KR20230003806A - Movable type high pressure oxygen chamber sysyem with sliding door - Google Patents

Abstract

A modularized mobile high-pressure oxygen therapy system is provided. The high-pressure oxygen therapy system can be quickly moved to the scene of an accident, to treat a patient, so that time can be remarkably shortened and a survival rate can be drastically increased. The high-pressure oxygen therapy system according to the present invention comprises: a sealing unit which has an inner space where a patient can be located, and includes an inlet port through which high-pressure oxygen is injected therein, and an outlet port through which air is discharged from the inside; a pressure control unit which controls the inlet port and the outlet port to be closed and closed, to adjust the pressure in the inner space of the sealing unit; a piping unit which receives high-pressure oxygen from the outside, and transfers the high-pressure oxygen to the sealing unit through the pressure control unit; a door unit; a support unit; and a second moving unit which opens and closes the door unit from the sealing unit by moving the door unit and the support unit in one direction and the other direction.

Description

Movable hyperbaric oxygen therapy system with sliding door {MOVABLE TYPE HIGH PRESSURE OXYGEN CHAMBER SYSYEM WITH SLIDING DOOR}

The present invention relates to a mobile hyperbaric oxygen therapy system. More specifically, it relates to a hyperbaric oxygen treatment system that is mounted and movably mounted on a vehicle, enabling immediate response and treatment in the event of an accident, and that is opened and closed by a sliding door.

The hyperbaric oxygen chamber is a major equipment used in hyperbaric oxygen treatment. It is a treatment that breathes for 1 to 2 hours with 100% purity or very high concentration oxygen at a higher pressure than the general breathing environment. It is used to increase the quality and effect of treatment by effectively supplying oxygen to tissue cells damaged by edema and infection. The hyperbaric oxygen chamber is provided with an entrance to accommodate the patient, but there is a problem in that oxygen leaks through the entrance during hyperbaric oxygen treatment. Hyperbaric oxygen therapy is a method of treating a patient using high-pressure oxygen. Because high-pressure oxygen is used, it is easily exposed to fire or explosion, so a technique for firmly blocking oxygen leakage from the above-mentioned entrance is important. In addition, when moving by storing high-pressure oxygen in a vehicle, there is a problem in that the risk in case of an accident may greatly increase.

Republic of Korea Registered Utility Model No. 20-0454012 (registered on Jun. 1, 2011)

A technical problem of the present invention is to quickly transport and treat a patient by moving to an accident point when an accident occurs.

In addition, a technical problem of the present invention is to provide a system capable of performing treatment while monitoring the patient's biosignals during treatment when a severely ill patient occurs due to gas poisoning or the like.

In addition, an object of the present invention is to reduce the size and weight of equipment necessary for high-pressure oxygen treatment so that they can be easily moved.

In addition, an object of the present invention is to provide a portable hyperbaric oxygen treatment system that does not require the carrying of hyperbaric oxygen.

In order to solve the above problems, the present invention discloses a modular mobile hyperbaric oxygen therapy system including a sealing part, a pressure control part and a pipe part.

According to the present invention, since the hyperbaric oxygen therapy system can be quickly moved to the scene of an accident to treat a patient, time can be significantly shortened and the survival rate can be dramatically increased.

In addition, since high-pressure oxygen can be supplied and treated at a moved treatment site without the need to carry a high-pressure oxygen tank, the risk of high-pressure oxygen explosion due to an accident occurring during movement can be eliminated.

In addition, the process of opening and closing the high-pressure oxygen treatment system can be easily performed, and accidents such as fire and explosion occurring during the opening and closing process can be prevented in advance.

1 is a block diagram showing a portable hyperbaric oxygen therapy system according to an embodiment of the present invention.
2 is a view showing that the hyperbaric oxygen therapy system according to an embodiment of the present invention is mounted on a vehicle.
3 is a view showing that the hyperbaric oxygen therapy system according to an embodiment of the present invention is mounted on a vehicle.
4 is a cross-sectional view showing a nozzle unit according to an embodiment of the present invention.
5 is a view showing a door frame and a door part according to an embodiment of the present invention.
6 is a view showing a door unit according to an embodiment of the present invention.
7 is a view showing a door part and a support part according to an embodiment of the present invention.
8 is a diagram illustrating a first moving unit according to an embodiment of the present invention.
9 is a view showing that the first moving unit moves the door unit backward according to an embodiment of the present invention.
10 is a view showing that a door unit is opened by a first moving unit according to an embodiment of the present invention.
11 is a diagram illustrating a second moving unit according to an embodiment of the present invention.
12 is an enlarged view of a second moving unit according to an embodiment of the present invention.
13 is a view illustrating movement of a door part in one direction and in another direction by a second moving part according to an embodiment of the present invention.

Terms used in this specification will be briefly described, and an embodiment of the present invention will be described in detail. The terms used in this specification have been selected from general terms that are currently widely used as much as possible while considering the functions in the present invention, but these may vary depending on the intention of a person skilled in the art, precedent, or the emergence of new technologies. In addition, in a specific case, there is also a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the invention. Therefore, the term used in this specification should be defined based on the meaning of the term and the overall content of the present invention, not simply the name of the term.

In this specification, terms indicating directions such as "upward direction", "downward direction", "upper direction" and "lower direction" will be described based on the drawings unless otherwise specified. In addition, prior to describing the present invention, "patient" means a person who needs hyperbaric oxygen treatment due to inhalation of harmful gases, etc., and "operator" drives and controls components required for hyperbaric oxygen treatment to treat the patient, A person who monitors the patient's condition.

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

According to the present invention, the high-pressure oxygen treatment system is characterized in that it can be modularized and installed in a vehicle or the like. According to one embodiment, the hyperbaric oxygen therapy system according to the present invention may be installed in a container transport vehicle or the like by being provided in the form of a container for ship transportation (hereinafter referred to as container form).

According to the present invention, since the high-pressure oxygen treatment system is modularized, it is possible to quickly move to the accident site and treat the patient using a vehicle. In particular, in the event of an accident such as a fire accident, marine accident, or gas poisoning, the patient needs to receive high-pressure oxygen to recover consciousness and receive treatment. Since is inevitable, there is a problem in that the patient's condition deteriorates or the probability of death increases.

1 is a block diagram showing a portable hyperbaric oxygen therapy system according to an embodiment of the present invention. The hyperbaric oxygen therapy system 10 according to the present invention includes a sealing part 100, a pressure control part 200 and a pipe part 300.

As a preferred embodiment, the high-pressure oxygen therapy system according to the present invention is provided as a module in the form of a container, and the sealing part, the pressure control part and the pipe part may be disposed inside the module.

2 is a diagram showing a hyperbaric oxygen therapy system and a vehicle according to an embodiment of the present invention. 3 is a view showing that the hyperbaric oxygen therapy system according to an embodiment of the present invention is installed in a vehicle.

The sealing part 100 is a configuration that provides a closed space for treating a patient. In detail, the sealing unit 100 is supplied with high-pressure oxygen through a pipe unit 300 to be described later in a state where a patient is located inside and the internal space is sealed to treat the patient. To this end, the sealing unit 100 may be located at the rear of the module and provided in the form of a chamber. As a more preferred embodiment, the sealing part 100 may have a rectangular cross section in the vertical direction. In detail, the sealing part 100 may be provided flat so that the upper and lower surfaces are parallel to the ground. Through the configuration of the sealing unit 100 as described above, a larger number of patients can be accommodated at the same time compared to the prior art of a chamber type provided in a circular shape, and the space can be used more efficiently when loaded in a vehicle. . In addition, the sealing unit 100 as described above can accommodate more equipment such as trays required for hyperbaric oxygen treatment of patients, so that restrictions in installation space can be more easily avoided. In addition, the sealing unit 100 is provided with a separate door portion through which the patient can be injected from the outside to the inside at the rear, and a separate door for the operator to grasp the inside of the sealing unit 100 and enter and exit as needed at the front or side. The entry portion of may be provided.

As a preferred embodiment, an emergency switch (not shown) may be provided inside the sealing part 100 . The emergency switch is used by the patient to notify the operator of an emergency or to call the operator. In detail, the emergency switch may be provided inside the sealing part 100 in the form of a switch that can be pressed quickly.

Preferably, the emergency switch is connected to a pressure control unit to be described later, and when operated by a patient, the pressure control unit can stop supplying high-pressure oxygen. Accordingly, it is possible to prevent an abnormal state from deteriorating even if the operator does not quickly respond to the operation of the emergency switch.

As a preferred embodiment, a state monitor (not shown) may be provided outside the sealing unit 100 . The status monitor unit displays the patient's status and provides it to the operator, and may include a screen unit that provides an image or an LED that is turned on when an abnormal condition occurs. Accordingly, the operator can continuously grasp the patient's condition to prevent accidents.

The pressure control unit 200 is a component for controlling the high-pressure oxygen concentration and air pressure inside the sealing part. In detail, the pressure control unit 200 determines the internal state of the sealing unit 100, and adjusts the input amount of high-pressure oxygen in response to the determination result. To this end, the pressure control unit 200 may be disposed in front of the sealing unit 100 and connected to the sealing unit 100 . In addition, the inside of the pressure control unit 200 is connected to the sealing unit 100 and the pipe unit 300 to adjust the input amount of the fluid is provided with a control box type adjustment means, additionally, the patient located in the sealing unit 100 A separate measuring means capable of checking an electrocardiogram, oxygen saturation, and the like may be further provided. Accordingly, the operator can easily grasp the patient's condition through the pressure control unit 200 . In addition, when the patient's condition deteriorates, the operator can prevent the patient from changing into a critically ill patient in advance by increasing the input amount of high-pressure oxygen from the pipe part 300 to the inside of the sealing part 100, thereby providing the patient with a golden time. With treatment, the mortality rate can be significantly reduced.

The pipe part 300 is provided to inject high-pressure oxygen into the aforementioned sealing part 100. In detail, the pipe part 300 assists the patient's treatment by injecting high-pressure oxygen toward the inside of the sealing part 100 . Preferably, the pipe part 300 is connected to the pressure control part 200.

In addition, one end of the pipe part 300 may be provided with an exhaust port for discharging residual gas in the pipe to the outside of the module. Before introducing the high-pressure oxygen into the sealing part 100, residual gas inside the pipe part 300 may be discharged with high-pressure oxygen through an exhaust port. Accordingly, it is possible to inject high-pressure oxygen into the sealing part 100 in a clean state. Additionally, a fire extinguishing means capable of suppressing a fire caused by high-pressure oxygen may be further provided inside the pipe part 300 .

In addition, the input amount of the pipe part 300 into the sealing part 100 is controlled by the adjusting means in the pressure control part 200 described above. In detail, the pipe part may include a nozzle part, a first pipe, and a second pipe.

4 is a cross-sectional view showing a nozzle unit according to an embodiment of the present invention.

The nozzle unit 310 is configured to provide a connection through an external oxygen tank (T) and a hose (H). Preferably, the nozzle unit may be connected to a first pipe 301 to be described later and may be provided in the form of a clamp to which the hose H is detachable. In the high-pressure oxygen treatment system according to the present invention, since high-pressure oxygen is injected from the outside through the nozzle unit, it is unnecessary to carry an oxygen tank, and treatment can be performed using the oxygen tank T supplied in the field. Accordingly, the possibility of a high-pressure oxygen explosion accident due to a collision accident or the like during movement of the high-pressure oxygen treatment system can be eliminated.

As a preferred embodiment, a fastening means 311 may be provided in the nozzle unit. The fastening means 311 may have a protruding shape protruding from the inner circumferential surface of the nozzle unit 310 . The fastening means 311 is caught on the fastening part H1 of the hose to prevent the hose from being separated, thereby preventing an accident due to the hose being separated while high-pressure oxygen is being supplied.

As a preferred embodiment, a driving unit connected to the pipe unit 300 may be provided separately. The driving unit is configured to increase the pressure of oxygen when the pressure of oxygen is insufficient before being introduced into the sealing unit. Preferably, the driving unit may be an electrically driven pump.

The first pipe is configured to supply high-pressure oxygen introduced through the nozzle unit to the pressure control unit. To this end, one end of the first pipe may be provided in the form of a pipe connected to the nozzle unit and the other end connected to the pressure control unit.

The second pipe is configured to inject oxygen supplied from the pressure control unit into the sealing unit. To this end, one end of the second pipe may be provided in the form of a pipe connected to the pressure control unit and the other end connected to the sealing unit.

As a more preferred embodiment of the present invention, a vibration prevention unit 14 may be further provided.

The anti-vibration unit 14 is a component that prevents the high-pressure oxygen treatment system 10 mounted in the vehicle from shaking depending on road conditions. To this end, the anti-vibration unit 14 is located between the high-pressure oxygen treatment system 10 and the vehicle. In detail, the anti-vibration unit 14 is located at the rear of the vehicle, but may be disposed in the lower direction of the high-pressure oxygen treatment system 10. In addition, the anti-vibration unit 14 may be provided as a means for damping and eliminating vertical movement of a vibration-proof pad, a damper, or the like. As the anti-vibration unit 14 easily cancels the vibration moving in the upward direction, it is possible to prevent the high-pressure oxygen treatment system 10 from shaking in the vertical direction. This assists in enabling the treatment of patients located inside the sealing part 100 to be performed more easily and quickly, and is caused by the pipe part 300 being damaged by the impact applied to the pipe part 300 and the high-pressure oxygen flowing out. It has the effect of preventing possible accidents in advance. In addition, the patient can relieve the anxiety caused by shaking inside the sealing part 100, so it is possible to treat more easily.

5 is a view showing a door frame and a door part according to an embodiment of the present invention.

As a preferred embodiment, the door unit according to the present invention may be a sliding door unit 30 . In detail, the door frame 12 is formed in the sealing part 100, the door part 30 is located inside the sealing part 100, and when closed, the front surface contacts the insertion groove 121 of the door frame 12 and opens. The front surface of the case is released from contact with the insertion groove 121. Meanwhile, the door unit 30 is opened and closed by moving forward and backward through a first guide unit 31 to be described later.

6 is a view showing a door unit according to an embodiment of the present invention.

The first guide part 31 guides the door part 30 to easily move forward and backward through a support part 40 to be described later. To this end, the first guide part 31 is formed in a rod shape, one end facing forward is connected to the rear surface of the door part 30, and the other end passes through the support part 40 to be described later and faces the rear. Since the first guide part 31 is provided, the door part 30 can move forward and backward along the first guide part 31 when moving forward and backward by the first moving part 50 to be described later. there is. Therefore, it is possible to prevent the door part 30 from being twisted or not engaged with the door frame 12 during the process of opening and closing the door part 30 . This has a remarkable effect of preventing accidents such as explosion and fire caused by sparks in advance compared to the prior art of opening and closing the door through a separate power supply unit.

The contact part 32 moves the door part 30 forward and backward more easily by the first moving part 50 . In detail, the contact portion 32 enables the door portion 30 to be easily moved forward and backward even with less force. To this end, the contact part 32 is located on the rear surface of the door part 30 . In addition, the contact portion 32 is connected to the first link portion 51 and the second link portion 52 to be described later, so that the first link portion 51 and the second link portion 52 are applied during hinge motion. The force is transmitted to the door part 30 . Therefore, the door unit 30 can be opened and closed with a smaller force than when the contact unit 32 is not present.

7 is a view showing a door part and a support part according to an embodiment of the present invention.

The support part 40 supports the door part 30 in the vertical direction and easily moves the door part 30 forward and backward. To this end, the support part 40 is formed in a plate shape and is located behind the door part 30 . In addition, a perforated hole corresponding to the aforementioned first guide portion 31 is formed in the support portion 40 . Accordingly, the support part 40 is inserted into the first guide part 31 and connected to the door part 30 . Here, the support part 40 is connected to the first guide part 31, and fastening means such as bolts and nuts are further provided around the perforated hole. Therefore, the position of the support part 40 is fixed without moving forward and backward.

The first moving unit 50 is configured to move the door unit 30 forward and backward by directly applying force. To this end, the first moving unit 50 is located between the door unit 30 and the support unit 40 . In addition, the first moving unit 50 includes a first link unit 51, a second link unit 52, and an expansion/contraction unit 53.

8 is a diagram illustrating a first moving unit according to an embodiment of the present invention.

As described above, the first moving unit 50 includes the first link unit 51, the second link unit 52, and the expansion and contraction unit 53, and through the expansion and contraction of the expansion and contraction unit 53, the The door unit 30 is moved forward and backward by hinge movement of the first link unit 51 and the second link unit 52 . In addition, the first moving parts 50 are provided as a pair and are respectively provided in the vertical direction of the door part 30 .

The first link part 51 induces a hinge motion by applying force from the support part 40 toward the second link part 52 to be described later. To this end, the first link unit 51 is provided as a pair, and upper ends are connected to each other through a separate hinge. In addition, among the pair of first link parts 51, the first link part 51 located at the front is connected to the door part 30. In detail, the lower end of the first link part 51 located in the front is connected to the upper end of the door part 30 and the second link part 52 . As a more preferred embodiment, the lower end of the first link part 51 located in the front is connected to the upper end of the above-described contact part 32 and the second link part 52, so that the door part 30 can be more easily attached to the door part 30. force can be applied In addition, the lower end of the first link part 51 located at the rear among the pair of first link parts 51 is connected to the upper end of the support part 40 and the second link part 52 . Through a series of configurations and actions as described above, the first link part 51 is simultaneously connected to the second link part 52, the support part 40, and the door part 30, so that force on the door part 30 is easily achieved. can be added.

The second link part 52 presses the door part 30 by a hinge motion in the same way as the first link part 51 . To this end, the second link portion 52 is provided as a pair, the lower end of which is hinged to each other, and is located in the lower direction of the first link portion 51 . In addition, among the pair of second link parts 52, the second link part 52 located at the front is connected to the lower end of the first link part 51 and the door part 30, and the second link part located at the rear The upper end of 52 is connected to the lower end of the first link part 51 and the support part 40, and the lower end is connected to the expansion and contraction part 53 to be described later. Through this, the second link part 52 performs a hinge movement so that the distance between the second link parts 52 (meaning the distance in the front and rear) is variable through the expansion and contraction of the expansion and contraction part 53, Correspondingly, as the first link unit 51 also performs a hinge motion, ?痔鎌構? The door unit 30 is moved forward and backward.

The expansion and contraction unit 53 is configured to allow the first link unit 51 and the second link unit 52 to perform a hinge movement. In detail, the extension part 53 is the second link part 52 connected to the upper end and the first link part 51 connected to the second link part 52 in the process of lengthwise expansion and contraction in the vertical direction. Opens and closes the door unit 30 according to. To this end, the stretchable part 53 has a variable length in the vertical direction through a separate hydraulic supply means and is formed in a rod shape. The hinge movement of the first link part 51 and the second link part 52 through the stretchable part 53 and the opening and closing of the door part 30 will be described later with reference to FIGS. 6 and 7 .

9 is a view showing that the first movable unit moves the door unit backward according to an embodiment of the present invention, and FIG. 10 is a view showing that the door unit is opened by the first movable unit according to an embodiment of the present invention. to be. In detail, FIG. 9 is a first link part 51 and a second link part 52 located in the upper direction of the door part 30 based on FIG. 5 described above, by the expansion and contraction part 53, the door part 30 ) is a view moving forward, FIG. 10A means a state in which the door part 30 is closed, and FIG. 10B shows a state in which the door part 30 is opened.

The closed state of the door unit 30 is the same as that shown in FIG. 9 , in which the expansion and contraction unit 53 extends upward, and correspondingly, the lower end of the pair of second link units connected to the ends of the expansion and contraction unit 53. (52) is a hinged state. In addition, the pair of first link parts 51 are in a state in which the gap in the front and rear increases in correspondence with the pair of second link parts 52 . Accordingly, the first link part 51 and the second link part 52 press the door part 30 forward so that the front surface contacts the insertion groove 121 of the door frame 12 . Accordingly, the door unit 30 maintains a closed state.

On the other hand, when the door is opened, as shown in FIG. 10 , as the elastic part 53 contracts, the lower end of the second link part 52 performs a hinge motion to move downward. That is, one end of the pair of second link parts 52 performs a hinge movement so that the gap between the front and rear ends is narrowed. In addition, the first link part 51 is hinged to correspond to the second link part 52 as described above, and as a result, the door part 30 moves backward and is separated from and opened from the door frame 12 .

Through a series of configurations and processes as described above, the door unit 30 can be easily opened and closed without a separate power supply means, which has an effect of preventing accidents caused by high-pressure oxygen in advance. Meanwhile, the door part 30 separated from the door frame 12 is completely opened by moving in one direction through a second moving part 60 to be described later.

11 is a diagram illustrating a second moving unit according to an embodiment of the present invention. In FIG. 11, some components are omitted in order to show the second moving unit 60 more clearly.

The second moving unit 60 is configured to open and close the door unit 30 by moving it in one direction and the other direction. In detail, the second moving unit 60 slides the door unit 30 to open and close the door unit 30 . To this end, the second moving unit 60 is provided as a pair in the vertical direction of the door unit 30 and includes a second guide unit 61 and a connection unit 62 .

12 is an enlarged view of a second moving unit according to an embodiment of the present invention, and FIG. 13 is a view illustrating movement of a door unit in one direction and the other direction by the second moving unit according to an embodiment of the present invention. .

The second guide part 61 provides a path for sliding the door part 30 along one direction and the other direction. To this end, the second guide parts 61 are formed in a rod shape and provided as a pair, respectively, located in the vertical direction of the door part 30 . In addition, the second guide part 61 is inserted into a connection part 62 to be described later, and moves the door part 30 as the connection part 62 moves.

The connection part 62 moves the door part 30 , which has been released from contact with the door frame 12 , in one direction to completely open it, and moves the opened door part 30 in the other direction to bring it into contact with the door frame 12 . To this end, the connection part 62 is located and connected in the vertical direction of the support part 40, and is pressed in one direction and the other direction through a separate hydraulic supply means to move the door part 30. Here, since the second guide part 61 is inserted into the connection part 62, the door part 30 can move in one direction and the other direction more stably.

13A is a state in which the door part 30 is released from contact with the door frame 12 . That is, as described above with reference to FIG. 8 , the door part 30 moves backward through the first moving part 50 and the contact with the door frame 12 is released.

13B shows a state in which the door unit 30 is fully opened. In detail, the connection part 62 connected to the support part 40 after FIG. 10A moves in one direction along the second guide part 61 through a separate hydraulic supply means. Accordingly, the door part 30 connected to the support part 40 also moves in one direction and is fully opened.

When trying to close the door part 30 after FIG. 13B, the connection part 62 moves the support part 40 and the door part 30 in the other direction along the second guide part 61, and then the first moving part Through (50), the door part (30) moves forward and is closed by contacting the door frame (12).

Through the configuration of the first moving unit 50 and the second moving unit 60 described above, it is possible to open and close the door more stably, and in the process, it is possible to prevent an accident such as an explosion due to pressure inside the chamber. This can maximize safety.

Through the above series of configurations, the hyperbaric oxygen therapy system can be quickly moved to the scene of an accident to treat a patient, thereby significantly reducing time and dramatically increasing the survival rate.

In addition, since high-pressure oxygen can be supplied and treated at a moved treatment site without the need to carry a high-pressure oxygen tank, the risk of high-pressure oxygen explosion due to an accident occurring during movement can be eliminated.

In addition, medical accidents can be prevented by objectively evaluating the state of the eardrum during the hyperbaric oxygen treatment process and controlling the pressure inside the sealing unit.

The preferred embodiments of the present invention described above have been disclosed for illustrative purposes, and those skilled in the art with ordinary knowledge of the present invention will be able to make various modifications, changes and additions within the spirit and scope of the present invention, and such modifications, changes and additions will be considered to fall within the scope of the above claims.

Those skilled in the art to which the present invention pertains can make various substitutions, modifications, and changes without departing from the technical spirit of the present invention. is not limited by

Claims (3)

In the hyperbaric oxygen treatment system that can be modularized and installed in a vehicle,
A sealing unit including an inlet through which a patient can be placed in the inner space and high-pressure oxygen is injected into the inner space and an outlet through which air is discharged from the inside;
a pressure control unit controlling the opening and closing of the inlet and outlet to adjust the pressure in the inner space of the sealing unit; and
a piping unit receiving high-pressure oxygen from the outside and delivering the high-pressure oxygen to the sealing unit through the pressure control unit;
a door part formed in the sealing part;
a support portion located behind the door portion;
Hyperbaric oxygen treatment, characterized in that it further comprises; a second moving unit located in the upper and lower directions of the support unit, and opening and closing the door unit from the sealing unit by moving the door unit and the support unit in one direction and the other direction. system.
According to claim 1,
The high-pressure oxygen treatment system is modularized in the form of a container for ship transportation, so that the high-pressure oxygen treatment system can be installed in a vehicle or the like.
According to claim 1,
The piping part,
A nozzle unit for connecting with an external oxygen tank;
a first pipe having one end connected to the nozzle unit and the other end connected to the pressure control unit; and
High-pressure oxygen therapy system comprising a; second pipe having one end connected to the pressure control unit and the other end connected to the inlet of the sealing unit.

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