KR101138310B1 - Self-contained oxygenator - Google Patents

Abstract

PURPOSE: A self-contained oxygen breathing device is provided to separately collect oxygen from exhaled air and to prevent inhaled air from coming into contact with exhaled air. CONSTITUTION: A self-contained oxygen breathing device comprises a mask(10), a chamber housing(20), an exhaled air expansion member(30), an oxygenator(40), a collecting member(50), and an oxygen supply unit(60). The mask blocks at least one of the oral cavity or nasal cavity of a wearer. The chamber housing receives exhaled air from the mask and is equipped with a check valve and a communication chamber. The oxygenator generates oxygen inside the chamber housing. The collecting member collects oxygen in a sealed state.

Description

Self-Contained Oxygen Respirator {SELF-CONTAINED OXYGENATOR}

The present invention relates to a self-contained oxygen respirator, and more particularly, to a self-contained oxygen respirator capable of preventing asphyxiation of a wearer without an oxygen tank by generating oxygen and supplying it to the wearer by using the wearer's breathing air.

In general, most accidents in industrial sites where there is a risk of fire or toxic gas are mainly caused by asphyxiation due to respiratory disorder. Accordingly, for example, in a site such as a subway or underground tunnel, gas masks or oxygen respirators are provided to minimize human injury caused by smoke or toxic gas during a fire.

Here, the oxygen respirator is typically composed of an oxygen tank filled with compressed oxygen and a mask connected to the oxygen tank and worn on the wearer's respirator.

However, such a conventional oxygen respirator has a heavy weight of the oxygen tank, so as to reduce mobility and portability, and to operate the valve of the oxygen tank to supply oxygen to the mask, it is very difficult for the general public to use in an emergency situation. There is a big problem in the economic burden to keep a large number of relatively expensive bar.

Therefore, in recent years, a self-contained oxygen respirator capable of generating oxygen through the wearer's breath has been developed.

As a self-contained oxygen respirator of the prior art, there is an oxygen mask disclosed in Korean Patent No. 10-518662. The conventional oxygen respirator converts oxygen and supplies carbon dioxide contained in the exhaler of the wearer through an oxygen generator as shown in FIG. 1.

Specifically, the oxygen generating apparatus according to the prior art is a carbon dioxide inlet tube 100 for introducing carbon dioxide (CO ₂ ) and calcium peroxide (CaO ₂ ) is filled as shown in Figure 1 the carbon dioxide inlet tube 100 The first reaction chamber 200 and a mixture of potassium peroxide (or sodium peroxide) (KO ₂ or NaO ₂ ) and CaO ₂ are filled with the first reaction chamber 200 to assist the chemical reaction while diffusing the carbon dioxide introduced through the gas into a larger area. The second reaction chamber 300 which generates oxygen through reaction with carbon dioxide introduced through the first reaction chamber 200 and generated in the second reaction chamber 300 using wet activated carbon or wet charcoal. A third reaction chamber 400 for lowering the temperature of oxygen, a fourth reaction chamber 500 for removing moisture of oxygen passing through the third reaction chamber 400 using dry activated carbon or charcoal, and the fourth Oxygen oil to allow oxygen to pass through the reaction chamber 500 The outlet tube 600 and the distilled water supply unit 700 for supplying distilled water to the third reaction chamber 400.

By the way, in the oxygen generator of the prior art, a plurality of reaction chambers 100, 200, 300, 400 are sequentially formed, the filler is in each reaction chamber 100, 200, 300, 400 Difficult to manufacture due to the complicated configuration of each filling, there is a problem that the oxygen is not smoothly generated and supplied because of poor communication of air.

On the other hand, another prior art is a portable self-oxygen breathing apparatus disclosed in Republic of Korea Patent No. 10-1047082.

As shown in FIG. 2, the oxygen respirator of the prior art includes a main housing 10 in which an oxygen generator 20 that generates oxygen by absorbing carbon dioxide or moisture when exposed to air or breathing is accommodated, and the main housing. The bag-shaped container 13 is connected to one end of the 10 to supply the generated oxygen back to the main housing 10, and the main housing 10 and the air purifying container 50 are combined to be worn on the face. The face protector 40 is configured.

However, the oxygen respirator of the prior art has a structure in which the vessel 13 is connected to the main housing 10 only through the tubular member 12 as shown in FIG. 2, so that the oxygen generated by the oxygen generator 20 is stored in the vessel. (13) after being introduced into the face protector 40 through the oxygen generator 20 and the air purifying tank 50 through the pipe member 12 in the reverse order, so the oxygen breathing of the wearer can not be made smoothly There is this.

That is, in the conventional oxygen respirator, as the inhalation and exhalation of the wearer is composed of the same line, the carbon dioxide contained in the exhalation can again flow back, and the generated oxygen is conflicted in the tubular member 12, so that communication of oxygen becomes poor. There is a problem.

On the other hand, another prior art is a portable oxygen respirator disclosed in the Republic of Korea Patent No. 10-794801.

As shown in FIG. 3, the oxygen respirator of the prior art forms a passage between the outer housing 10, the breathing tube 20 communicating with the upper housing 10, and the outer housing 10. An inner housing 30, a filler 40 filled with barium peroxide and a catalyst inside the inner housing 30, and positioned above and below the filler 40, and the filler 40 is discharged. Filter 50 ', 50 "for preventing, the injection portion 60 is located above the inner housing 30, the upper end is formed in a wide passage and the lower end is formed in a narrow passage, the outer housing 10 It is composed of an intake one-way valve 70 is coupled to the inner side and the outer side of the inner housing (30).

The conventional oxygen respirator is oxygen is generated by the filler 40 as the exhalation of the user introduced through the breathing tube 20 to the injection unit 60, the one-way valve 70 by the generated oxygen is inhaled And through the breathing tube 20 to the user.

By the way, another conventional oxygen respirator also has a problem that the inhalation and exhalation is moved only through the breathing tube 20, there is a lack of trapping space for the oxygen generated by the filler 40 is not able to supply sufficient oxygen There is a problem.

KR 10-0518662 B1 KR 10-1047082 B1 KR 10-0794801 B1

The present invention was created in order to solve the problems of the prior art as described above, while generating a supply of oxygen through the exhalation while spreading to prevent the backflow of the exhaler of the wearer, the generated oxygen in a state separated from the exhalation In addition to collecting and supplying the collected oxygen to the wearer through a separate supply unit to provide a self-contained oxygen respirator that can prevent the inhalation and exhalation conflict.

A self-contained oxygen respirator of the present invention for achieving the above object, in the self-contained oxygen respirator that generates oxygen to the wearer's breathing air to supply to the wearer, a mask that shields at least one of the wearer's mouth or nasal cavity ; A chamber housing connected to the mask to be supplied with exhalation from the mask, and having a check valve for preventing backflow of the exhalation and a communication chamber for communicating the exhalation; An exhalation expansion member which swirls the exhalation supplied to the chamber housing and provides a flow path for supplying the diffusion chamber to the communication chamber of the chamber housing in the chamber housing; An oxygen generator for generating oxygen in the chamber housing by reacting with the exhalation supplied through the flow path of the exhalation expansion member; A collecting member for collecting oxygen generated by the oxygen generating agent in an airtight state; And an oxygen supply unit supplying oxygen collected in the collecting member to the mask in a state in which backflow is prevented.

As the self-contained oxygen respirator according to the present invention as described above, the check valve is provided in the chamber housing for communicating the exhalation prevents backflow of the exhalation and expands while exhaling the exhalation by the exhalation expansion member, thereby exhaling smoothly Oxygen may be communicated with each other, and the generated oxygen may be collected in the collecting member and then supplied to the mask through the oxygen supply unit, so that oxygen may be smoothly supplied to the wearer without being crossed with exhalation.

1 is a longitudinal sectional view showing an oxygen generator of the oxygen respirator according to the prior art.
Figure 2 is a longitudinal sectional view showing another oxygen respirator according to the prior art.
Figure 3 is an exploded perspective view showing another oxygen respirator according to the prior art.
4 is a perspective view showing a self-contained oxygen respirator according to the present invention.
5 is a longitudinal sectional view showing a self-contained oxygen respirator according to the present invention.
6 is an exploded perspective view showing the main part of the present invention;
FIG. 7 is a longitudinal sectional view showing the combined state of FIG. 7; FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention. In the following description of the present invention, detailed descriptions of well-known general functions or configurations will be omitted.

The self-contained oxygen respirator according to the present invention, as shown in Figs. 4 and 5, the mask 10, the chamber housing 20, the exhalation expansion member 30, the oxygen generator 40, the collecting member 50 and It may be configured to include an oxygen supply unit 60.

Mask 10 is a member for shielding at least one of the wearer's mouth or nasal cavity, as shown in Figure 6 is formed in the form of a nose mask applied to a conventional respirator, formed of a stretchable material to the face portion of the wearer Closely seal your mouth or nasal passages.

As shown in FIG. 6, the mask 10 has an exhaust port 11 through which a wearer's exhalation is discharged and is formed at one side, and an inlet 13 through which oxygen is introduced is formed at the other side. That is, the mask 10 is in communication with the exhalation and exhalation of the wearer separated.

Here, the mask 10 may be embedded in a hood 1 provided with a lens 2 and worn on the wearer's head as shown in FIG. 4.

Hood (1) is formed in a bag shape as the fabric coated with a heat dissipating material on the surface as shown in Figure 4, the sewing portion is seam sealed by the seam tape (3), the edge is mounted in a sealing state The see-through lens 2 and the fixing hole 1b formed therethrough as shown in an enlarged view in FIG. 4 are provided in the same body on the front surface.

Here, the heat dissipating material may be composed of a thin film that is deposited on the fabric is aluminum or aluminum is deposited on the fabric. And, the fabric may be composed of a fiber material made of any one of polyester fiber, nylon fiber, cotton fiber or aramid having heat resistance.

The fixing hole 1a is a portion fixed to the chamber housing 20 to be described later together with the exhaust port 11 of the mask 10 described above, and the protrusion 1b is enlarged as shown in FIG. 4. 7, when the projections 1b are collected and fixed together to be fixed to the chamber housing 20 as shown in FIG. 7, the protrusions 1b are fixed to the chamber housing 20 by the band clamp 5 together with the mask 10. That is, the hood 1 seals the fixed portion as the fixed portion is extended by the protrusion 1b.

As shown in FIG. 5, the chamber housing 20 is connected to the exhaust port 11 of the mask 10 to be ventilated to receive exhalation from the mask 10, and to prevent backflow of the supplied exhalation 21. ) Is provided, and forms a communication chamber for communicating exhalation. The chamber housing 20 may include a hollow cylinder 22, a cap 24, and a cylinder cover 26, for example, as shown in FIG. 6.

As shown in FIG. 6, the hollow cylinder 22 has a check valve 21 provided at one end thereof, and one end thereof is connected to the exhaust port 11 of the mask 10 in a state of communication, as shown in FIG. 7, and the other end thereof. As an open member, the exhalation expansion member 30 and the oxygen generator 40 described later are embedded.

This hollow cylinder 22 is coupled to the exhaust port 11 of the mask 10 together with the hood 1 by the band clamp 5 described above, as shown in FIG. However, the hollow cylinder 22 may be coupled to the exhaust port 11 of the mask 10 in a conventional manner, as described above.

On the other hand, the check valve 21 is composed of a diaphragm (21a) as shown in Figure 7, coupled to the through-hole formed in one end of the hollow cylinder 22 is opened in accordance with the exhalation of the wearer, it is closed by inhalation.

Cap 24 is a member that is coupled to the other end of the hollow cylinder 22 as shown in Figure 6 to shield the other end of the hollow cylinder 22 to be ventilated. For example, as shown in FIG. 6, the cap 24 is formed of a porous plate or a strainer through which the pores 24a are formed to allow oxygen generated from the oxygen generating agent 40 to be described later to pass through the pores 24a. It is more preferable to comprise a metal material having heat resistance against high heat generated when oxygen is generated.

The cylinder cover 26 is provided with an accommodating space 26a for accommodating the hollow cylinder 22, as shown in FIG. 6, while accommodating the hollow cylinder 22 and the cap 24 in the accommodating space 26a. It is coupled to one end of the 22, and forms the communication chamber while isolating the hollow cylinder 22 in the sealed state.

The cylinder cover 26 may be coupled to the hollow cylinder 22 by, for example, a hook 26b fastened to one end of the hollow cylinder 22 as shown in FIG. 7. It may be bonded by conventional methods such as fusion or tetrabond. Here, the cylinder cover 26, as shown in Figure 7, the coupling portion is sealed as the O-ring-shaped packing 26c is interposed between the hollow cylinder 22.

The cylinder cover 26 is provided with a spacer 26d spaced apart from the cap 24 as shown in FIG. For example, the spacer 26d may be formed as a protrusion that protrudes on a portion of the cylinder cover 26 to form a spaced space as the spacer 26d is in close contact with the cap 24. That is, as the cylinder cover 26 is spaced apart from the cap 24 by the spacer 26d, the cylinder cover 26 provides a communication path for oxygen discharged from the pores 24a of the cap 24 to the space.

In addition, the cylinder cover 26 is provided with a connecting pipe 27 connected to the collecting member 50, which will be described later as shown in Figure 5 on one side to collect the oxygen generated by the oxygen generator 40 to be described later Provide to 50.

The connecting pipe 27 is connected to the collecting member 50 by a rubber bush 27a and a band clamp 27b as shown in FIG. 7.

Meanwhile, the chamber housing 20 supports the cap 24 or the hollow cylinder 22 in the cylinder cover 26 to prevent the flow of the cap 24 and the hollow cylinder 22. It can be configured to include more.

The flow preventing member 28 is, for example, an elastic body 28a of which the other side elastically supports the cap 24 while one side is supported by the spacer 26d of the cylinder cover 26 described above as shown in FIG. 7. Or as shown in the drawing, protruding from the cylinder cover 26 to support the cap 24 or the hollow cylinder 22 to support jaw 28b.

For example, as shown in FIG. 6, the elastic body 28a may be configured as a leaf spring formed by cutting a portion of the cap 24 to protrude to form a coil spring. The elastic body 28a elastically supports the cap 24 during the impact of the chamber housing 20 to mitigate the impact as well as to prevent the front and rear flow of the hollow cylinder 22.

For example, as shown in FIG. 6, the support jaw 28b may be formed of a rib-shaped protrusion spaced apart in the circumferential direction inside the bottom surface of the cylinder cover 26. The support jaw 28b is bent as shown in FIG. 7 to support the cap 24 on one side, and to support the hollow cylinder 22 on the other side. Thus, the support jaw 28b prevents the left and right flow of the cap 22 and the hollow cylinder 22.

The exhalation expansion member 30 is a member that provides a flow path for vortexing the exhalation supplied to the chamber housing 20 and supplying it in a diffusion state to the inside of the chamber housing 20, for example, as shown in FIG. 6. ) And the porous wing 33 can be configured.

As shown in FIG. 6, the receptacle 31 is formed in a tubular shape having one end open and the other end shielded, and is embedded in the hollow cylinder 22, and as illustrated in FIG. 7, the outer side of the receptacle 31 is hollow cylinder 22. A portion of the communication chamber of the chamber housing 20 is spaced apart from the inner surface of the spaced apart portion of the filling space 31a is filled with the oxygen generating agent 40 to be described later.

Such a receptacle 31 is shielded from exhalation flowing into one end through the check valve 21 by facing the above-described check valve 21 through one end opened while being embedded in the hollow cylinder 22, as shown in FIG. Reflected through the other end, the vortex was discharged to one end again.

The porous wing 33 is provided at one end of the receptacle 31 as shown in FIG. 6 to shield the inside of the chamber housing 20 through a plurality of pores 33a so as to ventilate the one end of the receptacle 31. The exhalation discharged to the negative portion is guided to the filling space 31a through the pores 33a to react the exhalation with the oxygen generator 40 described later.

The porous wing 33 is supported integrally in the receptacle 31 in the form of a flange, for example, as shown in FIG. 7, and is supported by the locking step 22a provided in the hollow cylinder 22. As shown in 6, the filter 33b may be attached to one side.

The filter 33b prevents the leakage of the oxygen generating agent 40 which will be described later, and may be formed of, for example, a nonwoven fabric. The nonwoven fabric may be attached to the porous wing 33 by ultrasonic welding.

The above-described oxygen generating agent 40 is a component that generates oxygen in the chamber housing 20 by reacting with the exhalation supplied through the flow path of the exhalation expanding member 30, for example, as illustrated in FIG. 7. One receptacle 31 may be composed of KO ₂ (potassium peroxide) in the form of granules or pills filled in the filling space 31a partitioned in the chamber housing 20.

That is, the oxygen generator 40 generates oxygen while reacting with the carbon dioxide contained in the exhaled supplied through the pores 33a of the porous wings 33 in a state filled with the potassium peroxide and filled in the filling space 31a. Let's do it. At this time, the oxygen generator 40 generates high heat together with oxygen.

On the other hand, the chamber housing 20 described above may further comprise a coolant 29 for reducing the heat generated by the oxygen generation of the oxygen generator 40.

For example, the coolant 29 may be embedded in the cooling jacket 29a formed along the circumferential direction of the cylinder cover 26 constituting the chamber housing 20, as shown in an enlarged view of FIG. 7. It is preferable to use a cooling member in the form of a gel used for cooling water or a conventional cool mat.

The collecting member 50 is a member for collecting oxygen generated by the oxygen generating agent 40 in an airtight state, and, for example, as illustrated in FIG. 5, can be vented to the connecting pipe 27 of the cylinder cover 26 described above. It can be configured as a rubber material or a vinyl material trap that is connected to the air inlet, and is connected to the intake port 13 of the mask 10 described above. Such a trap is preferably formed in the shape of a bag as shown in the drawing so as to be stretchable and easy to carry and store when breathing. Alternatively, the trap may be configured in a box shape.

This collecting member 50 is connected to the connecting pipe 27 by the above-described rubber bush (27a) and the band clamp 27b as shown in Figure 7, the mask by the oxygen supply unit 60 to be described later It is connected to the intake port 13 of (10).

The oxygen supply unit 60 is a component for supplying the oxygen collected in the collecting member 50 to the mask 10 in a state in which backflow is prevented. For example, as illustrated in FIG. 6, the communication tube 61 and the check valve ( 63) can be configured to include.

As shown in FIG. 7, one side of the communication tube 61 is fixed to the collecting member 50 in a communication state, and the other side of the communication tube 61 is connected to the inlet 13 of the mask 10 in a communication state. One side is fixed to the collecting member 50 by the ash bush 62a and the band clamp 62b.

In addition, as shown in FIG. 7, the communicating tube 61 is formed with an inward flange 61a facing inward at an end of the other side, and the hollow rivet 61b penetrates inwardly through the inlet 13 of the mask 10. The other side is connected to the mask 10 as riveted from the inside of the flange (61a).

The check valve 63 is a member which is built in the communication tube 61 and prevents the backflow of oxygen supplied to the mask 10. The check valve 63 includes a valve body 63a and a diaphragm 63b as shown in FIG. can do.

As shown in FIG. 7, the valve body 63a is formed with a ventilation hole and is built in the communication tube 61, and the diaphragm 63b is fixed to the valve body 63a to open and close the ventilation hole of the valve body 63a. .

On the other hand, the oxygen supply unit 60 may further comprise a coupling means (65) for detachably coupling the valve body (63a) to be assembled to the communication tube (61).

Coupling means (65), for example, as shown in the enlarged in Fig. 7 protruding to the inner circumferential surface of the coupling jaw (65a) and the communication tube 61 formed by the undercut to the outside of the valve body (63a) coupling jaw (65a) It can be configured to include a locking projection (65b) to be caught.

In addition, the communication tube 61 is formed in the stepped shape on the inner peripheral surface as shown in Figure 7 is configured to further include a check valve stopper (61c) to prevent the flow of the valve body (63a) while being in close contact with the valve body (63a) can do.

On the other hand, the oxygen supply unit 60 may be configured to further include a filter 67 as shown in FIG. As shown in FIG. 7, the filter agent 67 is provided on the other side of the diaphragm 63b to filter dust or dust of the oxygen generator supplied to the mask 10, and may be formed of, for example, a nonwoven fabric or a sponge.

It describes the operation of the self-contained oxygen respirator according to the present invention including the above components.

The mask 10 is worn on the face of the wearer as shown in FIG. 4 in an emergency situation such as a toxic gas generation or an oxygen deficiency place, and exhausts the wearer's exhalation through the exhaust port 11 as shown in FIG. 7. The oxygen of the collecting member 50 is supplied to the wearer through the inlet 13.

As shown in FIG. 7, the diaphragm 21a is opened by exhalation to supply the exhalation to the receptacle 31 embedded in the hollow cylinder 22, and is closed by inhalation as shown in FIG. 7. Accordingly, the mask 10 is prevented from backflow of exhalation.

The receptacle 31 reflects the exhaled flow into the open end and supplies it to the porous wing 33 by reflecting through the other end of the shield. At this time, the exhalation is reflected by the other end of the receptacle 31, so that vortices are generated and smoothly supplied to the pores 33a of the porous wings 33.

The oxygen generator 40 generates oxygen while reacting with the carbon dioxide of the exhalation supplied from the porous wing 33, and the generated oxygen moves through the pores 24a of the cap 24 to form a spacer of the cylinder cover 26. It is supplied to the connecting pipe 27 along the space | interval space spaced apart from the cap 24 by 27d.

The collecting member 50 collects oxygen supplied through the connecting pipe 27 and supplies the collected oxygen to the intake port 13 of the mask 10 through the communication tube 61 according to the inhalation of the wearer.

At this time, the check valve 63 is opened in accordance with the wearer's inhalation in the communication tube 61 to communicate oxygen to the mask 10, and closed in accordance with the exhaler of the wearer to reverse the flow of oxygen introduced into the mask 10. prevent.

Therefore, the wearer can smoothly breathe by the oxygen supplied through the inlet 13 while exhausting the exhalation through the exhaust port 11 of the mask 10.

As described above, according to the self-contained oxygen respirator of the present invention, as the check valve 21 is provided in the chamber housing 20 for communicating exhalation, backflow of the exhalation is prevented and exhalation is caused by the exhalation expanding member 30. Since the exhalation is smoothly communicated with each other to cause oxygen to be generated, oxygen generated by the oxygen generating agent 40 is collected in the collecting member 50 and then supplied to the mask through the oxygen supply unit 60. Therefore, oxygen can be supplied to the wearer smoothly without being crossed with exhalation.

In addition, as the exhalation expansion member 30 and the oxygen generator 50 are built into the hollow cylinder 22 constituting the chamber housing 20, the volume can be minimized, and the cylinder cover 26 has the hollow cylinder 22. ) Can be combined in a state where the airtightness can be improved.

In addition, since the flow of the cap 24 or the hollow cylinder 22 is prevented by the flow preventing member 28 inside the cylinder cover 26, the occurrence of noise is suppressed as well as the impact is suppressed and durability can be improved. .

In addition, since the receptacle 31 constituting the exhalation expansion member 30 is formed in a tubular shape in which one side is shielded to generate the vortex while reflecting the exhalation, the exhalation can be smoothly communicated to the oxygen generator 40.

In addition, the oxygen generator 50 is composed of potassium peroxide (KO ₂ ) to smoothly generate oxygen through the carbon dioxide contained in the exhalation, when the coolant 29 is provided in the chamber housing 20, oxygen and The heat generated together can be reduced.

In addition, since oxygen generated in the oxygen generating agent 40 is collected in the collecting member 50, a large amount of oxygen may be collected and supplied, and oxygen is bypassed to the collecting member 50 to supply the mask 10. The heat contained in can be cooled.

In addition, since the backflow of oxygen supplied to the mask 10 is prevented by the check valve 63 constituting the oxygen supply unit 60, the wearer can smoothly breathe with the supplied oxygen.

While specific embodiments of the present invention have been described above by way of example, these are for illustrative purposes only and are not intended to limit the protection scope of the present invention. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made therein without departing from the spirit of the invention.

10 mask 11 exhaust port
13: inlet 20: chamber housing
21: check valve 22: hollow cylinder
24: cap 26: cylinder cover
26a: accommodating space 26b: hook
26c: packing 26d: spacer
27: connector 28: flow preventing member
28a: elastic body 28b: support jaw
29: coolant 30: exhalation expansion member
31: Receptacle 31a: Charging Space
33: porous wing 40: oxygen generator
50: collecting member 60: oxygen supply unit
61: communication tube 63: check valve
63a: valve body 63b: diaphragm
65 binding means 67 filter

Claims (7)

In the self-contained oxygen respirator that generates oxygen to the wearer's breathing air and supplies it to the wearer,
A mask that shields at least one of the wearer's mouth or nasal cavity;
A chamber housing connected to the mask to be supplied with exhalation from the mask, and having a check valve for preventing backflow of the exhalation and a communication chamber for communicating the exhalation;
An exhalation expansion member which swirls the exhalation supplied to the chamber housing and provides a flow path for supplying the diffusion chamber to the communication chamber of the chamber housing in the chamber housing;
An oxygen generator for generating oxygen in the chamber housing by reacting with the exhalation supplied through the flow path of the exhalation expansion member;
A collecting member for collecting oxygen generated by the oxygen generating agent in an airtight state; And
And an oxygen supply unit for supplying the oxygen collected in the collecting member to the mask in a state in which backflow is prevented. The method of claim 1, wherein the chamber housing,
A hollow cylinder having one end of the check valve coupled to the mask in communication with the breath valve, the expansible expansion member and the oxygen generator, and an open end;
A cap coupled to the other end of the hollow cylinder to shield the other end of the hollow cylinder to be ventilated; And
An accommodation space for accommodating the hollow cylinder is formed while the communication chamber is formed, and the cap and the inner side are spaced apart from each other to be coupled to the hollow cylinder to isolate the hollow cylinder from the outside in a sealed state, and to the collecting member. One side is connected to the self-contained oxygen respirator including a; cylinder cover for providing the oxygen generated in the oxygen generator to the collecting member. The method of claim 2, wherein the chamber housing,
Further comprising a flow preventing member for supporting the cap or the hollow cylinder in the cylinder cover to prevent the flow of the cap or the hollow cylinder;
The flow preventing member,
Characterized in that the other side is formed of at least one of an elastic body for elastically supporting the cap in the state in which one side is supported by the cylinder cover, or a support jaw formed in the cylinder cover to support the cap or the hollow cylinder. Feed oxygen respirator. The method of claim 1, wherein the exhalation expansion member,
The inner space and the outer surface of the chamber housing is spaced apart from each other through the gap spaced apart from the communication chamber provided in the chamber housing the filling space in which the oxygen generating agent is filled, and communicates with the check valve of the chamber housing A receptacle having one end and a shielded other end, and vortexing while reflecting the exhalation flowing into the one end through the check valve through the other end to discharge to the one end; And
And a porous wing provided at one end of the receptacle to ventilate and shield the inside of the chamber housing, and guide the exhalation discharged to one end of the receptacle to the filling space to react exhalation with the oxygen generating agent. Feed oxygen respirator. The method of claim 1, wherein the oxygen generating agent,
A self-contained oxygen respirator, which is built in the chamber housing and is composed of granules or pellets of potassium peroxide in the form of oxygen by reacting with carbon dioxide of the exhalation supplied from the exhalation expansion member. The method of claim 1, wherein the collecting member,
A self-contained oxygen respirator, characterized in that consisting of a rubber or vinyl trap is connected to the chamber housing one side is ventilated, the other side is ventilated connected to the mask. The method according to any one of claims 1 to 6,
The oxygen supply unit,
A communication tube having one side fixed to the collecting member in a communicating state and the other side connected to the mask in a communicating state; And
A self-contained oxygen respirator including a check valve built in the communication tube to prevent a backflow of oxygen supplied to the mask.

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