CN210185932U

CN210185932U - Micro hyperbaric oxygen chamber

Info

Publication number: CN210185932U
Application number: CN201920852343.9U
Authority: CN
Inventors: Fuchun Liu; 刘富春; Huajun Xiao; 肖华军; Jianmin Xiao; 肖建民; Conggan Wen; 温从干
Original assignee: Jiangsu Senhang Health Technology Co ltd
Current assignee: Jiangsu Senhang Health Technology Co ltd
Priority date: 2019-06-06
Filing date: 2019-06-06
Publication date: 2020-03-27
Anticipated expiration: 2029-06-06

Abstract

The utility model relates to a micro hyperbaric oxygen chamber, which comprises a chamber body and a controller, wherein the controller comprises a shell, an oxygen generating device and a pressurizing device which are arranged in the shell, a fixed frame is fixedly arranged in the shell, and an air inlet and an air outlet are arranged on the shell; the oxygen generating device comprises a first compressor, a first cooling mechanism, a separating mechanism and a humidifying mechanism which are sequentially connected, wherein the first compressor is connected with an air inlet, the humidifying mechanism is connected with an air outlet, and the separating mechanism is fixedly arranged on the side wall of the fixing frame; the pressurizing device comprises a second compressor and a second cooling mechanism which are sequentially connected, the second compressor is connected with the air inlet, the second cooling mechanism is connected with the air outlet, the first compressor and the second compressor are fixedly installed in the cavity of the fixing frame, and the first cooling mechanism and the second cooling mechanism are fixedly installed above the fixing frame. The utility model discloses all install oxygenerator, pressure device's most mechanism on the mount, the installer of being convenient for installs, and the maintenance in the later stage of being convenient for.

Description

Micro hyperbaric oxygen chamber

Technical Field

The utility model relates to a recovered appurtenance equipment especially relates to a little hyperbaric oxygen cabin.

Background

The household micro-hyperbaric oxygen chamber is a novel high-tech rehabilitation auxiliary appliance which is made up at home and abroad in recent decades. The oxygen inhalation device has the advantages that a user inhales pure oxygen or high-concentration oxygen in a micro high-pressure environment, so that the blood oxygen content of the body is improved, and the auxiliary effects of relieving physical and mental fatigue, keeping vigorous energy, improving working efficiency and improving sub-health state and disease rehabilitation can be achieved. The existing oxygen making device and the pressurizing device are directly installed in a controller shell, the installation is troublesome, the pipeline connection is more disordered, and the later-stage maintenance is more troublesome.

SUMMERY OF THE UTILITY MODEL

The utility model provides a micro hyperbaric oxygen chamber with simple structure, convenient installation and convenient later maintenance.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: the micro hyperbaric oxygen chamber comprises a chamber body and a controller connected with the chamber body through an air pipe, wherein the controller comprises a shell, an oxygen generating device and a pressurizing device which are arranged in the shell, the shell comprises a base and a cover body covering the base, a fixing frame is fixedly arranged above the base, and the shell is provided with an air inlet and an air outlet, so that the oxygen generating device and the pressurizing device are fixedly arranged on the fixing frame, and a cavity is formed in the middle of the fixing frame; the oxygen generation device comprises a first compressor with an inlet connected with an air inlet, a first cooling mechanism with an inlet connected with an outlet of the first compressor, a separating mechanism with an inlet connected with an outlet of the first cooling mechanism, and a humidifying mechanism with an inlet connected with an outlet of the separating mechanism, wherein an outlet of the humidifying mechanism is connected with an air outlet, the first compressor is fixedly arranged in a cavity of the fixing frame, the first cooling mechanism is fixedly arranged above the fixing frame, the separating mechanism is fixedly arranged on the side wall of the fixing frame, and the humidifying mechanism is fixedly arranged outside the cover body; the pressurizing device comprises a second compressor connected with the air inlet at the inlet and a second cooling mechanism connected with the second compressor at the inlet, the outlet of the second cooling mechanism is connected with the air outlet, the second compressor is fixedly arranged in the cavity of the fixing frame, and the second cooling mechanism is fixedly arranged above the fixing frame.

The oxygen generation device further comprises a first silencing mechanism, wherein the first silencing mechanism comprises a first silencer arranged between the air inlet and the first compressor, a second silencer arranged between the first compressor and the first cooling mechanism, and a third silencer arranged between the separating mechanism and the humidifying mechanism.

Wherein, the oxygen generating device also comprises an anion generator which is arranged between the air inlet and the first silencing mechanism.

The pressurizing device further comprises a second silencing mechanism, and the second silencing mechanism comprises a fourth silencer arranged between the air inlet and the second compressor and a fifth silencer arranged between the second compressor and the second cooling mechanism.

Wherein, an opening is arranged on one side of the fixing frame and communicated with the cavity.

Wherein, the opening part of the fixed mount is fixedly provided with a cover plate for sealing the cavity.

Wherein, all be fixed with on the cavity inner wall of mount and inhale the sound cotton.

The cavity of the fixing frame is divided into an upper cavity and a lower cavity by a transverse plate, and the first compressor and the second compressor are fixedly installed in the upper cavity or the lower cavity respectively.

Wherein, fixed mounting has control circuit board on the cover body, and first compressor and second compressor all are connected with control circuit board electric connection.

Wherein, a plurality of gyro wheels are evenly installed to the base below.

Compared with the prior art, the utility model discloses all install oxygenerator, pressure device's most mechanism on the mount, the installer of being convenient for installs, and each mechanism installs on the mount surface in addition, the maintenance in the later stage of being convenient for.

Drawings

Fig. 1 is a schematic view of the cross air flow direction of the controller of the micro hyperbaric oxygen chamber of the present invention.

Fig. 2 is a rear view of the controller of the micro hyperbaric oxygen chamber of the present invention.

Fig. 3 is a schematic structural view of the micro hyperbaric oxygen chamber after the shell is removed.

Fig. 4 is a schematic top view of fig. 3.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

As shown in fig. 1, fig. 2 and fig. 4, the micro hyperbaric oxygen chamber of the present invention comprises a chamber body, a controller connected with the chamber body through an air pipe, the controller comprises a housing 1, an oxygen generator and a pressure device arranged in the housing 1, the housing 1 comprises a base 11, a cover body 12 covering the base 11, a fixing frame 13 is fixedly arranged above the base 11, the housing 1 is provided with an air inlet 14 and an air outlet 15, the oxygen generator and the pressure device are fixedly arranged on the fixing frame 13, and a cavity is formed in the middle of the fixing frame 13; a flow dividing valve 17 is arranged at the inlet of the air inlet 14, is fixedly arranged on the cover body 12 and is used for dividing the air entering from the air inlet, wherein one path of the air is led to the oxygen generating device, and the other path of the air is led to the pressurizing device; the oxygen generation device comprises a first compressor 21 with an inlet connected with the air inlet 14, a first cooling mechanism 22 with an inlet connected with an outlet of the first compressor 21, a separating mechanism 23 with an inlet connected with an outlet of the first cooling mechanism 22, and a humidifying mechanism 24 with an inlet connected with an outlet of the separating mechanism 23, wherein an outlet of the humidifying mechanism 24 is connected with the air outlet 15, the first compressor 21 is fixedly arranged in a cavity of the fixing frame 13, the first cooling mechanism 22 is fixedly arranged above the fixing frame 13, the separating mechanism 23 is fixedly arranged on the side wall of the fixing frame 13, and the humidifying mechanism 24 is fixedly arranged outside the cover body 12; the pressurizing device comprises a second compressor 31 with an inlet connected with the air inlet, and a second cooling mechanism 32 with an inlet connected with the second compressor 31, wherein an outlet of the second cooling mechanism 32 is connected with the air outlet 15, the second compressor 31 is fixedly arranged in a cavity of the fixed frame 13, and the second cooling mechanism 32 is fixedly arranged above the fixed frame 13. The pressure in the chamber is maintained at 1.25-1.3 atmospheres. The utility model discloses all install oxygenerator, pressure device's most mechanism on the mount, the installer of being convenient for installs, and each mechanism installs on the mount surface in addition, the maintenance in the later stage of being convenient for.

The oxygen generating apparatus further comprises a first silencer mechanism, which comprises a first silencer 251 disposed between the air inlet 14 and the first compressor 21, a second silencer 252 disposed between the first compressor 21 and the first cooling mechanism 22, and a third silencer 253 disposed between the separating mechanism 23 and the humidifying mechanism 24.

The housing is provided with an exhaust port 16 and a nitrogen gas outlet of the separating mechanism for discharging nitrogen gas, and a sixth silencer 254 is arranged between the nitrogen gas outlet of the separating mechanism and the exhaust port.

The oxygen generator also comprises an anion generator 26, the anion generator 26 is arranged between the air inlet and the first silencing mechanism, the anion generator is used for generating anions, and the anions have medical care effect on the human body.

The pressurizing device further includes a second silencing mechanism including a fourth silencer 331 disposed between the air inlet 14 and the second compressor 31, a fifth silencer 332 disposed between the second compressor 31 and the second cooling mechanism 32, and a seventh silencer 333 disposed between the second cooling mechanism 32 and the air outlet.

Above-mentioned each muffler is the muffler that the intussuseption was filled with sound absorbing material, and the muffler of other structures also can be adopted certainly, the setting of each muffler to reduce the noise that produces in the gas transmission process.

As shown in fig. 3, an opening is formed at one side of the fixing frame 13, and the opening is communicated with the cavity, so that later-stage maintenance is facilitated.

The opening part fixed mounting of mount 13 has the apron of closed cavity, covers the apron after, and the cavity is airtight state, is provided with on this apron and inhales the sound cotton to reduce the noise that the compressor during operation produced, can prevent moreover that the dust from getting into.

The inner wall of the cavity of the fixing frame 13 is fixedly provided with sound absorption cotton for absorbing noise generated during the operation of the compressor.

The cavity of the fixing frame 13 is divided into an upper cavity and a lower cavity by a transverse plate 131, the first compressor 21 and the second compressor 31 are respectively and fixedly installed in the upper cavity or the lower cavity so as to separate the first compressor and the second compressor, and sound-absorbing cotton is fixedly arranged on the upper surface and the lower surface of the transverse plate so as to absorb noise generated during the operation of the compressors and reduce noise emission.

The separating mechanism 23 comprises two separating tanks, a gas storage tank and a reversing valve, the inlet of the reversing valve is connected with the outlet of the cooling mechanism 6, the two outlets of the reversing valve are respectively connected with the inlets of the two separating tanks, the oxygen outlets of the two separating tanks are connected with the inlet of the gas storage tank, the outlet of the gas storage tank is connected with the inlet of the humidifying mechanism 24, and the nitrogen outlet of the separating tank is connected with the exhaust port. During operation, air enters one of the separating tanks through the reversing valve to be subjected to nitrogen and oxygen separation, after several seconds, the valve body of the reversing valve slides, the other channel is opened, the air enters the other separating tank under the action of the reversing valve to be subjected to nitrogen and oxygen separation, the nitrogen in the original separating tank is discharged, the two separating tanks work repeatedly in sequence, the nitrogen in the separating tanks is discharged in time, and high-concentration oxygen is continuously provided for the cabin body.

The inlet and the oxygen outlet of each separation tank are respectively provided with a molecular sieve plate to adsorb nitrogen and allow oxygen to pass through, thereby improving the oxygen concentration in the air.

The reversing valve is an electromagnetic reversing valve, namely, the electromagnetic coil generates electromagnetic force to drive the valve body to move, so that the channel is opened or closed, and the flow direction of air is changed; of course, the reversing valve can be automatically driven to reverse in other ways, such as a hydraulic system.

A pressure regulating valve 27 is arranged between the separating mechanism 23 and the humidifying mechanism 24, which plays a role of constant pressure and ensures the output of the output oxygen with constant pressure.

The humidifying mechanism 24 comprises a humidifying cup filled with water, and the humidifying cup is filled with water, so that the separated oxygen flows into the cabin body after passing through the water, thereby purifying dust carried in the oxygen and humidifying the oxygen; the inlet of the humidifying cup is provided with a one-way valve, so that when the oxygen generator stops working or generates negative pressure during air leakage, water in the humidifying cup is prevented from flowing back to enter the separating mechanism.

The cover body 12 is fixedly provided with a control circuit board and a display screen, the first compressor 21, the second compressor 31, the electromagnetic valve and the display screen are all electrically connected with the control circuit board, the control circuit board is a PLC and is used for controlling the first compressor and the second compressor to start and close, the electromagnetic valve is controlled to be reversed at regular time, uninterrupted continuous work of the double separation tanks is realized, information is communicated with the display screen, and data transmission is realized. The display screen sets up in the top of casing for show cabin body condition, and be provided with the control button that can supply the user to operate, convenient to use person operates.

A plurality of idler wheels 5 are uniformly arranged below the base 11, so that the controller can move conveniently.

The pipeline of being connected between controller and the cabin body is integrated pipeline, it contains 6 trachea, wherein 4 are used for carrying pressurized air, promptly with the exit linkage of second cooling body, wherein 1 is used for carrying high concentration oxygen, promptly with the exit linkage of humidifying mechanism, it is cabin body pressure feedback pipe to remain 1, it is connected with the control circuit board in the controller, be convenient for in time feed back the internal pressure in cabin to control circuit board, and with signal conversion and transmission for the display screen, make the internal real-time pressure in display cabin on the display screen, the operating personnel of being convenient for in time know the internal condition in cabin, the work of other devices of control circuit board control of also being convenient for, avoid appearing danger.

When the device works, air enters from the air inlet and is divided into two paths through the flow divider, wherein one path of air enters the oxygen generating device, and the other path of air enters the pressurizing device; air entering the oxygen generating device passes through the negative ion generating mechanism, negative ions are added to the air, then the air enters the first compressor, the air is pressurized, the pressurized air enters the first cooling mechanism and is cooled, the cooled air enters the separating mechanism, nitrogen is adsorbed, oxygen enters the air storage tank, the separated oxygen enters the humidifying mechanism, the oxygen is humidified and purified, the humidified oxygen enters the cabin body, and the separated nitrogen is discharged; and the air entering the pressurizing device enters a second compressor for pressurizing, the pressurized air enters a second cooling mechanism for cooling, and the cooled air enters the cabin body.

Finally, it should be noted that: the above embodiments are merely illustrative of the technical solutions of the present invention, and not limitative thereof; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims

1. A micro hyperbaric oxygen chamber, which is characterized in that: the micro hyperbaric oxygen chamber comprises a chamber body and a controller connected with the chamber body through an air pipe, wherein the controller comprises a shell (1), an oxygen generating device and a pressurizing device which are arranged in the shell (1), the shell (1) comprises a base (11) and a cover body (12) covering the base (11), a fixing frame (13) is fixedly arranged above the base (11), an air inlet (14) and an air outlet (15) are arranged on the shell (1), so that the oxygen generating device and the pressurizing device are fixedly arranged on the fixing frame (13), and a cavity is formed in the middle of the fixing frame (13); the oxygen generation device comprises a first compressor (21) with an inlet connected with the air inlet (14), a first cooling mechanism (22) with an inlet connected with an outlet of the first compressor (21), a separating mechanism (23) with an inlet connected with an outlet of the first cooling mechanism (22), and a humidifying mechanism (24) with an inlet connected with an outlet of the separating mechanism (23), wherein an outlet of the humidifying mechanism (24) is connected with the air outlet (15), the first compressor (21) is fixedly arranged in a cavity of the fixing frame (13), the first cooling mechanism (22) is fixedly arranged above the fixing frame (13), the separating mechanism (23) is fixedly arranged on the side wall of the fixing frame (13), and the humidifying mechanism (24) is fixedly arranged outside the cover body (12); the pressurizing device comprises an inlet and a second compressor (31) connected with the air inlet, and an inlet, wherein a second cooling mechanism (32) connected with the second compressor (31) is arranged, an outlet of the second cooling mechanism (32) is connected with the air outlet (15), the second compressor (31) is fixedly arranged in a cavity of the fixing frame (13), and the second cooling mechanism (32) is fixedly arranged above the fixing frame (13).

2. The micropressure chamber according to claim 1, characterized in that the oxygen production device also comprises a first silencing mechanism comprising a first silencer (251) arranged between the air inlet (14) and the first compressor (21), a second silencer (252) arranged between the first compressor (21) and the first cooling mechanism (22), and a third silencer (253) arranged between the separating mechanism (23) and the humidifying mechanism (24).

3. The micropressure chamber according to claim 2, characterized in that the oxygen generation device further comprises an anion generator (26), the anion generator (26) being arranged between the air inlet and the first silencing mechanism.

4. The micro hyperbaric chamber of claim 1, wherein the pressurizing means further comprises a second silencing mechanism comprising a fourth silencer (331) arranged between the gas inlet (14) and the second compressor (31), and a fifth silencer (332) arranged between the second compressor (31) and the second cooling mechanism (32).

5. The micro hyperbaric chamber according to claim 1, wherein an opening is opened at one side of the fixing frame (13), and the opening is communicated with the cavity.

6. The micro hyperbaric chamber according to claim 5, characterized in that a cover plate for closing the cavity is fixedly arranged at the opening of the fixing frame (13).

7. The micro hyperbaric oxygen chamber according to claim 1, wherein the inner walls of the cavities of the fixed frames (13) are fixedly provided with sound-absorbing cotton.

8. The micro hyperbaric chamber according to claim 1, wherein a transverse plate (131) is respectively divided into an upper chamber and a lower chamber in the chamber of the fixing frame (13), and the first compressor (21) and the second compressor (31) are respectively fixedly mounted in the upper chamber or the lower chamber.

9. The micro hyperbaric chamber according to claim 1, characterized in that a control circuit board is fixedly mounted on the cover body (12), and the first compressor (21) and the second compressor (31) are electrically connected with the control circuit board.

10. The micro hyperbaric chamber according to claim 1, characterized in that a plurality of rollers (5) are uniformly mounted under the base (11).