to produce hydrogen.
The drinking water supply device includes a fuel cell, a hydrogen storage device, and a water treatment device.
The hydrogen power generation and drinking water supply system has a hydrogen production device and a water collecting device that supplies water to the hydrogen production device and / or the water treatment device.
The water collecting device has an adsorbent that adsorbs water contained in the outside air or a collecting agent that collects water, and a water collecting tank that receives the adsorbent or water adsorbed and collected by the collecting agent. Have and
The water collecting device, the hydrogen generating device, and the drinking water supply device are separately configured.
The catchment device, freestanding hydrogen generation and drinking water supply system wheels below the hydrogen generator and the water supply device is movably formed respectively attached to said Tei Rukoto. The water collector
A heater that heats the adsorbent or collector and desorbs the water adsorbed and collected by the adsorbent or collector as water vapor.
The condenser that condenses the water vapor and
The self-contained hydrogen power generation and drinking water supply system according to claim 1, further comprising the water collecting tank for receiving the water generated by the condenser. The self-sustaining hydrogen power generation and drinking water supply system according to claim 1 or 2, wherein the water collecting device further includes an air supply fan that takes in outside air. The self-sustaining hydrogen power generation and drinking water supply system according to any one of claims 1 to 3, wherein the hydrogen production apparatus produces hydrogen by electrolysis of water. The hydrogen generator further has a renewable energy power generator.
The self-sustaining hydrogen power generation and drinking water supply system according to any one of claims 1 to 4, wherein the secondary battery stores electricity generated by a renewable energy power generation device. The hydrogen generating apparatus further includes a pure water producing apparatus.
The self-sustaining hydrogen power generation and drinking water supply system according to any one of claims 1 to 5, wherein the water generated by the pure water production apparatus and \ or the water produced by the water collecting apparatus are received. .. The self-sustaining hydrogen power generation and drinking water supply system according to any one of claims 1 to 6, wherein the hydrogen storage device is a hydrogen storage alloy. The self-sustaining hydrogen according to any one of claims 1 to 7, wherein the fuel cell and \ in the drinking water supply device or the secondary battery in the hydrogen generation device supply electricity as a household AC power source. Power generation and drinking water supply system.

Images