TWM507462U - Clean power apparatus and hydrogen-oxygen generator therein - Google Patents

Description

Clean power equipment and high concentration oxyhydrogen machine

The present invention relates to a power plant, and more particularly to a power plant having an internal combustion engine and a high concentration oxyhydrogen machine for use in the power plant.

According to the Asian Development Bank, Asia's fast-growing metropolis has serious air pollution, with Beijing being the dirtiest city and Xi'an. According to the statistics of the United Nations Environment Program, the Chinese government has spent more than $170 billion on environmental pollution in Beijing in recent years, and has also implemented a series of measures to improve Beijing's air quality. According to a survey by the United Nations Environmental Protection Agency, 75% of carbon oxides, 50% of hydrocarbons and nitrogen oxides in urban air pollution come from exhaust emissions from fuel vehicles. In Europe and the United States with large car ownership and some large cities in China, 60%-80% of air pollution sources come from automobile exhaust.

A power plant containing an internal combustion engine used in the prior art is powered by petroleum fuel (such as gasoline or diesel). The power equipment converts petroleum fuel into oil and gas, and mixes it with air in a certain proportion and then introduces it into the internal combustion engine. It uses explosive combustion to convert the chemical energy of petroleum fuel into kinetic energy, thereby driving the transmission device and driving the whole mechanism. After combustion, the fuel will form an exhaust gas containing carbon dioxide and other carbon oxyhydroxides.

However, when the explosion burns, energy is often caused by incomplete combustion. The efficiency of the conversion is poor, resulting in waste of fuel; and the lower the combustion efficiency, the higher the concentration of harmful substances contained in the exhaust gas.

In recent years, automobile factories have mainly used catalysts made of precious metals to reduce the emission of harmful substances, and use multi-stage filtration to convert harmful gases generated after incomplete combustion into environmentally friendly carbon dioxide, nitrogen and water vapor. However, the fundamental solution is to improve the combustion efficiency of the internal combustion engine, so that the complete combustion of oil and gas, of course, can reduce the emission of harmful substances.

In order to solve the above problems of the prior art, the present invention proposes a high-concentration oxyhydrogen machine capable of generating pure and high-concentration hydrogen and oxygen, thereby improving the combustion efficiency of the internal combustion engine, completely burning the oil and gas, and reducing the emission of harmful substances. the amount. The high-concentration oxyhydrogen machine (1) proposed by the present invention comprises a hydrogen-oxygen generating module (100), a liquid storage module (200), an electrolyte regulating module (300), and a first pipeline. (400), a second conduit (500).

The hydrogen-oxygen generating module (100) has a first liquid inlet (190), a first gas outlet (180) and a plurality of electrolytic cells (110) electrically connected in series, and each electrolytic cell (110) is provided with A vertically set positive electrode plate (111) and a vertically set negative electrode plate (112), the hydrogen-oxygen generating module (100) is further filled with a first electrolyte solution (170), and the first electrolyte solution (170) The surface height (170H) is lower than the height (111H, 112H) of the positive electrode plate (111) and the negative electrode plate (112), and lower than the height (180H) of the first gas outlet port (180), and each electrolytic cell (110) The bottom portion is further provided with a first liquid outlet (115), and a first accommodation space (160) is formed between the first air outlet (180) and the liquid level (170H) of the first electrolyte (170).

The liquid storage module (200) includes a second liquid inlet (210), a pressure cover (220), An intake pipe (230), a second liquid outlet (240) and a second air outlet (250), the liquid storage module (200) is filled with a second electrolyte (270), and the intake pipe (230) The second electrolyte (270) is inserted into the second electrolyte (270), and the liquid level (270H) of the second electrolyte (270) is higher than the height of the second liquid outlet (240).

The first pipeline (400) communicates with the first air outlet (180) of the hydrogen-oxygen generating module (100) and the intake pipe (230) of the liquid storage module (200); and the second pipeline (500) communicates with hydrogen and oxygen. A first liquid inlet (190) of the module (100) and a second liquid outlet (240) of the liquid storage module (200) are generated.

The electrolyte regulating module (300) comprises a third gas outlet (330), a plurality of third liquid inlets (310) and a plurality of regulating tubes (320), and the third gas outlet (330) is connected to the hydrogen-oxygen generating mold. a first accommodating space (160) of the group (100), each third liquid inlet (310) is connected to one end of each adjusting tube (320), and the other end of each adjusting tube (320) is connected to each first liquid discharging The mouth (115), each adjusting tube (320) is filled with a first electrolyte (170), and the vertical height of each third liquid inlet (310) is adjustable to have a first position (310H) and a second position (310L), the first position (310H) is higher than the liquid level (170H) of the first electrolyte (170), and the second position (310L) is lower than the liquid level (170H) of the first electrolyte (170).

The main purpose of the high-concentration oxyhydrogen machine proposed in the present invention is to provide a higher concentration of hydrogen and oxygen, and to introduce it into the internal combustion engine and mix with the fuel, thereby improving the combustion efficiency of the internal combustion engine, further saving the fuel consumption of the internal combustion engine, and further providing Additional power energy.

The purpose of the high-concentration oxyhydrogen machine proposed in the present invention is to purify the air to provide purer hydrogen and oxygen, and to introduce it into the internal combustion engine, thereby reducing the pollution emission of the internal combustion engine and further reducing the emission of harmful exhaust gas and carbon dioxide. To meet environmental requirements.

The present application further proposes an extended application of a high-concentration oxyhydrogen machine, which is a clean power equipment (9) including an internal combustion engine (910), an intake line (920) and a high-concentration oxyhydrogen machine (1). . The internal combustion engine (910) has an air inlet (911), and the high-concentration oxyhydrogen machine (1) passes through The air line (920) is connected to the air inlet (911) of the internal combustion engine (910), and the air intake line (920) is further provided with an air flow meter (930) and a throttle valve (940) toward the internal combustion engine (910). And the second air outlet (250) of the liquid storage module (200) of the high concentration oxyhydrogen machine (1) is connected to the intake line (920).

The clean power equipment proposed by the present invention provides a higher concentration of hydrogen and oxygen through the high-concentration oxyhydrogen machine used therein, and introduces it into the internal combustion engine, thereby improving the combustion efficiency of the internal combustion engine, further saving the fuel consumption of the internal combustion engine, and further providing Additional power energy.

The clean power equipment of this creation uses the high-concentration oxyhydrogen machine used to purify the air to provide pure hydrogen and oxygen, and introduces it into the internal combustion engine, which can reduce the pollution emission of the internal combustion engine and further reduce the emission of harmful exhaust gas and carbon dioxide. Quantity to meet environmental requirements.

(1)‧‧‧High concentration oxyhydrogen machine

(100)‧‧‧Hydrogen Oxygen Generation Module

(200) ‧ ‧ liquid storage module

(300)‧‧‧Electrolyte adjustment module

(400) ‧‧‧First line

(500) ‧‧‧Second line

(110)‧‧‧Electrolytic cells

(111)‧‧‧ positive plate

(111H)‧‧‧ Height of positive plate

(112)‧‧‧ Negative plate

(112H)‧‧‧ Height of negative plate

(115)‧‧‧First outlet

(160) ‧‧‧First accommodation space

(170)‧‧‧First electrolyte

(170H) ‧ ‧ the liquid level of the first electrolyte

(180) ‧‧‧first air outlet

(180H)‧‧‧The height of the first air outlet

(190)‧‧‧First filling port

(210)‧‧‧Second injection port

(220) ‧ ‧ pressure cover

(230)‧‧‧Air intake pipe

(240)‧‧‧Second outlet

(250) ‧‧‧second air outlet

(270)‧‧‧Second electrolyte

(270H)‧‧‧Level level of the second electrolyte

(240H) ‧‧‧ Height of the second outlet

(310) ‧‧‧ third injection port

(310H) ‧ ‧ the first position of the third filling port

(310L) ‧‧‧Second position of the third filling port

(320) ‧‧‧Adjustment tube

(330) ‧‧‧ third air outlet

(410)‧‧‧First solenoid valve

(510)‧‧‧Second solenoid valve

(520)‧‧‧Manual drain valve

(9)‧‧‧Clean power equipment

(910)‧‧‧ Internal combustion engine

(911)‧‧‧ Air intake

(920)‧‧‧Intake line

(930)‧‧‧Air flow meter

(940)‧‧‧ gas valve

1 is a schematic view of a high-concentration oxyhydrogen machine according to a first preferred embodiment of the present invention.

2 is a schematic view of a hydrogen-oxygen generating module in the first preferred embodiment.

3 is a schematic view of a liquid storage module in the first preferred embodiment.

4A and 4B are schematic views of an electrolyte regulating module in a first preferred embodiment.

FIG. 5 is a schematic view of a clean power device according to a second preferred embodiment of the present invention.

The present invention mainly discloses a high-concentration oxyhydrogen machine and a clean power device using a high-concentration oxyhydrogen machine. The basic principles of the power machine and electrochemistry used are well known to those skilled in the relevant art, and therefore, as explained below, Do not give a full description. At the same time, the following The drawings in the comparison mainly represent the structural diagrams related to the creative features, and do not need to be completely drawn according to the actual size, which is explained first.

Please refer to FIG. 1 , which is a schematic diagram of a first preferred embodiment of the present invention, which is a high-concentration oxyhydrogen machine (1) including a hydrogen-oxygen generating module (100) and a liquid storage module (200). An electrolyte regulating module (300), a first conduit (400), and a second conduit (500).

Referring to FIG. 2, the hydrogen-oxygen generating module (100) is filled with a first electrolyte (170) to generate hydrogen and oxygen by electrolysis. The oxyhydrogen generating module (100) has a first liquid inlet (190), a first gas outlet (180) and a plurality of electrolytic cells (110) electrically connected in series. The first fill port (190) provides supplemental entry of the first electrolyte (170). Each of the electrolytic cells (110) is provided with a vertically set positive electrode plate (111) and a vertically set negative electrode plate (112). Moreover, the liquid level (170H) of the first electrolyte (170) is lower than the height (111H, 112H) of the positive electrode plate (111) and the negative electrode plate (112), so that better electrolytic efficiency can be maintained. Meanwhile, the liquid level (170H) of the first electrolyte (170) is also required to be lower than the height (180H) of the first gas outlet (180), and the first gas outlet (180) and the first electrolyte (170) A first accommodating space (160) is formed between the liquid level (170H), whereby hydrogen and oxygen generated by electrolysis are maintained, and a sufficient capacity is stored in the first accommodating space (160) and can be discharged from the first air outlet. (180) is output to the first line (400). The bottom of each electrolytic cell (110) is further provided with a first liquid outlet (115), the function of which will be described later.

Please refer to FIG. 3, the liquid storage module (200) is mainly used for storing the electrolyte, and provides a high concentration of hydrogen and oxygen output to the internal combustion engine. The liquid storage module (200) includes a second liquid inlet (210), a pressure cover (220), an intake pipe (230), a second liquid outlet (240) and a second air outlet (250). ). The second liquid inlet (210) is used for an external operator to infuse pure water and electrolyte to form a second electrolyte (270), and the pressure cover (220) is placed on the second liquid inlet (210) due to the liquid storage. Module (200) A high concentration of pressurized gas is stored therein, and the pressure cap (220) needs to contain elastic airtight components to provide a leak-proof airtight effect. The intake pipe (230) extends into the second electrolyte (270), and the liquid level (270H) of the second electrolyte (270) is higher than the height of the second liquid outlet (240), and is also higher than the first The liquid level of the electrolyte (170) (170H). Thereby, the hydrogen and oxygen generated by the hydrogen-oxygen generating module (100) are connected to the intake pipe (230) through the first pipe (400) to be injected into the electrolyte (270) from the electrolyte (270) because It is supersaturated and precipitated, and then supplied to the internal combustion engine through the second gas outlet (250). Such a ratio of hydrogen and oxygen is more appropriate.

Referring to FIG. 1 and FIG. 2, the first pipeline (400) communicates with the first air outlet (180) of the hydrogen-oxygen generating module (100) and the air inlet tube (230) of the liquid storage module (200). The second conduit (500) communicates with the first liquid inlet (190) of the hydrogen-oxygen generating module (100) and the second liquid outlet (240) of the liquid storage module (200). Preferably, the first conduit (400) further includes a first solenoid valve (410) that is switchable in an openable and closed state. When the first solenoid valve (410) is in an open state, the first conduit (400) is conducted to the external environment; when the first solenoid valve (410) is in the closed state, the first conduit (400) is not conducted to the external environment. . The first electromagnetic valve (410) is mainly for safety protection. Its function is twofold: one is when the hydrogen-oxygen generating module (100) generates excessive hydrogen and oxygen, and when the pressure is too high, the first electromagnetic valve is opened (410). ), too much hydrogen and oxygen can be slowly discharged to the ambient atmosphere to avoid the danger of excessive pressure. Second, when the internal combustion engine stops and does not require intake combustion, of course, there is no need to supply high concentration of hydrogen, oxygen and oxygen. At this time, the first electromagnetic valve (410) is opened, and the pre-generated hydrogen and oxygen can be slowly discharged to Ambient atmosphere to avoid the danger of hydrogen and oxygen burning when the machine temperature is too high.

In this embodiment, the second conduit (500) further includes a second solenoid valve (510) that is switchable in an openable and closed state. When the second solenoid valve (510) is in the open state, the second conduit (500) is turned on, and the electrolyte (270) of the liquid storage module (200) can flow into the hydrogen-oxygen generating module (100). When the second solenoid valve (510) In the closed state, the second conduit (500) is non-conductive, and the second electrolyte (270) of the liquid storage module (200) does not flow into the hydrogen-oxygen generation module (100). The correct mode of operation is that when the internal combustion engine stops and does not require intake combustion, the second solenoid valve (510) is switched to the open state, and the second electrolyte (270) of the liquid storage module (200) flows into the hydrogen-oxygen generation mold. Group (100), supplemented. Normally, when the hydrogen-oxygen generating module (100) is operated, since the stable concentration of the first electrolyte (170) is maintained, the hydrogen and oxygen generating efficiency can be stabilized, and the second solenoid valve (510) should be kept closed to avoid The second electrolyte (270) of the liquid storage module (200) flows into the hydrogen-oxygen generating module (100) to destroy the concentration of the first electrolyte (170); when the hydrogen-oxygen generating module (100) does not operate and the When the first electrolyte (170) is insufficient, the second electromagnetic valve (510) needs to be switched to the open state, and the second electrolyte (270) of the liquid storage module (200) flows into the hydrogen-oxygen generating module (100). ) to supplement.

In this embodiment, the second conduit (500) may further include a manual drain valve (520) that can be manually switched between open and closed states. When the manual drain valve (520) is in the open state, the second conduit (500) is turned on, and the second electrolyte (270) of the liquid storage module (200) can flow into the hydrogen-oxygen generating module (100) for supplementation. When the manual drain valve (520) is in the closed state, the second conduit (500) is non-conducting, and the second electrolyte (270) of the liquid storage module (200) cannot flow into the hydrogen-oxygen generating module (100). .

Please refer to FIG. 4A and FIG. 4B, which are schematic diagrams of the electrolyte regulating module (300), and the electrolyte regulating module (300) is another feature of the creation. Since the oxyhydrogen generating module (100) has a plurality of electrolytic cells (110) electrically connected in series, when the electrolysis is operated, it is inevitable that the electrolysis efficiencies of the respective electrolysis cells (110) may differ. Therefore, after the hydrogen-oxygen generating module (100) is operated for a period of time, the first electrolyte (170) in each of the electrolytic cells (110) may have a concentration inconsistency. At this time, simply replenishing the second electrolyte (270) of the liquid storage module (200) does not effectively solve the problem of different concentrations, and the electrolyte regulating module (300) is an effective solution.

The electrolyte regulating module (300) comprises a third gas outlet (330), a plurality of third liquid inlets (310) and a plurality of regulating tubes (320), and the third gas outlet (330) is connected to the hydrogen-oxygen generating mold. The first accommodating space (160) of the group (100) has the same air pressure on both sides, so the liquid level of the first electrolyte (170) in the electrolyte regulating module (300) and the oxyhydrogen generating module (100) The height (170H) is the same. One end of each adjusting tube (320) is connected to each third liquid inlet (310), and the other end is connected to each first liquid outlet (115) of the electrolytic cell (110), so each regulating tube (320) is filled There is a first electrolyte (170) flowing from each of the electrolytic cells (110). The vertical height of each of the third liquid inlets (310) is adjustable to have a first position (310H) and a second position (310L), and the first position (310H) is higher than the liquid level of the first electrolyte (170) (170H), the second position (310L) is lower than the liquid level (170H) of the first electrolyte (170). The adjustment can be done manually or by means of a motor mechanism.

The working principle of the electrolyte regulating module (300) is as follows: since the electrolyte contains electrolyte, the specific gravity of the electrolyte is higher than that of water, so even if the electrolyte is in a state of being fully dissolved, the electrolytic cell (110) is near the bottom. The electrolyte concentration is still higher than the electrolyte concentration near the top. When the oxyhydrogen generation module (100) is operated, the height of the third liquid inlet (310) is the first position (310H), which is higher than the liquid level (170H) of the first electrolyte (170). The first electrolytes (170) in each of the adjustment tubes (320) are spaced apart from each other. When the concentration of the first electrolyte (170) of the electrolysis cell (110) of the oxyhydrogen generation module (100) needs to be adjusted, the height of the third liquid inlet (310) is adjusted to the second position (310L). The liquid level (170H) of the first electrolyte (170) is higher than the second position (310L) of the third liquid inlet (310), and the first electrolyte (170) of each electrolytic cell (110) is passed through The adjusting tube (320) flows into the electrolyte regulating module (300) to be mixed and diffused, and the concentration is adjusted and then flows back into the original electrolytic cell (110) to achieve the effect of concentration adjustment.

In this embodiment, the positive plate (111) and the negative plate (112) can use lead plates, not Made of rust steel, gold, platinum, aluminum alloy, graphite or copper alloy. Considering cost performance and durability, stainless steel is preferred.

In this embodiment, the first electrolyte solution (170) may include potassium hydroxide, sodium hydrogencarbonate, acetic acid, sulfuric acid, propylene carbonate, acetonitrile, ethylene glycol dimethyl ether, ethylene carbonate, dimethyl carbonate, carbonic acid. Ethyl ethyl acetate and diethyl carbonate are preferred, but potassium hydroxide is preferred as the main electrolyte, because the potassium hydroxide electrolyte has an advantage of a large discharge current, and the electrolysis efficiency can be effectively improved. However, the concentration of potassium hydroxide contained in the first electrolyte (170) is not too high, preferably less than 10%; and if the concentration is less than 4%, the effect is not good.

In this embodiment, the oxyhydrogen generation module (100) includes a plurality of electrolytic cells (110) electrically connected in series, and each of the electrolytic cells (110) preferably consumes 2 volts of direct current. When the supplied electric power supplied to the hydrogen-oxygen generation module (100) is 12V, six electrolytic cells (110) can be used; when the supplied electric power is 24V, 12 electrolytic cells (110) can be used. The power supplied to the electrolysis cell (110) can be used by the car's own battery module, or the high-concentration oxyhydrogen machine (1) can be provided with a separate power module (800), as shown in FIG.

The high-concentration oxyhydrogen machine proposed in this embodiment can provide a higher concentration of hydrogen and oxygen. If it is introduced into an internal combustion engine, the combustion efficiency of the internal combustion engine can be improved, the fuel consumption of the internal combustion engine can be further saved, and an additional power source can be provided. .

The high-concentration oxyhydrogen machine proposed in the embodiment can purify the air to provide pure hydrogen and oxygen, and if introduced into the internal combustion engine, the pollution of the internal combustion engine can be reduced, and the emission of harmful exhaust gas and carbon dioxide can be further reduced. Meet environmental requirements.

Referring to FIG. 5, a schematic diagram of a second preferred embodiment of the present invention is a clean power device (9) including an internal combustion engine (910), an intake line (920) and a high The concentration oxyhydrogen machine (1), the high concentration oxyhydrogen machine (1) is as described in the first preferred embodiment above. The internal combustion engine (910) has an intake port (911), and the high-concentration oxyhydrogen machine (1) is connected to the intake port (911) of the internal combustion engine (910) through an intake line (920), and the intake line (920) An air flow meter (930) and a throttle valve (940) are disposed in sequence toward the internal combustion engine (910), and a second air outlet (250) of the liquid storage module (200) of the high concentration oxyhydrogen machine (1) is provided. Connect to the intake line (920).

In this embodiment, the fuel used in the internal combustion engine (910) may be gasoline or diesel, and is not limited.

The clean power equipment (9) proposed in this embodiment can increase the combustion efficiency of the internal combustion engine and further save the fuel consumption of the internal combustion engine because the high-concentration hydrogen-oxygen machine (1) can provide a higher concentration of hydrogen and oxygen. Provide additional power energy.

The clean power equipment (9) proposed in this embodiment can reduce the pollution of the internal combustion engine by introducing the high-concentration hydrogen-oxygen machine (1) to purify the air to provide pure hydrogen and oxygen. To further reduce the emission of harmful exhaust gases and carbon dioxide to meet environmental requirements.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention; the above description should be understood and implemented by those skilled in the relevant art, so that other spirits are not disclosed in the present disclosure. Equivalent changes or modifications made below shall be included in the scope of the patent application.

(1)‧‧‧High concentration oxyhydrogen machine

(100)‧‧‧Hydrogen Oxygen Generation Module

(200) ‧ ‧ liquid storage module

(300)‧‧‧Electrolyte adjustment module

(400) ‧‧‧First line

(500) ‧‧‧Second line

Claims (10)

A high-concentration oxyhydrogen machine (1) comprises a hydrogen-oxygen generating module (100), a liquid storage module (200), an electrolyte regulating module (300), a first pipeline (400), a second pipeline (500), characterized in that: the hydrogen-oxygen generating module (100) has a first liquid inlet (190), a first gas outlet (180) and a plurality of electrolytic units connected in series (110), each of the electrolytic cells (110) is provided with a vertically set positive plate (111) and a vertically set negative plate (112), and the hydrogen-oxygen generating module (100) is further filled with the first An electrolyte (170), and a liquid level (170H) of the first electrolyte (170) is lower than a height (111H, 112H) of the positive electrode plate (111) and the negative electrode plate (112), and lower than the first a height (180H) of the air outlet (180), a bottom of each of the electrolytic cells (110) is further provided with a first liquid outlet (115), the first air outlet (180) and the first electrolyte (170) a first accommodating space (160) is formed between the liquid level (170H); the liquid storage module (200) includes a second liquid inlet (210), a pressure cover (220), and an air inlet. Tube (230), a second liquid outlet (240) and a second outlet a port (250), the liquid storage module (200) is filled with a second electrolyte (270), the inlet pipe (230) extends into the second electrolyte (270), and the second electrolyte (270) a liquid level (270H) higher than a height (240H) of the second liquid outlet (240); the first conduit (400) is connected to the first air outlet of the hydrogen-oxygen generating module (100) ( 180) the intake pipe (230) of the liquid storage module (200); the second pipe (500) is connected to the first liquid inlet (190) of the hydrogen-oxygen generating module (100) and the The second liquid outlet (240) of the liquid storage module (200); the electrolyte regulating module (300) comprises a third air outlet (330), a plurality of third liquid inlets (310) and a plurality of a regulating tube (320), the third air outlet (330) is connected to the first accommodating space (160) of the oxyhydrogen generating module (100), and each of the third liquid filling ports (310) is connected to each of the One end of the regulating tube (320), and the other end of each adjusting tube (320) is connected to each of the first liquid outlets (115), each of the adjusting tubes (320) is filled with the first electrolyte (170), and the vertical height of each of the third liquid inlets (310) is adjustable to have a first position (310H) and a second position (310L), the first A position (310H) is higher than a liquid level (170H) of the first electrolyte (170), and the second position (310L) is lower than a liquid level (170H) of the first electrolyte (170). The high concentration oxyhydrogen machine (1) according to claim 1, wherein the positive electrode plate (111) and the negative electrode plate (112) are stainless steel plates. The high concentration oxyhydrogen machine (1) according to claim 1, wherein the first electrolyte (170) is a potassium hydroxide electrolyte. The high concentration oxyhydrogen machine (1) according to claim 3, wherein the first electrolyte (170) contains potassium hydroxide at a concentration of less than 10%. The high concentration oxyhydrogen machine (1) according to claim 1, wherein the oxyhydrogen generation module (100) has six electrolysis cells (110) electrically connected in series. The high concentration oxyhydrogen machine (1) according to claim 1, wherein the oxyhydrogen generating module (100) has 12 electrolytic cells (110) electrically connected in series. The high concentration oxyhydrogen machine (1) according to claim 1, wherein the first line (400) further comprises a first solenoid valve (410) in a switchable open and close state, the first solenoid valve (410) In the open state, the first conduit (400) is conducted to the external environment; when the first solenoid valve (410) is in the closed state, the first conduit (400) is not electrically connected to the external environment. The high concentration oxyhydrogen machine (1) according to claim 1, wherein the second line (500) further comprises a second solenoid valve (510) in a switchable open and close state, the second solenoid valve (510) In the open state, the second conduit (500) is conductive; when the second solenoid valve (510) is in the closed state, the second conduit (500) is non-conductive. The high-concentration oxyhydrogen machine (1) according to claim 1, wherein the second line (500) further comprises a manual drain valve (520) that is switchable in an openable and closed state, the manual drain valve (520) In the open state, The second line (500) is conductive; when the manual drain valve (520) is in the closed state, the second line (500) is non-conductive. A clean power device (9) comprising an internal combustion engine (910), an intake line (920) and a high concentration oxyhydrogen machine (1), characterized in that the internal combustion engine (910) has an air inlet (911) The high-concentration oxyhydrogen machine (1) is connected to the intake port (911) of the internal combustion engine (910) through the intake line (920), and the intake line (920) faces the internal machine (910) Further, an air flow meter (930) and a throttle valve (940) are provided in sequence, and the high-concentration oxyhydrogen machine (1) is the high-concentration oxyhydrogen machine according to any one of claims 1 to 9. 1), and the second air outlet (250) of the liquid storage module (200) of the high concentration oxyhydrogen machine (1) is connected to the air inlet pipe (920).