CN114099198B - Intelligent oxygen cabin control system and method - Google Patents

Abstract

The application relates to an intelligent oxygen cabin control system and method, which belong to the technical field of medical equipment, and the method comprises the following steps: before use, acquiring external environment information, and adjusting the internal environment state of the oxygen cabin based on the external environment information; acquiring basic information of a user, and adjusting the oxygen supply state of the oxygen cabin based on the basic information; in the use process, the internal environment state and the oxygen supply state of the oxygen cabin are monitored in real time, a monitoring result is generated, the environment state and the oxygen supply state are adjusted based on the monitoring result, or an operation instruction of a user is received, and the internal environment state and the oxygen supply state are adjusted based on the operation instruction. The intelligent oxygen cabin control method has the advantages of reducing manual operation steps and improving the intelligent degree of the oxygen cabin.

Description

Intelligent oxygen cabin control system and method

Technical Field

The application relates to the technical field of medical equipment, in particular to an intelligent oxygen cabin control system and method.

Background

The oxygen cabin is special medical equipment, can be particularly divided into a hyperbaric oxygen cabin and a micro-hyperbaric oxygen cabin, and can be applied to the fields of economy, medical treatment, health management, cosmetology, sports, military, scientific investigation, aviation, families and the like.

For the ordinary people, when using the oxygen cabin, the special medical staff is required to adjust a large number of parameters of the oxygen cabin, including setting environmental information such as temperature and humidity in the oxygen cabin, oxygen supply information such as oxygen flow and oxygen cabin pressure, and the like.

With respect to the related art as described above, the inventors considered that when a medical staff is absent or a user wants to use the oxygen chamber alone, the number of steps of the manual operation is very inconvenient due to the excessive parameters of the oxygen chamber, and thus improvement is required.

Disclosure of Invention

In order to reduce the steps of manual operation and improve the intelligent automation degree of the oxygen cabin, the application provides an intelligent oxygen cabin control system and method.

In a first aspect, the present application provides an intelligent oxygen cabin control method, which adopts the following technical scheme:

an intelligent oxygen cabin control method comprises the following steps:

before use, acquiring external environment information, and adjusting the internal environment state of the oxygen cabin based on the external environment information;

acquiring basic information of a user, and adjusting the oxygen supply state of the oxygen cabin based on the basic information;

in the use process, the internal environment state and the oxygen supply state of the oxygen cabin are monitored in real time, a monitoring result is generated, the environment state and the oxygen supply state are adjusted based on the monitoring result,

Or alternatively

And receiving an operation instruction of a user, and adjusting the internal environment state and the oxygen supply state based on the operation instruction.

Through adopting above-mentioned technical scheme, obtain external environment information, according to external environment information automatic adjustment oxygen cabin internal environment state, obtain user's use reason, the inside oxygen supply state of oxygen cabin is tentatively confirmed according to use reason to adapt to most user, the user can also adjust oxygen cabin internal environment state and oxygen supply state at any time in the use simultaneously. The setting of this application has reduced user's manual operation step, has improved the intelligent degree of oxygen cabin, and the user still can adjust oxygen cabin internal environment state and oxygen supply state at any time according to self demand in the use, has improved the multifunctionality and the suitability of oxygen cabin.

Optionally, the external environment information includes an external temperature, an external humidity and an external PM2.5 value, and the adjusting the internal environment state of the oxygen cabin based on the external environment information includes the following steps:

comparing and analyzing the external temperature with a preset human body comfort temperature range, and adjusting the internal temperature of the oxygen cabin to the human body comfort temperature range if the external temperature exceeds the human body comfort temperature range;

Comparing and analyzing the external humidity with a preset human body comfort humidity range, and adjusting the internal humidity of the oxygen cabin to the human body comfort humidity range if the external humidity exceeds the human body comfort temperature range;

and comparing and analyzing the external PM2.5 value with a preset PM2.5 normal range, and purifying the air in the oxygen cabin if the external PM2.5 value exceeds the normal range.

By adopting the technical scheme, the oxygen cabin automatically adjusts the internal environment state, reduces the operation steps of users, and is very convenient.

Optionally, the basic information includes age and use reason, the oxygen supply requirement includes oxygen flow and oxygen cabin pressure, and the adjusting the oxygen supply state of the oxygen cabin based on the basic information includes the following steps:

judging whether the age of the user exceeds a preset age threshold range or not;

if the age of the user is within a preset age threshold range, preliminarily determining that the oxygen cabin pressure is in a normal pressure state;

and if the age of the user exceeds a preset age threshold, preliminarily determining that the oxygen cabin pressure is in a low-pressure state.

Through adopting above-mentioned technical scheme, preliminary oxygen cabin pressure is confirmed according to user's age to adapt to most user's demand, reduced user's operation step equally, it is very convenient.

Optionally, the adjusting the oxygen supply state of the oxygen cabin based on the basic information further includes the following steps:

determining the health type of a user according to the use reason of the user, and selecting corresponding oxygen flow based on the health type, wherein the health type comprises healthy people, sub-healthy people and disease people;

if the health type is determined to be a disease crowd, initially determining that the oxygen flow in the oxygen cabin is in a flow increasing mode;

and if the health type is determined to be healthy people or sub-healthy people, preliminarily determining that the oxygen flow in the oxygen cabin is in a conventional mode.

By adopting the technical scheme, the oxygen flow in the oxygen cabin is determined according to the use reasons of the user, so that the operation steps of the user are further reduced, and the operation is more convenient.

Optionally, the operation command includes a temperature adjustment command, a humidity adjustment command, an air quality adjustment command, an oxygen concentration adjustment command, a pressure boost adjustment command, and a pressure release adjustment command.

By adopting the technical scheme, a user can select to send out an operation instruction suitable for the user according to the situation of the user, so that the versatility and the applicability of the oxygen cabin are improved.

In a second aspect, the present application provides an intelligent oxygen cabin control system, which adopts the following technical scheme:

an intelligent oxygen cabin control system comprises a cabin body, an acquisition subsystem, a monitoring subsystem, an environment regulation subsystem, an oxygen supply regulation subsystem, a control subsystem and an operation terminal, wherein the acquisition subsystem, the monitoring subsystem, the environment regulation subsystem and the oxygen supply regulation subsystem are arranged on the cabin body, and the operation terminal is respectively connected with the acquisition subsystem, the monitoring subsystem, the environment regulation subsystem and the oxygen supply regulation subsystem;

the acquisition subsystem is used for acquiring external environment information and basic information of users;

the monitoring subsystem is used for monitoring the internal environment state and the oxygen supply state of the oxygen cabin in real time and obtaining a monitoring result;

the environment adjusting subsystem is used for adjusting the internal environment state of the cabin;

the oxygen supply adjusting subsystem is used for adjusting the oxygen supply state in the cabin body;

the operation terminal is used for receiving an operation instruction of a user and sending the operation instruction to the control subsystem;

the control subsystem is used for generating a control instruction based on the external environment information, the basic information, the monitoring result and the operation instruction, and controlling the environment adjusting subsystem and the oxygen supply adjusting subsystem to adjust the environment state and the oxygen supply state in the cabin body based on the control instruction.

By adopting the technical scheme, the control module automatically generates a proper cabin internal environment state and an oxygen supply state according to the external environment information acquired by the acquisition subsystem and the basic information of a user; if the user needs to adjust the internal environment state and the oxygen supply state of the cabin in the using process, the user can select the intended option through the operation terminal. The method reduces the steps of manual setting by users and improves the automation degree of the oxygen cabin; meanwhile, the oxygen cabin can be compatible with personal selection of users, and the versatility and applicability of the oxygen cabin are reflected.

Optionally, the environment adjustment subsystem includes:

the temperature adjusting module is used for adjusting the temperature in the cabin based on the control instruction;

the humidity adjusting module is used for adjusting the humidity in the cabin based on the control instruction;

and the air quality adjusting module is used for purifying the air in the cabin based on the control instruction.

By adopting the technical scheme, the environment adjusting subsystem adjusts the temperature, the humidity and the air according to the control instruction, so that the degree of automation of the system is improved.

Optionally, the oxygen supply regulation subsystem comprises;

the flow regulating module is used for regulating the oxygen flow in the cabin based on the control instruction;

and a pressure adjustment module for adjusting the oxygen cabin pressure based on the control command.

By adopting the technical scheme, the oxygen supply adjusting subsystem adjusts the oxygen flow and the pressure of the oxygen cabin according to the control instruction, so that the operation steps of users are reduced, and the automation degree of the system is further improved.

Optionally, the pressure adjustment module includes:

the boosting unit is used for performing boosting operation on the interior of the cabin according to the control instruction;

the protection unit is used for performing air pressure balancing operation on the cabin when the pressure monitoring unit monitors that the interior of the cabin has reached a preset air pressure value;

and the pressure relief unit is used for performing pressure relief operation on the interior of the cabin body based on the operation instruction.

Optionally, the operation terminal includes:

the display module is used for displaying the internal environment information of the oxygen cabin and the oxygen supply state;

And the operation module is used for issuing operation instructions by users.

Drawings

FIG. 1 is a schematic diagram of the overall modules of an intelligent oxygen cabin control system according to an embodiment of the present application.

FIG. 2 is a schematic block diagram of an acquisition subsystem in an intelligent oxygen cabin control system according to an embodiment of the present application.

FIG. 3 is a schematic block diagram of a monitoring subsystem in an intelligent oxygen cabin control system according to an embodiment of the present application.

FIG. 4 is a schematic block diagram of an environmental conditioning subsystem and an oxygen supply conditioning subsystem in an intelligent oxygen cabin control system according to an embodiment of the present application.

Fig. 5 is a schematic structural diagram of a boosting unit, a protecting unit and a pressure releasing unit in an intelligent oxygen cabin control system according to an embodiment of the present application.

Fig. 6 is a schematic block diagram of an operation terminal and a control subsystem in an intelligent oxygen cabin control system according to an embodiment of the present application.

Fig. 7 is an overall flow chart of an intelligent oxygen cabin control method according to an embodiment of the present application.

Fig. 8 is a schematic flow chart of step S201 to step S203 in the intelligent oxygen cabin control method according to the embodiment of the present application.

Fig. 9 is a schematic flow chart of step S301 to step S303 in an intelligent oxygen cabin control method according to an embodiment of the present application.

Fig. 10 is a schematic flow chart of steps S401 to S403 in the intelligent oxygen cabin control method according to the embodiment of the present application.

Reference numerals illustrate:

1. a cabin body; 2. an acquisition subsystem; 21. an environmental information acquisition module; 22. a basic information acquisition module; 221. a recording unit; 222. a storage unit; 3. a monitoring subsystem; 31. an internal environment monitoring module; 32. an oxygen supply monitoring module; 321. a flow monitoring unit; 322. a pressure monitoring unit; 4. an environmental conditioning subsystem; 41. a temperature adjustment module; 42. a humidity adjustment module; 43. an air quality adjustment module; 5. an oxygen supply regulation subsystem; 51. a flow rate adjustment module; 52. a pressure regulating module; 521. a boosting unit; 522. a protection unit; 523. a pressure relief unit; 6. an operation terminal; 61. a display module; 62. an operation module; 7. a control subsystem; 71. a first control module; 711. a storage unit; 712. a comparison unit; 72. a second control module; 721. an analysis unit; 722. a memory unit; 73. a third control module; 74. and a fourth control module.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-10.

The embodiment of the application discloses an intelligent oxygen cabin control system, referring to fig. 1, including a cabin body 1 and an acquisition subsystem 2, a monitoring subsystem 3, an environment adjusting subsystem 4, an oxygen supply adjusting subsystem 5, an operation terminal 6 and a control subsystem 7 which are arranged on the cabin body 1. The acquisition subsystem 2 is used for acquiring external environment information and basic information of users; the monitoring subsystem 3 is used for monitoring the environmental state and the oxygen supply state in the oxygen cabin in real time and obtaining a monitoring result; the environment adjusting subsystem 4 is used for adjusting the internal environment state of the cabin body 1; the oxygen supply adjusting subsystem 5 is used for adjusting the oxygen supply state in the cabin body 1; the operation terminal 6 is used for receiving an operation instruction of a user and sending the operation instruction to the control subsystem 7; the control subsystem 7 is configured to generate a control instruction based on the external information, the basic information, the monitoring result, and the operation instruction, and control the environmental conditioning subsystem 4 and the oxygen supply conditioning subsystem 5 to adjust the environmental status and the oxygen supply status inside the cabin 1 based on the control instruction.

Referring to fig. 2, the acquisition subsystem 2 includes an environmental information acquisition module 21 and a basic information acquisition module 22, where the environmental information acquisition module 21 is configured to acquire external environmental information, and the external environmental information includes an external temperature, an external humidity, an external PM2.5 value, and the like. The basic information collection module 22 is used for collecting basic information of the user, wherein the basic information includes age and use reason of the user.

Specifically, in this embodiment, the acquiring subsystem 2 may be a network device connected to the internet, such as a computer, and it is known that the computer may be installed inside the cabin 1 or outside the cabin 1. The environmental information obtaining module 21 may be a system in a tablet computer, and may obtain local real-time temperature, humidity and PM2.5 values, and send the real-time external temperature, external humidity and external PM2.5 values to the control subsystem 7. In addition, the environmental information acquisition module can also be a thermometer, a hygrometer and a PM2.5 detector which are arranged outside the cabin body 1, detect the temperature, the humidity and the PM2.5 value outside the cabin body 1 in real time, and send the detected external temperature, external humidity and external PM2.5 value into the tablet personal computer.

Specifically, the basic information collection module 22 includes a recording unit 221 and a storage unit 222, and before the first use, a user records the basic information of the user in the recording unit 221, in this embodiment, the recording mode of the recording unit 221 may be directly recorded on a computer, or the public number two-dimensional code of the oxygen cabin is scanned and recorded by a mobile phone. The storage unit 222 may be a cloud disk, and is configured to correlate and store basic information of the user for reuse.

More specifically, the user needs to select and fill out his own age and use reasons from the background, including the following categories:

1. for healthy people: relieving pressure, resisting fatigue, relieving alcoholic intoxication, activating skin for women, etc.;

2. for sub-health people: auxiliary physiotherapy for sub-health symptoms such as insomnia, headache, dysphoria, anxiety and the like;

3. for the disease population: auxiliary physiotherapy for cardiovascular and cerebrovascular diseases, hypertension, hyperglycemia, hyperlipidemia, depression, cerebral palsy, gout, etc.

The recording age and reason for use may be in the following pattern: wang Mou, age: 55, use reason: physical therapy of cerebral thrombosis; li Mou, age: 28, use reason: relief pressure … …

Referring to fig. 3, the monitoring subsystem 3 includes an internal environment monitoring module 31 and an oxygen supply monitoring module 32, where the internal environment monitoring module 31 is configured to monitor an internal environment state of the cabin 1, and the internal environment state includes an internal temperature, an internal humidity, an internal PM2.5 value, and the like; the oxygen supply monitoring module 32 is used for monitoring the oxygen supply state inside the oxygen cabin in real time, wherein the oxygen supply state comprises the oxygen flow and the oxygen cabin pressure.

Specifically, the internal environment monitoring module 31 includes a temperature monitoring unit, a humidity monitoring unit, and a PM2.5 monitoring unit, where the temperature monitoring unit is a temperature sensor disposed inside the cabin 1, monitors the internal temperature of the cabin 1 in real time, and sends the internal temperature to the control subsystem 7; the humidity monitoring unit is a humidity sensor arranged in the cabin body 1, monitors the humidity in the cabin body 1 in real time and sends the internal humidity to the control subsystem 7; the PM2.5 monitoring unit is a PM2.5 detector arranged in the cabin body 1, monitors the PM2.5 value in the cabin body 1 in real time, and sends the PM2.5 value to the control subsystem 7.

Specifically, the oxygen supply monitoring module 32 includes a flow monitoring unit 321 and a pressure monitoring unit 322, the cabin body 1 is connected with an oxygen generator, the oxygen generator is used for conveying oxygen to the cabin body 1 through an oxygen pipe, and the flow monitoring unit 321 is used for monitoring the oxygen flow in the oxygen pipe. The pressure monitoring unit 322 is an air pressure detecting sensor provided inside the cabin 1, which monitors the oxygen cabin pressure in real time and sends the oxygen cabin pressure to the control subsystem 7.

Referring to fig. 4, the environment conditioning subsystem 4 includes a temperature conditioning module 41, a humidity conditioning module 42, and an air quality conditioning module 43, where the temperature conditioning module 41 is configured to condition the temperature inside the cabin 1; the humidity adjusting module 42 is used for adjusting the humidity inside the cabin 1; the air quality adjusting module 43 is used for purifying the air in the cabin 1.

Specifically, in the present embodiment, the temperature adjustment module 41 is an air conditioner provided inside the oxygen chamber, capable of adjusting the temperature inside the chamber body 1; the humidity adjusting module 42 is a humidifier arranged in the oxygen cabin, and can perform humidification adjustment on the interior of the cabin 1 when the interior of the cabin 1 is dry; the air quality control module 43 is an air cleaner provided inside the cabin 1, and purifies air inside the cabin 1 when the PM2.5 value inside the cabin 1 is too high.

The oxygen supply regulation subsystem 5 comprises a flow regulation module 51 and a pressure regulation module 52, wherein the flow regulation module 51 regulates the flow of oxygen in an oxygen pipe so as to achieve the purpose of controlling the flow of oxygen; the pressure regulating module 52 is used for regulating the pressure in the cabin 1.

Specifically, the flow adjusting module 51 is a stepper motor of the oxygenerator, and adjusts the power of the oxygenerator by adjusting the rotation speed of the oxygenerator so as to provide oxygen flow with different sizes, thereby being capable of meeting various demands of users.

Specifically, referring to fig. 4 and 5, the pressure regulating module 52 includes a pressure increasing unit 521, a protecting unit 522, and a pressure releasing unit 523, the pressure increasing unit 521 being configured to perform a pressure increasing operation on the cabin 1; the protection unit 522 is used for performing an operation of balancing the air pressure when the pressure of the oxygen chamber reaches a preset pressure value; the pressure relief unit 523 is configured to perform a pressure relief operation on the cabin 1.

More specifically, in the present embodiment, the booster unit 521 includes a plurality of intake pipes communicating with the cabin 1 and an intake solenoid valve provided on the intake pipes, and a booster device is connected to an end of the intake pipe remote from the cabin 1. The air inlet solenoid valves are arranged in one-to-one correspondence with the air inlet pipes, the air inlet solenoid valves control the opening and closing of the corresponding air inlet pipes, and when the air inlet solenoid valves are opened, the pressure in the oxygen cabin is increased.

More specifically, referring to fig. 5, the protection unit 522 includes a plurality of relief valves provided on the intake pipe, the relief valves being provided with relief pressure values, and the relief valves being automatically opened when the pressure at the relief valves reaches the relief pressure values of the relief valves. In the embodiment, the safety valves are arranged in one-to-one correspondence with the air inlet electromagnetic valves, and when one of the air inlet electromagnetic valves is opened, a passage is formed between the inside of the cabin body 1 and the air inlet electromagnetic valve and the corresponding safety valve; when the air inlet electromagnetic valve is not opened, a passage cannot be formed between the air inlet electromagnetic valve and the corresponding safety valve in the cabin body 1.

When one of the air inlet electromagnetic valves is controlled to be opened and the corresponding safety valve of the air inlet electromagnetic valve is not opened, the interior of the cabin body 1 is boosted under the action of boosting equipment; when the pressure in the cabin body 1 is increased to the safety pressure value of the safety valve, the safety valve is opened, and the oxygen cabin performs the air leakage operation, so that the pressure in the cabin body 1 is maintained at the safety pressure value of the safety valve. In this embodiment, the number of the air inlet pipes is five, and correspondingly, the number of the air inlet solenoid valves and the safety valves is five, and the safety pressure values of the five safety valves are different.

For example, the safety pressure values of the five intake solenoid valves and the corresponding safety valves are set to:

intake solenoid valve 01—safety valve 01:1.1 atmospheres gauge;

intake solenoid valve 02—safety valve 02:1.15 standard atmospheres;

intake solenoid valve 03—safety valve 03:1.2 standard atmospheres;

intake solenoid valve 04-safety valve 04:1.25 standard atmospheres;

intake solenoid valve 05—safety valve 05:1.3 standard atmospheres.

When the pressure is required to be regulated to 1.1 standard atmospheric pressure, the air inlet electromagnetic valve 01 is controlled to be opened, the rest air inlet electromagnetic valves are closed, at the moment, the safety valve 01 forms a passage through the air inlet electromagnetic valve 01, and when the pressure in the cabin body 1 reaches 1.1 standard atmospheric pressure, the safety valve 01 is opened to perform air leakage operation, so that the pressure of the oxygen cabin is kept at 1.1 standard atmospheric pressure.

Specifically, referring to fig. 5, the pressure relief unit 523 includes a plurality of pressure relief pipes communicating with the cabin 1 and pressure relief solenoid valves provided on the pressure relief pipes, the pressure relief solenoid valves being provided in one-to-one correspondence with the pressure relief pipes. In this embodiment, the number of the pressure relief pipes is three, and the number of the pressure relief solenoid valves is three, and in other embodiments, the number of the pressure relief pipes may be other. For convenience of explanation, the pressure relief pipe and the corresponding pressure relief solenoid valve are set as:

Pressure relief pipe 01-pressure relief electromagnetic valve 01;

pressure relief pipe 02-pressure relief solenoid valve 02;

pressure relief pipe 03-pressure relief electromagnetic valve 03.

When the pressure relief operation is needed, the pressure relief electromagnetic valve 01 is controlled to be opened, so that the oxygen cabin can be slowly relieved; the pressure relief electromagnetic valve 01 and the pressure relief electromagnetic valve 02 are controlled to be opened, so that the oxygen cabin can be rapidly depressurized; the pressure relief electromagnetic valve 01, the pressure relief electromagnetic valve 02 and the pressure relief electromagnetic valve 03 are controlled to be opened, so that the oxygen cabin can be subjected to rapid pressure relief.

Referring to fig. 6, the operation terminal 6 includes a display module 61 and an operation module 62, where the display module 61 is used to display an operation state of the oxygen cabin, and the operation state includes an internal environment state and an oxygen supply state; the operation module 62 is used for a user to issue an operation command to adjust the internal environment state and the oxygen supply state of the oxygen cabin.

Specifically, in the present embodiment, the operation terminal 6 may be a touch display screen provided inside the oxygen chamber, and in fact, the operation terminal 6 may be integrated with the acquisition subsystem 2 in the form of a tablet computer mounted inside the chamber body 1. The display module 61 includes a plurality of display units for respectively displaying real-time oxygen chamber pressure, oxygen flow, oxygen chamber internal temperature, oxygen chamber internal humidity, oxygen chamber internal PM2.5 level, oxygen concentration, anion concentration, and use time, and is convenient for a user to check.

Specifically, the operation module 62 includes a pressure increasing operation unit, a pressure releasing operation unit, a flow operation unit, a temperature operation unit, a humidity operation unit, an air quality operation unit, and a negative ion operation unit.

More specifically, the boost operation unit is for the user to select the intended oxygen cabin pressure, and in this embodiment, the boost operation unit includes five levels for the user to select, respectively, 1.1 atmospheres, 1.15 atmospheres, 1.2 atmospheres, 1.25 atmospheres, and 1.3 atmospheres, and after the user selects, the boost operation unit generates a boost adjustment instruction and sends the boost adjustment instruction to the control subsystem 7.

More specifically, the pressure release operation unit is used for a user to select an intended pressure release speed, and in this embodiment, during the use, the pressure release operation unit automatically selects a pressure release closing option. In the use, the pressure release operation unit provides three grades for the user to select, is slow pressure release, quick pressure release and quick pressure release respectively, and after the user selected corresponding option, the pressure release operation unit produced pressure release adjustment command to send pressure release adjustment command to control subsystem 7.

More specifically, the flow rate operation unit is used to select the intended oxygen flow rate, and in this embodiment, the flow rate operation unit may provide three levels for the user to select, respectively, a normal mode, a gentle mode, in which the oxygen flow rate is relatively low, and a flow increasing mode, in which the oxygen flow rate is relatively high. After the user selects the corresponding option, the flow rate operation unit generates a flow rate adjustment instruction and sends the flow rate adjustment instruction to the control subsystem 7.

More specifically, the temperature operation unit is used for the user to select the intended internal temperature of the oxygen cabin, and in this embodiment, the temperature operation unit can provide a plurality of internal temperatures of the oxygen cabin for the user to adjust according to the self-adaptation condition. After the user selects the corresponding option, the temperature operating unit generates a temperature adjustment instruction and sends the temperature adjustment instruction to the control subsystem 7.

More specifically, in the present embodiment, the humidity operation unit is provided for a user to select a dehumidification or humidification function, and when the user selects a corresponding option, the humidity operation unit generates a humidity adjustment instruction and sends the humidity adjustment instruction to the control subsystem 7.

More specifically, in the present embodiment, the air quality operation unit is used for a user to select whether to turn on the air purification function, and when the user selects the corresponding option, the air quality operation unit generates an air quality adjustment unit and sends an air quality adjustment instruction to the control subsystem 7.

More specifically, in the present embodiment, the negative ion operation unit is used for a user to select whether or not to turn on the function of increasing the negative ion concentration, and when the user selects the corresponding option, the negative ion operation unit generates a negative ion adjustment instruction and sends the negative ion adjustment instruction to the control subsystem 7.

Referring to fig. 6, the control subsystem 7 includes a first control module 71, a second control module 72, and a third control module 73, where the first control module 71 is configured to receive external environment information acquired by the acquisition subsystem 2, analyze the external environment information, and generate a first control instruction; the second control module 72 is configured to receive basic information of a user, analyze the basic information, and generate a second control instruction; the third control module 73 is configured to analyze the monitoring result generated by the monitoring subsystem 3, and control the environment adjustment subsystem 4 to adjust the internal environment of the cabin 1 and the oxygen supply adjustment subsystem 5 to adjust the oxygen supply state of the cabin 1; the fourth control module 74 is configured to receive an operation instruction from the operation terminal 6, and control the environment adjustment subsystem 4 to adjust the internal environment of the cabin 1 and the oxygen supply adjustment subsystem 5 to adjust the oxygen supply state of the cabin 1 according to the operation instruction.

Specifically, the first control module 71 includes a storage unit 711 and a comparison unit 712, where the storage unit 711 is configured to store a preset human body comfort temperature range, a preset human body comfort humidity range, and a PM2.5 normal range, and the comparison unit 712 compares the external temperature, the external humidity, and the external PM2.5 value with the preset human body comfort temperature range, the preset human body comfort humidity range, and the preset PM2.5 normal range in the storage unit 711.

If the external temperature exceeds the comfortable temperature range of the human body, a first temperature control instruction is generated to adjust the internal temperature of the cabin body 1. For example, the preset human comfort temperature ranges are: 23-28 deg.c (summer); 10-20 deg.c (winter). When the external temperature is higher than 28 ℃ in summer, the comparison unit 712 determines that the external temperature exceeds the comfortable temperature range of the human body, and generates a first temperature control instruction to control the air conditioner inside the cabin body 1 to reduce the internal temperature of the cabin body 1 to 26 ℃; when the outside temperature is lower than 10 c in winter, the comparison unit 712 determines that the outside temperature exceeds the human body comfort temperature range and generates a first temperature control instruction to control the air conditioner inside the cabin 1 to raise the inside temperature of the cabin 1 to 16 c.

If the external humidity exceeds the comfortable temperature range of the human body, a first humidity control instruction is generated to adjust the internal humidity of the cabin body 1. For example, the predetermined human comfort humidity range is 30% -80%. When the external humidity is less than 30%, the comparison unit 712 determines that the external humidity is lower than the comfortable humidity range of the human body, and generates a first humidity control instruction to control the humidifier inside the cabin 1 to perform humidification treatment; when the external humidity is higher than 80%, the comparing unit 712 determines that the external humidity is higher than the comfortable humidity range of the human body, and generates a first humidity control instruction to dehumidify the cabin 1, that is, turn off the humidifier, and wait for the air in the cabin 1 to be exhausted.

If the outside PM2.5 value exceeds the normal range, a first air control instruction is generated to purify the air in the cabin 1. For example, the normal range of the predetermined PM2.5 value is 0-35 μg/m. When the outside PM2.5 value is higher than 35 μg/m, the comparing unit 712 determines that the PM2.5 value is out of the normal range, and generates a first air control command to control the air purifier to purify the air inside the cabin 1.

The first control module 71 can control the environment adjustment subsystem 4 to adjust the environment state inside the cabin body 1, so that the environment state is suitable for most people, steps needing manual operation are reduced, and the intelligent automation degree of the oxygen cabin is improved.

Specifically, the second control module 72 includes an analysis unit 721 and a memory unit 722, wherein the analysis unit 721 is configured to analyze basic information of a user, generate an appropriate oxygen supply state of the user, and generate a second control instruction based on the oxygen supply state; the memory unit 722 correlates and stores the basic information of the user with the appropriate oxygen supply state, so that the user can use the device again.

More specifically, the analysis unit 721 analyzes the age of the user, and preliminarily selects an appropriate oxygen chamber pressure. For example, the preset age threshold range is 16-50 years old, and when the age of the user is 28 years old, the analysis unit 721 determines that the age threshold range is not exceeded, and preliminarily generates a first pressure control instruction of "normal person" to control the oxygen cabin pressure to be a normal oxygen cabin pressure, for example, 1.2 atmospheres; when the age of the user is 55 years, the analysis unit 721 determines that the age threshold range is exceeded, and preliminarily generates a first pressure control instruction of "the elderly", adjusting the oxygen chamber pressure to a low pressure, for example, 1.1 atm.

More specifically, the analysis unit 721 analyzes the use cause selected by the user, determines the health type of the user, and primarily selects an appropriate oxygen flow rate. For example, when the reason for using is cerebral thrombosis physiotherapy, the analysis unit 721 determines that the user is a symptom group, and primarily determines that the oxygen flow in the oxygen cabin is in an increasing mode, at this time, the analysis unit 721 generates a first flow control instruction of "increasing mode", and controls the power of the stepper motor of the oxygenerator to increase; when the reason for the use is to relieve the pressure, the analysis unit 721 determines that the user is healthy, and preliminarily determines that the oxygen flow in the oxygen cabin is in the normal mode, and at this time, the analysis unit 721 generates a first flow control instruction of the normal mode to control the stepper motor of the oxygenerator to be in a normal working state.

The second control module 72 can analyze the use cause of the user and preliminarily determine the oxygen supply state so as to adapt to the normal demands of most users, reduce the steps of manual operation and further improve the intelligent automation degree of the oxygen cabin.

Specifically, during the use, if the internal environmental state is monitored to exceed the preset range or the oxygen supply state is abnormal, the third control module 73 generates a third control instruction according to the monitoring result, and the environmental conditioning subsystem 4 and the oxygen supply conditioning subsystem 5 regulate the internal environmental state and the oxygen supply state of the cabin 1 according to the third control instruction.

Specifically, the fourth control module 74 generates a fourth control instruction according to the operation instruction of the user, and controls the environment adjusting subsystem 4 to adjust the internal environment of the cabin 1 and the oxygen supply adjusting subsystem 5 to adjust the oxygen supply state of the cabin 1 according to the fourth control instruction, and the specific processing flow can be known from the steps in the operation terminal 6. In the actual use process, if the user feels uncomfortable or wants to adjust the internal environment state or the oxygen supply state of the cabin body 1 for other reasons, the user can operate the operation terminal 6.

It should be noted that, in the present embodiment, the fourth control instruction has a higher priority than the first control instruction, the second control instruction, and the third control instruction.

The implementation principle of the intelligent oxygen cabin control system in the embodiment of the application is as follows: the control module automatically generates a proper internal environment state and oxygen supply state of the cabin body 1 according to the external environment information acquired by the acquisition subsystem 2 and the basic information of a user; if the user needs to adjust the internal environment state and the oxygen supply state of the cabin 1 during the use process, the user can select the intended option through the operation terminal 6. The method reduces the steps of manual setting by users and improves the automation degree of the oxygen cabin; meanwhile, the oxygen cabin can be compatible with personal selection of users, and the versatility and applicability of the oxygen cabin are reflected.

The embodiment also discloses an intelligent oxygen cabin control method, which is applied to the intelligent oxygen cabin control system, and referring to fig. 7, and comprises the following steps:

s101, before use, acquiring external environment information, and adjusting the internal environment state of the oxygen cabin based on the external environment information;

s102, acquiring basic information of a user, and adjusting the oxygen supply state in the oxygen cabin based on the basic information;

s103, in the use process, the environment state and the oxygen supply state in the oxygen cabin are monitored in real time, a monitoring result is generated, and the environment state and the oxygen supply state are adjusted based on the monitoring result, or

S104, receiving an operation instruction of a user, and adjusting the environment state and the oxygen supply state based on the operation instruction.

In step S101, before the user starts using the oxygen cabin, the external environment information is analyzed, so as to automatically adjust the internal environment state of the oxygen cabin.

In this embodiment, the external environment information is acquired through the acquisition subsystem, where the acquisition subsystem includes an environment information acquisition module and a basic information acquisition module, and the environment information acquisition module is configured to acquire the external environment information, where the external environment information includes an external temperature, an external humidity, an external PM2.5 value, and the like. The basic information acquisition module is used for acquiring basic information of users, wherein the basic information comprises ages and use reasons of the users and the like.

Specifically, in this embodiment, the acquisition subsystem may be a network device connected to the internet, such as a computer, where it is known that the computer may be installed inside the cabin or outside the cabin. The environment information acquisition module can be a system in the tablet personal computer, can acquire local real-time temperature, humidity and PM2.5 values, and sends the real-time external temperature, external humidity and external PM2.5 values to the control subsystem. In addition, the environmental information acquisition module can also be a thermometer, a hygrometer and a PM2.5 detector which are arranged outside the cabin body, and can detect the temperature, the humidity and the PM2.5 value outside the cabin body in real time and send the detected external temperature, external humidity and external PM2.5 value into the tablet personal computer.

Referring to fig. 8, after the external environment information is acquired, adjusting the internal environment state of the oxygen chamber based on the external environment information includes the steps of:

s201, comparing and analyzing the external temperature with a preset human body comfort temperature range, and if the external temperature exceeds the human body comfort temperature range, adjusting the internal temperature of the oxygen cabin to the human body comfort temperature range;

s202, comparing and analyzing the external humidity with a preset human body comfortable humidity range, and if the external humidity exceeds the human body comfortable temperature range, adjusting the internal humidity of the oxygen cabin to the human body comfortable humidity range;

S203, comparing and analyzing the external PM2.5 value with a preset PM2.5 normal range, and purifying the air in the oxygen cabin if the external PM2.5 value exceeds the normal range.

Specifically, in this embodiment, the first control module analyzes the external environment information and adjusts the internal environment state of the oxygen chamber. The first control module comprises a storage unit and a comparison unit, wherein the storage unit is used for storing a preset human body comfort temperature range, a preset human body comfort humidity range and a PM2.5 normal range, and the comparison unit is used for comparing the external temperature, the external humidity and the external PM2.5 value with the preset human body comfort temperature range, the preset human body comfort humidity range and the preset PM2.5 normal range in the storage unit.

If the external temperature exceeds the comfortable temperature range of the human body, a first temperature control instruction is generated, and the internal temperature of the cabin body is adjusted. For example, the preset human comfort temperature ranges are: 23-28 deg.c (summer); 10-20 deg.c (winter). When the external temperature in summer is higher than 28 ℃, the comparison unit determines that the external temperature exceeds the comfortable temperature range of the human body, generates a first temperature control instruction, and controls an air conditioner in the cabin to reduce the internal temperature of the cabin to 26 ℃; when the external temperature in winter is lower than 10 ℃, the comparison unit determines that the external temperature exceeds the comfortable temperature range of the human body, and generates a first temperature control instruction to control an air conditioner in the cabin to raise the internal temperature of the cabin to 16 ℃.

If the external humidity exceeds the comfortable temperature range of the human body, a first humidity control instruction is generated, and the humidity in the cabin body is adjusted. For example, the predetermined human comfort humidity range is 30% -80%. When the external humidity is less than 30%, the comparison unit determines that the external humidity is lower than the comfortable humidity range of the human body, generates a first humidity control instruction, and controls a humidifier in the cabin to perform humidification treatment; when the external humidity is higher than 80%, the comparison unit determines that the external humidity is higher than the comfortable humidity range of the human body, generates a first humidity control instruction, dehumidifies the cabin body, namely closes the humidifier, and waits for the air in the cabin body to be discharged.

And if the external PM2.5 value exceeds the normal range, generating a first air control instruction to purify the air in the cabin. For example, the normal range of the predetermined PM2.5 value is 0-35 μg/m. When the external PM2.5 value is higher than 35 mug/m, the comparison unit determines that the PM2.5 value exceeds the normal range and generates a first air control instruction to control the air purifier to purify the air in the cabin.

In step S102, basic information of the user is collected by the basic information collection module.

Specifically, the basic information acquisition module includes a recording unit and a storage unit, and before first use, a user records own basic information in the recording unit. The storage unit may be a cloud disk, and is configured to correlate and store basic information of the user, so as to use the basic information again.

More specifically, the user needs to select and fill out his own age and use reasons from the background, including the following categories:

1. for healthy people: relieving pressure, resisting fatigue, relieving alcoholic intoxication, activating skin for women, etc.;

2. for sub-health people: auxiliary physiotherapy for sub-health symptoms such as insomnia, headache, dysphoria, anxiety and the like;

3. for the disease population: auxiliary physiotherapy for cardiovascular and cerebrovascular diseases, hypertension, hyperglycemia, hyperlipidemia, depression, cerebral palsy, gout, etc.

The recording age and reason for use may be in the following pattern: wang Mou, age: 55, use reason: physical therapy of cerebral thrombosis; li Mou, age: 28, use reason: relief pressure … …

Specifically, referring to fig. 9 and 10, after the basic information is acquired, the oxygen supply state of the oxygen chamber is adjusted based on the basic information, the oxygen supply state including the oxygen flow rate and the oxygen chamber pressure, specifically including the steps of:

s301, judging whether the age of a user exceeds a preset age threshold range;

s302, if the age of the user is within a preset age threshold range, primarily determining that the oxygen cabin pressure is in a normal pressure state;

s303, if the age of the user exceeds a preset age threshold, preliminarily determining that the oxygen cabin pressure is in a low-pressure state.

S304, determining the health type of the user according to the use reason of the user, and selecting corresponding oxygen flow based on the health type, wherein the health type comprises healthy people, sub-healthy people and disease people;

s305, if the health type is determined to be the disease population, primarily determining that the oxygen flow in the oxygen cabin is in a flow increasing mode;

s306, if the health type is determined to be healthy people or sub-healthy people, the oxygen flow in the oxygen cabin is initially determined to be in a conventional mode.

Specifically, in this embodiment, the second control module is used to analyze the basic information. The second control module comprises an analysis unit and a memory unit, wherein the analysis unit is used for analyzing basic information of a user, generating a proper oxygen supply state of the user, and generating a second control instruction based on the oxygen supply state; the memory unit is used for associating and storing the basic information of the user with the proper oxygen supply state, so that the user can use the device again.

More specifically, the analysis unit analyzes the age of the user, and initially selects an appropriate oxygen cabin pressure. For example, the preset age threshold range is 16-50 years old, and when the age of the user is 28 years old, the analysis unit determines that the age threshold range is not exceeded, and initially generates a first pressure control instruction of "normal person" to control the oxygen cabin pressure to be normal oxygen cabin pressure, for example, 1.2 atmospheres; when the age of the user is 55 years, the analysis unit determines that the age threshold range is exceeded, and initially generates a first pressure control instruction for "the elderly", adjusting the oxygen chamber pressure to a low pressure, for example 1.1 atmospheres.

More specifically, the analysis unit analyzes the use cause selected by the user, determines the health type of the user, and primarily selects an appropriate oxygen flow rate. For example, when the reason is cerebral thrombosis physiotherapy, the analysis unit determines that the user is a symptom crowd, and preliminarily determines that the oxygen flow in the oxygen cabin is in a flow increasing mode, and at the moment, the analysis unit generates a first flow control instruction of the flow increasing mode to control the power of a stepping motor of the oxygenerator to be increased; when the use reason is to relieve the pressure, the analysis unit determines that the user is healthy people, and preliminarily determines that the oxygen flow in the oxygen cabin is in a conventional mode, and at the moment, the analysis unit generates a first flow control instruction of the conventional mode to control the stepping motor of the oxygenerator to be in a normal working state.

The second control module can analyze the use reasons of the users and preliminarily determine the oxygen supply state so as to adapt to the normal demands of most users, reduce the steps of manual operation and further improve the intelligent automation degree of the oxygen cabin.

In step S103, the monitoring result is analyzed by the third control module, and if the internal environment state is monitored to exceed the preset range or the oxygen supply state is abnormal in the use process, the third control module generates a third control instruction according to the monitoring result, and the environment adjusting subsystem and the oxygen supply adjusting subsystem adjust the internal environment state and the oxygen supply state of the cabin according to the third control instruction.

In step S104, the operation command includes a temperature adjustment command, a humidity adjustment command, an air quality adjustment command, an oxygen concentration adjustment command, a pressure increase adjustment command, and a pressure release adjustment command. In this embodiment, the user can issue an operation instruction through the operation terminal. The operation terminal comprises a display module and an operation module, wherein the display module is used for displaying the operation state of the oxygen cabin, and the operation state comprises an internal environment state and an oxygen supply state; the operation module is used for sending an operation instruction by a user to adjust the internal environment state and the oxygen supply state of the oxygen cabin.

Specifically, in this embodiment, the operation terminal may be a touch display screen disposed inside the oxygen cabin, and in fact, the operation terminal may be integrated with the acquisition subsystem, representing a tablet computer mounted inside the cabin. The display module comprises a plurality of display units which respectively display real-time oxygen cabin pressure, oxygen flow, oxygen cabin internal temperature, oxygen cabin internal humidity, oxygen cabin internal PM2.5 grade, oxygen concentration, anion concentration and service time, and is convenient for users to check.

Specifically, the operation module comprises a boosting operation unit, a pressure relief operation unit, a flow operation unit, a temperature operation unit, a humidity operation unit, an air quality operation unit and a negative ion operation unit.

More specifically, the boost operating unit is for the user to select the intended oxygen cabin pressure, and in this embodiment, the boost operating unit includes five levels for the user to select, respectively, 1.1 atmospheres, 1.15 atmospheres, 1.2 atmospheres, 1.25 atmospheres, and 1.3 atmospheres, and after the user selects, the boost operating unit generates a boost adjustment command and sends the boost adjustment command to the control subsystem.

More specifically, the pressure release operation unit is used for a user to select an intended pressure release speed, and in this embodiment, during the use, the pressure release operation unit automatically selects a pressure release closing option. In the use, pressure release operating element provides three grades and supplies the user to select, is slow pressure release, quick pressure release and extremely fast pressure release respectively, and after the user selected corresponding option, pressure release operating element produced pressure release adjustment command to send pressure release adjustment command to control subsystem.

More specifically, the flow rate operation unit is used to select the intended oxygen flow rate, and in this embodiment, the flow rate operation unit may provide three levels for the user to select, respectively, a normal mode, a gentle mode, in which the oxygen flow rate is relatively low, and a flow increasing mode, in which the oxygen flow rate is relatively high. After the user selects the corresponding option, the flow operation unit generates a flow adjustment instruction and sends the flow adjustment instruction to the control subsystem.

More specifically, the temperature operation unit is used for the user to select the intended internal temperature of the oxygen cabin, and in this embodiment, the temperature operation unit can provide a plurality of internal temperatures of the oxygen cabin for the user to adjust according to the self-adaptation condition. After the user selects the corresponding option, the temperature operation unit generates a temperature adjustment instruction and sends the temperature adjustment instruction to the control subsystem.

More specifically, in the present embodiment, the humidity operation unit is provided for a user to select a dehumidification or humidification function, and when the user selects a corresponding option, the humidity operation unit generates a humidity adjustment instruction and sends the humidity adjustment instruction to the control subsystem.

More specifically, in the present embodiment, the air quality operation unit is used for a user to select whether to turn on the air purification function, and when the user selects the corresponding option, the air quality operation unit generates the air quality adjustment unit and sends an air quality adjustment instruction to the control subsystem.

More specifically, in the present embodiment, the negative ion operation unit is configured to allow a user to select whether to turn on the function of increasing the negative ion concentration, and when the user selects the corresponding option, the negative ion operation unit generates a negative ion adjustment instruction and sends the negative ion adjustment instruction to the control subsystem.

The fourth control module generates a fourth control instruction according to the operation instruction of the user, the control environment adjusting subsystem adjusts the internal environment of the cabin according to the fourth control instruction, the oxygen supply adjusting subsystem adjusts the oxygen supply state of the cabin, and the specific processing flow can be known through the steps in the operation terminal. In the actual use process, if a user feels uncomfortable or wants to adjust the internal environment state or the oxygen supply state of the cabin for other reasons, the user can operate the cabin through the operation terminal.

The implementation principle of the intelligent oxygen cabin control method in the embodiment of the application is as follows: the method comprises the steps of obtaining external environment information, automatically adjusting the internal environment state of the oxygen cabin according to the external environment information, obtaining the use reason of a user, and preliminarily determining the oxygen supply state of the interior of the oxygen cabin according to the use reason so as to adapt to most users, wherein the user can also adjust the internal environment state and the oxygen supply state of the oxygen cabin at any time in the use process. The setting of this application has reduced user's manual operation step, has improved the intelligent degree of oxygen cabin, and the user still can adjust oxygen cabin internal environment state and oxygen supply state at any time according to self demand in the use, has improved the multifunctionality and the suitability of oxygen cabin.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (6)

1. An intelligent oxygen cabin control method is characterized by comprising the following steps:

before use, acquiring external environment information, and adjusting the internal environment state of the oxygen cabin based on the external environment information;

acquiring basic information of a user, and adjusting the oxygen supply state of the oxygen cabin based on the basic information; the basic information comprises age and use reason, and the oxygen supply state comprises oxygen flow and oxygen cabin pressure;

specifically, the user needs to select and fill out his own age and use reasons from the background, and the use reasons of the oxygen chamber include the following categories:

1) For healthy people: relieving pressure, relieving fatigue, relieving alcoholic intoxication, and activating skin for women;

2) For sub-health people: insomnia, headache, dysphoria, anxiety;

3) For the disease population: cardiovascular and cerebrovascular diseases, hypertension, hyperglycemia, hyperlipidemia, depression, cerebral palsy and gout;

judging whether the age of the user exceeds a preset age threshold range or not;

If the age of the user is within a preset age threshold range, preliminarily determining that the oxygen cabin pressure is in a normal pressure state;

if the age of the user exceeds a preset age threshold, preliminarily determining that the oxygen cabin pressure is in a low-pressure state;

determining the health type of a user according to the use reason of the user, and selecting corresponding oxygen flow based on the health type, wherein the health type comprises healthy people, sub-healthy people and disease people;

if the health type is determined to be a disease crowd, initially determining that the oxygen flow in the oxygen cabin is in a flow increasing mode;

if the health type is determined to be healthy people or sub-healthy people, preliminarily determining that the oxygen flow in the oxygen cabin is in a conventional mode;

in the use process, the internal environment state and the oxygen supply state of the oxygen cabin are monitored in real time, a monitoring result is generated, the environment state and the oxygen supply state are adjusted based on the monitoring result,

Or receiving an operation instruction of a user, and adjusting the internal environment state and the oxygen supply state based on the operation instruction;

the external environment information comprises external temperature, external humidity and an external PM2.5 value, and the adjusting of the internal environment state of the oxygen cabin based on the external environment information comprises the following steps:

Comparing and analyzing the external temperature with a preset human body comfort temperature range, and adjusting the internal temperature of the oxygen cabin to the human body comfort temperature range if the external temperature exceeds the human body comfort temperature range;

comparing and analyzing the external humidity with a preset human body comfort humidity range, and adjusting the internal humidity of the oxygen cabin to the human body comfort humidity range if the external humidity exceeds the human body comfort temperature range;

and comparing and analyzing the external PM2.5 value with a preset PM2.5 normal range, and purifying the air in the oxygen cabin if the external PM2.5 value exceeds the normal range.

2. The intelligent oxygen cabin control method of claim 1, wherein the operating instructions include temperature regulation instructions, humidity regulation instructions, air quality regulation instructions, oxygen concentration regulation instructions, pressure boost regulation instructions, and pressure release regulation instructions.

3. The intelligent oxygen cabin control system is characterized by comprising a cabin body (1), and an acquisition subsystem (2), a monitoring subsystem (3), an environment regulation subsystem (4), an oxygen supply regulation subsystem (5), a control subsystem (7) and an operation terminal (6) which are arranged on the cabin body (1), wherein the operation terminal (6) is respectively connected with the acquisition subsystem (2), the monitoring subsystem (3), the environment regulation subsystem (4) and the oxygen supply regulation subsystem (5);

The acquisition subsystem (2) is used for acquiring external environment information and basic information of users;

the monitoring subsystem (3) is used for monitoring the internal environment state and the oxygen supply state of the oxygen cabin in real time and obtaining a monitoring result; the monitoring subsystem (3) comprises an internal environment monitoring module (31) and an oxygen supply monitoring module (32), and the oxygen supply monitoring module (32) comprises a flow monitoring unit (321) and a pressure monitoring unit (322);

the environment adjusting subsystem (4) is used for adjusting the internal environment state of the cabin (1);

the oxygen supply adjusting subsystem (5) is used for adjusting the oxygen supply state inside the cabin body (1);

the operation terminal (6) is used for receiving an operation instruction of a user and sending the operation instruction to the control subsystem (7);

the control subsystem (7) is used for generating a control instruction based on the external environment information, the basic information, the monitoring result and the operation instruction, and controlling the environment regulating subsystem (4) and the oxygen supply regulating subsystem (5) to regulate the environment state and the oxygen supply state in the cabin body (1) based on the control instruction;

Wherein the basic information comprises age and use reason, and the oxygen supply state comprises oxygen flow and oxygen cabin pressure; specifically, the user needs to select and fill out his own age and use reasons from the background, and the use reasons of the oxygen chamber include the following categories:

1) For healthy people: relieving pressure, relieving fatigue, relieving alcoholic intoxication, and activating skin for women;

2) For sub-health people: insomnia, headache, dysphoria, anxiety;

3) For the disease population: cardiovascular and cerebrovascular diseases, hypertension, hyperglycemia, hyperlipidemia, depression, cerebral palsy and gout;

the control subsystem (7) judges whether the age of the user exceeds a preset age threshold range;

if the age of the user is within the preset age threshold range, initially determining that the oxygen cabin pressure is in a normal pressure state;

if the age of the user exceeds a preset age threshold, preliminarily determining that the oxygen cabin pressure is in a low-pressure state;

the control subsystem (7) also determines the health type of the user according to the use reason of the user, and selects corresponding oxygen flow based on the health type, wherein the health type comprises healthy people, sub-healthy people and disease people;

if the health type is determined to be a disease crowd, initially determining that the oxygen flow in the oxygen cabin is in a flow increasing mode;

If the health type is determined to be healthy people or sub-healthy people, preliminarily determining that the oxygen flow in the oxygen cabin is in a conventional mode;

the environment conditioning subsystem (4) comprises:

a temperature adjustment module (41), wherein the temperature adjustment module (41) is used for adjusting the temperature in the cabin (1) based on the control instruction;

a humidity adjustment module (42), wherein the humidity adjustment module (42) is used for adjusting the humidity in the cabin (1) based on the control instruction;

and an air quality adjusting module (43), wherein the air quality adjusting module (43) purifies the air in the cabin (1) based on the control instruction.

4. An intelligent oxygen cabin control system according to claim 3, characterized in that the oxygen supply regulation subsystem (5) comprises;

the flow regulating module (51) is used for regulating the oxygen flow in the cabin (1) based on the control instruction;

and a pressure adjustment module (52), the pressure adjustment module (52) being configured to adjust the oxygen cabin pressure based on the control command.

5. The intelligent oxygen cabin control system of claim 4, wherein the pressure regulation module (52) comprises:

A boosting unit (521), the boosting unit (521) performing a boosting operation on the inside of the cabin (1) according to the control instruction;

a protection unit (522), when the pressure monitoring unit (322) monitors that the interior of the cabin (1) has reached a preset air pressure value, the protection unit (522) performs an air pressure balancing operation on the cabin (1);

and a pressure relief unit (523), wherein the pressure relief unit (523) performs a pressure relief operation on the interior of the cabin (1) based on the operation instruction.

6. An intelligent oxygen cabin control system according to claim 3, characterized in that the operating terminal (6) comprises:

the display module (61) is used for displaying the internal environment information of the oxygen cabin and the oxygen supply state;

and an operation module (62), wherein the operation module (62) is used for issuing operation instructions by a user.