CN110652702B

CN110652702B - Intermittent high-low oxygen training method, device and storage medium

Info

Publication number: CN110652702B
Application number: CN201910947520.6A
Authority: CN
Inventors: 王博宇; 奥列格·谢·格拉扎切夫; 陈阔; 郭嘉; 胡小州
Original assignee: Shenzhen Russian Chinese Bo Medical Technology Co ltd
Current assignee: Shenzhen Russian Chinese Bo Medical Technology Co ltd
Priority date: 2019-09-30
Filing date: 2019-09-30
Publication date: 2021-07-20
Anticipated expiration: 2039-09-30
Also published as: CN110652702A

Abstract

The invention discloses an intermittent high-low oxygen training method which is applied to an intermittent high-low oxygen training system, wherein the intermittent high-low oxygen training system comprises oxygen-containing gas generating equipment, breathing training equipment and a controller, and the intermittent high-low oxygen training method comprises the following steps: the method comprises the steps that when a controller receives a training instruction, physiological parameters of a user are obtained; determining target parameters of the mixed gas according to the physiological parameters, wherein the target parameters comprise a target oxygen concentration, a target duration and a target gas pressure, and the target gas pressure is standard atmospheric pressure; controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters. The invention also discloses an intermittent high-low oxygen training and storage medium. According to the invention, as the target air pressure of the mixed gas is the standard atmospheric pressure, the physiological bearing capacity requirement of the user is reduced, the training risk is reduced, and the device is suitable for a wide range of people.

Description

Intermittent high-low oxygen training method, device and storage medium

Technical Field

The invention relates to the field of hypoxia training, in particular to an intermittent hypoxia training method, device and storage medium.

Background

Intermittent Hypoxia Training (IHT) is a method of simulating a hypoxic, high-pressure breathing environment for respiratory training. The intermittent hypoxia training has obvious treatment effects on cardiovascular system and metabolic diseases and improvement of human brain cognition, and has wide application.

However, due to the differences in the constitutions of individuals, the risk of continuous exposure of a human body to a respiratory environment of low oxygen and high pressure is high, and thus the current intermittent hypoxia training method is generally only suitable for athletes or special occupational people and is suitable for narrow people.

The above is only for the purpose of assisting understanding of the technical aspects of the present invention, and does not represent an admission that the above is prior art.

Disclosure of Invention

The invention mainly aims to provide an intermittent high-low oxygen training method, device and storage medium, and aims to solve the technical problems that the existing intermittent low-oxygen training has higher risk and is narrow in applicable crowd.

In order to achieve the above object, the present invention provides an intermittent hypoxia training method, applied to an intermittent hypoxia training system, wherein the intermittent hypoxia training system comprises an oxygen-containing gas generating device, a breathing training device and a controller, and the intermittent hypoxia training method comprises the following steps:

the method comprises the steps that when a controller receives a training instruction, physiological parameters of a user are obtained;

determining target parameters of the mixed gas according to the physiological parameters, wherein the target parameters comprise a target oxygen concentration, a target duration and a target gas pressure, and the target gas pressure is standard atmospheric pressure;

controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters.

Preferably, the oxygen-containing gas generating apparatus comprises an oxygen-generating plant comprising an oxygen outlet and a nitrogen-rich gas outlet; the breathing training equipment comprises a gas mixing device, wherein the gas mixing device is provided with a gas mixing valve; the gas mixing valve comprises an air inlet, an oxygen inlet and a nitrogen-rich gas inlet, wherein the air inlet, the oxygen inlet and the nitrogen-rich gas inlet are respectively provided with a starting and closing piece, the oxygen-containing gas generating equipment is controlled to operate, and the operation parameters of the breathing training equipment are adjusted to output mixed gas meeting the target parameters, and the steps comprise:

controlling operation of an oxygen-containing gas generating apparatus to generate oxygen and nitrogen-rich gas;

acquiring oxygen concentration of oxygen, nitrogen-rich gas and air;

adjusting the operation parameters of the opening and closing piece of the gas mixing valve according to the oxygen concentration of the oxygen, the nitrogen-rich gas and the air so as to output the mixed gas meeting the target parameters.

Preferably, the intermittent hypoxia training system further comprises a wearable device, the wearable device is used for acquiring physiological parameters of the user, and the step of acquiring the physiological parameters of the user by the controller when receiving the training instruction comprises:

the method comprises the steps that when a controller receives a training instruction, target parameters of mixed gas required by testing are obtained;

adjusting the operation parameters of the breathing training equipment to output mixed gas meeting the target parameters, and acquiring the test physiological parameters of the user through the wearable equipment;

and acquiring the test physiological parameters, and taking the test physiological parameters as the physiological parameters of the user.

Preferably, before the step of obtaining the target parameter of the mixed gas required by the test, the method further comprises:

determining whether a test physiological parameter corresponding to the user is prestored;

when a test physiological parameter corresponding to the user is prestored, executing the step of acquiring the test physiological parameter and taking the test physiological parameter as the physiological parameter of the user;

and when the test physiological parameters corresponding to the user are not pre-stored, executing the step of acquiring the target parameters of the mixed gas required by the test.

Preferably, the intermittent hyperhypoxic training system further comprises a wearable device for acquiring physiological parameters of a user, and after the steps of controlling the operation of the oxygen-containing gas generation device and adjusting the operation parameters of the respiratory training device to output a mixed gas satisfying the target parameters, the intermittent hyperhypoxic training system further comprises:

acquiring training physiological parameters of a user through the wearable device;

and when the training physiological parameter exceeds a preset physiological parameter range, adjusting the operating parameter of the respiratory training equipment, wherein the preset physiological parameter threshold is determined according to the physiological parameter of the user.

Preferably, after the step of providing the breathing training device with a gas pressure balance valve, when the gas pressure balance valve is opened, communicating the mixed gas with the outside air, controlling the operation of the oxygen-containing gas generating apparatus, and adjusting the operation parameters of the breathing training apparatus to output the mixed gas satisfying the target parameters, the breathing training device further comprises:

detecting the gas pressure of the mixed gas in real time or at regular time;

and when the air pressure exceeds a preset air pressure range, opening the air pressure balance valve and outputting prompt information.

Preferably, the step of determining a target parameter of the mixed gas according to the physiological parameter comprises:

acquiring historical training data, wherein the historical training data comprises historical mixed gas parameters and historical training physiological parameters;

updating the corresponding relation between the physiological parameters and the mixed gas parameters according to the historical training data;

and determining the target parameters of the mixed gas according to the updated corresponding relation between the physiological parameters and the parameters of the mixed gas and the physiological parameters.

Preferably, before the step of controlling the operation of the oxygen-containing gas generating device and adjusting the operation parameters of the respiratory training device to output the mixed gas satisfying the target parameters, the method further comprises:

determining whether the wearable device is worn normally;

when the wearable device is worn normally, executing the step of controlling the oxygen-containing gas generation device to operate and adjusting the operation parameters of the breathing training device to output the mixed gas meeting the target parameters;

and when the wearable equipment is abnormal in wearing, outputting reminding information.

Furthermore, to achieve the above object, the present invention further provides an intermittent high-hypoxia training device, which comprises an oxygen-containing gas generating device, a respiratory training device and a controller, wherein the controller comprises a memory, a processor and an intermittent high-hypoxia training program stored on the memory and operable on the processor, and the intermittent high-hypoxia training program, when executed by the processor, implements the steps of the intermittent high-hypoxia training method as described in any one of the above.

In addition, to achieve the above object, the present invention further provides a storage medium, on which an intermittent high-hypoxia training program is stored, wherein the intermittent high-hypoxia training program, when executed by a processor, implements the steps of the intermittent high-hypoxia training method as described in any one of the above.

The embodiment of the invention provides an intermittent high-low oxygen training method, an intermittent high-low oxygen training device and a storage medium, which are applied to an intermittent high-low oxygen training system, wherein the intermittent high-low oxygen training system comprises an oxygen-containing gas generating device, a breathing training device and a controller, and the controller acquires physiological parameters of a user when receiving a training instruction; determining target parameters of the mixed gas according to the physiological parameters, wherein the target parameters comprise a target oxygen concentration, a target duration and a target gas pressure, and the target gas pressure is standard atmospheric pressure; controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters. Because the target air pressure of the mixed gas is the standard atmospheric pressure, the physiological bearing capacity requirement of the user is reduced, the training risk is reduced, and the device is suitable for wide crowds.

Drawings

Fig. 1 is a schematic terminal structure diagram of a hardware operating environment according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an intermittent hyperhypoxic training system according to the invention;

FIG. 3 is a schematic flow chart of a first embodiment of the intermittent hyperhypoxic training method of the present invention;

FIG. 4 is a schematic flow chart of the intermittent hyperhypoxic training method according to the second embodiment of the invention;

FIG. 5 is a schematic flow chart of the intermittent hyperhypoxic training method according to the third embodiment of the invention;

fig. 6 is a flowchart illustrating an intermittent hyperhypoxic training method according to a fourth embodiment of the present invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The main solution of the embodiment of the invention is as follows:

the controller acquires the physiological parameters of the user when receiving the training instruction;

In the prior art, intermittent hypoxia training has higher risk and is suitable for a narrow crowd.

The invention provides a solution, the target air pressure of the mixed gas is standard atmospheric pressure, the requirement of the physiological bearing capacity of a user is reduced, the training risk is reduced, and the application range is wide.

As shown in fig. 1, fig. 1 is a schematic terminal structure diagram of a hardware operating environment according to an embodiment of the present invention.

As shown in fig. 1, the terminal may include: a processor 1001, such as a CPU, a network interface 1004, a user interface 1003, a memory 1005, a communication bus 1002. Wherein a communication bus 1002 is used to enable connective communication between these components. The user interface 1003 may include a Display screen (Display), an input unit such as a Keyboard (Keyboard), and the optional user interface 1003 may also include a standard wired interface, a wireless interface. The network interface 1004 may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface). The memory 1005 may be a high-speed RAM memory or a non-volatile memory (e.g., a magnetic disk memory). The memory 1005 may alternatively be a storage device separate from the processor 1001.

Those skilled in the art will appreciate that the terminal structure shown in fig. 1 is not intended to be limiting and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.

As shown in fig. 1, the memory 1005, which is a type of computer storage medium, may include an operating system, a network communication module, a user interface module, and an intermittent hyperhypoxic training program.

In the terminal shown in fig. 1, the network interface 1004 is mainly used for connecting to a backend server and performing data communication with the backend server; the user interface 1003 is mainly used for connecting a client (user side) and performing data communication with the client; and the processor 1001 may be configured to invoke the intermittent hyperhypoxic training program stored in the memory 1005 and perform the following operations:

Further, the processor 1001 may call the intermittent hyperhypoxic training program stored in the memory 1005, and also perform the following operations:

acquiring oxygen concentration of oxygen, nitrogen-rich gas and air;

detecting the gas pressure of the mixed gas in real time or at regular time;

determining whether the wearable device is worn normally;

According to the scheme, when the controller receives a training instruction, the physiological parameters of the user are obtained; determining target parameters of the mixed gas according to the physiological parameters, wherein the target parameters comprise a target oxygen concentration, a target duration and a target gas pressure, and the target gas pressure is standard atmospheric pressure; controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters. Because the target air pressure of the mixed gas is the standard atmospheric pressure, the physiological bearing capacity requirement of the user is reduced, the training risk is reduced, and the device is suitable for wide crowds.

Referring to fig. 2, fig. 2 is a schematic structural diagram of an intermittent hyperhypoxic training system according to an embodiment of the present invention. The invention provides an intermittent high-low oxygen training system which is mainly used for intermittent high-low oxygen training. The intermittent hyperhypoxic training system comprises an oxygen-containing gas generating device 100, a respiratory training device 200, and a controller 300. The controller 300 may include an editable controller, or an intelligent controller, or the controller 300 may include an Artificial Intelligence (AI) module, which performs intelligent control through an AI. Optionally, the intermittent high-low oxygen training system further comprises a human-computer interaction module, wherein the human-computer interaction module includes, but is not limited to, a display device, a keyboard, a mouse and the like; the man-machine interaction module is used for outputting the acquired data and receiving parameters input by a user. Wherein the oxygen-containing gas generating apparatus 100 comprises an oxygen plant 110. The oxygen generator 110 may be a PSA (Pressure Swing Adsorption) oxygen generator 110, or may be another oxygen generator 110. When the PSA oxygen production device 110 is used for producing oxygen by absorbing and separating air, the PSA oxygen production device 110 is internally provided with a zeolite molecular sieve which has high nitrogen adsorption, nitrogen, carbon dioxide and the like are absorbed under the pressurization condition to produce oxygen, and the nitrogen and the carbon dioxide absorbed after the depressurization are released from the zeolite molecular sieve to obtain nitrogen-rich gas. Further, to meet the requirements for continuous production of oxygen or nitrogen-rich gas, the oxygen-containing gas generation plant 100 can include multiple PSA oxygen generation plants 110. The oxygen generating device 110 comprises a first air inlet 111, an oxygen outlet 112 and a nitrogen-rich gas outlet 113, wherein air enters the oxygen generating device 110 from the first air inlet 111 and is processed by the oxygen generating device 110 to generate oxygen and nitrogen-rich gas, the oxygen is output from the oxygen outlet 112, and the nitrogen-rich gas is output from the nitrogen-rich gas outlet 113.

The respiratory training device 200 comprises a gas mixing device (not shown) and a breathing mask 220, wherein the gas mixing device is provided with a gas mixing valve 210 communicated with the breathing mask 220 and the oxygen generating device 110; the gas mixing valve 210 comprises a first mixed gas outlet 114, a second air inlet 211, an oxygen inlet 212 communicated with the oxygen outlet 112, and a nitrogen-rich gas inlet 213 communicated with the nitrogen-rich gas outlet 113, wherein the second air inlet 211, the oxygen inlet 212, and the nitrogen-rich gas inlet 213 are all provided with an opening and closing member (such as a valve plate, a valve ball, a valve rod, or the like, which are not shown in the figure), and the breathing mask 220 is communicated with the first mixed gas outlet 214 of the gas mixing valve 210. When the opening and closing member is opened, the corresponding gas enters the gas mixing valve 210, the flow rate of the corresponding gas can be controlled by adjusting the operation parameters (such as the opening degree) of the opening and closing member, so that the oxygen concentration and the gas pressure of the mixed gas are adjusted, the mixed gas with different oxygen concentrations is obtained, and the obtained mixed gas is output to the breathing mask 220 through the first mixed gas outlet 214, and the breathing training of the user can be performed.

Further, the intermittent hyperhypoxic training system provided by the present embodiment further includes a wearable device (not shown), which is connected to the controller 300, so as to transmit the acquired physiological parameters of the user to the controller 300. The wearable device comprises a physiological parameter detection unit, wherein the physiological parameter detection unit comprises at least one of a heart rate detection unit, a blood pressure detection unit, a blood oxygen detection unit, a brain oxygen detection unit and an electrocardio detection unit. The wearable device is used for acquiring physiological parameters of a user, wherein the physiological parameters comprise at least one of heart rate, blood pressure, blood oxygen, brain oxygen and electrocardio. For example, the wearable device includes a finger-clipped blood oxygen heart rate detection module, an arm-worn electrocardiogram monitoring module, a brain oxygen detection module, and the like. The connection mode between the wearable device and the controller 300 may be a conventional data line connection mode, a network connection mode such as 3G, 4G, or 5G, or a bluetooth connection mode, and is not limited herein. The wearable device sends the acquired physiological parameters of the user to the controller 300, and the controller 300 receives the physiological parameters and stores and/or outputs the physiological parameters to a display device. Furthermore, the controller 300 may be further configured to adjust the opening of the shutter of the gas mixing valve 210 according to the physiological parameters detected by the wearable device, for example, when one of the physiological parameters of the user is detected to be out of a preset physiological parameter range, the opening of the shutter is adjusted to adjust the oxygen concentration of the mixed gas.

The oxygen concentration of the mixed gas needs to be adjusted according to the oxygen concentration and flow rate of each gas, and the gas pressure is adjusted by adjusting the total flow rate of the gases. Therefore, in the intermittent hyperhypoxic training system provided by the present implementation, an oxygen concentration sensor 500 and a gas flow meter 400 are respectively disposed between the oxygen outlet 112 and the oxygen inlet 212, between the nitrogen-rich gas outlet 113 and the nitrogen-rich gas inlet 213, and between the second air inlet 211, and an oxygen concentration sensor, a gas flow sensor and a pressure sensor 600 are disposed between the gas mixing device and the breathing mask 220. The oxygen concentration sensor 500, the gas flow meter 400, and the pressure sensor 600 are all connected to the controller 300 to transmit the collected gas parameters (at least one of oxygen concentration, gas flow rate, and gas pressure) to the controller 300. The oxygen concentration sensor 500 is used for detecting the oxygen concentrations of the air, the prepared oxygen, the nitrogen-rich gas and the mixed gas respectively, and sending the detected oxygen concentrations to the controller 300; the gas flow meter 400 is configured to detect flow rates of the detection air, the prepared oxygen, the prepared nitrogen-rich gas, and the mixed gas, respectively, and send the detected flow rates to the controller 300. The pressure sensor 600 is configured to detect a gas pressure of the mixed gas and transmit the detected gas pressure to the controller 300.

In the intermittent hyperhypoxic training using the intermittent hyperhypoxic training system, since the face of the user is covered by the breathing mask, only the mixture gas provided by the breathing mask 220 can be inhaled, and thus, when the pressure of the mixture gas is too high or too low, the user is not comfortable and may be dangerous in a serious case. Thus, the respiratory training device 200 is provided with a gas pressure equalizing valve 230 that opens to communicate the mixture with the ambient air, e.g., the gas pressure equalizing valve 230 may be connected to the gas circuit between the gas mixing valve 210 and the breathing mask 220 by a tee. The air pressure balancing valve 230 is connected to the controller 300 to receive a control command sent by the controller 300 and open or close according to the control command. Specifically, when the intermittent high-low oxygen training system operates, the air pressure of the mixed gas is detected in real time or at regular time, and when the air pressure of the mixed gas exceeds the preset air pressure range, the controller 300 sends a start instruction to the air pressure balance valve 230 to control the air pressure balance valve 230 to be opened so as to balance the pressure of the mixed gas and prevent the mixed gas from being threatened by too high or too low pressure.

Based on the intermittent high-low oxygen training system, the invention also provides an intermittent high-low oxygen training method.

Referring to fig. 3, fig. 3 is a schematic flow chart of a first embodiment of the intermittent hypoxia training method according to the present invention, the intermittent hypoxia training method includes:

step S10, when the controller receives the training instruction, the controller obtains the physiological parameters of the user;

in this embodiment, the controller may include an editable controller, an intelligent controller, an Artificial Intelligence (AI) controller, or the like. When the user needs to perform intermittent high-low oxygen training, the physiological parameters of the user are input through the interactive interface, and a training instruction is triggered. The user physiological parameter may include at least one of a height, a weight, a disease, a blood pressure, a blood oxygen, a respiratory rate, and a heart rate of the user. The method comprises the steps that when a controller receives a training instruction triggered by a user, physiological parameters of the user are obtained; the physiological parameter of the user can be manually input through a physiological parameter input interface by the user.

Step S20, determining target parameters of the mixed gas according to the physiological parameters, wherein the target parameters comprise a target oxygen concentration, a target duration and a target air pressure, and the target air pressure is standard atmospheric pressure;

in this embodiment, the training mode of the user may be one of continuous hypoxia training, intermittent hypoxia training, and intermittent hyperhypoxia training. The continuous hypoxia training is to continuously provide the mixed gas with low oxygen concentration for the user, detect the physiological parameter (such as blood oxygen concentration) of the user, and provide air for the user to breathe when the physiological parameter of the user reaches a preset threshold. The intermittent hypoxia training means that mixed gas with low oxygen concentration and air are alternately provided for a user to carry out breathing training. The intermittent hyperhypoxic training refers to providing a mixed gas breathing environment with high oxygen concentration and low oxygen concentration for a user alternately for the user to carry out breathing training, and compared with continuous hypohypoxic training, the intermittent hyperhypoxic training can avoid the overlong exposure time of the user in the hypohypoxic environment; whereas intermittent hyperhypoxic training provides a high oxygen concentration of the gas mixture during the recovery phase that enables faster recovery of the user's physiological parameters relative to air, relative to intermittent hypoxic training. The training mode may be selected according to actual conditions, and is not limited in particular, and may be selected according to training purposes or physiological conditions of the user, for example.

Because the physiological parameters of different users are different, in order to enable the training to better meet the physiological requirements of the users, the parameters of the mixed gas need to be correspondingly set according to the physiological parameters of the users during the training, namely, the parameters of different mixed gases are correspondingly set to different physiological parameters. The types of the parameters of the mixed gas are correspondingly set according to a training mode, and specifically, the parameters of the mixed gas in continuous hypoxia training comprise low oxygen concentration and air pressure; the parameters of the mixed gas in the intermittent hypoxia training comprise the hypoxia concentration, the air supply duration of the low-oxygen-concentration mixed gas, the air supply duration of air and the air pressure; the parameters of the mixed gas in the intermittent hyperhypoxic training comprise the oxygen concentration (including low oxygen concentration and high oxygen concentration) of the mixed gas, the duration (including the duration of the gas supply of the low oxygen concentration mixed gas and the duration of the gas supply of the high oxygen concentration mixed gas) and the gas pressure.

The controller stores the corresponding relation of the parameters of physiological parameters and mixed gas, the corresponding relation can be set according to actual conditions, the intermittent high-low oxygen training is taken as an example, the intermittent high-low oxygen training experiment can be carried out on users in different physiological parameter ranges through the passing, the parameters of the mixed gas corresponding to different physiological parameter ranges are determined, the parameters of the mixed gas comprise the oxygen concentration (including low oxygen concentration and high oxygen concentration) of the mixed gas, the duration (including the duration of the gas supply of the mixed gas with low oxygen concentration and the duration of the gas supply of the mixed gas with high oxygen concentration) and the gas pressure, optionally, the risk of the intermittent breathing training is reduced in order to reduce the requirement of the bearing capacity of the users for the intermittent breathing training, and in the embodiment, the target gas pressure is standard atmospheric pressure.

After acquiring physiological parameters of a user, a controller determines target parameters of mixed gas required by intermittent training according to the corresponding relation between the physiological parameters and the parameters of the mixed gas, wherein the target parameters comprise target oxygen concentration, target duration and target air pressure, and the target air pressure is standard atmospheric pressure.

And step S30, controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters.

After the controller acquires the target parameters of the mixed gas, the controller controls the oxygen-containing gas generating equipment to operate to generate oxygen and nitrogen-rich gas, adjusts the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters, and provides the mixed gas for a user to perform intermittent high-low oxygen training through a breathing mask; meanwhile, training physiological parameters of the user are collected through the wearable device. After training is finished, a training report can be output, wherein the training report can comprise a target parameter of the mixed gas, an actual parameter of the mixed gas and a training physiological parameter of a user, and the training physiological parameter can be checked by the user or a training person. Further, the training report can be evaluated to make a next training scheme.

Specifically, the intermittent hyperhypoxic training system related to the present embodiment is shown in fig. 3, wherein the oxygen-containing gas generation device comprises an oxygen generation device, and the oxygen generation device comprises an oxygen outlet and a nitrogen-rich gas outlet; the breathing training equipment comprises a gas mixing device, wherein the gas mixing device is provided with a gas mixing valve; the gas mixing valve comprises an air inlet, an oxygen inlet and a nitrogen-rich gas inlet, wherein the air inlet, the oxygen inlet and the nitrogen-rich gas inlet are all provided with opening and closing pieces.

That is, the step S30 includes:

step S31, controlling the oxygen-containing gas generating equipment to operate so as to generate oxygen and nitrogen-rich gas;

step S32, obtaining oxygen concentration of oxygen, nitrogen-rich gas and air;

and step S33, adjusting the operation parameters of the opening and closing piece of the gas mixing valve according to the oxygen concentration of the oxygen, the nitrogen-rich gas and the air so as to output the mixed gas meeting the target parameters.

In this embodiment, the mixed gas is obtained by mixing two of air, oxygen and nitrogen-rich gas. And after determining the target parameters of the mixed gas according to the physiological parameters, the controller controls the oxygen-containing gas generation equipment to operate so as to generate oxygen and nitrogen-rich gas, then respectively acquires the oxygen concentrations of the oxygen, the nitrogen-rich gas and air through the sensor, and adjusts the operation parameters of the opening and closing piece of the gas mixing valve according to the oxygen concentrations of the oxygen, the nitrogen-rich gas and the air so as to output the mixed gas meeting the target parameters. Specifically, the controller determines a target oxygen concentration of the current mixed gas according to a target parameter of the mixed gas, and then calculates a flow ratio of the oxygen gas, the nitrogen-rich gas and the air according to the target oxygen concentration, the oxygen concentration of the oxygen gas, the nitrogen-rich gas and the oxygen concentration of the air, and further obtains a total flow of the gas according to a target gas pressure of the mixed gas. And calculating to obtain target flow rates of the oxygen, the nitrogen-rich gas and the air according to the total flow rate of the gas and the flow rate ratio of the oxygen, the nitrogen-rich gas and the air, controlling the opening degrees of the opening and closing pieces corresponding to the oxygen, the nitrogen-rich gas and the air, and adjusting the flow rates of the oxygen, the nitrogen-rich gas and the air to the target flow rates to obtain the mixed gas meeting the target parameters. Meanwhile, the controller acquires the oxygen concentration and the air pressure of the mixed gas in real time and adjusts the oxygen, the nitrogen-rich gas and the air according to the oxygen concentration and the air pressure of the mixed gas.

In this embodiment, optionally, when the current target oxygen concentration is a high oxygen concentration, the mixed gas may be prepared by mixing oxygen and control gas, at this time, the opening and closing element corresponding to the nitrogen-rich gas inlet is closed, and the flow ratio between oxygen and air may be calculated according to the target oxygen concentration, the oxygen concentration of oxygen, and the oxygen concentration of air; and calculating the total gas flow according to the gas pressure of the mixed gas, obtaining the target flow of the oxygen and the air according to the flow ratio of the oxygen and the air and the total gas flow, and regulating the flow of the oxygen and the air to the corresponding target flow by controlling the opening degree of the opening and closing piece corresponding to the oxygen inlet and the air inlet. When the current target oxygen concentration is low oxygen concentration, the mixed gas can be obtained by mixing the nitrogen-rich gas and the air, at the moment, the opening and closing piece corresponding to the oxygen inlet is closed, and the flow ratio of the nitrogen-rich gas and the air can be obtained through calculation according to the target oxygen concentration, the oxygen concentration of the nitrogen-rich gas and the oxygen concentration of the air; and calculating the total flow of the gas according to the pressure of the mixed gas, obtaining the target flow of the nitrogen-rich gas and the air according to the flow ratio of the nitrogen-rich gas to the air and the total flow of the gas, and regulating the flow of the nitrogen-rich gas and the air to the corresponding target flow by controlling the opening of the opening and closing piece corresponding to the nitrogen-rich gas inlet and the air inlet.

Further, since the physiological parameters of the user can only be accurately collected if the wearable device is worn normally, in this embodiment, before step S30, the method further includes:

step S40, determining whether the wearable device is worn normally;

when the wearable device is worn normally, executing step S30, controlling the oxygen-containing gas generating device to operate, and adjusting an operating parameter of the respiratory training device to output a mixed gas meeting the target parameter;

and step S50, outputting reminding information when the wearable device is abnormal in wearing.

In this embodiment, determining whether the wearable device is normally worn may be set by itself according to an actual situation, and no specific limitation is made herein. For example, whether the wearable device is worn normally can be determined according to whether the corresponding physiological parameter can be detected, when the physiological parameter can be detected, the wearable device is judged to be worn normally, and when at least one physiological parameter cannot be detected, the wearable device is judged to be worn abnormally. When the wearable device is worn normally, controlling the oxygen-containing gas generation device to operate, adjusting the operation parameters of the breathing training device to output mixed gas meeting the target parameters, and starting intermittent hyperhypoxic breathing training; when the wearable equipment is worn abnormally, reminding information is output to remind a user that the wearable equipment is abnormal, and a training instruction is restarted after the user is checked.

Further, in actual use, abnormal situations such as insufficient gas production or failure of the opening and closing member may occur, and at this time, the gas pressure of the mixed gas may be too low or too high, and since the face of the user is covered by the mask, only the mixed gas provided by the breathing mask may be provided, and therefore, when the pressure of the mixed gas is too high or too low, the mixed gas may cause discomfort to the user and may cause danger in severe cases. Therefore, in this embodiment, the respiratory training device is provided with the air pressure balance valve, and one end of the air pressure balance valve is communicated with the mixed gas, and the other end is communicated with the outside air. After the step S30, the method further includes:

step S60, detecting the pressure of the mixed gas in real time or at regular time;

and step S70, when the air pressure exceeds a preset air pressure range, opening the air pressure balance valve and outputting prompt information.

In the training process, intermittent type nature high hypoxia training equipment operation in-process promptly, real-time or regularly detect the atmospheric pressure of mist, work as when other exceed when predetermineeing the atmospheric pressure scope, the controller to atmospheric pressure balanced valve sends control command, opens atmospheric pressure balanced valve to the dangerous condition avoids appearing in balanced mist's pressure. Meanwhile, the controller outputs prompt information. And when the system is still abnormal after the air pressure balance valve is opened, the system is immediately stopped, and error information is output.

Further, in this embodiment, in the abnormal power down mode, the system can normally release the pressure, and it is ensured that there is no residual pressure in the system in the power down mode. Further, the intermittent high-low oxygen training equipment can be further provided with an emergency braking button, and when the controller receives an emergency instruction triggered by the emergency braking button, the intermittent high-low oxygen training system is controlled to stop providing gas with the current oxygen concentration, and the intermittent high-low oxygen training system is controlled to output gas with the oxygen content of 30%.

In this embodiment, the manner of outputting the prompt message or the reminding message may be set by itself, and is not limited specifically herein. For example, the prompt message or the reminder message may be output on a connected display device, or the prompt message or the reminder message may be output in the form of voice.

In the embodiment, the controller acquires the physiological parameters of the user when receiving the training instruction; determining target parameters of the mixed gas according to the physiological parameters, wherein the target parameters comprise a target oxygen concentration, a target duration and a target gas pressure, and the target gas pressure is standard atmospheric pressure; controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters. Because the target air pressure of the mixed gas is the standard atmospheric pressure, the physiological bearing capacity requirement of the user is reduced, the training risk is reduced, and the device is suitable for wide crowds.

Further, referring to fig. 4, fig. 4 is a flowchart illustrating a second embodiment of the intermittent hyperhypoxia training method according to the present invention, wherein the step S10 includes:

step S11, when the controller receives the training instruction, the controller obtains the target parameters of the mixed gas needed by the test;

step S12, adjusting the operation parameters of the breathing training equipment to output the mixed gas meeting the target parameters, and acquiring the test physiological parameters of the user through the wearable equipment;

step S13, acquiring the test physiological parameter, and using the test physiological parameter as the physiological parameter of the user.

In actual use, the physiological parameters of the user can change along with time. Therefore, in order to more accurately determine the target parameter of the mixed gas required by the user to perform the intermittent breathing training, in this embodiment, the user is tested first to obtain the test physiological parameter of the user during the test, and then the target parameter of the mixed gas required by the intermittent breathing training is determined according to the test physiological parameter of the user.

Specifically, when the controller receives a training instruction, the target parameters of the mixed gas required by the test are obtained, and the target parameters of the mixed gas required by the test can be manually input by a user or determined according to the physiological parameters input by the user. The controller outputs mixed gas meeting the target parameters according to the operation parameters of the breathing training equipment, so that a user can test the mixed gas, and meanwhile, the wearable equipment collects the test physiological parameters of the user. Optionally, during testing, the mixed gas with low oxygen concentration for a preset time may be continuously provided to the testing user for the user to perform the low oxygen test, and the physiological parameter of the user in the testing process is collected through the wearable device, where the physiological parameter includes the blood oxygen concentration of the user, and the preset time may be set according to an actual situation, and is not specifically limited herein, for example, the preset time may be set to 10min or 20 min. After the mixed gas with low oxygen concentration is continuously provided for a preset time, the mixed gas with high oxygen concentration is continuously provided for a test user for high oxygen recovery, and when the blood oxygen concentration of the user is detected to be recovered to a normal level (the blood oxygen concentration when the user starts to perform the test), the test is finished. Through the test, obtaining the test physiological parameters of the user, wherein the test physiological parameters can comprise at least one of the blood oxygen concentration decrease rate, the minimum blood oxygen concentration when the user is subjected to the hypoxia test, the blood oxygen concentration increase rate when the user is subjected to the high oxygen recovery, and the time length for recovering the blood oxygen concentration to the normal level; optionally, the test physiological parameters of the user may also include pulse parameters during the test, and the like. Wherein, the low oxygen concentration and the high oxygen concentration in the test can be set according to the actual situation, and are not limited specifically herein. After the test is finished, the controller obtains the test physiological parameters, takes the test physiological parameters as the physiological parameters of the user, and then determines the target parameters of the mixed gas required by the training of the user according to the physiological parameters (the test physiological parameters).

Alternatively, if the user has already performed the test, the test physiological parameters acquired at the previous test may be directly acquired, and the test physiological parameters may be used as the physiological parameters of the user. Specifically, the controller may store the collected test physiological parameters in association with the user after the test is performed. When the controller obtains a training control instruction, whether a test physiological parameter corresponding to the user is prestored is determined, and when the test physiological parameter corresponding to the user is prestored, the test physiological parameter is obtained and used as the physiological parameter of the user. When the test physiological parameters corresponding to the user are not prestored, the target parameters of the mixed gas required by the test are obtained, the operation parameters of the breathing training equipment are adjusted to output the mixed gas meeting the target parameters, the user is tested, the test physiological parameters of the user are collected through the wearable equipment, the test physiological parameters are obtained, and the test physiological parameters are used as the physiological parameters of the user.

Since the physiological parameters of the user may change with time, when the time interval between the time point of the user performing the test and the time point of the training is too long, the stored test physiological parameters may not accurately reflect the current physiological characteristics of the user, and need to be detected again. Therefore, in this embodiment, it is further determined whether a test physiological parameter corresponding to the user is pre-stored, when the test physiological parameter corresponding to the user is pre-stored, a test time point corresponding to the test physiological parameter is further obtained, and when a time interval between the test time point and a current time point is greater than or equal to a preset time length, an operation parameter of the respiratory training device is adjusted to output a mixed gas meeting the target parameter, and the test physiological parameter of the user is collected through the wearable device; and acquiring the test physiological parameters, and taking the test physiological parameters as the physiological parameters of the user. And when the time interval between the test time point and the current time point is greater than or equal to the preset time length, directly acquiring the test physiological parameters stored in the controller, and taking the test physiological parameters as the physiological parameters of the user.

In the embodiment, the controller acquires target parameters of the mixed gas required by the test when receiving the training instruction; adjusting the operation parameters of the breathing training equipment to output mixed gas meeting the target parameters, and acquiring the test physiological parameters of the user through the wearable equipment; and acquiring the test physiological parameters, taking the test physiological parameters as the physiological parameters of the user, determining target parameters of mixed gas according to the physiological parameters, controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output the mixed gas meeting the target parameters. The physiological parameters of the target parameters of the mixed gas required by the training acquired by the user are obtained through testing, so that the current physiological state of the user can be reflected more accurately, and the target parameters of the mixed gas required by the testing are more suitable for the user.

Further, referring to fig. 5, fig. 5 is a flowchart illustrating a third embodiment of the intermittent hyperhypoxia training method according to the present invention, and based on the first or second embodiment, after the step S30, the method further includes:

step S80, acquiring training physiological parameters of a user through the wearable device;

and step S90, when the training physiological parameter exceeds the preset physiological parameter range, adjusting the operation parameter of the respiratory training equipment, wherein the preset physiological parameter threshold is determined according to the physiological parameter of the user.

In actual use, when the user carries out high-hypoxia intermittent type nature training, because respiratory environment and conventional respiratory environment gap are great, the physiological parameter change is great, and when the physiological parameter change was too big, the user can the comfort relatively poor, probably takes place danger when serious. Therefore, in this embodiment, a preset physiological parameter range may be set, and the operation parameter may be adjusted when the training physiological parameter exceeds the preset physiological parameter range.

Specifically, the controller stores a preset physiological parameter range, including but not limited to one or more of a preset heart rate range, a preset respiratory rate range, and a preset prepressing range, where the preset physiological parameter range may be determined according to a physiological parameter of a user.

In the training process, the testing physiological parameters of the user are detected in real time, and when at least one of the testing physiological parameters exceeds the corresponding preset physiological parameter range, the operating parameters of the breathing training equipment are adjusted so as to adjust the parameters of the mixed gas. For example, when the breathing training device is currently in a high oxygen environment and the training physiological parameter is detected to exceed the preset physiological parameter range, the operating parameter of the breathing training device is adjusted, the oxygen content in a high oxygen state is reduced, or the duration of the high oxygen state is shortened; the current hypoxia environment, when the training physiological parameter that detects surpassed preset physiological parameter scope, the operating parameter of adjustment respiratory training equipment improved the oxygen content of hypoxia state, perhaps shortened the duration of hypoxia state. For example, in the examination and treatment mode, when the oxygen concentration of the user is detected to be lower than the preset level, the intermittent hyperhypoxic training system is controlled to stop the treatment immediately, and the gas with the oxygen content of 30% is controlled to be output.

In this embodiment, the wearable device collects training physiological parameters of a user, and when the training physiological parameters exceed a preset physiological parameter range, the operation parameters of the breathing training device are adjusted to adjust the parameters of the mixed gas, wherein the preset physiological parameter threshold is determined according to physiological parameters of the user, so that intermittent breathing training is safer.

Further, referring to fig. 6, fig. 6 is a flowchart illustrating a fourth embodiment of the intermittent hyperhypoxia training method according to the present invention, based on any one of the first to third embodiments, wherein the step S20 includes:

step S21, obtaining historical training data, wherein the historical training data comprises historical mixed gas parameters and historical training physiological parameters;

step S22, updating the corresponding relation between the physiological parameters and the mixed gas parameters according to the historical training data;

and step S23, determining the target parameter of the mixed gas according to the updated corresponding relation between the physiological parameter and the mixed gas parameter.

In this embodiment, the target parameter of the mixed gas required for training may be determined according to the historical training data and the physiological parameter of the user. Specifically, after acquiring physiological parameters of a user, a controller acquires historical training data, wherein the historical training data comprises historical mixed gas parameters and historical training physiological parameters; updating the corresponding relation between the physiological parameters and the mixed gas parameters according to the historical training data, specifically, presetting a big data algorithm in the controller, and after the historical training data is obtained, calculating according to the big data algorithm according to the historical training data by the controller to update the corresponding relation between the physiological parameters and the mixed gas parameters; and then determining the target parameters of the mixed gas according to the updated corresponding relation between the physiological parameters and the parameters of the mixed gas and the physiological parameters. Optionally, the controller may also acquire and obtain historical training data (including the training data of this time) when each training is completed, where the historical training data includes a historical mixed gas parameter and a historical training physiological parameter, perform calculation according to the historical training data and the big data algorithm, update the correspondence between the physiological parameter and the mixed gas parameter, then store the updated correspondence between the physiological parameter and the mixed gas parameter, and determine the target parameter of the mixed gas according to the physiological parameter directly according to the stored correspondence between the physiological parameter and the mixed gas parameter during each training.

In the embodiment, historical training data is obtained, wherein the historical training data comprises historical mixed gas parameters and historical training physiological parameters; updating the corresponding relation between the physiological parameters and the mixed gas parameters according to the historical training data; and determining the target parameters of the mixed gas according to the updated corresponding relation between the physiological parameters and the parameters of the mixed gas and the physiological parameters. The corresponding relation between the physiological parameters and the mixed gas parameters can be updated according to historical training data, so that the obtained mixed gas parameters can meet the requirements of users more.

In addition, to achieve the above object, an embodiment of the present invention further provides an intermittent high-hypoxia training device, which includes an oxygen-containing gas generating device, a respiratory training device, and a controller, the controller includes a memory, a processor, and an intermittent high-hypoxia training program stored on the memory and executable on the processor, and when the intermittent high-hypoxia training program is executed by the processor, the steps of the intermittent high-hypoxia training method according to any one of the above embodiments are implemented.

In addition, to achieve the above object, an embodiment of the present invention further provides a storage medium, on which an intermittent high-hypoxia training program is stored, and the intermittent high-hypoxia training program, when executed by a processor, implements the steps of the intermittent high-hypoxia training method according to any one of the above embodiments.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) as described above and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. An intermittent hypoxia-high training method applied to an intermittent hypoxia-high training system, wherein the intermittent hypoxia-high training system comprises an oxygen-containing gas generating device, a breathing training device, a controller and a wearable device, the wearable device is connected with the controller and is used for acquiring physiological parameters of a user, and the intermittent hypoxia-high training method comprises the following steps:

acquiring the test physiological parameters, and taking the test physiological parameters as the physiological parameters of the user;

acquiring target parameters of the mixed gas corresponding to the physiological parameters of the user based on the corresponding relation between preset physiological parameters and the parameters of the mixed gas, wherein the target parameters comprise target oxygen concentration, target duration and target air pressure, and the target air pressure is standard atmospheric pressure;

controlling the oxygen-containing gas generating equipment to operate, and adjusting the operating parameters of the breathing training equipment to output mixed gas meeting the target parameters;

before the step of obtaining the target parameter of the mixed gas required by the test, the method further comprises the following steps:

2. The intermittent hyperhypoxic training method of claim 1, wherein the oxygen-containing gas generation apparatus comprises an oxygen generation plant comprising an oxygen outlet and a nitrogen-rich gas outlet; the breathing training equipment comprises a gas mixing device, wherein the gas mixing device is provided with a gas mixing valve; the gas mixing valve comprises an air inlet, an oxygen inlet and a nitrogen-rich gas inlet, wherein the air inlet, the oxygen inlet and the nitrogen-rich gas inlet are respectively provided with a starting and closing piece, the oxygen-containing gas generating equipment is controlled to operate, and the operation parameters of the breathing training equipment are adjusted to output mixed gas meeting the target parameters, and the steps comprise:

acquiring oxygen concentration of oxygen, nitrogen-rich gas and air;

3. The intermittent hyperhypoxic training method of claim 1, wherein the intermittent hyperhypoxic training system further comprises a wearable device for acquiring physiological parameters of a user, the step of controlling the oxygen-containing gas generating device to operate, and adjusting operating parameters of the respiratory training device to output a mixed gas that meets the target parameters further comprises:

4. The intermittent hyperhypoxic training method according to claim 1, wherein the breathing training equipment is provided with a gas pressure balance valve, the gas pressure balance valve is opened to communicate the mixed gas with the outside air, the step of controlling the operation of the oxygen-containing gas generation equipment and adjusting the operation parameters of the breathing training equipment to output the mixed gas satisfying the target parameters further comprises:

detecting the gas pressure of the mixed gas in real time or at regular time;

5. An intermittent hypoxia-high training method applied to an intermittent hypoxia-high training system, wherein the intermittent hypoxia-high training system comprises an oxygen-containing gas generating device, a breathing training device, a controller and a wearable device, the wearable device is connected with the controller and is used for acquiring physiological parameters of a user, and the intermittent hypoxia-high training method comprises the following steps:

when the test physiological parameters corresponding to the user are not pre-stored, executing the step of acquiring the target parameters of the mixed gas required by the test;

the step of determining the target parameter of the mixed gas according to the physiological parameter comprises the following steps:

6. The intermittent hyperhypoxic training method according to any one of claims 1-5, wherein prior to the step of controlling operation of the oxygen-containing gas generating device and adjusting operating parameters of the respiratory training device to output a mixed gas that meets the target parameters, further comprises:

determining whether the wearable device is worn normally;

7. An intermittent hyperhypoxic training apparatus, comprising an oxygen-containing gas generation device, a respiratory training device, and a controller, the controller comprising a memory, a processor, and an intermittent hyperhypoxic training program stored on the memory and executable on the processor, the intermittent hyperhypoxic training program when executed by the processor implementing the steps of the intermittent hyperhypoxic training method as claimed in any one of claims 1 to 6.

8. A storage medium having stored thereon an intermittent hyperhypoxic training procedure, which when executed by a processor, carries out the steps of the intermittent hyperhypoxic training method according to any one of claims 1 to 6.