CN217286380U - Single micro-hyperbaric oxygen therapy cabin - Google Patents

Abstract

The utility model relates to the technical field of hyperbaric oxygen therapy cabins, in particular to a single micro hyperbaric oxygen therapy cabin, which comprises a cabin body, wherein the upper layer inside the cabin body is fixedly connected with sound equipment, a gas concentration monitor and a pressure sensor which are distributed in sequence, an uninterruptible power supply and a controller are fixedly connected above the cabin body, one side of the cabin body is communicated with a pressure reduction control valve, a first air pipe is arranged outside the pressure reduction control valve, the other side of the cabin body is communicated with a second air pipe, and an oxygenerator is arranged below the second air pipe; the device is convenient to use, does not need professional operation, can automatically control and complete pressurization-oxygen supply-pressure reduction operation, and an uninterrupted power supply provides power supply after power failure, can realize self-contained pressurization, self-contained oxygen generation, self-service operation and automatic safety control of a single micro-hyperbaric oxygen therapy cabin, and is convenient for users to independently use.

Description

Single micro-hyperbaric oxygen therapy cabin

Technical Field

The utility model relates to a hyperbaric oxygen treatment cabin technical field specifically is a cabin is treated to single little hyperbaric oxygen.

Background

The air pressure oxygen cabin has the advantages that the pressure medium is air, a user breathes oxygen in the air pressure oxygen cabin, compared with common oxygen inhalation, the effect of oxygen inhalation in the air pressure oxygen cabin is better, oxygen supply of tissues of the whole body can be quickly recovered, the health state of the body is effectively improved, and the air pressure oxygen cabin is particularly suitable for solving the problems of oxygen deficiency by directly utilizing high partial pressure oxygen.

Traditional air pressurization oxygen cabin, generally arrange the hyperbaric oxygen department in large-scale hospital, need the professional to operate, at present anxiety, insomnia, the mental consumption is big, the sports injury is restoreed, the sports physical ability resumes, the crowd volume that has the oxygen uptake demand such as immunity low increases gradually, especially in epidemic situation special period, limited traditional air pressurization oxygen cabin more can not satisfy the market demand, need design one kind from taking the pressurization oxygen generation function, convenience of customers self-service operation's safe automatic control's single little hyperbaric oxygen therapy cabin, consequently, propose a single little hyperbaric oxygen therapy cabin to above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a single little hyperbaric oxygen treatment cabin to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a single little hyperbaric oxygen therapy cabin, includes the cabin body, the lighting apparatus, sound equipment, gas concentration monitor and the pressure sensor that the inside upper strata fixedly connected with of cabin body distributes in proper order, cabin body top fixedly connected with uninterrupted power source and controller, cabin body one side intercommunication has the pressure reducing control valve, and installs first trachea in the pressure reducing control valve outside, cabin body opposite side intercommunication has the second trachea, and second trachea other end intercommunication has air compressor, second trachea below is equipped with the oxygenerator, the pressure increasing control valve is installed in the second trachea outside, oxygen mask is installed to the inside bottom of cabin body, cabin body bottom fixedly connected with tail gas treater.

Preferably, a third air pipe is communicated with the outer side of the second air pipe between the air compressor and the pressure control valve, and the other end of the third air pipe is communicated with the tail gas processor.

Preferably, the outer side of the oxygen generator is communicated with a fourth air pipe, the other end of the fourth air pipe is communicated with an oxygen mask, and an oxygen supply control valve is installed on the outer side of the fourth air pipe.

Preferably, one side of the oxygen inhalation mask facing the pressure reduction control valve is communicated with a fifth air pipe, and the other end of the fifth air pipe is communicated with the tail gas processor.

Preferably, the controller is electrically connected with the gas concentration monitor and the pressure sensor, and the controller is electrically connected with the first gas pipe, the pressure control valve and the oxygen supply control valve.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses in, can satisfy the different oxygen uptake demands of all kinds of crowds through the stereo set equipment that sets up, gas concentration monitor, pressure sensor, air compressor, oxygenerator and oxygen inhalation mask, and this device convenient to use need not the professional operation, but pressurization-oxygen suppliment-decompression operation are accomplished in automated control, and is very convenient, and uninterrupted power source provides the power supply after the outage, can realize that single little hyperbaric oxygen treats the self-contained pressurization of cabin, self-sufficient oxygen generation, self-service operation and automatic safety control, convenience of customers uses independently.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic diagram of the present invention.

In the figure: 1. a cabin body; 2. an acoustic device; 3. a gas concentration monitor; 4. a pressure sensor; 5. an uninterruptible power supply; 6. a controller; 7. a pressure reducing control valve; 8. a first air pipe; 9. an air compressor; 10. A second air pipe; 11. a pressure control valve; 12. a third air pipe; 13. a tail gas processor; 14. an oxygen generator; 15. a fourth air pipe; 16. an oxygen supply control valve; 17. an oxygen inhalation mask; 18. fifth trachea, 19-lighting device.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1

Referring to fig. 1-2, the present invention provides a technical solution:

the utility model provides a single little hyperbaric oxygen therapy cabin, includes the cabin body 1, 1 inside upper strata fixedly connected with of the cabin body has lighting apparatus 19, sound equipment 2, gas concentration monitor 3 and the pressure sensor 4 that distribute in proper order, 1 top fixedly connected with uninterrupted power source 5 and the controller 6 of the cabin body, 1 one side intercommunication of the cabin body has pressure reducing control valve 7, and installs first trachea 8 in the 7 outside of pressure reducing control valve, 1 opposite side intercommunication of the cabin body has second trachea 10, and the 10 other end intercommunications of second trachea has air compressor 9, 10 below of second trachea is equipped with oxygenerator 14, pressure increasing control valve 11 is installed in the 10 outside of second trachea, oxygen inhalation mask 17 is installed to 1 inside bottom of the cabin body, 1 bottom fixedly connected with tail gas processor 13 of the cabin body.

A third air pipe 12 is communicated with the outer side of the second air pipe 10 between the air compressor 9 and the pressure control valve 11, and the other end of the third air pipe 12 is communicated with an exhaust gas processor 13.

A fourth air pipe 15 is communicated with the outer side of the oxygen generator 14, the other end of the fourth air pipe 15 is communicated with an oxygen mask 17, and an oxygen supply control valve 16 is installed on the outer side of the fourth air pipe 15.

A fifth air pipe 18 is communicated with one side of the oxygen inhalation mask 17 facing the pressure reduction control valve 7, and the other end of the fifth air pipe 18 is communicated with the tail gas processor 13.

The controller 6 is electrically connected with the gas concentration monitor 3 and the pressure sensor 4, and the controller 6 is electrically connected with the first gas pipe 8, the pressure control valve 11 and the oxygen supply control valve 16.

The working process is as follows: a pressurizing system which is composed of an air compressor 9, a pressurizing control valve 11 and a pressure reducing control valve 7, wherein after the air is compressed by the air compressor 9, the gas is filled into the cabin body 1 through a second air pipe 10 by opening the pressurizing control valve 11, when the cabin body 1 is decompressed, the gas is discharged out of the cabin body 1 through a first air pipe 8 by opening the pressure reducing control valve 7, and the air compressor 9 is connected to a tail oxygen processor 13 through a third air pipe 12 to provide compressed gas required for processing tail oxygen;

an oxygen supply system consists of an oxygen generator 14, an oxygen supply control valve 16, an oxygen mask 17 and a tail oxygen processor 13, wherein after oxygen is generated by the oxygen generator 14, the oxygen supply control valve 16 is opened to charge oxygen into the oxygen mask 17 in the cabin body 1, and then the oxygen is discharged out of the cabin body 1 through the tail oxygen processor 13;

the control system is composed of a controller 6, a pressure sensor 4 and a gas concentration detector 3, wherein the pressure sensor 4 monitors the pressure in the cabin body 1, when the pressure is lower than a set value, a pressure control valve 11 is opened, compressed air enters the cabin body 1, when the pressure is higher than the set value, a pressure reduction control valve 7 is opened, and the compressed air is discharged out of the cabin body 1;

the outside-cabin sound pickup, the outside-cabin loudspeaker, the inside-cabin sound pickup and the inside-cabin loudspeaker form sound equipment, and communication between the inside and the outside of the cabin can be realized;

the lighting equipment 19 is used for lighting the interior of the cabin 1, so that various operations are convenient for personnel;

the gas concentration detector 3 can measure the concentration of oxygen and carbon dioxide in the cabin, and when the concentration of oxygen or carbon dioxide exceeds a set value, the pressure control valve 11 and the pressure reduction control valve 8 are synchronously opened to realize the exchange of gas in the cabin.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a single little hyperbaric oxygen therapy cabin, includes cabin body (1), its characterized in that: the upper layer inside the cabin body (1) is fixedly connected with a lighting device (19), a sound device (2), a gas concentration monitor (3) and a pressure sensor (4) which are distributed in sequence, an uninterruptible power supply (5) and a controller (6) are fixedly connected above the cabin body (1), one side of the cabin body (1) is communicated with a decompression control valve (7), a first air pipe (8) is arranged on the outer side of the pressure reducing control valve (7), a second air pipe (10) is communicated with the other side of the cabin body (1), the other end of the second air pipe (10) is communicated with an air compressor (9), an oxygen generator (14) is arranged below the second air pipe (10), pressure control valve (11) are installed to the second trachea (10) outside, oxygen inhalation mask (17) are installed to the inside bottom of the cabin body (1), the cabin body (1) bottom fixedly connected with tail gas treater (13).

2. The single person micro-hyperbaric oxygen therapy chamber according to claim 1, characterized in that: and a third air pipe (12) is communicated with the outer side of the second air pipe (10) between the air compressor (9) and the pressure control valve (11), and the other end of the third air pipe (12) is communicated with a tail gas processor (13).

3. The single person micro-hyperbaric oxygen therapy chamber according to claim 1, characterized in that: the outer side of the oxygen generator (14) is communicated with a fourth air pipe (15), the other end of the fourth air pipe (15) is communicated with an oxygen inhalation mask (17), and an oxygen supply control valve (16) is installed on the outer side of the fourth air pipe (15).

4. The single person micro hyperbaric oxygen chamber of claim 1, wherein: one side of the oxygen inhalation mask (17) facing the pressure reduction control valve (7) is communicated with a fifth air pipe (18), and the other end of the fifth air pipe (18) is communicated with the tail gas processor (13).

5. The single person micro hyperbaric oxygen chamber of claim 1, wherein: the controller (6) is electric connection with the gas concentration monitor (3) and the pressure sensor (4), and the controller (6) is electric connection with the first air pipe (8), the pressure control valve (11) and the oxygen supply control valve (16).

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