CN216855441U - Hydrogen conveying device for oxyhydrogen atomizing machine - Google Patents

Abstract

A hydrogen conveying device for a oxyhydrogen gas atomizer comprises a hydrogen pipe I connected with a hydrogen outlet of an electrolytic bath, wherein the hydrogen pipe I is sequentially connected with at least two groups of gas-liquid separators, and the gas outlets of the last group of gas-liquid separators are communicated with a mixed gas pipe through a hydrogen pipe II; the hydrogen pipe II is provided with a pressure release valve or the hydrogen pipe II is connected with a hydrogen pipe III, and the hydrogen pipe III is provided with a pressure release valve. The gas-liquid separation effect of hydrogen and water is better, and the pressure in the conveying pipeline is effectively controlled.

Description

Hydrogen conveying device for oxyhydrogen atomizing machine

Technical Field

The utility model relates to the technical field of atomizers, in particular to a hydrogen conveying device for a oxyhydrogen atomizer.

Background

The oxyhydrogen gas atomizer is a device capable of replacing, controlling or changing normal physiological respiration of people, increasing lung ventilation, improving respiratory function, reducing respiratory function consumption and saving heart reserve capacity, is mainly used in places such as hospitals, clinics, families and the like, can play a role in preventing and treating respiratory failure, reducing complications and saving and prolonging vital medical equipment of the life of patients, and occupies a very important position in the field of modern medicine.

The principle of the hydrogen-oxygen atomizer on the market at present is that hydrogen and oxygen are generated by electrolyzing water through an electrolytic cell, and in the process of conveying the oxygen and the hydrogen, the following three aspects need to be focused: 1. in order to reduce the potential safety hazard, hydrogen and oxygen need to be conveyed separately; 2. in the process of oxygen delivery, the temperature of oxygen needs to be well reduced; 3. in the transportation process of hydrogen, the gas-liquid separation effect of hydrogen and water and the pressure control in a hydrogen conveying pipeline are very important.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a hydrogen conveying device for an oxyhydrogen atomizer, aiming at the defects in the prior art, the hydrogen conveying device has good gas-liquid separation effect of hydrogen and water, and can effectively control the pressure in a conveying pipeline.

The scheme is realized by the following technical measures: the utility model provides a oxyhydrogen gas hydrogen delivery mechanism for atomizing machine, includes hydrogen pipe I with electrolysis trough hydrogen exit linkage, hydrogen pipe I has connected gradually at least two sets of vapour and liquid separator, and hydrogen pipe II and gas mixture intercommunication are passed through to last a set of vapour and liquid separator's gas outlet, be provided with the relief valve on hydrogen pipe II.

Further, hydrogen pipe II is connected with hydrogen pipe III, hydrogen pipe III is connected with pressure controller.

Furthermore, three groups of gas-liquid separators are connected in series between the hydrogen pipe I and the hydrogen pipe II.

Further, the mixed gas pipe comprises an upper section, a middle section and a lower section which are sequentially communicated from top to bottom, a mixed gas outlet is formed in the upper section, a liquid medicine tank is fixedly connected with the lower section, a gas baffle plate is fixedly arranged in the middle section, an oxygen channel for supplying oxygen to descend is formed by the gas baffle plate and the middle section, the lower end of the oxygen channel is communicated with the lower section, and a gap for hydrogen to pass through is formed in the gas baffle plate; the middle section is fixedly connected with an oxygen guide pipe, the oxygen guide pipe is communicated with an oxygen channel, the middle section is also fixedly connected with a hydrogen guide pipe which can be communicated with a hydrogen pipe II, hydrogen entering from the hydrogen guide pipe can enter the inner cavity of the choke plate through the notch, the upper end of the inner cavity of the choke plate is communicated with the upper section, and the lower end of the inner cavity of the choke plate is communicated with the lower section.

By adopting the technical scheme, the method has the following technical effects:

(1) the hydrogen conveying device is provided with at least two groups of gas-liquid separators, so that a better gas-liquid separation effect can be achieved, and more space can be provided for the hydrogen conveying device to relieve the pressure in the hydrogen conveying device.

(2) The pressure relief valve is arranged, so that the pressure in the hydrogen pipe II can be well controlled, and the potential safety hazard caused by overhigh pressure is reduced.

(3) Under the effect of choke plate, oxygen that gets into the middle section through the oxygen guide tube is down along the oxygen passageway with the liquid medicine contact and carry the liquid medicine granule to get into the choke plate inner chamber under the effect of ultrasonic wave vibrations piece, and the hydrogen that gets into the middle section through the hydrogen guide tube can get into the choke plate inner chamber through the breach, and then oxygen, hydrogen and liquid medicine mix and form the mist, and the mist supplies patients to use through the upper segment. Adopt above-mentioned structure, the effectual oxygen and hydrogen direct contact that has reduced mix, but oxygen, hydrogen and liquid medicine three mix, and is specific, and oxygen is forced earlier to move downwards and is carried the liquid medicine granule, then mixes with a large amount of hydrogen, can carry the liquid medicine granule on the one hand, and on the other hand oxygen and hydrogen mix under moist environment, greatly reduced the production of static, and then reduced the potential safety hazard.

Therefore, compared with the prior art, the utility model has substantive characteristics and progress, and the beneficial effects of the implementation are also obvious.

Drawings

FIG. 1 is a schematic perspective view of an oxyhydrogen atomizer;

FIG. 2 is a schematic view showing the internal structure of the hydrogen-oxygen atomizer;

FIG. 3 is a schematic view of the internal structure of the hydrogen-oxygen atomizer;

FIG. 4 is a third schematic diagram of the internal structure of the hydrogen-oxygen atomizer;

FIG. 5 is a perspective view of the mixing tube;

FIG. 6 is a schematic bottom view of the air mixing tube;

FIG. 7 is a front view of the mixing tube;

FIG. 8 is a schematic cross-sectional view of FIG. 7;

fig. 9 is a schematic view of the choke plate;

fig. 10 is a schematic structural view of the connection of the mixed gas pipe and the liquid medicine tank.

Wherein: 1-shell, 1.1-heat dissipation hole II, 1.2-heat dissipation hole I; 2-a water tank; 3-an electrolytic cell; 4-oxygen conveying device, 4.1-oxygen pipe I, 4.2-coil radiator, 4.3-oxygen pipe II, 4.4-oxygen pipe III, 4.5-oxygen pipe IV, 4.6-fixing plate and 4.7-fan I; 5-hydrogen conveying device, 5.1-hydrogen pipe I, 5.2-gas-liquid separator, 5.3-hydrogen pipe II, 5.4-hydrogen pipe III and 5.5-pressure release valve; 6.1-mixed gas pipe, 6.1.1-upper segment, 6.1.2-middle segment, 6.1.3-lower segment, 6.1.3.1-threaded connection segment, 6.1.4-choke plate, 6.1.4.1-notch, 6.1.5-oxygen channel, 6.1.6-oxygen guide pipe, 6.1.6.1-sealing element I, 6.1.7-hydrogen guide pipe, 6.1.7.1-sealing element II, 6.1.8-upper positioning plate and 6.1.9-lower positioning plate; 7-universal wheels; 8-a water tank cover; 9-a display screen; 10-fan II; 11-control box.

Detailed Description

In order to clearly illustrate the technical features of the present solution, the following explains the present solution by way of specific embodiments and with reference to the accompanying drawings.

Example 1

As shown in fig. 1-2 and 3-10, a hydrogen conveying device for oxyhydrogen atomizer comprises a hydrogen pipe i 5.1 connected with a hydrogen outlet of an electrolytic bath 3, wherein the hydrogen pipe i 5.1 is sequentially connected with at least two groups of gas-liquid separators 5.2, and the gas outlets of the last group of gas-liquid separators 5.2 are communicated with a mixed gas pipe 6.1 through a hydrogen pipe ii 5.3; and a pressure release valve 5.5 is arranged on the hydrogen pipe II 5.3.

Three groups of gas-liquid separators 5.2 are connected in series between the hydrogen pipe I5.1 and the hydrogen pipe II 5.3.

The mixed gas pipe 6.1 comprises an upper section 6.1.1, a middle section 6.1.2 and a lower section 6.1.3 which are sequentially communicated from top to bottom, a mixed gas outlet is arranged on the upper section 6.1.1, the lower section 6.1.3 is fixedly connected with a liquid medicine tank 6.3, a gas baffle plate 6.1.4 is fixedly arranged in the middle section 6.1.2, the gas baffle plate 6.1.4 and the middle section 6.1.2 form an oxygen channel 6.1.5 for supplying oxygen to descend, the lower end of the oxygen channel 6.1.5 is communicated with the lower section 6.1.3, and a notch 6.1.4.1 for supplying hydrogen to pass is arranged on the gas baffle plate 6.1.4; an oxygen guide pipe 6.1.6 is fixedly connected to the middle section 6.1.2, the oxygen guide pipe 6.1.6 is communicated with the oxygen channel 6.1.5, a hydrogen guide pipe 6.1.7 which can be communicated with the hydrogen pipe II 5.3 is also fixedly connected to the middle section 6.1.2, hydrogen entering from the hydrogen guide pipe 6.1.7 can enter the inner cavity of the choke plate 6.1.4 through a notch 6.1.4.1, the upper end of the inner cavity of the choke plate 6.1.4 is communicated with the upper section 6.1.1, and the lower end of the inner cavity of the choke plate 6.1.4 is communicated with the lower section 6.1.3.

Hydrogen generated by water electrolysis in the electrolytic bath 3 enters the hydrogen guide pipe 6.1.7 through the hydrogen pipe I5.1, the gas-liquid separator 5.2 and the hydrogen pipe II 5.3, and oxygen generated by water electrolysis in the electrolytic bath 3 enters the oxygen guide pipe 6.1.6 through a pipeline; under the action of the choke plate 6.1.4, oxygen entering the middle section 6.1.2 through the oxygen guide pipe 6.1.6 descends along the oxygen channel 6.1.5 to contact with liquid medicine under the action of the ultrasonic vibration sheet and carry liquid medicine particles into the inner cavity of the choke plate 6.1.4, hydrogen entering the middle section 6.1.2 through the hydrogen guide pipe 6.1.7 can enter the inner cavity of the choke plate 6.1.4 through the notch 6.1.4.1, and then the oxygen, the hydrogen and the liquid medicine are mixed to form mixed gas, and the mixed gas is supplied to a patient through the upper section 6.1.1.

Example 2

The difference from embodiment 1 is that in this embodiment, a hydrogen pipe iii 5.4 is connected to the hydrogen pipe ii 5.3, and a pressure controller (not shown in the figure) is connected to the hydrogen pipe iii 5.4.

Technical features that are not described in the present invention can be implemented by or using the prior art, and are not described herein again, and of course, the above description is not limited to the present invention, and the present invention is not limited to the above embodiments, and variations, modifications, additions or substitutions that are made by those skilled in the art within the spirit and scope of the present invention should also fall within the protection scope of the present invention.

Claims (4)

1. The utility model provides a hydrogen conveyor for oxyhydrogen gas atomizing machine which characterized by: include hydrogen pipe I (5.1) with electrolysis trough (3) hydrogen exit linkage, hydrogen pipe I (5.1) have connected gradually at least two sets of vapour and liquid separator (5.2), and hydrogen pipe II (5.3) and gas mixture pipe (6.1) intercommunication are passed through to the gas outlet of last a set of vapour and liquid separator (5.2), be provided with relief valve (5.5) on hydrogen pipe II (5.3).

2. The hydrogen gas supplying apparatus for an oxyhydrogen gas atomizing machine according to claim 1, characterized in that: the hydrogen pipe II (5.3) is connected with a hydrogen pipe III (5.4), and the hydrogen pipe III (5.4) is connected with a pressure controller.

3. The hydrogen gas supplying apparatus for an oxyhydrogen gas atomizing machine according to claim 1, characterized in that: three groups of gas-liquid separators (5.2) are connected in series between the hydrogen pipe I (5.1) and the hydrogen pipe II (5.3).

4. The hydrogen gas supplying apparatus for an oxyhydrogen gas atomizing machine according to claim 1, characterized in that: the mixed gas pipe (6.1) comprises an upper section (6.1.1), a middle section (6.1.2) and a lower section (6.1.3) which are sequentially communicated from top to bottom, a mixed gas outlet is arranged on the upper section (6.1.1), the lower section (6.1.3) is fixedly connected with a liquid medicine tank (6.3), a gas baffle plate (6.1.4) is fixedly arranged in the middle section (6.1.2), the gas baffle plate (6.1.4) and the middle section (6.1.2) form an oxygen channel (6.1.5) for supplying oxygen to descend, the lower end of the oxygen channel (6.1.5) is communicated with the lower section (6.1.3), and a notch (6.1.4.1) for hydrogen to pass through is formed in the gas baffle plate (6.1.4); fixedly connected with oxygen guide tube (6.1.6) on middle section (6.1.2), oxygen guide tube (6.1.6) and oxygen passageway (6.1.5) intercommunication, still fixedly connected with can get into choke board (6.1.4) inner chamber with hydrogen guide tube (6.1.7) of hydrogen pipe II (5.3) intercommunication on middle section (6.1.2), the hydrogen accessible breach (6.1.4.1) that gets into from hydrogen guide tube (6.1.7) gets into the inner chamber of choke board (6.1.4), the upper end and the upper segment (6.1.1) intercommunication of choke board (6.1.4) inner chamber, the lower extreme and the hypomere (6.1.3) intercommunication of choke board (6.1.4) inner chamber.

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