CN115414564B

CN115414564B - Oxyhydrogen gas atomizing machine

Info

Publication number: CN115414564B
Application number: CN202210564612.8A
Authority: CN
Inventors: 邹方明; 张在庆; 李庆雨; 张克; 谢松梅; 闫永丽; 张春霞; 宗晓燕; 高伟伟; 韩春艳; 刘信宏
Original assignee: Saikesaisi Biotechnology Co ltd
Current assignee: Saikesaisi Biotechnology Co ltd
Priority date: 2021-05-21
Filing date: 2022-05-23
Publication date: 2023-07-07
Anticipated expiration: 2042-05-23
Also published as: CN115414564A

Abstract

The utility model provides an oxyhydrogen gas atomizing machine, belongs to the technical field of oxyhydrogen gas atomizing machine, which comprises a housin, the casing internal fixation is provided with the water tank, the water tank is through delivery pipe and electrolysis trough intercommunication, the hydrogen exit linkage of electrolysis trough has hydrogen conveyor, the oxygen exit linkage of electrolysis trough has oxygen conveyor, and hydrogen and oxygen separately independently carry to mixing device, the hydrogen that hydrogen conveyor carried and the oxygen that oxygen conveyor carried mix in mixing device department, mixing device's exit linkage has the air feed pipeline, for patient's oral cavity and/or nasal cavity air feed through the air feed pipeline. When hydrogen and oxygen are supplied to a patient, the liquid medicine can be carried, so that the patient can be conveniently treated, and meanwhile, the independent direct contact of the oxygen and the hydrogen can be effectively reduced, so that the potential safety hazard is reduced.

Description

Oxyhydrogen gas atomizing machine

Technical Field

The invention relates to the technical field of atomizers, in particular to an oxyhydrogen gas atomizer.

Background

The hydrogen is the gas with the lightest mass and the smallest molecular weight in the atmosphere, so the hydrogen is extremely easy to diffuse (the diffusion coefficient is 3.8 times of that of the air), the flow speed resistance of the gas in bronchi can be reduced by sucking the hydrogen due to the special physical property of the hydrogen, the gas can enter alveoli more easily, the utilization rate of oxygen is improved, ventilation is improved, and thus the symptoms of dyspnea of patients are relieved; oxygen in the mixture may increase the concentration of oxygen inhaled by the patient. After the gas is atomized and humidified, the trachea can be kept moist, and the sputum excretion is facilitated.

The oxyhydrogen gas atomizer is a device which can replace, control or change normal physiological respiration of people, increase lung ventilation, improve respiratory function, reduce respiratory function consumption and save heart reserve capacity, is mainly used in places such as hospitals, clinics and families, can prevent and treat respiratory failure, reduces complications, saves and prolongs vital medical equipment of patient life, and occupies very important positions in the modern medical field.

Patients using oxyhydrogen gas nebulizers generally need medication, and existing oxyhydrogen nebulizers cannot carry liquid medicine when supplying hydrogen and oxygen to patients, and have fewer functions.

Meanwhile, the principle of the existing oxyhydrogen gas atomizer is basically that water is electrolyzed by an electrolytic tank to generate hydrogen and oxygen, and then oxyhydrogen and oxygen are mixed and conveyed to an air outlet pipe. The hydrogen and the oxygen generated by the electrolysis of water in the electrolytic tank have great potential safety hazards during mixed transportation. Even though the hydrogen and oxygen are separately supplied, the hydrogen and oxygen are mixed together before the supply port of the oxyhydrogen gas atomizer. This is a disadvantage of the prior art.

Disclosure of Invention

The invention aims to solve the technical problems of the prior art, and provides the oxyhydrogen gas atomizing machine which can carry liquid medicines when supplying hydrogen and oxygen to a patient, is convenient for the treatment of the patient, and can effectively reduce the independent direct contact of the oxygen and the hydrogen at the same time, thereby reducing the potential safety hazard.

The scheme is realized by the following technical measures: the utility model provides a oxyhydrogen gas atomizing machine, includes the casing, the casing internal fixation is provided with the water tank, the water tank passes through delivery pipe and electrolysis trough intercommunication, the hydrogen exit linkage of electrolysis trough has hydrogen conveyor, the oxygen exit linkage of electrolysis trough has oxygen conveyor, and hydrogen and oxygen separate independently carry to mixing device, hydrogen that hydrogen conveyor carried and oxygen that oxygen conveyor carried mix in mixing device department, mixing device's exit linkage has air feed line.

Further, along the running direction of oxygen, a gas-liquid separator I and a flame arrester I are sequentially arranged on a pipeline of the oxygen conveying device.

Further, along the direction of operation of hydrogen, gas-liquid buffer, gas-liquid separator II, relief valve and flame arrester II have set gradually on hydrogen conveyor's the pipeline, gas-liquid separator II's liquid outlet passes through return water pipeline II and water tank intercommunication.

Further, a fan is fixedly arranged near the gas-liquid separator I, a radiating hole matched with the fan is formed in the shell, the bottom end of the gas-liquid separator I is communicated with the water tank through a water return pipeline I, and an electromagnetic valve is arranged on the water return pipeline I.

Further, two water tanks are arranged and are communicated, and a water pump is arranged on the water supply pipe.

Further, the medicine mixing device comprises an atomization groove fixedly connected with the shell, a mixed gas pipe is arranged in the atomization groove, the lower end of the mixed gas pipe is fixedly connected with a medicine liquid groove, the mixed gas pipe is communicated with the medicine liquid groove, an oxygen guide pipe and a hydrogen guide pipe are fixedly connected to the mixed gas pipe, the oxygen guide pipe and the hydrogen guide pipe are communicated with the mixed gas pipe, and an ultrasonic vibration sheet is arranged below the medicine liquid groove.

Further, the atomizing groove comprises an atomizing barrel, an oxygen inlet and a hydrogen inlet are arranged on the atomizing barrel, one end of the oxygen inlet is communicated with the oxygen guide pipe, the other end of the oxygen inlet is communicated with the oxygen conveying device, one end of the hydrogen inlet is communicated with the hydrogen guide pipe, and the other end of the hydrogen inlet is communicated with the hydrogen conveying device.

Further, be provided with the ring channel in the atomizing section of thick bamboo, in the below of ring channel, still be provided with two vertical grooves in the atomizing section of thick bamboo, oxygen import and hydrogen import set up respectively in two vertical grooves, the size in vertical groove matches with the terminal size of oxygen guide pipe, hydrogen guide pipe, be provided with limiting plate and lower limiting plate on the gas mixture pipe, it all sets up in the ring channel to go up limiting plate and lower limiting plate, atomizing section of thick bamboo top still is provided with the atomizing lid, atomizing section of thick bamboo, atomizing lid pass through the bolt fastening on the casing, the upper end of gas mixture pipe is located the top of atomizing lid, the upper end of going up limiting plate is laminated with the lower extreme of atomizing lid, the lower extreme of lower limiting plate is laminated with the bottom of ring channel.

Further, the mixed gas pipe comprises an upper section, a middle section and a lower section which are sequentially communicated from top to bottom, the oxygen guide pipe and the hydrogen guide pipe are fixedly connected with the middle section, a choke plate is fixedly arranged in the middle section, an oxygen supply descending oxygen channel is formed by the choke plate and the middle section, the lower end of the oxygen channel is communicated with the lower section, and a notch for passing hydrogen is formed in the choke plate; the oxygen guiding tube and the hydrogen guiding tube are fixedly arranged on the middle section, the oxygen guiding tube is communicated with the oxygen channel, hydrogen entering from the hydrogen guiding tube 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, the lower end of the inner cavity of the choke plate is communicated with the lower section, and the lower section is communicated with the liquid medicine groove.

The shell is connected with a power supply module, the power supply module is connected with a controller through a transformer, the power supply module is also connected with a control power supply, the controller is respectively connected with a gas-liquid separator I, a gas-liquid separator II, an ultrasonic vibration sheet, a display screen and a fan, the controller is connected with the control power supply, and the control power supply is connected with a water pump; the controller is connected with an electrolysis power supply, and the electrolysis power supply is respectively connected with the power supply module and the electrolysis tank.

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

(1) The water is electrolyzed by the electrolyzer to generate hydrogen and oxygen, the water tank supplies water to the electrolyzer, the hydrogen and the oxygen generated by the electrolysis of the electrolyzer are respectively conveyed by independent conveying devices, and the hydrogen, the oxygen and the liquid medicine are mixed to form mixed gas after being contacted.

(2) The ultrasonic vibration piece acts on the liquid medicine groove, so that liquid in the liquid medicine groove is slowly carried into a patient body by oxygen and hydrogen entering the mixed gas pipe. When the oxyhydrogen atomizer does not work, the liquid medicine can be poured into the liquid medicine tank from the mixed gas pipe.

(3) Under the effect of the choke plate, oxygen entering the middle section through the oxygen guide pipe descends along the oxygen channel to contact with the liquid medicine under the effect of the ultrasonic vibration sheet and carry liquid medicine particles into the inner cavity of the choke plate, hydrogen entering the middle section through the hydrogen guide pipe can enter the inner cavity of the choke plate through the notch, and then oxygen, hydrogen and the liquid medicine are mixed to form mixed gas, and the mixed gas is supplied to a patient through the upper section. By adopting the structure, the direct contact mixing of oxygen and hydrogen is effectively reduced, but the oxygen, the hydrogen and the liquid medicine are mixed, specifically, the oxygen is forced to downwards run to carry liquid medicine particles, and then is mixed with a large amount of hydrogen, so that the liquid medicine particles can be carried on one hand, and on the other hand, the oxygen and the hydrogen are mixed in a moist environment, thereby greatly reducing the generation of static electricity and further reducing the potential safety hazard.

(4) Be provided with ring channel, go up limiting plate, lower limiting plate and atomization cap, joint and close fit in oxygen guide pipe, the hydrogen guide pipe insert vertical recess have guaranteed the relative position of mixing gas pipe and atomizing section of thick bamboo for mixing gas pipe can not take place to rock.

(5) When the oxygen conveying device conveys oxygen, the oxygen is sufficiently cooled through the gas-liquid separator I, the oxygen and water are separated, and water stored in the gas-liquid separator I can enter the water tank through the water return pipeline I; when the hydrogen conveying device conveys hydrogen, the gas-liquid separator II is used for separating the hydrogen from the water, the water separated by the gas-liquid separator II can enter the water tank through the water return pipeline II, and the pressure in the hydrogen conveying device is well controlled by arranging the pressure relief valve.

It can be seen that the present invention has outstanding substantial features and significant advances over the prior art, as well as the benefits of its implementation.

Drawings

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

FIG. 2 is a schematic diagram of the workflow of an oxyhydrogen atomizer;

FIG. 3 is a schematic structural view of a drug mixing device;

FIG. 4 is a schematic perspective view of a gas mixing tube;

FIG. 5 is a schematic view of the bottom view of the gas mixing tube;

FIG. 6 is a schematic view of the structure of the choke plate;

fig. 7 is a control schematic diagram of the oxyhydrogen gas atomizer.

Wherein: 1-a shell, 1.1-a heat dissipation hole; 2-a water tank; 3-an electrolytic cell; 4-oxygen delivery device, 4.1-gas-liquid separator I, 4.2-flame arrester I, 4.3-electromagnetic valve; 5-hydrogen conveying device, 5.1-gas-liquid buffer, 5.2-gas-liquid separator II, 5.3-pressure release valve and 5.4-flame arrester II; 6-medicine mixing device, 6.1-gas mixing tube, 6.1.1-upper section, 6.1.2-middle section, 6.1.3-lower section, 6.1.3.1-threaded connection section, 6.1.4-choke plate, 6.1.4.1-notch, 6.1.5-oxygen channel, 6.1.6-oxygen guide tube, 6.1.6.1-seal I, 6.1.7-hydrogen guide tube, 6.1.7.1-seal II, 6.1.8-upper limit plate, 6.1.9-lower limit plate, 6.2-atomizing groove, 6.2.1-atomizing cylinder, 6.2.1.1-annular groove, 6.2.1.2-vertical groove, 6.2.1.3-oxygen inlet, 6.2.1.4-hydrogen inlet, 6.2.2-atomizing cover, 6.3-medicine liquid groove, 6.4-ultrasonic vibration piece, 6.5-bolt I, 6.6-bolt II; 7-universal wheels; 8-a water tank cover; 9-a display screen; 11-a water pump.

Detailed Description

In order to clearly illustrate the technical characteristics of the present solution, the present solution is described below by means of specific embodiments and with reference to the accompanying drawings.

As shown in fig. 1-7, an oxyhydrogen gas atomizer comprises a shell 1, a water tank 2 is fixedly arranged in the shell 1, the water tank 2 is communicated with an electrolytic tank 3 through a water supply pipe, a hydrogen outlet of the electrolytic tank 3 is connected with a hydrogen conveying device 5, an oxygen outlet of the electrolytic tank 3 is connected with an oxygen conveying device 4, hydrogen conveyed by the hydrogen conveying device 5 and oxygen conveyed by the oxygen conveying device 4 are mixed at a medicine mixing device 6, an outlet of the medicine mixing device 6 is connected with an air supply pipeline, and air is supplied to an oral cavity and/or a nasal cavity of a patient through the air supply pipeline.

Along the direction of oxygen travel, set gradually gas-liquid separator I4.1 and flame arrester I4.2 on the pipeline of oxygen conveyor 4, the oxygen that the electrolysis water produced cools down through gas-liquid separator I4.1, and rethread flame arrester I4.2 gets into in the medicine mixing device 6, sets up flame arrester I4.2 effectually avoids gas combustion explosion. The gas-liquid separator I4.1 can be a coiled pipe radiator.

Along the direction of travel of hydrogen, set gradually gas-liquid buffer 5.1, gas-liquid separator II 5.2, relief valve 5.3 and flame arrester II 5.4 on the pipeline of hydrogen conveyor 5, the liquid outlet of gas-liquid separator II 5.2 carries out the gas-liquid separation through gas-liquid separator II 5.2 through the hydrogen that return water pipeline II and water tank 2 intercommunication electrolysis water produced, again in entering medicine mixing device 6 through flame arrester II 5.4, sets up flame arrester II 5.4 effectual avoiding gas combustion explosion.

A fan is fixedly arranged near the gas-liquid separator I4.1, and a radiating hole 1.1 matched with the fan is formed in the shell 1.

The bottom of the gas-liquid separator I4.1 is communicated with the water tank 2 through a water return pipeline I, and the water return pipeline I is provided with an electromagnetic valve 4.3.

The two water tanks 2 are communicated, and the water supply pipe is provided with a water pump 11.

The medicine mixing device 6 comprises an atomization groove 6.2 fixedly connected with the shell 1, a mixed gas pipe 6.1 is arranged in the atomization groove, the lower end of the mixed gas pipe 6.1 is fixedly connected with a medicine liquid groove 6.3, the mixed gas pipe 6.1 is communicated with the medicine liquid groove 6.3, an oxygen guide pipe 6.1.6 and a hydrogen guide pipe 6.1.7 are fixedly connected to the mixed gas pipe 6.1, both the oxygen guide pipe 6.1.6 and the hydrogen guide pipe 6.1.7 are communicated with the mixed gas pipe 6.1, and an ultrasonic vibration piece 6.4 is arranged below the medicine liquid groove 6.3.

The atomizing tank 6.2 comprises an atomizing cylinder 6.2.1, an oxygen inlet 6.2.1.3 and a hydrogen inlet 6.2.1.4 are arranged on the atomizing cylinder 6.2.1, one end of the oxygen inlet 6.2.1.3 is communicated with an oxygen guide pipe 6.1.6, the other end of the oxygen inlet 6.2.1.3 is communicated with a flame arrester I4.2, one end of a hydrogen inlet 6.2.1.4 is communicated with a hydrogen guide pipe 6.1.7, and the other end of the hydrogen inlet 6.2.1.4 is communicated with a flame arrester II 5.4.

An annular groove 6.2.1.1 is arranged in the atomizing cylinder 6.2.1, two vertical grooves 6.2.1.2 are also arranged in the atomizing cylinder 6.2.1 below the annular groove 6.2.1, an oxygen inlet 6.2.1.3 and a hydrogen inlet 6.2.1.4 are respectively arranged in the two vertical grooves 6.2.1.2, the sizes of the vertical grooves 6.2.1.2 are matched with the sizes of the tail ends of an oxygen guide pipe 6.1.6 and a hydrogen guide pipe 6.1.7, an upper limit plate 6.1.8 and a lower limit plate 6.1.9 are arranged on the mixed gas pipe 6.1, the upper limiting plate 6.1.8 and the lower limiting plate 6.1.9 are both arranged in the annular groove 6.2.1.1, an atomization cover 6.2.2 is further arranged above the atomization cylinder 6.2.1, the atomization cylinder 6.2.1 and the atomization cover 6.2.2 are fixed on the shell 1 through bolts 6.6, the upper end of the mixed gas pipe 6.1 is positioned above the atomization cover 6.2.2, the upper end of the upper limiting plate 6.1.8 is attached to the lower end of the atomization cover 6.2.2, and the lower end of the lower limiting plate 6.1.9 is attached to the bottom end of the annular groove 6.2.1.1.

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, the oxygen guiding pipe 6.1.6 and the hydrogen guiding pipe 6.1.7 are fixedly connected with the middle section 6.1.2, a gas blocking plate 6.1.4 is fixedly arranged in the middle section 6.1.2, the gas blocking plate 6.1.4 and the middle section 6.1.2 form an oxygen channel 6.1.5 for oxygen supply to flow downwards, 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 is formed in the gas blocking plate 6.1.4; the oxygen guiding pipe 6.1.6 and the hydrogen guiding pipe 6.1.7 are both fixedly arranged on the middle section 6.1.2, the oxygen guiding pipe 6.1.6 is communicated with the oxygen channel 6.1.5, hydrogen entering from the hydrogen guiding pipe 6.1.7 can enter the inner cavity of the choke plate 6.1.4 through the 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, the lower end of the inner cavity of the choke plate 6.1.4 is communicated with the lower section 6.1.3, and the lower section 6.1.3 is communicated with the liquid medicine groove 6.3.

The end of the oxygen guide tube 6.1.6 is provided with an elastic seal i 6.1.6.1.

The hydrogen guide tube 6.1.7 is provided with an elastic seal ii 6.1.7.1 at its end.

The lower section 6.1.3 is provided with a threaded connection section 6.1.3.1, and the lower section 6.1.3 is in threaded connection with the liquid medicine tank 6.3.

The upper section 6.1.1, the middle section 6.1.2 and the lower section 6.1.3 are of an integrated structure.

Both seal I6.1.6.1 and seal II 6.1.7.1 are made of an elastomeric silicone material.

The ultrasonic vibration plate 6.4 is fixed on the atomizing cylinder 6.2.1 through a bolt 6.5.

The ultrasonic vibration piece 6.4 acts on the liquid medicine groove 6.3, so that the liquid in the liquid medicine groove 6.3 is slowly carried into the human body of a patient by the oxygen and the hydrogen which enter the mixed gas pipe. When the oxyhydrogen gas atomizer does not work, liquid medicine can be poured into the liquid medicine tank 6.3 from the mixed gas pipe 6.1.

The shell 1 is connected with a power supply module, the power supply module is connected with a controller through a transformer, the power supply module is also connected with a control power supply, the controller is respectively connected with the gas-liquid separator I4.1, the gas-liquid separator II 5.2, the ultrasonic vibration sheet 6.4, the display screen 9 and the fan, the controller is connected with a control power supply, and the control power supply is connected with the water pump 11; the controller is connected with an electrolysis power supply, and the electrolysis power supply is respectively connected with the power supply module and the electrolysis tank.

The hydrogen and oxygen are separately and independently transported before entering the mixing pipe 6.1.1. Under the effect 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 the liquid medicine under the effect of the ultrasonic vibration sheet and carry the 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 enters the inner cavity of the choke plate 6.1.4 through the notch 6.1.4.1, then oxygen, hydrogen and the liquid medicine are mixed to form mixed gas, the mixed gas is supplied to a patient for use through the upper section 6.1.1, the direct contact and mixing of the oxygen and the hydrogen are effectively reduced, the oxygen, the hydrogen and the liquid medicine are mixed, specifically, the oxygen is forced to downwards run to carry the liquid medicine particles and then be mixed with a large amount of hydrogen, on one hand, the liquid medicine particles can be carried, on the other hand, the oxygen and the hydrogen are mixed in a moist environment, the generation of static electricity is greatly reduced, and the potential safety hazard is further reduced.

The technical features not described in the present invention may be implemented by or using the prior art, and are not described herein in detail, but the above description is not intended to limit the present invention, and the present invention is not limited to the above embodiments, but is also intended to be limited to the following changes, modifications, additions or substitutions made by those skilled in the art within the spirit and scope of the present invention.

Claims

1. An oxyhydrogen gas atomizer, characterized by: the hydrogen and oxygen separation device comprises a shell (1), wherein a water tank (2) is fixedly arranged in the shell (1), the water tank (2) is communicated with an electrolytic tank (3) through a water supply pipe, a hydrogen outlet of the electrolytic tank (3) is connected with a hydrogen conveying device (5), an oxygen outlet of the electrolytic tank (3) is connected with an oxygen conveying device (4), hydrogen and oxygen are separately and independently conveyed to a medicine mixing device (6), hydrogen conveyed by the hydrogen conveying device (5) and oxygen conveyed by the oxygen conveying device (4) are mixed at the medicine mixing device (6), and an outlet of the medicine mixing device (6) is connected with a gas supply pipeline;

the medicine mixing device (6) comprises an atomization groove (6.2) fixedly connected with the shell (1), a mixed gas pipe (6.1) is arranged in the atomization groove (6.2), a medicine liquid groove (6.3) is fixedly connected to the lower end of the mixed gas pipe (6.1), the mixed gas pipe (6.1) is communicated with the medicine liquid groove (6.3), an oxygen guide pipe (6.1.6) and a hydrogen guide pipe (6.1.7) are fixedly connected to the mixed gas pipe (6.1), both an oxygen guide pipe (6.1.6) and a hydrogen guide pipe (6.1.7) are communicated with the mixed gas pipe (6.1), and an ultrasonic vibration piece (6.4) is arranged below the medicine liquid groove (6.3);

the atomization tank (6.2) comprises an atomization cylinder (6.2.1), an oxygen inlet (6.2.1.3) and a hydrogen inlet (6.2.1.4) are arranged on the atomization cylinder (6.2.1), one end of the oxygen inlet (6.2.1.3) is communicated with an oxygen guide pipe (6.1.6), the other end of the oxygen inlet (6.2.1.3) is communicated with an oxygen conveying device (4), one end of a hydrogen inlet (6.2.1.4) is communicated with a hydrogen guide pipe (6.1.7), and the other end of the hydrogen inlet (6.2.1.4) is communicated with a hydrogen conveying device (5);

an annular groove (6.2.1.1) is formed in the atomizing barrel (6.2.1), two vertical grooves (6.2.1.2) are formed in the atomizing barrel (6.2.1) below the annular groove (6.2.1), an oxygen inlet (6.2.1.3) and a hydrogen inlet (6.2.1.4) are respectively formed in the two vertical grooves (6.2.1.2), the size of the vertical grooves (6.2.1.2) is matched with the sizes of the tail ends of an oxygen guide pipe (6.1.6) and a hydrogen guide pipe (6.1.7), an upper limit plate (6.1.8) and a lower limit plate (6.1.9) are arranged on the mixing air pipe (6.1), both the upper limit plate (6.1.8) and the lower limit plate (6.1.9) are arranged in the annular groove (6.2.1.1), an atomizing cover (6.2.2.2) is further arranged above the atomizing barrel (6.1), the size of the vertical grooves (6.2.1.2) is matched with the size of the tail ends of the oxygen guide pipe (6.1.6) and the hydrogen guide pipe (6.1.7), and the upper limit plate (6.1.8) and the lower limit plate (6.1.9) are attached to the upper end of the upper end (6.1.2.2.2.2) of the upper end of the mixing air pipe (6.1) and the lower end (6.1) of the upper limit plate (6.2.1).

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, the oxygen guide pipe (6.1.6) and the hydrogen guide pipe (6.1.7) are fixedly connected with the middle section (6.1.2), a choke plate (6.1.4) is fixedly arranged in the middle section (6.1.2), the choke plate (6.1.4) and the middle section (6.1.2) form an oxygen channel (6.1.5) for oxygen supply to flow downwards, 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 is formed in the choke plate (6.1.4); oxygen guide pipe (6.1.6) and hydrogen guide pipe (6.1.7) are all fixed to be set up on middle section (6.1.2), oxygen guide pipe (6.1.6) and oxygen passageway (6.1.5) intercommunication, the hydrogen accessible breach (6.1.4.1) that gets into from hydrogen guide pipe (6.1.7) get into choke plate (6.1.4) inner chamber, the upper end and the upper segment (6.1.1) intercommunication of choke plate (6.1.4) inner chamber, the lower extreme and the hypomere (6.1.3) intercommunication of choke plate (6.1.4) inner chamber, hypomere (6.1.3) and liquid medicine groove (6.3) intercommunication.

2. The oxyhydrogen gas atomizer according to claim 1, characterized in that: along the running direction of oxygen, a gas-liquid separator I (4.1) and a flame arrester I (4.2) are sequentially arranged on a pipeline of the oxygen conveying device (4).

3. The oxyhydrogen gas atomizer according to claim 1, characterized in that: along the direction of travel of hydrogen, set gradually gas-liquid buffer (5.1), gas-liquid separator II (5.2), relief valve (5.3) and flame arrester II (5.4) on the pipeline of hydrogen conveyor (5), the liquid outlet of gas-liquid separator II (5.2) is through return water pipeline II and water tank (2) intercommunication.

4. The oxyhydrogen gas atomizer according to claim 2, characterized in that: the novel air-liquid separation device is characterized in that a fan is fixedly arranged near the air-liquid separator I (4.1), a radiating hole (1.1) matched with the fan is formed in the shell (1), the bottom end of the air-liquid separator I (4.1) is communicated with the water tank (2) through a water return pipeline I, and an electromagnetic valve (4.3) is arranged on the water return pipeline I.

5. A oxyhydrogen gas atomizer according to claim 3, characterized in that: the two water tanks (2) are communicated, and the water supply pipe is provided with a water pump (11).

6. The oxyhydrogen gas atomizer according to claim 1, characterized in that: the shell (1) is connected with a power supply module, the power supply module is connected with a controller through a transformer, the power supply module is also connected with a control power supply, the controller is respectively connected with a gas-liquid separator I (4.1), a gas-liquid separator II (5.2), an ultrasonic vibration sheet (6.4), a display screen (9) and a fan, the controller is connected with the control power supply, and the control power supply is connected with a water pump (11); the controller is connected with an electrolysis power supply, and the electrolysis power supply is respectively connected with the power supply module and the electrolysis tank.