Micro-high pressure oxygen cabin and micro-high pressure oxygen cabin main machine with high integration degree
By integrating oxygen generation, pressurization, and condensate treatment functions into the main unit of the micro hyperbaric oxygen chamber, the problem of improper condensate treatment in existing technologies has been solved, achieving stable operation and extended lifespan of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANYANG XIANGYU MEDICAL EQUIP
- Filing Date
- 2025-05-19
- Publication Date
- 2026-06-12
AI Technical Summary
Existing micro-hyperbaric oxygen chambers have cumbersome structures and high costs. Improper condensate treatment can easily lead to problems such as water accumulation in the equipment, short circuits, or corrosion.
The micro hyperbaric oxygen chamber main unit integrates oxygen generation, pressurization, and condensate treatment functions. Through the integration of an air compressor, molecular sieve, pressure regulating filter, and water treatment device, it effectively treats condensate and avoids water accumulation and corrosion in the equipment.
It achieves efficient condensate treatment, extends equipment life, reduces costs, and improves equipment operational stability.
Smart Images

Figure CN224345113U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of micro hyperbaric oxygen chamber technology, and more specifically, to a highly integrated micro hyperbaric oxygen chamber host. Furthermore, it also relates to a micro hyperbaric oxygen chamber including the aforementioned highly integrated micro hyperbaric oxygen chamber host. Background Technology
[0002] In existing technology, a hyperbaric oxygen chamber is a device used for medical treatment, health care, or sports rehabilitation. It provides an oxygen environment above atmospheric pressure to help users increase blood oxygen levels and promote physical recovery. Common hyperbaric oxygen chamber main units typically include an oxygen generation module and a pressurization module. However, existing hyperbaric oxygen chambers have cumbersome structures and high costs. During operation, the air conditioning system and main unit generate condensate. This condensate cannot be effectively treated, easily leading to problems such as water accumulation inside the equipment, short circuits, or equipment corrosion, affecting the normal operation and lifespan of the equipment. The layout of the oxygen generation and pressurization modules and solenoid valves in commercially available hyperbaric oxygen chambers is unreasonable and costly. They also do not treat the condensate generated by the air conditioning system and main unit, mostly relying on water storage boxes to collect and discharge the condensate.
[0003] In summary, how to provide a structure that effectively treats cabin air conditioning water and main unit condensate, integrating oxygen generation, pressurization, and condensate treatment functions into one unit, is a problem that urgently needs to be solved by those skilled in the art. Utility Model Content
[0004] In view of this, the purpose of this utility model is to provide a highly integrated micro hyperbaric oxygen chamber host that can effectively treat the air conditioning water in the chamber and the condensate water in the host, integrating oxygen generation, pressurization and condensate water treatment functions into one unit.
[0005] Another objective of this invention is to provide a micro hyperbaric oxygen chamber that includes the aforementioned highly integrated micro hyperbaric oxygen chamber host.
[0006] To achieve the above objectives, this utility model provides the following technical solution:
[0007] A highly integrated micro hyperbaric oxygen chamber main unit includes:
[0008] case;
[0009] An oxygen generating and pressurizing device is disposed inside the housing. The oxygen generating and pressurizing device includes an air compressor for pressurizing air to a set pressure and a molecular sieve for generating oxygen. The air compressor is connected to the housing via an air supply pipe.
[0010] A pressure regulating filter device is installed inside the housing and is used to regulate the concentration and pressure of oxygen. The molecular sieve is connected to the pressure regulating filter device, and the pressure regulating filter device is connected to the cabin through an oxygen supply pipe.
[0011] A water treatment device includes a collection tank located at the bottom of the housing and a water processor located in the collection tank. The housing is provided with a guide pipe for guiding the condensate generated by the air conditioning system and the pressure regulating filter of the cabin into the collection tank. The water processor is used to vaporize the condensate in the collection tank.
[0012] The control device is connected to the oxygen generating and pressurizing device, the pressure regulating and filtering device, and the water processor.
[0013] In one embodiment, the pressure regulating and filtering device includes a heat exchanger, a first filter, and a second filter. The air compressor's outlet end is provided with a first air path and a second air path distributed in parallel. The second air path includes a first branch and a second branch arranged in parallel. Both the first branch and the first air path are connected to the heat exchanger. The heat exchanger is connected to the inlet end of a three-way solenoid valve. The two outlet ends of the three-way solenoid valve are respectively provided with a first control valve and a second control valve. The first control valve is connected to the first filter, and the second control valve is connected to the second filter. Both the first filter and the second filter are connected to a throttle valve. The throttle valve is connected to the cabin through the air supply pipe.
[0014] The molecular sieve is connected to the second branch, and the molecular sieve is connected to the cabin body through the oxygen supply pipe. The oxygen supply pipe is equipped with an oxygen concentration regulating valve. The air compressor, the molecular sieve, the heat exchanger, the three-way solenoid valve, the first control valve, the second control valve, and the oxygen concentration regulating valve are all connected to the control device.
[0015] In one embodiment, the interior of the housing is divided into an upper region and a lower region, with the pressure regulating filter device located in the upper region and the oxygen generating and pressurizing device and the water treatment device located in the lower region.
[0016] In one embodiment, the bottom of the housing is provided with casters.
[0017] In one embodiment, the water processor includes a filter device, a level sensor located on one side of the collection tank, and a humidifier located in the collection tank. The guide pipe is connected to the inlet end of the filter device, and the outlet end of the filter device is connected to the collection tank. The level sensor and the humidifier are both connected to the control device to control the operation of the humidifier after the level sensor is triggered.
[0018] In one embodiment, an indicator light is provided on the front of the top cover of the housing, and the top cover is provided with multimedia and a buzzer. Both the multimedia and the buzzer are connected to the control device, and a glass panel is provided above the multimedia.
[0019] In one embodiment, the front end of the housing is provided with a front cover, and the rear end of the housing is provided with a side cover for inspecting and repairing the internal components of the housing. The front cover and the side cover are detachably connected.
[0020] In one embodiment, the housing is equipped with a fan for cooling and heat dissipation, the fan is connected to the control device, and a heat dissipation window is provided on one side of the housing.
[0021] A micro hyperbaric oxygen chamber, comprising the highly integrated micro hyperbaric oxygen chamber main unit as described in any of the above claims.
[0022] In one embodiment, the system further includes a chamber, with the highly integrated micro hyperbaric oxygen chamber host located at the front of the chamber and the two connected by a trachea. The chamber is equipped with an air conditioning system, and the condensate generated by the air conditioning system is connected to the water treatment device of the highly integrated micro hyperbaric oxygen chamber host through a guide pipe.
[0023] When using the highly integrated micro-hyperbaric oxygen chamber main unit provided by this utility model, the oxygen generation and pressurization device uses molecular sieves to efficiently produce high-concentration oxygen. The molecular sieve and pressure regulating filter are connected, and the pressure regulating filter is connected to the chamber body through an oxygen delivery pipe. This increases the oxygen concentration inside the chamber through the molecular sieve and pressure regulating filter, enhances the oxygen partial pressure, and promotes the body's absorption of oxygen. Furthermore, an air compressor pressurizes the air to a set pressure. The air compressor is connected to the chamber body through an air delivery pipe, raising the pressure inside the chamber to 1.2~1.5 atmospheres (micro-hyperbaric range) and maintaining it stable, thereby simulating the effect of hyperbaric oxygen therapy.
[0024] During operation, the air conditioning system inside the cabin operates to regulate the cabin temperature. Condensate from the air conditioning system and the pressure regulating filter is guided through a guide pipe into a collection tank. The control device controls the water processor to vaporize the condensate in the collection tank, effectively treating it and preventing water accumulation inside the equipment, which could cause short circuits or corrosion, thus affecting the normal operation and lifespan of the equipment. In other words, this device can effectively treat the condensate generated by the air conditioning system and the pressure regulating filter, integrating oxygen generation, pressurization, and condensate treatment functions into the housing.
[0025] In summary, the highly integrated micro hyperbaric oxygen chamber main unit provided by this utility model can effectively treat the air conditioning water in the chamber and the condensate water of the main unit, integrating oxygen generation, pressurization and condensate water treatment functions into one unit.
[0026] In addition, this utility model also provides a micro hyperbaric oxygen chamber including the above-mentioned highly integrated micro hyperbaric oxygen chamber host. Attached Figure Description
[0027] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the provided drawings without creative effort.
[0028] Figure 1 A schematic diagram of the appearance of the highly integrated micro hyperbaric oxygen chamber main unit provided by this utility model;
[0029] Figure 2 Internal schematic diagram of a highly integrated micro hyperbaric oxygen chamber main unit;
[0030] Figure 3 for Figure 2 AA sectional view.
[0031] Figures 1-3 middle:
[0032] 1 is the housing, 11 is the top cover, 12 is the indicator light, 13 is the multimedia system, 14 is the buzzer, 15 is the glass panel, 16 is the front cover, 17 is the fan, 18 is the heat dissipation window, 2 is the oxygen generating and pressurizing device, 21 is the air compressor, 22 is the molecular sieve, 23 is the pressure regulating valve, 3 is the pressure regulating and filtering device, 31 is the heat exchanger, 32 is the first filter, 33 is the second filter, 34 is the three-way solenoid valve, 35 is the throttle valve, 36 is the oxygen concentration regulating valve, 4 is the water treatment device, 41 is the filter device, 42 is the liquid level sensor, 43 is the humidifier, 44 is the collection tank, and 5 is the caster. Detailed Implementation
[0033] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0034] The core of this invention is to provide a highly integrated micro hyperbaric oxygen chamber main unit, which can effectively treat the air conditioning water and condensate water of the chamber and integrate oxygen generation, pressurization and condensate water treatment functions into one unit. Another core aspect of this invention is to provide a micro hyperbaric oxygen chamber including the aforementioned highly integrated micro hyperbaric oxygen chamber main unit.
[0035] This specific embodiment provides a highly integrated micro hyperbaric oxygen chamber main unit, including:
[0036] Casing 1;
[0037] The oxygen generating and pressurizing device 2 is located inside the housing 1. The oxygen generating and pressurizing device 2 includes an air compressor 21 for pressurizing air to a set pressure and a molecular sieve 22 for generating oxygen. The air compressor 21 is connected to the housing through an air supply pipe.
[0038] The pressure regulating filter device 3 is located inside the housing 1 and is used to regulate the concentration and pressure of oxygen. The molecular sieve 22 is connected to the pressure regulating filter device 3, and the pressure regulating filter device 3 is connected to the cabin through the oxygen supply pipe.
[0039] Water treatment device 4 includes a collection tank 44 located at the bottom of housing 1 and a water processor located in the collection tank 44. The housing 1 is provided with a guide pipe for guiding the condensate generated by the air conditioning system and pressure regulating filter device 3 of the cabin into the collection tank 44. The water processor is used to vaporize the condensate in the collection tank 44.
[0040] The control device, oxygen generating and pressurizing device 2, pressure regulating and filtering device 3, and water processor are all connected to the control device.
[0041] It should be noted that a pressure regulating valve 23 can be installed at the end of the air compressor 21. The pressure regulating valve 23 is used to pressurize the gas to a set pressure. That is, the air compressor 21 and the pressure regulating valve 23 can generate pressure and regulate the oxygen pressure entering the chamber. The molecular sieve 22 adopts pressure swing adsorption technology to efficiently produce high-concentration oxygen. The molecular sieve 22 is connected to the pressure regulating filter device 3, which can adjust the concentration and pressure of oxygen. In actual application, the shape, structure, size, and material of the shell 1, oxygen generating and pressurizing device 2, pressure regulating filter device 3, water treatment device 4, and control device can be determined according to the actual situation and needs.
[0042] When using the highly integrated micro-hyperbaric oxygen chamber main unit provided by this utility model, the oxygen generating and pressurizing device 2 uses a molecular sieve 22 to efficiently produce high-concentration oxygen. The molecular sieve 22 is connected to the pressure regulating and filtering device 3, which is connected to the chamber body through an oxygen delivery pipe. This increases the oxygen concentration in the chamber through the molecular sieve 22 and the pressure regulating and filtering device 3, enhances the oxygen partial pressure, and promotes the body's absorption of oxygen. Furthermore, the air compressor 21 pressurizes the air to a set pressure. The air compressor 21 is connected to the chamber body through an air delivery pipe, which increases the pressure inside the chamber to 1.2~1.5 atmospheres (micro-hyperbaric range) and maintains it stable, thereby simulating the effect of hyperbaric oxygen therapy.
[0043] During use, the air conditioning system inside the cabin operates to regulate the temperature inside the cabin. The condensate generated by the air conditioning system and the pressure regulating filter 3 can be guided into the collection tank 44 through the guide pipe. The control device can control the operation of the water processor to vaporize the condensate in the collection tank 44, effectively treating the condensate and preventing water accumulation inside the equipment, which could cause short circuits or equipment corrosion, thus avoiding affecting the normal operation and service life of the equipment. In other words, this device can effectively treat the condensate generated by the air conditioning system and the pressure regulating filter 3, and integrates the oxygen generation, pressurization, and condensate treatment functions into the housing 1.
[0044] In summary, the highly integrated micro hyperbaric oxygen chamber main unit provided by this utility model can effectively treat the air conditioning water in the chamber and the condensate water of the main unit, integrating oxygen generation, pressurization and condensate water treatment functions into one unit.
[0045] In one embodiment, the pressure regulating and filtering device 3 includes a heat exchanger 31, a first filter 32, and a second filter 33. The air compressor 21 has a first air path and a second air path distributed in parallel at its outlet end. The second air path includes a first branch and a second branch arranged in parallel. Both the first branch and the first air path are connected to the heat exchanger 31. The heat exchanger 31 is connected to the inlet end of a three-way solenoid valve 34. The two outlet ends of the three-way solenoid valve 34 are respectively provided with a first control valve and a second control valve. The first control valve is connected to the first filter 32, and the second control valve is connected to the second filter 33. Both the first filter 32 and the second filter 33 are connected to a throttle valve 35. The throttle valve 35 is connected to the cabin through an air supply pipe.
[0046] Molecular sieve 22 is connected to the second branch line. Molecular sieve 22 is connected to the cabin through an oxygen supply pipe. An oxygen concentration regulating valve 36 is installed on the oxygen supply pipe. Air compressor 21, molecular sieve 22, heat exchanger 31, three-way solenoid valve 34, first control valve, second control valve and oxygen concentration regulating valve 36 are all connected to the control device.
[0047] It should be noted that after the highly integrated micro hyperbaric oxygen chamber main unit starts working, the air compressor 21 in the oxygen generation and pressurization device 2 is divided into two pressurization paths, and the two paths output air in parallel (that is, the air compressor 21 has a first air path and a second air path connected in parallel at its outlet). The second air path includes a first branch and a second branch connected in parallel (the second branch opens upon receiving a command). Both the first branch and the first air path are connected to the heat exchanger 31. The heat exchanger 31 is connected to the inlet end of the three-way solenoid valve 34. The two outlet ends of the three-way solenoid valve 34 are respectively equipped with a first control valve and a second control valve. The first control valve is connected to the first filter 32, and the second control valve is connected to the second filter 33. Both the first filter 32 and the second filter 33 are connected to the throttle valve 35, that is, the gas paths from the first filter 32 and the second filter 33 are both connected to the throttle valve 35 (parallel connection is converted to series connection). The throttle valve 35 is connected to the chamber through the gas supply pipe to introduce gas into the chamber and adjust the pressure of the chamber to reach the expected pressure. For example, the pressure in the chamber can be increased to 1.2~1.5 standard atmospheres (micro-high pressure range) and maintained stably, thereby simulating the effect of hyperbaric oxygen therapy.
[0048] Meanwhile, the molecular sieve 22 is connected to the second branch. The molecular sieve 22 is connected to the chamber through an oxygen supply pipe. The oxygen supply pipe is equipped with an oxygen concentration regulating valve 36. That is, after the chamber pressure reaches the expected value, the second branch works with the molecular sieve 22 (which is used to generate oxygen) and the oxygen concentration regulating valve 36 to regulate the pressure and concentration of oxygen entering the chamber. In other words, the oxygen concentration in the chamber is increased by the molecular sieve 22 and the oxygen concentration regulating valve 36, which enhances the oxygen partial pressure and promotes the human body's absorption of oxygen.
[0049] It should also be noted that during operation, the heat exchanger 31, the three-way solenoid valve 34, the first filter 32, and the second filter 33 work together to regulate the gas pressure. Furthermore, condensate will be generated in the first filter 32 and the second filter 33. The outlets of the first filter 32 and the second filter 33 can be connected to the collection tank 44 via guide pipes. Simultaneously, the air conditioning system inside the cabin will operate to maintain a constant and suitable temperature inside the cabin. Condensate will also be generated during the operation of the air conditioning system, and its outlet can also be connected to the collection tank 44 via guide pipes. The water treatment device 4 can vaporize the condensate in the collection tank 44 to prevent direct discharge of the condensate.
[0050] In one embodiment, such as Figure 2 As shown, the interior of the housing 1 is divided into an upper region and a lower region. The pressure regulating filter device 3 is located in the upper region, while the oxygen generating and pressurizing device 2 and the water treatment device 4 are located in the lower region, making the device structure more compact and the layout more reasonable. The oxygen generating and pressurizing device 2 is connected to the pressure regulating filter device 3 through a pipeline. The first filter 32 and the second filter 33 of the pressure regulating filter device 3 are connected to the collection tank 44 of the water treatment device 4 through a guide pipe.
[0051] It should be noted that the core components of the highly integrated micro hyperbaric oxygen chamber main unit include an oxygen generating and pressurizing device 2, a pressure regulating and filtering device 3, and a water filtration system. The highly integrated micro hyperbaric oxygen chamber main unit is connected to the chamber body via a gas pipe. That is, the oxygen generating and pressurizing device 2 regulates the appropriate pressure through the pressure regulating and filtering device 3, and oxygen is introduced into the chamber body through the gas pipe. In addition, the air conditioning system inside the chamber operates to maintain a suitable temperature. The condensate generated by the air conditioning system and the condensate generated by the pressure regulating and filtering device 3 are connected to the water treatment device 4 through a guide pipe for vaporization treatment.
[0052] In one embodiment, such as Figure 1 As shown, the bottom of the housing 1 is equipped with casters 5 to facilitate the movement of the highly integrated micro hyperbaric oxygen chamber main unit.
[0053] In one embodiment, such as Figure 3 As shown, the water processor includes a filter device 41, a liquid level sensor 42 located on one side of the collection tank 44, and a humidifier 43 located in the collection tank 44. The guide pipe is connected to the inlet end of the filter device 41, and the outlet end of the filter device 41 is connected to the collection tank 44. The liquid level sensor 42 and the humidifier 43 are both connected to a control device to control the operation of the humidifier 43 after the liquid level sensor 42 is triggered.
[0054] It should be noted that the condensate generated by the air conditioning system inside the cabin and the condensate generated by the pressure regulating filter device 3 can both be connected to the inlet end of the filter device 41 in the lower area of the shell 1 through the guide pipe. After being filtered by the filter device 41, the condensate flows into the collection tank 44. When the condensate level in the collection tank 44 reaches a certain position, the liquid level sensor 42 is triggered to send a signal to the control device. The control device can then control the humidifier 43 to start working in order to process the condensate in the collection tank 44.
[0055] In one embodiment, such as Figure 1 and Figure 2 As shown, the top cover 11 of the housing 1 has an indicator light 12 at its front. The top cover 11 also has a multimedia 13 and a buzzer 14, both of which are connected to the control device. A glass panel 15 is located above the multimedia 13, protecting both the multimedia 13 and the control device. The multimedia 13 refers to a technology or content presentation that integrates multiple media formats (such as text, images, audio, video, animation, etc.) through a computer or other digital device to achieve interactive information transmission. Its core characteristics are diversity and interactivity, enabling more vivid and intuitive presentation of information. Audio and video can be broadcast externally via the buzzer 14, and the indicator light 12 can show whether the device is operating normally.
[0056] It should be further explained that temperature and humidity sensors, oxygen sensors, and pressure sensors can be installed inside the cabin, and all of these sensors are connected to the control device. The control device can transmit the feedback detection data to the multimedia 13, which presents the detection data in a more vivid and intuitive way.
[0057] In one embodiment, the front end of the housing 1 is provided with a front cover 16, and the rear end of the housing 1 is provided with a side cover for inspecting and repairing the internal components of the housing 1. The front cover 16 and the side cover are detachably connected. When the components inside the housing 1 are damaged or need repair, the operator can remove the side cover to facilitate the replacement or repair of the components inside the housing 1.
[0058] In one embodiment, such as Figure 2 and Figure 3 As shown, the housing 1 is equipped with a fan 17 for cooling and heat dissipation. The fan 17 is connected to a control device, and a heat dissipation window 18 is provided on one side of the housing 1.
[0059] It should be noted that a fan 17 can be installed inside the housing 1 to dissipate heat and cool the components, thus preventing damage caused by excessively high temperatures during operation. The heat dissipation window 18 helps to expel high-temperature gases and allow low-temperature gases to enter from the housing 1. The agitation process of the fan 17 can accelerate the cooling process of the components inside the housing 1. Furthermore, once the condensate water level in the collection tank 44 reaches a certain position, the liquid level sensor 42 is triggered to send a signal to the control device. The control device then controls the humidifier 43 to start working, vaporizing the condensate water in the collection tank 44. The vaporization of condensate water refers to the process by which liquid water absorbs heat and converts into water vapor, which helps to lower the temperature inside the housing 1.
[0060] In addition to the highly integrated micro hyperbaric oxygen chamber host described above, this utility model also provides a micro hyperbaric oxygen chamber that includes the highly integrated micro hyperbaric oxygen chamber host disclosed in the above embodiments. For the structure of other parts of the micro hyperbaric oxygen chamber, please refer to the prior art, which will not be repeated here.
[0061] In one embodiment, the system also includes a cabin, with a highly integrated micro hyperbaric oxygen chamber main unit located at the front of the cabin and connected to it via a trachea. An air conditioning system is installed inside the cabin, and the condensate generated by the air conditioning system is connected to the water treatment device 4 of the highly integrated micro hyperbaric oxygen chamber main unit via a guide pipe. That is, the condensate generated by the air conditioning system inside the cabin is connected to the filter device 41 in the water treatment device 4 at the lower level of the highly integrated micro hyperbaric oxygen chamber main unit via a guide pipe. Furthermore, the condensate generated by the pressure regulating filter device 3 can also be connected to the filter device 41 in the water treatment device 4 via a guide pipe. Then, all the condensate flows into a collection tank 44. Once the condensate level in the collection tank 44 reaches a certain level, the level sensor 42 is triggered to send a signal to the control device, which then controls the humidifier 43 to start working to vaporize the condensate in the collection tank 44.
[0062] It should be noted that the first filter 32 and the second filter 33, the first air path and the second air path, the first branch path and the second branch path, the first control valve and the second control valve mentioned in this application are only distinguished by their different positions and do not have any order of precedence.
[0063] In addition, it should be noted that the orientation or positional relationship indicated by "top" and "bottom" in this application is based on the orientation or positional relationship shown in the accompanying drawings, and is only for the purpose of simplifying the description and making it easier to understand, and is not intended to indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model.
[0064] The various embodiments in this specification are described in a progressive manner, with each embodiment focusing on its differences from other embodiments. Similar or identical parts between embodiments can be referred to interchangeably. Any combination of all embodiments provided by this utility model is within the protection scope of this utility model and will not be elaborated upon here.
[0065] The above provides a detailed description of the micro hyperbaric oxygen chamber and its highly integrated main unit provided by this utility model. Specific examples have been used to illustrate the principles and implementation methods of this utility model. The descriptions of the embodiments above are merely for the purpose of helping to understand the method and core ideas of this utility model. It should be noted that those skilled in the art can make various improvements and modifications to this utility model without departing from its principles, and these improvements and modifications also fall within the protection scope of the claims of this utility model.
Claims
1. A highly integrated micro hyperbaric oxygen chamber main unit, characterized in that, include: Shell (1); An oxygen-generating pressurizing device (2) is located inside the housing (1). The oxygen-generating pressurizing device (2) includes an air compressor (21) for pressurizing air to a set pressure and a molecular sieve (22) for generating oxygen. The air compressor (21) is connected to the housing via an air supply pipe. A pressure regulating filter (3) is installed inside the housing (1) and is used to regulate the concentration and pressure of oxygen. The molecular sieve (22) is connected to the pressure regulating filter (3), and the pressure regulating filter (3) is connected to the cabin through an oxygen supply pipe. A water treatment device (4) includes a collection tank (44) located at the bottom of the housing (1) and a water processor located in the collection tank (44). The housing (1) is provided with a guide pipe for introducing the condensate generated by the air conditioning system of the cabin and the pressure regulating filter device (3) into the collection tank (44). The water processor is used to vaporize the condensate in the collection tank (44). The control device is connected to the oxygen generating and pressurizing device (2), the pressure regulating and filtering device (3), and the water processor.
2. The highly integrated micro hyperbaric oxygen chamber main unit according to claim 1, characterized in that, The pressure regulating and filtering device (3) includes a heat exchanger (31), a first filter (32), and a second filter (33). The air compressor (21) has a first air path and a second air path distributed in parallel at its outlet end. The second air path includes a first branch and a second branch arranged in parallel. The first branch and the first air path are both connected to the heat exchanger (31). The heat exchanger (31) is connected to the inlet end of a three-way solenoid valve (34). The two outlet ends of the three-way solenoid valve (34) are respectively provided with a first control valve and a second control valve. The first control valve is connected to the first filter (32), and the second control valve is connected to the second filter (33). The first filter (32) and the second filter (33) are both connected to a throttle valve (35). The throttle valve (35) is connected to the cabin through the air supply pipe. The molecular sieve (22) is connected to the second branch, and the molecular sieve (22) is connected to the cabin through the oxygen supply pipe. The oxygen supply pipe is equipped with an oxygen concentration regulating valve (36). The air compressor (21), the molecular sieve (22), the heat exchanger (31), the three-way solenoid valve (34), the first control valve, the second control valve, and the oxygen concentration regulating valve (36) are all connected to the control device.
3. The highly integrated micro hyperbaric oxygen chamber main unit according to claim 2, characterized in that, The interior of the shell (1) is divided into an upper region and a lower region. The pressure regulating filter (3) is located in the upper region, and the oxygen generating pressurizing device (2) and the water treatment device (4) are located in the lower region.
4. The highly integrated micro hyperbaric oxygen chamber main unit according to any one of claims 1 to 3, characterized in that, The bottom of the housing (1) is provided with casters (5).
5. The highly integrated micro hyperbaric oxygen chamber main unit according to any one of claims 1 to 3, characterized in that, The water processor includes a filter device (41), a liquid level sensor (42) located on one side of the collection tank (44), and a humidifier (43) located in the collection tank (44). The guide pipe is connected to the inlet end of the filter device (41), and the outlet end of the filter device (41) is connected to the collection tank (44). The liquid level sensor (42) and the humidifier (43) are both connected to the control device to control the operation of the humidifier (43) after the liquid level sensor (42) is triggered.
6. The highly integrated micro hyperbaric oxygen chamber main unit according to any one of claims 1 to 3, characterized in that, The top cover (11) of the housing (1) is provided with an indicator light (12) at the front. The top cover (11) is provided with a multimedia (13) and a buzzer (14). The multimedia (13) and the buzzer (14) are both connected to the control device. A glass panel (15) is provided above the multimedia (13).
7. The highly integrated micro hyperbaric oxygen chamber main unit according to any one of claims 1 to 3, characterized in that, The front end of the housing (1) is provided with a front cover (16), and the rear end of the housing (1) is provided with a side cover for inspecting and repairing the internal components of the housing (1). The front cover (16) and the side cover are detachably connected.
8. The highly integrated micro hyperbaric oxygen chamber main unit according to any one of claims 1 to 3, characterized in that, The housing (1) is equipped with a fan (17) for cooling and heat dissipation. The fan (17) is connected to the control device. A heat dissipation window (18) is provided on one side of the housing (1).
9. A micro-hyperbaric oxygen chamber, characterized in that, The high-integration micro hyperbaric oxygen chamber host as described in any one of claims 1 to 8 above.
10. The micro-hyperbaric oxygen chamber according to claim 9, characterized in that, It also includes a cabin body, the highly integrated micro hyperbaric oxygen chamber host is located on the front side of the cabin body and the two are connected by a trachea, the cabin body is equipped with an air conditioning system, and the condensate generated by the air conditioning system is connected to the water treatment device (4) of the highly integrated micro hyperbaric oxygen chamber host through a guide pipe.