JPH08312596A - Bubble pump - Google Patents

Abstract

PURPOSE: To provide a bubble pump to electrolyze water by electric power obtained from solar energy, utilize the buoyancy of hydrogen bubble for pumping-up and utilize water and hydrogen. CONSTITUTION: A bubble pump is composed of a solar battery 11 to photoelectrically convert solar energy to electric power, an electrode 3 to electrolyze water 4 with the electric power, a guide pipe 6 to guide water 4 from the water level upward by the buoyancy of hydrogen bubble generated by the electrolysis and an air-liquid separator 7 to separate air-liquid mixture water 4b into the hydrogen and water 4 above the guide pipe 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bubble pump for electrolyzing water by photoelectric conversion of solar energy to generate hydrogen bubbles, and utilizing the buoyancy of the hydrogen bubbles to pump water. It is about.

[0002]

2. Description of the Related Art FIG. 4 is a schematic configuration diagram showing an example of a conventional hydrogen generating electrolyzer.

In this figure, 1 is a commercial power source, 2 is a wiring part, 3 is an electrode, 4 is water, and seawater or fresh water is used. In the present specification, the term “water” is used when distinction between fresh water and seawater is not necessary. 4a is a hydrogen bubble generated by electrolysis of the water 4, and 4b is a hydrogen bubble 4a in the water 4.
Gas-liquid mixed water mixed with 5 is a pump for pumping the water 4, 6 is a guide pipe immersed in the water 4, and FR
It is made of a heat insulating material such as P or high density polyethylene, and pumps the deep water 4 having a low temperature to the surface of the water. 7 is a gas-liquid separator provided at the upper end of the guide pipe 6, 8 is a liquid discharge port of water 4 from which hydrogen bubbles 4a have been removed from the gas-liquid mixed water 4b, and 9 is removed from the gas-liquid mixed water 4b. It is a hydrogen gas discharge port.

Since a direct current is used for the electrode 3 for electrolysis, a rectifier for converting the commercial power source 1 into a direct current is provided, but the electrode 3 is not shown and is shown in common with the power source of the pump 5. is there.

Thus, in order to electrolyze the water 4, the pump 5 is used to pump up the deep water 4. Therefore, power is supplied from the external commercial power source 1 and the like for driving the pump 5 and performing electrolysis.

[0006]

By the way, it is expensive to receive electric power from the outside, and in particular, it is necessary to use private power generation or the like on the ocean or in a remote area, which causes a lot of cost. there were. In addition, since fossil fuels such as petroleum are used for power generation, there is a problem in that the usefulness and significance of producing hydrogen as a fuel is reduced from the standpoint of global environmental protection.

The present invention has been made to solve the above-mentioned problems, and was obtained by solar energy without using a commercial power source or a so-called mechanical pump, and without using fossil fuel. The purpose is to obtain a bubble pump that electrolyzes water and pumps water by electric power.

[0008]

DISCLOSURE OF THE INVENTION The present invention is directed to an electrolyzer for electrolyzing water with electric power obtained by photoelectric conversion of solar energy, hydrogen bubbles generated by the electrolyzer, and upward buoyancy of the hydrogen bubbles. A guide pipe for guiding the guided water from the electrolyzer, and a gas-liquid separator provided above the guide pipe for separating the gas-liquid mixed water of the floating hydrogen bubbles and water into hydrogen bubbles and water. It consists of and.

A fresh water supply pipe for supplying fresh water;
An electrolysis device provided at the outlet end of the fresh water supply pipe for electrolyzing the fresh water with electric power obtained by photoelectrically converting solar energy, hydrogen bubbles generated by the electrolysis device, and buoyancy of the hydrogen bubbles lead upwards. It comprises a guide pipe for guiding seawater, and a gas-liquid separator provided above the guide pipe for separating the gas-liquid mixed water of the floating hydrogen bubbles and seawater into hydrogen and seawater.

Further, the electrolysis device for electrolyzing water by electric power obtained by photoelectric conversion of solar energy, the hydrogen bubble generated by the electrolysis device, and the seawater guided upward by the buoyancy of the hydrogen bubble are provided in the electrolysis device. And a gas-liquid separator that is provided above the guide pipe and separates the gas-liquid mixed water of the floating hydrogen bubbles and seawater into hydrogen bubbles and seawater, and the electrolyzer is seawater. In the electrolysis, the electrode on the side where chlorine is generated is provided outside the guide pipe, and the electrode on the side where hydrogen is generated is provided inside the guide pipe.

[0011]

In the present invention, electric power can be self-supplied by photoelectric conversion of solar energy, and hydrogen bubbles electrolyzed by this electric power,
The buoyancy of the hydrogen bubbles, that is, the average density of the hydrogen bubbles and water is increased to pump water, and the obtained hydrogen and the pumped water can be used.

Further, since hydrogen generated by electrolyzing fresh water is used for pumping seawater, chlorine can be suppressed and pumped.

Furthermore, even when seawater is electrolyzed, chlorine is prevented from being mixed in because the electrode on the side that generates chlorine is outside the guide pipe.

[0014]

FIG. 1 is a schematic configuration diagram showing an embodiment of the present invention, in which the same reference numerals as those in FIG. 4 denote the same parts, and 11 is a solar cell, which is an electric power source for photoelectric conversion of solar energy which is natural energy. It enables self-sufficiency. Guide pipe 6
Is thermally insulated so that the inside and outside of the guide pipe 6 are thermally separated. Further, the electrolysis device 10 is composed of the electrodes 3 which are insulated and opposed to the guide pipe 6.

Next, the operation will be described.

Hydrogen generated by electrolyzing the water 4 by the electric power of the solar cell 11 becomes hydrogen bubbles 4a in the water 4, and the hydrogen bubbles 4a are mixed with the water 4 to form gas-liquid mixed water 4b.
It should be noted that although oxygen is generated by electrolysis, oxygen dissolves immediately in water (N ₂ : O ₂ ≈1: 2), so this is not a problem here. Since the specific gravity of the gas-liquid mixed water 4b is lighter than that of the water 4, the gas-liquid mixed water 4b rises in the guide pipe 6 and enters the gas-liquid separator 7. In the gas-liquid separator 7, hydrogen bubbles 4a are separated from the gas-liquid mixed water 4b and discharged from the gas discharge port 9. Also,
The water 4 from which the hydrogen bubbles 4 a are separated is discharged from the liquid discharge port 8. This makes it possible to continuously generate hydrogen. Further, cold water can be obtained from the liquid discharge port 8.

FIG. 2 is a schematic diagram showing another embodiment of the present invention, in which seawater 14 is pumped. The same reference numerals as those in FIG. 1 denote the same parts, and 12 is a fresh water supply pipe,
3 is supplied into the fresh water supply pipe 12. Further, since the fresh water 13 is electrolyzed by providing the electrodes 3 facing each other in the end portion of the fresh water supply pipe 12, it is possible to prevent electrolysis of the seawater 14 and prevent chlorine from being generated.

Further, 13a is a bubble of hydrogen and oxygen generated by electrolysis of the fresh water 13, and 15 is the fresh water 13
Is mixed with seawater 14 and bubbles 13a.

The fresh water 13 is a reverse osmosis membrane (not shown).
Can be obtained directly from the seawater 14.

As described above, since the hydrogen and oxygen bubbles 13a generated by electrolyzing the fresh water 13 by the electrode 3 in the fresh water supply pipe 12 float upward, the fresh water supply pipe 12
The fresh water 13 inside will flow upwards. Therefore, the fresh water 13 can be continuously supplied into the gas-liquid separator 7. Further, since the oxygen bubbles 13a are easily dissolved in water, the fresh water 13 is supplied into the gas-liquid separator 7 only by the hydrogen bubbles 13a.

FIG. 3 is a schematic constitutional view showing still another embodiment of the present invention for preventing chlorine contamination when the application target is seawater 14, and the same reference numerals as those in FIGS.
a and 3b are electrodes for electrolyzing the seawater 14, which are positive electrodes,
Negative electrodes are applied respectively. 16 is the guide pipe 6
The case 17 is provided so as to project laterally, and 17 is a through hole formed on the upper surface and the lower surface of the case 16, and the direct current serves as a positive electrode,
Generates chlorine 14a. The electrode 3a is arranged so as to be removed from the flow path of the seawater 14 so that the generated chlorine 14a does not flow into the guide pipe 6. In this case, seawater 1
The difference H between the water surface of No. 4 and the water surface of the gas-liquid mixed water 4b increases as the average density of the hydrogen bubbles 4a decreases.

As described above, according to the present invention, the water in the deep layer can be pumped up and stored using the bubble pump for aquaculture, or the water having a low temperature stored in the deep layer can be used for cooling. As a result, the deep water cooling can be used for cooling and heating.

[0023]

As described above, according to the present invention, the electrolysis device for electrolyzing water by the electric power obtained by photoelectric conversion of solar energy, the hydrogen bubble generated by this electrolysis device, and the buoyancy of the hydrogen bubble raises the above. A guide pipe for guiding the water guided to the electrolysis device from the electrolyzer, and a gas-liquid separation for separating the gas-liquid mixed water of the floating hydrogen bubbles and water provided above the guide pipe into hydrogen bubbles and water. Since it consists of a vessel, it is not necessary to receive electric power from an external commercial power source, nor is it necessary to receive electric power from fossil fuels, and hydrogen and water can be obtained, which can contribute to global environment conservation. Further, since the water is pumped by the buoyancy of the gas-liquid mixed water obtained by the electrolysis device, so-called mechanical pump equipment is not required, and electric power for driving the pump is not required. Since deep water can be pumped up, it is possible to cool and keep cold by using low temperature deep water. Further, since hydrogen obtained by electrolysis by solar energy which is natural energy can be used as a fuel, there is an advantage that pollution is not generated.

A fresh water supply pipe for supplying fresh water,
An electrolysis device provided at the outlet end of the fresh water supply pipe for electrolyzing the fresh water with electric power obtained by photoelectrically converting solar energy, hydrogen bubbles generated by the electrolysis device, and buoyancy of the hydrogen bubbles lead upwards. Since it is composed of a guide pipe for guiding seawater and a gas-liquid separator provided above the guide pipe for separating the gas-liquid mixed water of the floating hydrogen bubbles and seawater into hydrogen and seawater, the pumping of seawater Can be realized by reducing the generation of chlorine.

Further, since an electrode on the side where chlorine is generated is provided outside the guide pipe as an electrolysis device to prevent mixing into pumped water, an effect that chlorine is not mixed into electrolysis of seawater can be obtained.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram showing another embodiment of the present invention.

FIG. 3 is a schematic configuration diagram showing still another embodiment of the present invention.

FIG. 4 is a schematic configuration diagram showing an example of a conventional hydrogen generation electrolysis device.

[Explanation of symbols]

 2 Wiring part 3 Electrode 4 Water 4a Hydrogen bubble 4b Gas-liquid mixed water 5 Pump 6 Guide pipe 7 Gas-liquid separator 8 Liquid discharge port 9 Gas discharge port 10 Electrolytic device 11 Solar cell 12 Fresh water supply pipe 13 Fresh water 14 Sea water 15 Gas liquid Mixed water 16 Housing 17 Through hole

Claims (3)

[Claims] 1. An electrolysis device for electrolyzing water with electric power obtained by photoelectric conversion of solar energy, hydrogen bubbles generated by the electrolysis device, and water guided upward by buoyancy of the hydrogen bubbles. And a gas-liquid separator which is provided above the guide pipe and separates the gas-liquid mixed water of the floating hydrogen bubbles and water into hydrogen bubbles and water. Bubble pump. 2. A fresh water supply pipe for supplying fresh water, an electrolysis device provided at an outlet end of the fresh water supply pipe for electrolyzing the fresh water with electric power obtained by photoelectrically converting solar energy, and an electrolysis device generated by the electrolysis device. A guide pipe for guiding hydrogen bubbles and seawater guided upward by the buoyancy of the hydrogen bubbles, and a gas-liquid mixed water of the floating hydrogen bubbles and seawater provided above the guide pipe into hydrogen and seawater. An air bubble pump comprising a gas-liquid separator for separating the gas. 3. An electrolyzer for electrolyzing water with electric power obtained by photoelectric conversion of solar energy, hydrogen bubbles generated by the electrolyzer, and seawater guided upward by buoyancy of the hydrogen bubbles. And a gas-liquid separator that is provided above the guide pipe and separates the gas-liquid mixed water of the floating hydrogen bubbles and seawater into hydrogen bubbles and seawater, and the electrolyzer is seawater. 2. An air bubble pump, wherein an electrode on the side where chlorine is generated during the electrolysis is provided outside the guide pipe, and an electrode on the side where hydrogen is generated is provided inside the guide pipe.