KR102516428B1 - Local type oxygen chamber - Google Patents

Abstract

A soft type localized oxygen chamber into which one of the user's extremities is inserted is disclosed. The disclosed localized oxygen chamber includes an entrance into which a treatment site, which is one of a user's extremities, is inserted, and includes an airbag inflated by injected air; a tube frame coupled to the airbag, inflated by injected air, and supporting the airbag in a preset chamber shape; a compression tube positioned at the entrance, expanded by the injected air, and compressing the treatment area; and an air supply unit supplying the air to the air bag, the tube frame, and the compression tube.

Description

Local type oxygen chamber {LOCAL TYPE OXYGEN CHAMBER}

The present invention relates to a localized oxygen chamber, and more particularly, to a soft type localized oxygen chamber into which one of a user's extremities is inserted.

Hyperbaric oxygen therapy is a treatment in which a patient obtains dissolved oxygen by inhaling high-concentration oxygen by creating an environment of higher pressure than atmospheric pressure. Through this, the oxygen concentration in the patient's body is increased and hypoxia is improved. Types of pressurized gas include oxygen, air, mixed gas, and the like.

Since Henshaw designed and first used the hyperbaric oxygen treatment device for medical research in 1662, it has been steadily researched in the United States and European countries. A hyperbaric oxygen chamber for hyperbaric oxygen treatment may have a single or double chamber structure to treat one patient or multiple patients.

The range of hyperbaric oxygen treatment is gradually widening, and recently, an oxygen chamber into which a part of the limbs rather than the whole body is inserted has been developed. These localized oxygen chambers are widely used for patients with partial necrosis of limbs or burn patients.

As a related prior art, there is Japanese Patent Registration No. 5180592.

An object of the present invention is to provide a localized oxygen chamber with improved usability.

In addition, the present invention is to provide a soft type localized oxygen chamber using an airbag as a chamber.

According to one embodiment of the present invention for achieving the above object, an airbag including an entrance into which a treatment site, which is one of the user's limbs, is inserted, and inflated by injected air; a tube frame coupled to the airbag, inflated by injected air, and supporting the airbag in a preset chamber shape; a compression tube positioned at the entrance, expanded by the injected air, and compressing the treatment area; and an air supply unit supplying the air to the air bag, the tube frame, and the compression tube.

In addition, according to another embodiment of the present invention for achieving the above object, an airbag including an entrance into which a treatment site, which is one of the user's limbs, is inserted, and inflated by injected air; an air supply unit supplying the air to the air bag; and an entrance blocking part for bringing the entrance into close contact with the treatment site in a state in which the treatment site is inserted into the airbag.

According to one embodiment of the present invention, a localized oxygen chamber capable of securing an entrance into which a treatment site is inserted may be provided using a tube frame.

In addition, according to one embodiment of the present invention, air leakage occurring between the entrance of the airbag and the treatment area can be blocked by using the compression tube and the elastic body disposed inside the compression tube.

1 is a view for explaining a localized oxygen chamber according to an embodiment of the present invention.
2 is a view for explaining a compression tube according to an embodiment of the present invention.
3 is a view for explaining an air supply unit according to an embodiment of the present invention.
4 is a view for explaining a localized oxygen chamber according to another embodiment of the present invention.
5 and 6 are views for explaining the entrance blocking unit according to an embodiment of the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. Like reference numerals have been used for like elements throughout the description of each figure.

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

1 is a view for explaining a localized oxygen chamber according to an embodiment of the present invention.

Referring to FIG. 1 , a localized oxygen chamber according to an embodiment of the present invention includes an airbag 110, tube frames 121 to 123, a compression tube 130, and an air supply unit 130.

The airbag 110 is inflated by the injected air, and the user's treatment area is disposed. The airbag 110 includes an open entrance 111, and a treatment site, which is one of the user's limbs, may be inserted into the airbag through the entrance 111. The entrance 111 is an opening formed in the airbag 110, and may be, for example, circular, and includes two arms and two legs, and a concept including hands and feet connected to the arms and legs.

The air injected into the airbag 110 may be air containing more than a preset concentration of oxygen, and air may be injected into the airbag 110 through a compressor. The airbag 110 is a chamber in which air containing oxygen is maintained at a certain atmospheric pressure or higher, and may be made of a flexible and stretchable material such as synthetic resin. In addition, the tube frames 121 to 123 and the compression tube 130, which will be described later, may also be made of the same or similar material as the airbag 110.

The tube frames 121 to 123 are coupled to the airbag 110 and inflated by the injected air to support the airbag 110 in a preset shape. 1 shows an embodiment in which the airbag 110 is supported in a cylindrical shape in which the area of the upper surface, that is, the area of the entrance 111, which is an opening, and the area of the lower surface are different from each other, and the tube frames 121 to 123 are airbags. It includes a tube for supporting 110 in such a cylindrical shape.

As an embodiment, the tube frame includes a ring-shaped first tube 121 supporting the lower surface 112 of the cylinder, and second and third rod-shaped bars disposed between the entrance 111 and the first tube 121. tubes 122 and 123. The first tube 121 is disposed between the lower surface 112 and the outer circumferential surface of the cylinder, and the second and third tubes 122 and 123 are spaced apart from each other and may be coupled to the outer circumferential surface. And, the first to third tubes 121 to 123 are coupled to each other, and may be connected so that air can move from the inside to each other. When the second and third tubes 122 and 123 are also combined with the compression tube 130 described below, the compression tube and the second and third tubes 122 and 123 have an air movement path so that air cannot move inside. It is blocked.

The compression tube 130 is located at the entrance 111, expands by the injected air, and compresses the treatment area inserted into the air bag 110. The compression tube 130 may have a ring shape surrounding the circular entrance 111, and expands while the treatment site is inserted, thereby narrowing the width of the entrance 111 and compressing the treatment site. As the compression tube 130 compresses the treatment area, air leakage between the entrance 111 and the treatment area can be minimized.

A plurality of wires 131 may be connected to the compression tube 130 to increase the area of the entrance 111 so that a user can easily insert a treatment site into the entrance. This wire 131 may be coupled to a contact surface of the compression tube 130 that contacts the treatment area. Although four wires are shown in FIG. 1, the number of wires may vary according to embodiments. A ring for hanging or tying the wire 131 is disposed on the outer circumferential surface of the airbag 110 or on the second and third tubes 122 and 123, and when the wire 131 is coupled to the ring, the wire 131 While pulling the pressure tube 130 toward the outside of the entrance 111, the area of the entrance 111 may increase.

The air supply unit 140 supplies air to the airbag 110, the tube frames 121 to 123, and the compression tube 130. A hole into which the air supply unit 140 can be inserted may be formed in the tube frames 121 to 123 and the compression tube 130, and the air supplied to the compression tube 130 is supplied to the air bag 110 and the compression tube ( 130 may be delivered to the airbag 110 through the air movement path between them.

The air supply unit 140 may be connected to a compressor and deliver air supplied from the compressor to the airbag 110 , the tube frames 121 to 123 , and the compression tube 130 .

As an embodiment, the air supply unit 140 preferentially supplies air to the tube frames 121 to 123, and when the internal air pressure of the tube frames 121 to 123 is greater than or equal to the critical air pressure, the air bag 110 and the compression tube ( 130) may supply air. That is, air is supplied to the tube frames 121 to 123 and the compression tube 130 with a time difference. Air is primarily supplied to the tube frames 121 to 123, and air is supplied to the airbag 110 and the compression tube 130 after a certain period of time from when air is supplied to the tube frames 121 to 123. .

The internal air pressure of the tube frames 121 to 123 may be measured by an air pressure sensor installed in the tube frames 121 to 123, or the air supply unit 140 determines that the internal air pressure of the tube frames 121 to 123 is critical. During the time required to reach atmospheric pressure, air may be preferentially supplied to the tube frames 121 to 123 .

According to one embodiment of the present invention, while the airbag 110 is supported in a preset shape by the tube frames 121 to 123 that are preferentially inflated, the space of the airbag 110 is widened, so that the user can easily access the treatment area. can be inserted into the airbag.

2 is a view for explaining a compression tube according to an embodiment of the present invention, and is a view showing a cross section of the compression tube.

Referring to FIG. 2 , the compression tube according to an embodiment of the present invention may include a spiral elastic body 231 .

The elastic body 231 is disposed inside the compression tube 130 . The elastic body 231 provides an elastic force that pushes the contact surface 131 of the pressure tube in contact with the treatment site in the direction of the entrance 250 . As described above, since the compression tube 130 is disposed in a form surrounding the entrance 111, when the user inserts the treatment area into the airbag through the entrance 111, the treatment area and the compression tube 130 are In contact, the elastic body 231 pushes the contact surface 131 of the compression tube in the direction of the entrance and exit 250, so air leakage between the airbag 110 and the treatment area can be further reduced.

In addition, even if air leaks from the compression tube 130 due to scratches on the compression tube 130, air leakage between the airbag 110 and the treatment area may be blocked by the elastic body 231.

3 is a view for explaining an air supply unit according to an embodiment of the present invention.

Referring to FIG. 3 , the air supply unit 140 according to an embodiment of the present invention includes an air injection pipe 300, a first air discharge pipe 310, and a second air discharge pipe 320 together with a first opening/closing unit ( 331), a first hinge 341, a second opening/closing portion 332, and a second hinge 342.

A hose connected to the compressor is coupled to the air injection pipe 300, and air is injected into the air injection pipe 300.

The first air discharge pipe 310 is connected to the air injection pipe 300 and discharges the air injected into the air injection pipe 300 to the tube frame. As an example, the first air discharge pipe 310 may be inserted into the third tube 123 of the tube frame.

The second air discharge pipe 320 is connected to the air injection pipe 300 and discharges the air injected into the air injection pipe 300 to the compression tube 130 . The second air discharge pipe 320 may be inserted into the compression tube 130, and as described above, the air supplied to the compression tube 130 is an air movement path between the air bag 110 and the compression tube 130. Through, it can be transmitted to the airbag 110.

The first opening/closing part 331 opens and closes the first outlet 311 of the first air discharge pipe. The first hinge 341 connects the first opening/closing portion 331 and the first air discharge pipe 310 and provides an elastic force for pushing the first opening/closing portion 331 toward the first outlet.

The second opening/closing part 332 opens and closes the second outlet 321 of the second air discharge pipe. The second hinge 342 connects the second opening/closing part 332 and the second air discharge pipe 320, and provides elastic force to push the second opening/closing part 332 toward the second outlet.

The first outlet 311 is opened or closed by the first opening/closing part 331 that rotates by the first hinge 341 . When the first opening/closing portion 331 rotates counterclockwise and is coupled to the first outlet 311, the first outlet 311 is closed, and when the first opening/closing portion 331 rotates clockwise, the first outlet 311 is closed. 1 outlet 311 is open.

The second outlet 321 is opened or closed by the second opening/closing part 332 rotated by the second hinge 342 . When the second opening/closing portion 332 rotates counterclockwise and is coupled to the second outlet 321, the second outlet 321 is closed, and when the second opening/closing portion 332 rotates clockwise, the second outlet 321 is closed. The second outlet 321 is open.

The first and second opening/closing parts 331 and 332 are coupled to the first and second outlets 311 and 321 by the elastic force of the first, first and second hinges 341 and 342 . Then, when air is injected into the air injection pipe 300, since the elastic force of the second hinge 342 is stronger than the elastic force of the first hinge 341, the first opening/closing part 331 rotates clockwise, The outlet 311 is open, and the second opening/closing part 332 does not rotate. Therefore, air is preferentially supplied to the third tube 123 .

Thereafter, when the internal air pressure of the tube frame rises and exceeds the critical air pressure, the force of the injected air pushing the first opening/closing portion 331 is weakened, so that the first opening/closing portion 331 rotates counterclockwise to the first opening/closing portion ( 331 closes the first outlet 311. In this case, since the injected air does not move in the direction of the first air injection pipe and the pressure applied to the second opening/closing part 332 increases due to the injected air, the second opening/closing part 332 rotates clockwise to remove the The second outlet 321 is opened by the two opening/closing parts 332, and air is supplied to the compression tube 130.

4 is a view for explaining a localized oxygen chamber according to another embodiment of the present invention.

The localized oxygen chamber described in FIG. 4 is a disposable localized oxygen chamber. That is, it is a localized oxygen chamber used by a user for a one-time use. Since the localized oxygen chamber is used in a form where the treatment area of a patient with severe trauma is inserted, mucus or a dressing applied to the treatment area may get on the localized oxygen chamber, which may cause users to feel rejected. . Accordingly, there is a demand for a disposable local oxygen chamber that has a simple structure and can be manufactured at low cost.

Depending on the embodiment, the localized oxygen chamber described in FIGS. 1 to 3 may include components of the localized oxygen chamber described below, and the localized oxygen chamber described below may also be illustrated in FIGS. 1 to 3 It may include components of the localized oxygen chamber described.

Referring to FIG. 4 , a localized oxygen chamber according to an embodiment of the present invention includes an air bag 410, an air supply unit 420, and entrance and exit blocking units 431 and 432.

The airbag 410 includes an entrance 411 into which a treatment site, which is one of the user's limbs, is inserted, and is inflated by injected air.

The air supply unit 420 supplies air to the airbag 410 . As an embodiment, it may be a tube inserted into a hole formed in the airbag 410 or a valve formed in the airbag, and air supplied from a compressor is injected into the airbag 410 .

The entrance and exit blocking parts 431 and 432 bring the entrance 411 into close contact with the treatment site in a state where the treatment site is inserted into the air bag 410 . Since the entrance 411 is brought into close contact with the treatment site by the entrance blocking portions 431 and 432, air leakage between the entrance 411 and the treatment site may be reduced.

The entrance blocking parts 431 and 432 reduce the area of the entrance 411, so that the entrance 411 can be brought into close contact with the treatment area. As an embodiment, a zipper structure or a wire used to open and close the entrance of a zipper bag may be used as the entrance and exit blocking parts 431 and 432, and in FIG. 4, the wire is used as the entrance and exit blocking parts 431 and 432. An example is shown.

The entrance blocking unit may include a tube 431 and a wire 432 . The tube 431 is disposed along the boundary of the entrance 411, and one end and the other end of the tube 431 are open. That is, a rod-shaped tube 431 made of a flexible material and penetrating the inside may be disposed along a boundary line between the entrance 411 and the airbag 410 .

Wire 432 is inserted into tube 431. One end and the other end of the wire 432 protrude from one end and the other end of the tube 431 . That is, the length of the wire 432 is longer than the length of the tube 431, and one end and the other end of the wire 432 are exposed to the outside of the tube 431.

When the user grabs one end and the other end of the wire 432 and binds the wire 432, the area of the entrance 411 is reduced so that the entrance 411 can adhere to the treatment area. Alternatively, the wire may be a cable tie, and when the user binds the cable tie, the entrance 411 may be brought into close contact with the treatment area.

5 and 6 are views for explaining the entrance blocking unit according to an embodiment of the present invention.

Referring to Figure 5, the entrance blocking unit according to an embodiment of the present invention includes a tube 431, a wire 432 and a block (433). And according to embodiments, a guide panel 434 may be further included.

The block 433 is coupled to the entrance 411, is spaced apart from one end and the other end of the tube 431, and is disposed between one end and the other end of the tube 431. The block 433 may have a hexahedral shape as an embodiment, the block 433 may have a thickness greater than that of the tube 431, and may be made of the same flexible material as the tube 431.

Then, in a state in which the entrance 411 is in close contact with the treatment area by the wire 432, a portion of the wire 432 is disposed on the block 433. As described above, the embodiment of FIG. 4 relates to a disposable local oxygen chamber, and after use of the oxygen chamber is finished, the user can remove the treatment site from the oxygen chamber by cutting the wire 432 . At this time, since the wire 432 is in close proximity to the treatment area, the body part may be damaged in the process of cutting the wire 432. When part is cut, the treatment part can be taken out of the oxygen chamber by easily cutting the wire 432 without damaging the body part.

The guide panel 434 is disposed at one end and the other end of the block 433 facing one end and the other end of the tube 431, and air leaking from the gap between the block 433 and the tube 431 is removed from the user. move in the direction Considering an arm or leg, which is a treatment area where a localized oxygen chamber is used, air leaking from the gap between the block 433 and the tube 431 is directed toward the user in a state where the treatment area is inserted into the localized oxygen chamber. facing, which may cause discomfort to the user. The guide panel 434, as a thin and flexible substrate coupled to the block 433, blocks air leaking from the gap between the block 433 and the tube 431 from moving in the direction of the user, and blocks the movement in the direction of the arrow 435. ) is moved to

A through hole is formed in the guide panel 434, and one end and the other end of the wire 432 may be disposed through the through hole, and thus, in a state in which the wire 432 is bundled, a part of the wire 432 blocks ( 434) can be placed on.

As described above, the present invention has been described by specific details such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , Those skilled in the art in the field to which the present invention belongs can make various modifications and variations from these descriptions. Therefore, the spirit of the present invention should not be limited to the described embodiments, and it will be said that not only the claims to be described later, but also all modifications equivalent or equivalent to these claims belong to the scope of the present invention. .

Claims (5)

an airbag including an entrance into which a treatment area, one of a user's limb, is inserted and inflated by injected air;
a tube frame coupled to the airbag, inflated by injected air, and supporting the airbag in a preset chamber shape;
a compression tube positioned at the entrance, expanded by the injected air, and compressing the treatment area; and
An air supply unit that preferentially supplies air to the tube frame and supplies air to the air bag and the compression tube when the internal air pressure of the tube frame is greater than or equal to a critical air pressure;
the air supply
an air injection pipe into which the air is injected;
a first air discharge pipe connected to the air injection pipe and discharging the injected air to the tube frame;
a second air discharge pipe connected to the air injection pipe and discharging the injected air to the compression tube;
a first opening/closing unit opening and closing the first outlet of the first air discharge pipe;
a first hinge connecting the first opening/closing portion and the first air discharge pipe and providing an elastic force for pushing the first opening/closing portion toward the first outlet;
a second opening/closing unit opening and closing the second outlet of the second air discharge pipe; and
A second hinge connecting the second opening/closing portion and the second air discharge pipe and providing an elastic force for pushing the second opening/closing portion toward the second outlet,
The elastic force of the second hinge is stronger than the elastic force of the first hinge,
The air supplied to the compression tube is transferred to the airbag through an air movement path between the airbag and the compression tube.
Localized oxygen chamber.
According to claim 1,
the compression tube
It is ring-shaped surrounding the circular entrance and includes a spiral elastic body disposed inside the compression tube,
The elastic body provides an elastic force that pushes the contact surface of the compression tube in contact with the treatment site in the direction of the entrance.
Localized oxygen chamber.
delete delete According to claim 1,
Further comprising a plurality of wires connected to the compression tube,
On the outer circumferential surface of the airbag, a ring to which the wire is coupled is disposed
Localized oxygen chamber.

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