KR102218162B1 - Hyperbaric oxygen therapy device using carbon fiber - Google Patents

Abstract

The present invention relates to a hyperbaric oxygen therapy apparatus using carbon fiber as a major material to provide portability. According to the present invention, the hyperbaric oxygen therapy apparatus comprises: a chamber having a receiving space formed therein to receive a patient and having one side formed therein to be opened by an opening and closing unit; an oxygen supply unit connected to the chamber by a connection line to supply high-pressure oxygen to the receiving space; and a control unit electrically connected to a power supply unit and the oxygen supply unit and controlling operation of the oxygen supply unit. The chamber is made of carbon fiber and includes a carbon fiber layer provided as one or more layers and a fixing material hardened after being applied to the outer and inner surfaces of the carbon fiber layer.

Description

Hyperbaric oxygen therapy device using carbon fiber

The present invention relates to a high-pressure oxygen treatment apparatus using carbon fiber as the main material, and more particularly, to a high pressure oxygen treatment device using carbon fiber as the main material, which has convenience of movement by reducing the weight of the chamber. Oxygen therapy device It relates to a hyperbaric oxygen therapy device.

In general, the hyperbaric oxygen therapy device is the main equipment used for hyperbaric oxygen therapy, and has a treatment method of breathing 1 to 2 hours with 100% pure oxygen in a state where the atmospheric pressure higher than the general breathing environment is raised.

This high-pressure oxygen treatment device is manufactured in a cylindrical shape to withstand a pressure of 1 to 5 atmospheres, and a chamber in which an accommodation space is formed to accommodate the user, and oxygen supply to supply high pressure oxygen into the chamber. Consist of devices, etc. In addition, the chamber is equipped with an opening and closing door to allow the user to enter, and is manufactured in a form that can be entered by one or multiple personnel, and the outer wall is made of thick steel to withstand high pressure (6 atmospheres, etc.). .

However, since the conventional chamber weighs a lot (approximately 20 to 30 tons), a separate structural reinforcement work was required to support the weight of the chamber in the case of the ground floor.In the process of transporting the chamber, the traffic line passes through a narrow entrance door. It had to be done, so there was a difficulty in the transport and installation process. In addition, since it was manufactured using steel, the manufacturing cost increased, and the appearance was not beautiful due to poor workability.

In the case of a single-person chamber, movable wheels are installed, but the weight of the chamber is heavy, so patients are treated while being fixedly installed in a separate chamber. Therefore, there was a discomfort in that critically ill patients or elderly people with disabilities had to frequently move to the location where the chamber was installed.

A prior document related to the present invention is Korean Patent Registration No. 10-1671506 (October 26, 2016), and the prior document discloses a locking device for a multi-person hyperbaric oxygen chamber.

An object of the present invention relates to a hyperbaric oxygen treatment apparatus using carbon fiber as a main material, which can reduce the weight of the chamber and thus has the convenience of movement.

The hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention includes a chamber in which an accommodation space for accommodating a user is formed, and one side is provided to be opened and closed by an opening and closing part, and the chamber and the connection line An oxygen supply unit that is connected to supply high pressure oxygen to the accommodation space, and a control unit that is electrically connected to a power supply unit and controls driving of the oxygen supply unit, wherein the chamber is made of carbon fiber, and one It characterized in that it comprises a carbon fiber layer provided with the above layers, and a fixing material that is hardened after being applied to the outer and inner surfaces of the carbon fiber layer, respectively.

In addition, the carbon fiber layer may be spaced apart from a plurality of the spaced portions to form two or more layers, and the spacer may further include a buffer material attached to the inner and outer surfaces of the carbon fiber layer by the fixing material. .

In addition, a first reinforcing mesh portion having a lattice shape may be further provided within the thickness of the carbon fiber layer, and the first reinforcing mesh portion may form one or more layers.

In addition, a second reinforcing mesh portion having a grid shape may be further provided within the thickness of the buffer material, and the second reinforcing mesh portion may form one or more layers.

In addition, a far-infrared lamp may be further provided inside the receiving space, which is electrically connected to the control unit and emits far infrared ray to the user's head when driven.

In addition, a sterilization lamp may be further provided inside the accommodation space, which is electrically connected to the control unit and emits ultraviolet rays (UV) having a set wavelength to the outside when driving.

In addition, the interior of the accommodation space is further provided with a charging unit electrically connected to the control unit and provided with a charging terminal, and at least one frequency generator that is charged in contact with the charging terminal and generates low or high frequencies when driven Can be.

In addition, the pressure pipe is coupled through to one side of the chamber, the internal pressure space penetrates the receiving space and the outside of the chamber, and is coupled to one end of the pressure pipe from the outside of the chamber in a screwing manner, A first plug portion having a first through hole formed so that the infusion supply line passes from the outside, and the other end of the pressure tube in the receiving space is screwed together, and through the first through hole and the pressure space A second stopper having a second through hole formed so that the infusion supply line passes into the receiving space, and a ring coupled to the inner circumferential surfaces of the first through hole and the second through hole, respectively, and in close contact with the outer circumferential surface of the infusion supply line A sealing member having a shape may be further provided.

In the present invention, the weight of the chamber can be reduced, so it is easy to carry and install, and it can be easily moved to various locations such as a hospital room, so that the convenience of use can be secured. It has the effect of securing diversity of designs.

1 is a perspective view showing a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
2 is a front view showing a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
3 is a cross-sectional view illustrating a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
Figure 4 is a cross-sectional view showing a state in which the door of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention is opened.
5 is an enlarged cross-sectional view of a main part for showing in detail a far-infrared lamp, a sterilization lamp, a charging part, and a frequency generator of the high-pressure oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
6 is an enlarged cross-sectional view illustrating a state in which a carbon fiber layer is formed in one layer of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
7 is a cross-sectional view illustrating a first reinforcing mesh portion of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
FIG. 8 is a front view of a portion of a chamber in cross section to show the first reinforcing mesh portion of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
9 is a cross-sectional view showing a second reinforcing mesh portion of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
10 is a cross-sectional view showing a state in which an inflow groove is formed in a buffer material of a high-pressure oxygen treatment apparatus using carbon fiber as a main material according to the present invention.
11 is a cross-sectional view showing a state in which a fluid supply structure is applied to a chamber of a high-pressure oxygen treatment apparatus using carbon fiber as a main material according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Advantages and features of the present invention, and a method of achieving the same will become apparent with reference to the embodiments described below in detail together with the accompanying drawings.

However, the present invention is not limited by the embodiments disclosed below, but will be implemented in a variety of different forms, only these embodiments are intended to complete the disclosure of the present invention, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims.

In addition, when it is determined that related well-known technologies or the like may obscure the subject matter of the present invention in describing the present invention, detailed descriptions thereof will be omitted.

1 is a perspective view for showing a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention, and FIG. 2 is a front view for showing a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention, 3 is a cross-sectional view illustrating a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.

Figure 4 is a cross-sectional view showing a state in which the door of the hyperbaric oxygen treatment device made of carbon fiber as a main material according to the present invention is opened, and FIG. 5 is a view of the hyperbaric oxygen treatment device made of carbon fiber as a main material according to the present invention. It is an enlarged cross-sectional view of the main part to show in detail the far-infrared lamp, the sterilization lamp, the charging part, and the frequency generating part. It is an enlarged cross-sectional view of the main part to show.

7 is a cross-sectional view showing a first reinforcing mesh portion of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention, and FIG. 8 is a first view of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention. It is a front view in which a part of the chamber is processed in cross section to show the first reinforcing mesh part, and FIG. 9 is a cross-sectional view illustrating the second reinforcing mesh part of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention. 10 is a cross-sectional view showing a state in which an inflow groove is formed in a buffer material of a high-pressure oxygen treatment apparatus using carbon fiber as a main material according to the present invention. 11 is a cross-sectional view showing a state in which a fluid supply structure is applied to a chamber of a hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention.

Referring to FIGS. 1 to 11, a high-pressure oxygen treatment apparatus using carbon fiber as a main material according to the present invention includes a chamber 100, an oxygen supply unit 200, and a control unit 300.

In the chamber 100, the lower end of the chamber 100 is horizontally seated on the installation surface, and a receiving space 101 of a certain width is formed therein to accommodate a user, and one side of the chamber 100 is opened so that the user can enter and exit. An opening/closing part 120 is provided at the inlet 102 so as to be open/closed.

Here, the chamber 100 may have lengths on both sides so that the user can lie down, a plurality of rollers capable of rotating and fixing may be provided at the bottom of the chamber 100, and the bottom surface of the accommodation space 101 may have a user A mattress of a certain width may be installed so that the person can lie down. In addition, the inlet 102 may be formed on the upper portion of the chamber 100, but the location of the inlet 102 is not limited.

The opening/closing unit 160 is installed on the inner circumferential surface of the installation space 101 and has a guide rail 161 having a length in the opening and closing direction, and both ends are slidably connected to the guide rail 161 to open the inlet 102 And a door 162 that is movable in a closing direction, and a handle 163 coupled to an outer surface of the door 162 so that the user can grip it with his or her hand.

The guide rail 161 may be horizontally coupled to both side walls of the installation space 101, and both ends of the door 162 may be connected to the guide rail 161, respectively, and the door 162 is an accommodation space 101 It can be made of a transparent material so that users of the company can be seen from the outside.

In a different form, the opening/closing unit 160 may be applied in an opening/closing method instead of a slide method. In this case, the opening/closing unit 160 is provided so that the door can be rotated and opened based on a hinge unit (not shown) installed on one side of the entrance 102, and the one end of the door and the corresponding one side of the entrance are locked to enable coupling and separation. A member (not shown) may be provided.

In particular, the chamber 100 is provided with carbon fiber, a carbon fiber layer 110 provided with one or more layers, and a fixing material 120 that is hardened after being applied to the outer and inner surfaces of the carbon fiber layer 110, respectively. It may include. The fixing member 120 may be made of a material such as resin or epoxy, but the fixing member 120 may selectively use various materials as needed.

In addition, the carbon fiber layer 110 is spaced apart from each other based on the gap portion (G) to form two or more layers, and the gap portion (G) is attached to the inner and outer surfaces of the carbon fiber layer 110 by a fixing material, respectively. A buffer material 130 may be further provided. The cushioning material 130 may be made of a urethane material capable of elastic deformation, but the cushioning material 130 may be selectively used in a variety of materials as needed.

Here, a plurality of inlet grooves 131 may be further concave formed on the outer and inner surfaces of the buffer material 130, and the shape and number of the inlet grooves 131 may be variously applied as necessary. Since the inflow groove 131 forms a space through which the fixing member 120 is introduced, the contact area with the hardened fixing member 120 can be increased, and the bonding force between the buffer member 130 and the fixing member 120 can be further improved through this. .

Since such a cushioning material 130 is applied as a material capable of elastic deformation, it can buffer the force acting in the outer and inner directions between the carbon fiber layers 110, and the receiving space 101 greatly affects the external temperature, etc. It has a function to insulate so that it is not received.

For example, the carbon fiber layer 110 may be formed of one layer or a plurality of layers. When the carbon fiber layer 110 is applied as one layer as shown in FIG. 6, the outer and inner surfaces of the carbon fiber layer 110 The fixing member 120 may be provided in an attached state. At this time, since the fixing material 120 is hardened after being applied to the surface of the carbon fiber layer 110 in a viscous state, it has a function of protecting the outer and inner surfaces of the carbon fiber layer 110 from external force.

On the other hand, when the carbon fiber layer 110 is applied as a plurality of layers, the cushioning material 130 may be disposed in the gap G formed between the carbon fiber layers 110, and on the outer and inner surfaces of the buffering material 130 Each of the fixing members 120 may be attached. At this time, since the fixing material 120 is hardened after being applied to the surface of the carbon fiber layer 110 in a viscous state, it has a function of protecting the outer and inner surfaces of the carbon fiber layer 110 from external forces, and the carbon fiber layer 110 The fixing material 120 formed between them has a function of attaching the carbon fiber layer 110 and the buffer material 130.

In addition, the carbon fiber layer 110 may further include a first reinforcing mesh portion 140 having a lattice shape as shown in FIGS. 7 and 8. The first reinforcing mesh portion 140 may be formed of a material such as metal, and the first reinforcing mesh portion 140 may form one or more layers.

Here, the first reinforcing mesh portion 140 may combine or integrally form a plurality of metal beams having a length in a grid form, and the first reinforcing mesh portion 140 is inserted into the thickness of the carbon fiber layer 110 It may be installed in a state that is installed or attached to the outer or inner surface of the carbon fiber layer 110.

Since the first reinforcing mesh unit 140 is installed in a state of being combined with the carbon fiber layer 110, the strength of the carbon fiber layer 110 can be improved, and the shape of the carbon fiber layer 110 is deformed by the action of an external force. Can be prevented from being damaged or damaged.

Meanwhile, the buffer material 130 may further include a second reinforcing mesh portion 150 having a lattice shape as shown in FIG. 9. The second reinforcing mesh portion 150 may be formed of a material such as metal, and the second reinforcing mesh portion 150 may form one or more layers.

Here, the second reinforcing mesh portion 150 may combine or integrally form a plurality of metal beams having a length in a grid shape, and the second reinforcing mesh portion 150 is inserted into the thickness of the buffer material 130. It may be installed in a state, or may be installed in a state attached to the outer or inner surface of the cushioning material 130.

Since the second reinforcing mesh unit 150 is installed in a state coupled to the buffer material 130, the strength of the buffer material 130 can be improved, and the shape of the buffer material 130 is deformed or damaged by the action of an external force. Can be prevented.

The oxygen supply unit 200 is connected to the chamber 100 by a connection line 210 to supply high pressure oxygen to the accommodation space 110. Here, the oxygen supply unit 200 may be composed of an oxygen tank in which liquid oxygen is stored, a vaporizer, a liquid nitrogen tank, a compressor, a filter, etc., and the high pressure is transferred to the receiving space 101 of the chamber 100 by driving the compressor. Oxygen can be supplied. The structure of the oxygen supply unit 200 may be applied in various ways as necessary.

The control unit 300 is electrically connected to an external power supply unit 400 and controls driving of the oxygen supply unit 200. Here, the control unit 300 may include a display unit 310 for displaying various types of information by users and managers, and a manipulation unit 320 so that users and managers can control operations.

In this case, the display unit 310 and the operation unit 320 may be installed outside the chamber 100 so that a user and an administrator can manipulate it, and a user located inside the accommodation space 101 can check various information or The display unit 310 and the operation unit 320 may be installed inside the accommodation space 101 so as to be manipulated.

Here, a speaker (not shown) may be provided on the display unit 310 to output voice, music, etc., and a plurality of selection switches may be provided on the operation unit 320 to allow users and administrators to select various functions. have.

In addition, the control unit 300 may interlock with a dedicated application installed in a portable terminal (such as a smartphone). In this case, the controller 300 may be provided with a Bluetooth communication module (not shown), and the user may wirelessly control the controller 300 using a Bluetooth function after installing a dedicated application on the mobile terminal. .

Meanwhile, a far-infrared lamp 500 may be further provided inside the accommodation space 110, which is electrically connected to the control unit 300 as shown in FIG. 5, and emits far infrared ray to the user's head when driven. .

The far-infrared ray lamp 500 is electrically connected to a mounting part installed on one side in the longitudinal direction of the accommodation space 101, a head part installed in an angle-adjustable manner in the mounting part, and a power supply part 400, and driving the control unit 300 It may be provided as a far-infrared ray generator or the like that is heated by control and radiates far-infrared rays to the user's head.

Since such a far infrared lamp 500 emits far infrared rays to the user's head, it can help to eliminate bacteria that cause various diseases, and expand capillaries for blood circulation and cell tissue generation. As it can help, the effect of hair loss treatment can be expected, and it is effective in preventing aging, promoting metabolism, and preventing various adult diseases such as chronic fatigue by activating cell tissue.

In addition, an ultraviolet ray sterilizing lamp 600 is further provided inside the accommodation space 101, which is electrically connected to the control unit 300 as shown in FIG. 5 and emits ultraviolet rays (UV) of a set wavelength to the outside when driving. Can be.

One or more sterilization lamps 600 are installed on the ceiling of the accommodation space 101 to emit ultraviolet (UV) light, and a low-pressure mercury lamp made of ultraviolet-transmitting glass may be used.

Such a sterilization lamp 600 may emit ultraviolet rays (UV) having sterilizing power at a predetermined wavelength (250-280 mm, etc.). That is, since harmful bacteria existing in the receiving space 101 can be removed, the receiving space 101 can be maintained in a sterile state.

In addition, the interior of the accommodation space 101 is electrically connected to the control unit 300 as shown in FIG. 5 and is charged in contact with the charging terminal and the charging unit 710 provided with a charging terminal, and a low frequency or high frequency is generated when driving. One or more frequency generators 720 for generating generation may be further provided.

For example, the frequency generator 720 may be attached to the user's human body (arms, legs, waist, etc.) to transmit low frequencies. In this case, the frequency generator 720 is provided with a pad attachable to the user's human body, a body coupled to the pad, and installed inside the body, and provided with an operation switch to enable operation, and connected to the charging unit 710 It may be composed of a circuit unit provided with a terminal, and a power supply unit installed inside the body to supply power to the circuit unit.

On the other hand, the frequency generator 720 may transmit a high frequency to the user's human body (face, arms, legs, waist, etc.). In this case, the frequency generator 720 is provided with a main body that can be gripped by the user, a contact part provided on one side of the main body and in contact with the user's human body, and an operation switch installed inside the main body and operable. , A circuit unit provided with a connection terminal to be connected to the charging unit 710, and a power supply unit installed inside the main body and supplying power to the circuit unit.

When generating a low frequency, the frequency generator 720 can repeat muscle contraction by electrical stimulation of nerves and muscles, so that a low frequency pulse is applied to the user's body to eliminate pain or stimulation of nerves and muscles. Can be used for purposes. That is, it can activate the user's metabolism and relieve symptoms such as muscle pain and stiffness that occur in areas such as arms, legs, shoulders, and back.

In addition, when high frequency is generated, high therapeutic effects can be obtained for a short period of time, and biological heat can be generated, thereby increasing blood flow, increasing metabolism, promoting lymphatic circulation, and regenerating cells in damaged tissues.

On the other hand, to the hyperbaric oxygen treatment apparatus using carbon fiber as a main material of the present invention, a fluid supply structure for supplying the sap 10 from the outside may be applied. For this purpose, a pressure tube 810 which is coupled through to one side of the chamber 100 and penetrates to the outside of the receiving space 101 and the chamber 100, and a pressure tube from the outside of the chamber 100. A first plug part 820, which is coupled to one end of the 810 in a screw connection manner, and in which a first through hole 821 is formed so that the infusion supply line 20 passes from the outside of the chamber 100, and an accommodation space It is coupled to the other end of the pressure pipe 810 in the interior of 101 in a screwing manner, and the infusion supply line 20 through the first through hole 821 and the pressure space 811 passes through the receiving space 101 A second stopper 830 in which a second through hole 831 is formed, and a ring coupled to the inner circumferential surfaces of the first through hole 821 and the second through hole 831, respectively, and in close contact with the outer circumferential surface of the infusion supply line A sealing member 840 having a shape may be further provided.

The pressure tube 810 may be manufactured using a metal material (stainless, etc.) to withstand a certain pressure, and a first plug portion 830 and a second plug portion 840 are provided on the outer peripheral surfaces of both ends of the pressure tube 810. The thread can be formed so that the can be coupled and separated by a screwing method.

The first stopper 830 and the second stopper 840 may be made of reinforced plastics material to withstand a certain pressure, and the first stopper 830 and the second stopper 840 ) May protrude to a certain length so as to surround both ends of the pressure tube 810 from the outside, and both ends of the pressure tube 810 are provided on the inner circumferential surfaces of the first and second stoppers 830 and 840. The thread can be formed so that it can be coupled in a threaded manner.

The sealing member 840 may be manufactured in a ring shape using a material such as rubber or silicon, and the infusion supply line 20 and the first through hole 821 and the infusion supply line 20 and the sealing member 840 Each inner circumferential surface of the second through hole 831 may be sealed.

That is, the infusion supply line 20 connected to the lower end of the infusion solution 10 container passes through the first through hole 821 from the outside of the chamber 100, and is received through the pressure space 811 and the second through hole. It is inserted into the interior of the space 101, the needle coupled to the lower end of the fluid supply line 20 can be connected to the user's body to inject the fluid.

At this time, since the pressure space 811 is maintained at a constant pressure by the first plug portion 820 and the second plug portion 830, the fluid supply line 20 has a great influence on the internal pressure of the receiving space 101. Since it is not received, the fluid 10 can be smoothly injected into the human body of the user from the outside of the chamber 100, and the user can be smoothly supplied with the fluid 10 in the external space and in a predicated space.

As a result, the present invention can reduce the weight of the chamber 100 to facilitate transportation and installation, and can be easily moved to various locations such as a hospital room, thereby ensuring convenience of use, and good processability Since it is possible to manufacture the chamber 100 of various types, it is possible to secure diversity of designs.

Until now, specific embodiments of the hyperbaric oxygen treatment apparatus using carbon fiber as a main material according to the present invention have been described, but it is obvious that various implementation modifications are possible within the limit not departing from the scope of the present invention.

Therefore, the scope of the present invention is limited to the described embodiments and should not be transmitted, and should be determined by the claims and equivalents to the claims to be described later.

That is, it should be understood that the above-described embodiments are illustrative in all respects and not limiting, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

10: sap 20: sap supply line
100: chamber 101: accommodation space
102: inlet 110: carbon fiber layer
120: fixing material 130: cushioning material
131: inlet groove 140: first reinforcing mesh portion
150: second reinforcing mesh portion 160: opening and closing portion
161: guide rail 162: door
163: handle 200: oxygen supply
210: connection line 300: control unit
310: display unit 320: operation unit
400: power supply 500: far infrared lamp
600: germicidal lamp 710: charging unit
720: frequency generator
810: pressure pipe 811: pressure space
820: first plug 821: first through hole
830: second stopper 831: second through hole
840: sealing member G: spacing portion

Claims (8)

A chamber in which an accommodation space capable of accommodating a user is formed, and one side thereof is provided to be opened and closed by an opening/closing unit;
An oxygen supply unit connected to the chamber by a connection line to supply high pressure oxygen to the accommodation space; And
Includes; a control unit electrically connected to the power supply unit and controlling the driving of the oxygen supply unit,
The chamber includes a carbon fiber layer provided with carbon fiber and provided with one or more layers, and a fixing material that is hardened after being applied to the outer and inner surfaces of the carbon fiber layer, respectively,
A plurality of the carbon fiber layers are spaced apart from each other to form two or more layers,
The hyperbaric oxygen therapy apparatus comprising carbon fibers as a main material, wherein a buffer material attached to the inner and outer surfaces of the carbon fiber layer is further provided in the spacer by the fixing member. delete The method of claim 1,
A grid-shaped first reinforcing mesh portion is further provided within the thickness of the carbon fiber layer,
The hyperbaric oxygen treatment apparatus comprising carbon fibers as a main material, wherein the first reinforcing mesh portion forms one or more layers. The method of claim 1,
A second reinforcing mesh portion having a grid shape is further provided within the thickness of the buffer material,
The second reinforcing mesh portion is a hyperbaric oxygen treatment apparatus comprising carbon fibers as a main material, characterized in that one or more layers are formed. The method of claim 1,
Hyperbaric oxygen therapy using carbon fiber as a main material, characterized in that a far infrared ray lamp is further provided in the interior of the accommodation space, which is electrically connected to the control unit and emits a far infrared ray to the user's head when driven Device. The method of claim 1,
A high-pressure oxygen treatment apparatus comprising carbon fiber as a main material, further comprising a sterilizing lamp electrically connected to the control unit in the receiving space and emitting ultraviolet (UV) rays of a set wavelength to the outside when driving. The method of claim 1,
A charging unit electrically connected to the control unit and provided with a charging terminal inside the accommodation space,
The hyperbaric oxygen treatment apparatus comprising carbon fiber as a main material, characterized in that at least one frequency generator that is charged in contact with the charging terminal and generates a low or high frequency when driven is further provided. The method of claim 1,
A pressure tube penetratingly coupled to one side of the chamber and penetrating an inner pressure space to the receiving space and the outside of the chamber,
A first stopper coupled to one end of the pressure tube from the outside of the chamber in a screwing manner, and having a first through hole formed so that the fluid supply line passes from the outside of the chamber,
A second stopper coupled with the other end of the pressure tube in the receiving space in a screw connection manner and having a second through hole formed so that the first through hole and the fluid supply line through the pressure space pass through the receiving space Wealth and,
The hyperbaric oxygen treatment apparatus comprising carbon fiber as a main material, further comprising a ring-shaped sealing member coupled to the inner circumferential surfaces of the first through hole and the second through hole and in close contact with the outer circumferential surface of the infusion supply line.

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