CN215628325U

CN215628325U - Gas collecting and delivering mechanism of oxyhydrogen machine

Info

Publication number: CN215628325U
Application number: CN202023347159.0U
Authority: CN
Inventors: 李晓浩; 丁文江; 卢晨; 高金榜
Original assignee: Shenzhen Facai Technology Co ltd
Current assignee: Shenzhen Facai Technology Co ltd
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2022-01-25
Anticipated expiration: 2030-12-31

Abstract

The utility model discloses a gas collecting and sending mechanism of an oxyhydrogen machine, which comprises a hydrogen collecting mechanism and an oxygen collecting mechanism, wherein the oxygen collecting mechanism comprises an oxygen collecting cover arranged in a water tank, and the top of the oxygen collecting cover is provided with an oxygen outlet; the hydrogen collecting mechanism comprises a hydrogen pipe connected with the hydrogen output end of the electrolysis device, the hydrogen pipe is connected into the steam-water separating mechanism, and the steam-water separating mechanism is also connected with the hydrogen output end; the bottom of the water tank is provided with an oxygen port connected with the oxygen output end of the electrolysis device, and the oxygen collecting cover is arranged right above the oxygen port. Through the design, the hydrogen and the oxygen generated by electrolysis can be collected and utilized, and the hydrogen absorption and oxygen absorption functions are provided for users at the same time, so that the functions are more comprehensive, and the health care effect is better.

Description

Gas collecting and delivering mechanism of oxyhydrogen machine

Technical Field

The utility model relates to the field of design and manufacture of oxyhydrogen machines, in particular to a gas collecting and delivering mechanism of an oxyhydrogen machine.

Background

The existing hydrogen absorption machine on the market generates hydrogen and oxygen by electrolyzing water through SPE membrane, then collects the hydrogen and conveys the hydrogen to the hydrogen absorption port, and the oxygen is directly discharged without utilizing the oxygen. In addition, if oxygen and hydrogen are supplied simultaneously, they cannot be simply supplied through pipes and ports, and the oxygen and hydrogen produced need to be properly isolated to prevent potential explosion risks.

Disclosure of Invention

The utility model provides a gas collecting and sending mechanism of a hydrogen-oxygen machine, aiming at solving the technical problem that the gas supply mechanism of the existing hydrogen absorption machine can only provide hydrogen, and the gas collecting and sending mechanism can provide hydrogen absorption and oxygen absorption functions for users at the same time, and has more comprehensive functions and better health care effect.

In order to solve the technical problem, the utility model provides a gas collecting and sending mechanism of an oxyhydrogen machine, which comprises a hydrogen collecting mechanism and an oxygen collecting mechanism, wherein the oxygen collecting mechanism comprises an oxygen collecting cover arranged in a water tank, and the top of the oxygen collecting cover is provided with an oxygen outlet; the hydrogen collecting mechanism comprises a hydrogen pipe connected with the hydrogen output end of the electrolysis device, the hydrogen pipe is connected into the steam-water separating mechanism, and the steam-water separating mechanism is also connected with the hydrogen output end; the bottom of the water tank is provided with an oxygen port connected with the oxygen output end of the electrolysis device, and the oxygen collecting cover is arranged right above the oxygen port.

As an improvement of the scheme, the oxygen collecting cover abuts against the bottom of the water tank.

As an improvement of the scheme, the lower end of the oxygen collecting cover is provided with a communication port which is communicated with the inner side and the outer side of the oxygen collecting cover.

As a modification of the above scheme, the side surface of the oxygen collecting cover is trapezoidal.

As an improvement of the scheme, the oxygen output port is arranged in the accommodating groove at the top of the outer shell.

As the improvement of the scheme, a water tank water inlet switch is further arranged in the accommodating groove.

As an improvement of the scheme, the bottom of the water tank is provided with a positioning block, and the oxygen collecting cover is fixed in the water tank through the positioning block.

As an improvement of the scheme, the steam-water separation mechanism comprises a steam-water separation cavity, a separation cavity air inlet, a separation cavity air outlet and a separation cavity water outlet, wherein the separation cavity air inlet, the separation cavity air outlet and the separation cavity water outlet are connected with the steam-water separation cavity; the air inlet of the separation cavity is lower than the air outlet of the separation cavity, and the water outlet of the separation cavity is arranged at the bottom of the steam-water separation cavity.

The implementation of the utility model has the following beneficial effects:

by adopting the structure, the hydrogen generated by the electrolysis device is connected with external consumables through the hydrogen pipe, the steam-water separation mechanism and the hydrogen output end, so as to provide hydrogen for users; the oxygen of production is collected through the oxygen collection cover of locating in the water tank to collect the oxygen delivery outlet and the outside consumptive material at cover top through oxygen and be connected, provide oxygen for the user. Through the design, the hydrogen and the oxygen generated by electrolysis can be collected and utilized, and the hydrogen absorption and oxygen absorption functions are provided for users at the same time, so that the functions are more comprehensive, and the health care effect is better. In addition, because the oxygen is collected in the water tank, and the hydrogen is completely transmitted outside the water tank, the two gases can be separated as far as possible, and the use safety is improved.

Drawings

FIG. 1 is a schematic view of the overall structure of an oxyhydrogen machine according to the present invention;

FIG. 2 is a schematic view of a oxyhydrogen machine according to the present invention with a hidden housing;

FIG. 3 is a schematic view of the structure of the water tank of the present invention;

FIG. 4 is a cross-sectional view of the AA face of FIG. 3;

FIG. 5 is a schematic view of the construction of the oxygen collection enclosure of the present invention;

fig. 6 is a schematic structural view of the steam-water separation mechanism of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the utility model is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the utility model.

As shown in fig. 1-3, the embodiment of the present invention provides a gas collecting and sending-out mechanism of an oxyhydrogen machine, including a hydrogen collecting mechanism 1 and an oxygen collecting mechanism 2, where the oxygen collecting mechanism 2 includes an oxygen collecting cover 21 disposed in a water tank 3, and an oxygen output port 22 is disposed at the top of the oxygen collecting cover 21; the hydrogen collecting mechanism 1 comprises a hydrogen pipe (not shown in the figure) connected with the hydrogen output end of the electrolysis device 4, the hydrogen pipe is connected into a steam-water separating mechanism 11, and the steam-water separating mechanism 11 is also connected with a hydrogen output end 12; the bottom of the water tank 3 is provided with an oxygen port 31 connected with the oxygen output end of the electrolysis device 4, and the oxygen collecting cover 21 is arranged right above the oxygen port 31. The electrolyzer 4 may be an existing SPE membrane electrolyzer.

By adopting the structure, the hydrogen generated by the electrolysis device 4 is connected with external consumables through the hydrogen pipe, the steam-water separation mechanism 11 and the hydrogen output end 12, so as to provide hydrogen for users; the oxygen of production is collected through locating the oxygen collection cover 21 in the water tank 3 to oxygen delivery outlet 22 through oxygen collection cover 21 top is connected with outside consumptive material, provides oxygen for the user. Through the design, the hydrogen and the oxygen generated by electrolysis can be collected and utilized, and the hydrogen absorption and oxygen absorption functions are provided for users at the same time, so that the functions are more comprehensive, and the health care effect is better. In addition, because the oxygen is collected in the water tank 3 and the hydrogen is completely transmitted outside the water tank 3, the two gases can be separated as far as possible, and the use safety is improved.

Preferably, with reference to fig. 4 and 5, the oxygen collection cap 21 abuts against the bottom of the water tank 3. The lower end of the oxygen collecting cover 21 is provided with a communication port 211 for communicating the inner side and the outer side of the oxygen collecting cover 21. The bottom of the water tank 3 is provided with a positioning block 32, and the oxygen collection cover 21 is fixed in the water tank 3 through the positioning block 32. In a normal state, water in the water tank 3 enters the oxygen collection cap 21 from the communication port 211, so that the water level in the oxygen collection cap 21 is as high as the water level of the water tank 3. When oxygen emerges from the oxygen port 31, it rises by the buoyancy of water to the top of the oxygen collection enclosure 21. When the oxygen outlet 22 or the consumables connected with the oxygen outlet are blocked, the oxygen can discharge the water in the oxygen collection cover 21 to the water tank 3 through the communication port 211, and when the blockage disappears, the water level in the oxygen collection cover 21 can rise again along with the discharge of the oxygen, so that a certain buffering effect is achieved. When the oxygen output port 22 or the consumables connected with the oxygen output port are blocked for a long time, oxygen can be directly discharged from the communication port 211 and finally escapes from the top of the water tank 3, so that the corresponding pipeline is prevented from being damaged by air pressure, and the user is prevented from being injured by the air pressure.

In order to achieve the collecting effect, the side surface of the oxygen collecting cover 21 is trapezoidal. With this mechanism, oxygen will automatically collect toward the top center of the oxygen collection mask 21.

Preferably, the oxygen outlet 22 is located in a receiving groove 33 in the top of the housing. A water tank inlet switch 34 is also arranged in the accommodating groove 33. The user can fill the water tank 3 by opening the water tank inlet switch 34; the oxygen output port 22 is arranged in the accommodating groove 33 so as to be connected with consumables such as an oxygen mask, and the accommodating groove 33 is arranged at the top of the shell, so that even if a small amount of oxygen escapes, electronic elements in the shell cannot be influenced, and the operation safety of the equipment is ensured.

Preferably, as shown in fig. 6, the steam-water separation mechanism 11 includes a steam-water separation chamber 13, and a separation chamber air inlet 14, a separation chamber air outlet 15 and a separation chamber water outlet 16 which are connected to the steam-water separation chamber 13; the air inlet 14 of the separation cavity is lower than the air outlet 15 of the separation cavity, and the water outlet 16 of the separation cavity is arranged at the bottom of the steam-water separation cavity 13. Hydrogen gets into steam-water separation chamber 13 from disengagement chamber air inlet 14 to discharge from disengagement chamber delivery port 16, under the action of gravity, the water droplet that it carried can stop in steam-water separation chamber 13 bottom, flows into disengagement chamber delivery port 16, and comparatively dry and comfortable hydrogen can be discharged from disengagement chamber delivery port 16, in order to reach steam-water separation's effect, in order to avoid the water droplet in the hydrogen to gather in consumptive materials such as outside outlet duct, influence user experience.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the utility model.

Claims

1. The gas collecting and sending mechanism of the oxyhydrogen machine is characterized by comprising a hydrogen collecting mechanism and an oxygen collecting mechanism, wherein the oxygen collecting mechanism comprises an oxygen collecting cover arranged in a water tank, and the top of the oxygen collecting cover is provided with an oxygen outlet;

the hydrogen collecting mechanism comprises a hydrogen pipe connected with the hydrogen output end of the electrolysis device, the hydrogen pipe is connected into the steam-water separating mechanism, and the steam-water separating mechanism is also connected with the hydrogen output end;

the bottom of the water tank is provided with an oxygen port connected with the oxygen output end of the electrolysis device, and the oxygen collecting cover is arranged right above the oxygen port.

2. The oxyhydrogen machine gas collection and delivery mechanism according to claim 1, wherein the oxygen collection hood abuts the bottom of the water tank.

3. The gas collecting and delivering mechanism of oxyhydrogen machine according to claim 2, wherein the lower end of the oxygen collecting hood is provided with a communicating opening communicating the inside and outside of the oxygen collecting hood.

4. The gas collecting and dispensing mechanism for an oxyhydrogen machine according to claim 1, wherein the oxygen collecting hood has a trapezoidal side.

5. The gas collecting and dispensing mechanism for an oxyhydrogen machine according to claim 1, wherein the oxygen outlet is provided in a receiving groove at the top of the housing.

6. The oxyhydrogen machine gas collection and delivery mechanism according to claim 5, wherein a tank inlet switch is further provided in the housing tank.

7. The gas collecting and delivering mechanism of oxyhydrogen machine according to claim 1, wherein a positioning block is provided at the bottom of the water tank, and the oxygen collecting hood is fixed in the water tank through the positioning block.

8. The gas collecting and delivering mechanism of an oxyhydrogen machine according to claim 1, wherein the steam-water separating mechanism comprises a steam-water separating chamber, a separating chamber gas inlet, a separating chamber gas outlet and a separating chamber water outlet which are connected with the steam-water separating chamber; the air inlet of the separation cavity is lower than the air outlet of the separation cavity, and the water outlet of the separation cavity is arranged at the bottom of the steam-water separation cavity.