CN215780797U - Intelligent hydrogen-oxygen mixing gas machine - Google Patents

Abstract

The utility model discloses an intelligent oxyhydrogen gas mixing machine, which comprises a primary water tank, a secondary water tank, an electrolytic cell, a primary gas-water separator, a secondary gas-water separator, a humidifying tank and a tail end gas-water separator, wherein the water electrolysis efficiency is improved through the optimization of a series of electrolytic cells, a water path system, a gas path system and a water temperature control system, the unpowered and smoother circulation of the water path and the gas path is realized, the moisture content in the applied oxyhydrogen gas is more controllable, the purification effect is improved, and the utilization efficiency and the utilization quality of the oxyhydrogen gas are improved. It is also more comfortable and safe in human breathing applications.

Description

Intelligent hydrogen-oxygen mixing gas machine

Technical Field

The utility model relates to the technical field of hydrogen and oxygen mixed gas machines for producing hydrogen by electrolyzing water, in particular to an intelligent hydrogen and oxygen mixed gas machine.

Background

The technology of producing hydrogen and oxygen mixed gas by electrolyzing water has been continuously innovated, wherein the core electrolysis efficiency technology, temperature control technology, automatic power and power water circulation system technology, gas circuit system technology, gas-water separation and purification control technology and the like are in urgent need to be promoted. Therefore, a multifunctional hydrogen-oxygen mixed gas engine is provided.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the utility model provides an intelligent hydrogen-oxygen mixing gas engine which comprises a primary water tank, a secondary water tank, an electrolytic cell, a primary gas-water separator, a secondary gas-water separator, a humidifying tank and a tail end gas-water separator, wherein water in the primary water tank enters the secondary water tank through a pipeline and then enters the electrolytic cell from the secondary water tank for electrolysis; hydrogen and oxygen mixed gas produced by electrolysis sequentially passes through the secondary water tank and the primary water tank and enters the primary gas-water separator, and water separated in the primary gas-water separator flows back to the secondary water tank; the hydrogen-oxygen mixed gas filtered by the primary gas-water separator enters the secondary gas-water separator, and water separated in the secondary gas-water separator flows back to the primary water tank; and the oxyhydrogen mixed gas filtered by the primary gas-water separator enters the humidification box through a pipeline, and the oxyhydrogen mixed gas passes through the humidification box and then enters the tail end gas-water separator through a pipeline.

According to some embodiments of the utility model, the electrolytic cell comprises two pressing plates, an electrolytic assembly and a frame, wherein the electrolytic assembly is arranged between the two pressing plates, the frame is arranged on the edge of the assembly of the pressing plates and the electrolytic assembly, the pressing plates are provided with binding posts, water inlet pipes and oxyhydrogen gas outlet pipes, the water inlet pipes are communicated with the secondary water tank through pipelines, and the oxyhydrogen gas outlet pipes are communicated with the gas inlet of the secondary water tank through pipelines.

According to some embodiments of the utility model, the electrolytic assembly includes a separator, an electrode plate, and the separator is disposed between the pressure plate and the electrode plate and between the electrode plate.

According to some embodiments of the utility model, each of the first-stage gas-water separator and the second-stage gas-water separator comprises a body, wherein the body is respectively provided with a gas inlet, a gas outlet and a liquid outlet, the gas inlet and the gas outlet are respectively arranged at the left end and the right end of the body, and the liquid outlet is arranged at the bottom of the body; a plurality of draining pore plates are arranged in the body.

According to some embodiments of the utility model, the humidification chamber comprises a water tank seat and a water tank, wherein an opening of the water tank seat faces the front, the water tank is arranged in the water tank seat, an air inlet insertion tube and an air outlet insertion tube are respectively arranged at the upper part of the water tank, an inner cavity of the water tank is divided into a first cavity and a second cavity, the first cavity is communicated with the air inlet insertion tube, and the second cavity is communicated with the air outlet insertion tube; gas flows to the bottom of the second cavity through the first cavity and enters the second cavity, a diagonal plate is arranged in the second cavity, a bubble hole plate is arranged between the first cavity and the second cavity, and oxyhydrogen in the first cavity enters the second cavity through the bubble hole plate.

According to some embodiments of the utility model, the terminal gas-water separator comprises a cylinder, wherein an inlet pipe, a drain pipe and an exhaust pipe are respectively arranged on the cylinder, the inlet pipe and the exhaust pipe are positioned at the top of the cylinder, the inlet pipe extends out of an inner pipe towards an inner cavity of the cylinder, so that the tail end of the inner pipe is positioned at the lower part of the inner cavity of the cylinder, and the drain pipe is positioned at the bottom of the cylinder; and a draining plate is arranged at the upper part of the inner cavity of the cylinder body.

The utility model has at least the following beneficial effects:

the primary gas-water separator and the secondary gas-water separator are used for carrying out gas-water separation on the oxyhydrogen mixed gas generated by the electrolytic cell, so that the purity of the oxyhydrogen mixed gas is improved, and the purified oxyhydrogen mixed gas enters the humidification tank for humidification treatment; the moisture content of the humidified oxyhydrogen mixture is adjusted in a tail end gas-water separator, so that the oxygen therapy effect and the comfort of a patient are improved.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is an overall schematic diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of an electrolytic cell according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a first stage gas-water separator and a second stage gas-water separator according to an embodiment of the present invention;

FIG. 4 is a schematic view of a humidification chamber of an embodiment of the present invention;

FIG. 5 is a schematic diagram of a terminal gas-water separator according to an embodiment of the utility model.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

Referring to fig. 1 to 5, an intelligent hydrogen-oxygen mixing gas engine comprises a primary water tank 100, a secondary water tank 200, an electrolytic cell 300, a primary gas-water separator 400, a secondary gas-water separator 500, a humidifying tank 600 and a tail end gas-water separator 700, wherein when in use, electrolyte is added into the primary water tank 100 through a water filling port, and then water is added into the primary water tank 100; the water in the first-level water tank 100 enters the second-level water tank 200 through the one-way valve, the water flows from the second-level water tank 200 to the electrolytic tank 300 for electrolysis to generate a mixed hydrogen-oxygen gas of 66.6% of hydrogen and 33.3% of oxygen, the mixed hydrogen-oxygen gas flows from the electrolytic tank 300 to the first-level gas-water separator 400 through the second-level water tank 200 and the first-level water tank 100 in sequence, the water separated from the first-level gas-water separator 400 flows back to the second-level water tank 200, the filtered mixed hydrogen-oxygen gas flows to the second-level gas-water separator 500, adding adsorption filter media such as active carbon and the like into the secondary gas-water separator 500 to strengthen the filtration and purification of gas, the water separated in the secondary gas-water separator 500 flows back to the primary water tank 100, the oxyhydrogen gas purified by the secondary gas-water separator 500 flows to the humidifying tank 600, flows through the tiny holes of the humidifying tank 600, enters the purified water in the humidifying tank 600, and further cleans the gas and properly humidifies the gas in the humidifying tank 600; the oxyhydrogen gas flows from the humidification case 600 to the tail end gas-water separator 700 through the oxyhydrogen gas mixing pipe for breathing, and the excessive moisture is filtered and then is transmitted to the tail end for breathing, so that the oxygen therapy effect and the comfort level of a patient are improved.

The electrolytic cell 300 comprises a pressing plate 310, an electrolytic component 320 and a frame 330, wherein the pressing plate 310 is divided into two pieces, the electrolytic component 320 is arranged between the two pressing plates 310, the frame 330 is arranged at the edge of the combination of the pressing plate 310 and the electrolytic component 320, a binding post 311, a water inlet pipe 312 and an oxyhydrogen gas outlet pipe 313 are arranged on the pressing plate 310, the water inlet pipe 312 is communicated with the secondary water tank 200 through a pipeline, the oxyhydrogen gas outlet pipe 313 is communicated with the gas inlet 102 of the secondary water tank 200 through a pipeline, the electrolytic component 320 comprises a separating sheet 321 and an electrode plate 322, the separating sheet 321 is arranged between the pressing plate 310 and the electrode plate 322 and between the electrode plates 322, the electrolytic component 320 is arranged between the two pressing plates 310, the frame 330 is arranged at the edge of the combination of the pressing plate 310 and the electrolytic component 320, the force on the electrolytic component 320 is uniform through the frame 330, and the electrolytic effect is improved.

The primary gas-water separator 400 and the secondary gas-water separator 500 are both a body 101, the body 101 is respectively provided with a gas inlet 102, a gas outlet 103 and a liquid outlet 104, the liquid outlet 104 of the primary gas-water separator 400 is communicated with the secondary water tank 200 through a pipeline, and the liquid outlet 104 of the secondary gas-water separator 500 is communicated with the primary water tank 100 through a pipeline.

The gas inlet 102 and the gas outlet 103 are respectively arranged at the left end and the right end of the body 101, oxygen enters the inner cavity of the body 101 through the gas inlet 102 and passes through a draining pore plate 105 in the inner cavity of the body 101, so that liquid is retained on the draining pore plate and is discharged from a liquid outlet 104 at the bottom of the body 101; the separator has the advantages of simple structure, easy production and manufacture, convenient disassembly and maintenance and remarkable gas-water separation effect.

The humidifying box 600 comprises a water box base 610 and a water box 620, wherein the opening of the water box base 610 faces the front, the water box 620 is arranged in the water box base 610, the upper part of the water box 620 is respectively provided with an air inlet cannula 621 and an air outlet cannula 622, the air inlet cannula 621 is communicated with the air outlet 103 of the secondary gas-water separator 500, the inner cavity of the water box 620 is divided into a first cavity 623 and a second cavity 624, the first cavity 623 is communicated with the air inlet cannula 621, the second cavity 624 is communicated with the air outlet cannula 622, oxygen enters the water box 620 through the air inlet cannula 621, gas flows to the bottom of the second cavity 624 through the first cavity 623 and enters the second cavity 624 for humidification, and the gas is discharged from the air outlet cannula 622; the inclined flow plates 625 are arranged in the second chamber 624, at least two inclined flow plates 625 are adopted, the inclined flow plates 625 are alternately arranged from top to bottom and from left to right, before gas is discharged from the gas outlet insertion pipe 622, humidification water flows to the next inclined flow plate 625 along the previous inclined flow plate 625, humidification liquid is retained in the water tank 620, the humidification liquid is prevented from entering the oxygen inhalation pipe, a bubble hole plate 626 is arranged between the first chamber 623 and the second chamber 624, and oxyhydrogen in the first chamber 623 enters the second chamber 624 through the bubble hole plate 626.

The tail end gas-water separator 700 comprises a cylinder 710 and the cylinder 710, wherein an inlet pipe 711, a water discharge pipe 712 and an air discharge pipe 713 are respectively arranged on the cylinder 710, the inlet pipe 711 and the air discharge pipe 713 are positioned at the top of the cylinder 710, an inner pipe 714 extends from the inlet pipe 711 to the inner cavity of the cylinder 710, the inlet pipe 711 is connected with an air outlet insertion pipe 622, the tail end of the inner pipe 714 is positioned at the lower part of the inner cavity of the cylinder 710, and the water discharge pipe 712 is positioned at the bottom of the cylinder 710; the upper part of the inner cavity of the cylinder 710 is provided with a draining plate 715; the electrolyzed oxyhydrogen gas passes through the inlet pipe 711 and enters the lower part of the inner cavity of the cylinder 710 along the inner pipe 714, the oxyhydrogen gas passes through the draining plate upwards in the inner cavity of the cylinder 710, so that water is left on the draining plate and drops from the draining plate 715, and is finally discharged from the water discharging pipe 712, and the oxyhydrogen gas after being drained is discharged through the gas discharging pipe 713; the separator has the advantages of simple structure, easy production and manufacture, convenient disassembly and maintenance and remarkable gas-water separation effect.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.

Claims (6)

1. An intelligent hydrogen-oxygen mixing gas machine is characterized by comprising a primary water tank (100), a secondary water tank (200), an electrolytic cell (300), a primary gas-water separator (400), a secondary gas-water separator (500), a humidifying tank (600) and a tail end gas-water separator (700), wherein water in the primary water tank (100) enters the secondary water tank (200) through a pipeline and then enters the electrolytic cell (300) through the secondary water tank (200) for electrolysis; hydrogen and oxygen mixed gas produced by electrolysis sequentially passes through the secondary water tank (200) and the primary water tank (100) to enter the primary gas-water separator (400), and water separated from the primary gas-water separator (400) flows back to the secondary water tank (200); the hydrogen-oxygen mixed gas filtered by the primary gas-water separator (400) enters the secondary gas-water separator (500), and water separated in the secondary gas-water separator (500) flows back to the primary water tank (100); the mixed hydrogen and oxygen gas filtered by the primary gas-water separator (400) enters the humidifying box (600) through a pipeline, and the mixed hydrogen and oxygen gas passes through the humidifying box (600) and then enters the tail-end gas-water separator (700) through a pipeline.

2. The intelligent hydrogen-oxygen mixing gas machine according to claim 1, wherein the electrolytic cell (300) comprises two pressing plates (310), an electrolytic component (320) and a frame (330), the pressing plates (310) are two, the electrolytic component (320) is arranged between the two pressing plates (310), the frame (330) is arranged on the edge of the combination body of the pressing plates (310) and the electrolytic component (320), a binding post (311), a water inlet pipe (312) and a hydrogen-oxygen outlet pipe (313) are arranged on the pressing plates (310), the water inlet pipe (312) is communicated with the secondary water tank (200) through a pipeline, and the hydrogen-oxygen outlet pipe (313) is communicated with the gas inlet (102) of the secondary water tank (200) through a pipeline.

3. The intelligent hydrogen-oxygen mixing gas generator as claimed in claim 2, wherein the electrolysis assembly (320) comprises a separation sheet (321) and an electrode plate (322), and the separation sheet (321) is arranged between the pressure plate (310) and the electrode plate (322) and between the electrode plates (322).

4. The intelligent hydrogen-oxygen mixing gas machine according to claim 1, wherein the primary gas-water separator (400) and the secondary gas-water separator (500) each comprise a body (101), the body (101) is provided with a gas inlet (102), a gas outlet (103) and a liquid outlet (104), the gas inlet (102) and the gas outlet (103) are respectively arranged at the left end and the right end of the body (101), and the liquid outlet (104) is arranged at the bottom of the body (101); a plurality of draining pore plates (105) are arranged in the body (101).

5. The intelligent hydrogen-oxygen mixing machine as claimed in claim 1, wherein the humidification box (600) comprises a water box base (610) and a water box (620), the opening of the water box base (610) faces the front, the water box (620) is installed in the water box base (610), the upper part of the water box (620) is respectively provided with an air inlet insertion pipe (621) and an air outlet insertion pipe (622), the inner cavity of the water box (620) is divided into a first chamber (623) and a second chamber (624), the first chamber (623) is communicated with the air inlet insertion pipe (621), and the second chamber (624) is communicated with the air outlet insertion pipe (622); the gas flows to the bottom of the second chamber (624) through the first chamber (623) and enters the second chamber (624), a diagonal flow plate (625) is arranged in the second chamber (624), a bubble hole plate (626) is arranged between the first chamber (623) and the second chamber (624), and oxyhydrogen in the first chamber (623) enters the second chamber (624) through the bubble hole plate (626).

6. The intelligent hydrogen-oxygen mixing gas machine is characterized in that the terminal gas-water separator (700) comprises a cylinder (710), an inlet pipe (711), a drain pipe (712) and an exhaust pipe (713) are respectively arranged on the cylinder (710), the inlet pipe (711) and the exhaust pipe (713) are positioned at the top of the cylinder (710), the inlet pipe (711) extends out of an inner pipe (714) towards the inner cavity of the cylinder (710), the terminal of the inner pipe (714) is positioned at the lower part of the inner cavity of the cylinder (710), and the drain pipe (712) is positioned at the bottom of the cylinder (710); the upper part of the inner cavity of the cylinder body (710) is provided with a draining plate (715).

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