CN114403537B - Equipment for promoting cell perception and adapting to oxygen change mechanism and application method - Google Patents

Abstract

The application relates to a device for promoting cell perception and adapting to an oxygen change mechanism, which comprises a helmet and a high-low oxygen generation host, wherein the high-low oxygen generation host comprises a high-concentration interface and a low-concentration interface; the helmet is formed by splicing a first cambered surface type region, a second cambered surface type region, a third cambered surface type region and a fourth cambered surface type region; the second cambered surface type area, the third cambered surface type area and the fourth cambered surface type area are respectively provided with an air outlet, the first cambered surface type area is provided with a plurality of air inlets, the air outlets are provided with electromagnetic valves, the high-low oxygen generating host is provided with a controller, the outer surface of the helmet is uniformly distributed with a plurality of touch switches, and all electromagnet assemblies are powered off when any touch switch is triggered; the automatic switching between hypoxia and hyperoxia can be operated through the operation of the controller, the device can be triggered and disintegrated when the device is in a motion sickness state, the device is separated from a training device, and the device is more convenient to train and can improve safety.

Description

Equipment for promoting cell perception and adapting to oxygen change mechanism and application method

Technical Field

The application relates to the technical field of normal pressure intermittent high-low oxygen training, in particular to equipment for promoting cell perception and adapting to an oxygen change mechanism and an application method thereof.

Background

The mechanism for promoting cell perception and adapting to oxygen change refers to accumulation of HIF-1 alpha in Hypoxia inducible factor (Hypoxia-inducible factors, abbreviated as HIF-1) consisting of alpha and beta subunits under Hypoxia conditions, and the accumulation of HIF-1 alpha and HIF-1 beta form HIF-1 together with a cofactor by transport of an input protein into a cell nucleus, thereby exerting its transcriptional activation function. Under normal oxygen conditions, hypoxia inducible factor (HIF-1) in the human body rapidly breaks down, but when the oxygen content is reduced, the level of hypoxia inducible factor (HIF-1) in the human body increases, and hypoxia inducible factor (HIF-1) can control the expression level of Erythropoietin (EPO), and when the level of hypoxia inducible factor (HIF-1) increases, the level of Erythropoietin (EPO) also increases, stimulating bone marrow to produce new red blood cells, and red blood cells bring oxygen.

Intermittent hypoxia training (INTERVAL HYPOXIA TRAINING-abbreviated as IHT) can achieve the training effect of promoting cell perception and adapting to oxygen change mechanism by applying the principle, effectively improve body functions and improve tolerance of the body to hypoxia environment. The intermittent hypoxia training is proved by medicine and physiology at present, has obvious treatment effects on cardiovascular system and metabolic diseases and improving human brain cognition, and can be used for improving human body functions, enhancing human body immune system, nonspecific compensation capability and aerobic output.

The intermittent hypoxia training device adopted at present is quite simple, manual switching of high-oxygen and low-oxygen tracheal connection is generally needed, operation is quite inconvenient, and equipment which is more convenient to switch and can be used for passively triggering and releasing the training device when accidental motion sickness occurs is needed.

Disclosure of Invention

The application aims to overcome the defects in the prior art and provides equipment for promoting cell perception and adapting to an oxygen change mechanism and an application method thereof.

The technical scheme adopted for solving the technical problems is as follows:

an apparatus configured to facilitate cellular perception and to accommodate oxygen change mechanisms, comprising a wearable helmet and a hypoxia generating host comprising a high concentration interface to generate a high concentration of oxygen and a low concentration interface to generate a low concentration of oxygen; the helmet is formed by splicing a hollow first cambered surface type region corresponding to the face of a human body, a hollow second cambered surface type region corresponding to the brain on the left side of the human body, a hollow third cambered surface type region corresponding to the brain on the right side of the human body and a hollow fourth cambered surface type region corresponding to the back brain and the top of the brain of the human body, wherein a breathing port for breathing the mouth and nose of the human body is arranged on the first cambered surface type region; any two adjacent first cambered surface type areas, second cambered surface type areas, third cambered surface type areas and fourth cambered surface type areas are adsorbed by an electromagnet assembly; one of the second cambered surface type region and the third cambered surface type region is communicated with the high-concentration interface and is used for providing a high-oxygen environment, the other is communicated with the low-concentration interface and is used for providing a low-oxygen environment, and an opening communicated with the outside is arranged on the fourth cambered surface type region and is used for providing a normal oxygen environment; the novel helmet comprises a helmet body, wherein a first cambered surface type region, a second cambered surface type region, a third cambered surface type region and a fourth cambered surface type region are arranged on the helmet body, a plurality of air inlets corresponding to the air outlets one by one are arranged on the first cambered surface type region, electromagnetic valves are arranged on the air inlets, controllers for controlling the electromagnetic valves are arranged on a high-low oxygen generation host, a plurality of touch switches are uniformly distributed on the outer surface of the helmet body, and all electromagnet assemblies are powered off when any touch switch is triggered.

The application relates to a device for promoting cell perception and adapting to an oxygen change mechanism, wherein an electromagnet assembly comprises an electromagnet and an iron piece which are matched and adsorbed; the electromagnet is provided with a plurality of positioning convex blocks, a plurality of positioning grooves matched with the positioning convex blocks are formed in the iron piece, and springs and containing holes for containing the springs are formed in the bottom of the positioning grooves.

The application relates to a device for promoting cell perception and adapting to an oxygen change mechanism, wherein a silica gel ring which is attached to the face of a human body is arranged on the peripheral side of a breathing port.

The device for promoting cell perception and adapting to an oxygen change mechanism disclosed by the application is characterized in that the helmet is made of a transparent material.

The device for promoting cell perception and adapting to an oxygen change mechanism comprises a helmet, wherein the inner surface of the helmet is provided with a flexible lining which is attached to the head of a human body.

The application method of the device for promoting cell perception and adapting to the oxygen change mechanism is applied to the device for promoting cell perception and adapting to the oxygen change mechanism, and the application method is as follows:

the first cambered surface type region, the second cambered surface type region, the third cambered surface type region and the fourth cambered surface type region are respectively and correspondingly attached to the face, the left brain, the right brain, the back brain and the top of the brain of a human body, all electromagnetic assemblies are started to be adsorbed and spliced to form a helmet, in an initial state, a battery valve on the fourth cambered surface type region is kept normally open, the battery valves on the second cambered surface type region and the third cambered surface type region are kept normally closed, and after the helmet is worn, the fourth cambered surface type region provides a normal air supply environment for the first cambered surface type region;

firstly, generating a high-oxygen environment for the second cambered surface type region and generating a low-oxygen environment for the third cambered surface type region by operating a high-low oxygen generating host; when high-oxygen training is needed, the battery valves on the fourth cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the second cambered surface type region is opened; when the hypoxia training is needed, the battery valves on the fourth cambered surface type region and the second cambered surface type region are operated by the controller to be closed, and the battery valve on the third cambered surface type region is opened; when training is finished, the battery valves on the second cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the fourth cambered surface type region is opened;

after training, any touch switch is actively triggered or the human head collides with the external ground when accidental dizziness occurs, so that all electromagnet assemblies are powered off, and the first cambered surface type region, the second cambered surface type region, the third cambered surface type region and the fourth cambered surface type region are automatically disassembled.

The application has the beneficial effects that: the first cambered surface type region, the second cambered surface type region, the third cambered surface type region and the fourth cambered surface type region are respectively and correspondingly attached to the face, the left brain, the right brain, the back brain and the top of the brain of a human body, all electromagnetic assemblies are started to be adsorbed and spliced to form a helmet, in an initial state, a battery valve on the fourth cambered surface type region is kept normally open, the battery valves on the second cambered surface type region and the third cambered surface type region are kept normally closed, and after the helmet is worn, the fourth cambered surface type region provides a normal air supply environment for the first cambered surface type region; firstly, generating a high-oxygen environment for the second cambered surface type region and generating a low-oxygen environment for the third cambered surface type region by operating a high-low oxygen generating host; when high-oxygen training is needed, the battery valves on the fourth cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the second cambered surface type region is opened; when the hypoxia training is needed, the battery valves on the fourth cambered surface type region and the second cambered surface type region are operated by the controller to be closed, and the battery valve on the third cambered surface type region is opened; when training is finished, the battery valves on the second cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the fourth cambered surface type region is opened; after training, actively triggering any touch switch or passively triggering the touch switch when the human head collides with the external ground when the accidental dizziness occurs, so that all electromagnet assemblies are powered off, and the first cambered surface type area, the second cambered surface type area, the third cambered surface type area and the fourth cambered surface type area are automatically disassembled; the automatic switching between hypoxia and hyperoxia can be operated through the operation of the controller, and the automatic switching device can trigger and disintegrate when in motion sickness, so that the automatic switching device is separated from a training device, is reasonable and compact in overall structure, is more convenient to train, and can improve safety.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the present application will be further described with reference to the accompanying drawings and embodiments, in which the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained by those skilled in the art without inventive effort:

FIG. 1 is a top view of an apparatus for facilitating cellular sensing and adapting to oxygen change mechanisms in accordance with a preferred embodiment of the present application;

FIG. 2 is a cross-sectional view of an electromagnet assembly of a device for facilitating cellular sensing and adapting to oxygen change mechanisms in accordance with a preferred embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more apparent, the following description will be made in detail with reference to the technical solutions in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by a person skilled in the art without any inventive effort, are intended to be within the scope of the present application, based on the embodiments of the present application.

The device for promoting cell perception and adapting to oxygen change mechanism according to the preferred embodiment of the present application is shown in fig. 1, and referring to fig. 2, the device comprises a wearable helmet and a high-low oxygen generating host 2, wherein the high-low oxygen generating host 2 comprises a high-concentration interface 20 for generating high-concentration oxygen and a low-concentration interface 21 for generating low-concentration oxygen; the helmet is formed by splicing a hollow first cambered surface type region 10 corresponding to the face of a human body, a hollow second cambered surface type region 11 corresponding to the left brain of the human body, a hollow third cambered surface type region 12 corresponding to the right brain of the human body and a hollow fourth cambered surface type region 13 corresponding to the rear brain and the top of the brain of the human body, wherein a breathing port (forming a breathing mask for breathing by the mouth and nose of the human body) for breathing by the mouth and nose of the human body is arranged on the first cambered surface type region 10; any two adjacent first cambered surface type region 10, second cambered surface type region 11, third cambered surface type region 12 and fourth cambered surface type region 13 are adsorbed by electromagnet assembly 3; a second arc surface type region 11 and a third arc surface type region 12, one of which is communicated with the high concentration interface 20 for providing a high oxygen environment, the other is communicated with the low concentration interface 21 for providing a low oxygen environment, and an opening 130 communicated with the outside is arranged on the fourth arc surface type region 13 for providing a normal oxygen environment; the second cambered surface type region 11, the third cambered surface type region 12 and the fourth cambered surface type region 13 are respectively provided with an air outlet 14, the first cambered surface type region 10 is provided with a plurality of air inlets 15 which are in one-to-one correspondence with the air outlets 14, the air outlets 14 are provided with electromagnetic valves 140, the high-low oxygen generating host 2 is provided with a controller 22 for controlling the plurality of electromagnetic valves 140, the outer surface of the helmet is uniformly distributed with a plurality of touch switches 16, and all the electromagnet assemblies 3 are powered off when any touch switch 16 is triggered;

the first cambered surface type region 10, the second cambered surface type region 11, the third cambered surface type region 12 and the fourth cambered surface type region 13 are respectively and correspondingly attached to the face, the left brain, the right brain, the rear brain and the top of the brain of a human body, all electromagnetic assemblies are started to be adsorbed and spliced to form a helmet (the helmet can be completed with the help of other people and can be assembled and worn one by one), in an initial state, a battery valve on the fourth cambered surface type region 13 is kept normally open (normal oxygen concentration is maintained to supply breath during initial installation), the battery valves on the second cambered surface type region 11 and the third cambered surface type region 12 are kept normally closed, and after the helmet is worn, the fourth cambered surface type region 13 provides a normal air supply environment for the first cambered surface type region 10;

starting training, generating a high-oxygen environment for the second cambered surface type region 10 and generating a low-oxygen environment for the third cambered surface type region 11 by operating the high-low oxygen generating host 2; it should be noted that, the connection relationships may be interchanged as needed, which also belongs to the protection scope of the present application;

when high-oxygen training is required, the battery valves on the fourth cambered surface region 13 and the third cambered surface region 12 are operated by the controller 22 to be closed, and the battery valve on the second cambered surface region 11 is opened;

when the hypoxia training is required, the battery valves on the fourth cambered surface region 13 and the second cambered surface region 11 are closed, and the battery valve on the third cambered surface region 12 is opened through the controller 22;

when training is finished, the battery valves on the second cambered surface type region 11 and the third cambered surface type region 12 are operated by the controller 22 to be closed, and the battery valve on the fourth cambered surface type region 13 is opened;

after training, actively triggering any touch switch or passively triggering the touch switch when the human head collides with the external ground when the accidental dizziness occurs, so that all electromagnet assemblies are powered off, and the first cambered surface type area, the second cambered surface type area, the third cambered surface type area and the fourth cambered surface type area are automatically disassembled;

the automatic switching between hypoxia and hyperoxia can be operated through the operation of the controller, and the automatic switching device can trigger and disintegrate when in motion sickness, so that the automatic switching device is separated from a training device, is reasonable and compact in overall structure, is more convenient to train, and can improve safety.

Preferably, the electromagnet assembly 3 comprises an electromagnet 30 and an iron piece 31 which are matched and attracted; the electromagnet 30 is provided with a plurality of positioning convex blocks 300, the iron piece 31 is provided with a plurality of positioning grooves 310 matched with the positioning convex blocks 300, and the bottom of the positioning groove 310 is provided with a spring 311 and a containing hole 312 for containing the spring 311;

when the electromagnet is mounted, the positioning convex blocks and the positioning grooves are positioned in one-to-one correspondence, at the moment, the springs are compressed and are all positioned in the accommodating holes, the electromagnet is started to absorb the iron piece, namely, the assembly is completed, when the electromagnet is dismounted, the electromagnet is powered off, and the electromagnet and the iron piece are separated by the elasticity of the springs;

it should be noted that the length of the positioning protruding block needs to be paid attention to, and interference is not brought to the disassembly of the helmet; in a preferred embodiment, the positioning lug is a cambered surface, and of course, the positioning lug can also be in other forms such as a pyramid.

Preferably, the breathing mouth week side is provided with the laminating silica gel circle of laminating human face, and the internal surface of helmet is provided with the flexible inside lining of laminating human head, and the travelling comfort of being convenient for ensure to dress to and the laminating leakproofness to the mouth and nose.

Preferably, the helmet is made of transparent material, preferably plastic or glass material.

The application method of the device for promoting cell perception and adapting to the oxygen change mechanism is applied to the device for promoting cell perception and adapting to the oxygen change mechanism, and the application method is as follows:

the first cambered surface type region, the second cambered surface type region, the third cambered surface type region and the fourth cambered surface type region are respectively and correspondingly attached to the face, the left brain, the right brain, the back brain and the top of the brain of a human body, all electromagnetic assemblies are started to be adsorbed and spliced to form a helmet, in an initial state, a battery valve on the fourth cambered surface type region is kept normally open, the battery valves on the second cambered surface type region and the third cambered surface type region are kept normally closed, and after the helmet is worn, the fourth cambered surface type region provides a normal air supply environment for the first cambered surface type region;

firstly, generating a high-oxygen environment for the second cambered surface type region and generating a low-oxygen environment for the third cambered surface type region by operating a high-low oxygen generating host; when high-oxygen training is needed, the battery valves on the fourth cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the second cambered surface type region is opened; when the hypoxia training is needed, the battery valves on the fourth cambered surface type region and the second cambered surface type region are operated by the controller to be closed, and the battery valve on the third cambered surface type region is opened; when training is finished, the battery valves on the second cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the fourth cambered surface type region is opened;

after training, actively triggering any touch switch or passively triggering the touch switch when the human head collides with the external ground when the accidental dizziness occurs, so that all electromagnet assemblies are powered off, and the first cambered surface type area, the second cambered surface type area, the third cambered surface type area and the fourth cambered surface type area are automatically disassembled;

the automatic switching between hypoxia and hyperoxia can be operated through the operation of the controller, and the automatic switching device can trigger and disintegrate when in motion sickness, so that the automatic switching device is separated from a training device, is reasonable and compact in overall structure, is more convenient to train, and can improve safety.

It will be understood that modifications and variations will be apparent to those skilled in the art from the foregoing description, and it is intended that all such modifications and variations be included within the scope of the following claims.

Claims (6)

1. An apparatus for facilitating cellular perception and adapting to oxygen change mechanisms comprising a wearable helmet and a high-low oxygen generating host comprising a high-concentration interface for generating high concentration oxygen and a low-concentration interface for generating low concentration oxygen; the helmet is formed by splicing a hollow first cambered surface type region corresponding to the face of a human body, a hollow second cambered surface type region corresponding to the brain on the left side of the human body, a hollow third cambered surface type region corresponding to the brain on the right side of the human body and a hollow fourth cambered surface type region corresponding to the back brain and the top of the brain of the human body, wherein a breathing port for breathing the mouth and nose of the human body is arranged on the first cambered surface type region; any two adjacent first cambered surface type areas, second cambered surface type areas, third cambered surface type areas and fourth cambered surface type areas are adsorbed by an electromagnet assembly; one of the second cambered surface type region and the third cambered surface type region is communicated with the high-concentration interface and is used for providing a high-oxygen environment, the other is communicated with the low-concentration interface and is used for providing a low-oxygen environment, and an opening communicated with the outside is arranged on the fourth cambered surface type region and is used for providing a normal oxygen environment; the novel helmet comprises a helmet body, wherein a first cambered surface type region, a second cambered surface type region, a third cambered surface type region and a fourth cambered surface type region are arranged on the helmet body, a plurality of air inlets corresponding to the air outlets one by one are arranged on the first cambered surface type region, electromagnetic valves are arranged on the air inlets, controllers for controlling the electromagnetic valves are arranged on a high-low oxygen generation host, a plurality of touch switches are uniformly distributed on the outer surface of the helmet body, and all electromagnet assemblies are powered off when any touch switch is triggered.

2. The apparatus for facilitating cellular sensing and adapting to oxygen change mechanisms of claim 1, wherein the electromagnet assembly comprises an electromagnet and a ferrous member that cooperate to attract; the electromagnet is provided with a plurality of positioning convex blocks, a plurality of positioning grooves matched with the positioning convex blocks are formed in the iron piece, and springs and containing holes for containing the springs are formed in the bottom of the positioning grooves.

3. The apparatus for promoting cellular perception and adapting to oxygen changing mechanisms according to claim 1, wherein the peripheral side of the breathing opening is provided with a fitting silicone ring fitting the face of the human body.

4. The apparatus for promoting cellular perception and adaptation to the oxygen change mechanism of claim 1, wherein the helmet is made of a transparent material.

5. The apparatus for promoting cellular perception and adapting to the mechanism of oxygen change according to claim 1, wherein the inner surface of the helmet is provided with a flexible lining that fits the human head.

6. A method for applying a device for promoting cell perception and adapting to oxygen change mechanism, applied to the device for promoting cell perception and adapting to oxygen change mechanism according to any one of claims 1-5, characterized in that the application method is as follows:

the first cambered surface type region, the second cambered surface type region, the third cambered surface type region and the fourth cambered surface type region are respectively and correspondingly attached to the face, the left brain, the right brain, the back brain and the top of the brain of a human body, all electromagnetic assemblies are started to be adsorbed and spliced to form a helmet, in an initial state, a battery valve on the fourth cambered surface type region is kept normally open, the battery valves on the second cambered surface type region and the third cambered surface type region are kept normally closed, and after the helmet is worn, the fourth cambered surface type region provides a normal air supply environment for the first cambered surface type region;

firstly, generating a high-oxygen environment for the second cambered surface type region and generating a low-oxygen environment for the third cambered surface type region by operating a high-low oxygen generating host; when high-oxygen training is needed, the battery valves on the fourth cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the second cambered surface type region is opened; when the hypoxia training is needed, the battery valves on the fourth cambered surface type region and the second cambered surface type region are operated by the controller to be closed, and the battery valve on the third cambered surface type region is opened; when training is finished, the battery valves on the second cambered surface type region and the third cambered surface type region are operated by the controller to be closed, and the battery valve on the fourth cambered surface type region is opened;

after training, any touch switch is actively triggered or the human head collides with the external ground when accidental dizziness occurs, so that all electromagnet assemblies are powered off, and the first cambered surface type region, the second cambered surface type region, the third cambered surface type region and the fourth cambered surface type region are automatically disassembled.