KR102544650B1 - Rechargeable oxygen respirator for cardio-pulmonary resuscitation and emergency evacuation - Google Patents

Abstract

The present invention relates to a rechargeable oxygen respirator for emergency evacuation combined with CPR, which can easily recharge oxygen, can easily check the remaining amount of oxygen with the naked eye, and improves the convenience of use by allowing the oxygen outlet to rotate 360 degrees. Its purpose is to make
To this end, the present invention includes a cylindrical container body 17 for storing compressed high-pressure oxygen, an oxygen discharge unit 10 provided in a horizontal direction from the top of the container body 17, and the oxygen discharge unit ( 10) in the rechargeable oxygen respirator including a button 3 for discharging oxygen, an oxygen filling part provided at the lower end of the container body 17, and an upper part of the container body 17 A nozzle guide 12 assembled to guide oxygen discharge, a spray nozzle cap 6 assembled on top of the nozzle guide 12, and a rotating cap 5 assembled on top of the spray nozzle cap 6 And, a switch member 4 assembled inside the rotary cap 5 and moving up and down a certain distance, and an oxygen discharge unit 10 formed on one side of the rotary cap 5, the It is characterized in that oxygen inside the container body 17 is discharged through the oxygen discharge unit 10 by the vertical movement of the switch member 4 .

Description

Rechargeable oxygen respirator for emergency evacuation with CPR {RECHARGEABLE OXYGEN RESPIRATOR FOR CARDIO-PULMONARY RESUSCITATION AND EMERGENCY EVACUATION}

The present invention relates to a rechargeable oxygen respirator for emergency evacuation combined with CPR, and more particularly, can be easily recharged and used with oxygen, can easily check the oxygen charge state and oxygen remaining amount with the naked eye by an oxygen remaining amount gauge, A rechargeable coral respirator that can be used both for evacuation and for CPR (cardiopulmonary resuscitation), which induces self-breathing for those who cannot breathe on their own, and improves the convenience of use by allowing the oxygen outlet to rotate 360 degrees. It is about.

When a fire breaks out at home or at an industrial site, petrochemical products, such as various household items, textiles, and interior materials, are incompletely burned, generating toxic gases that are fatal to the human body.

The toxic gas generated at this time is a toxic gas synthesized by carbon monoxide gas and various compounds, and causes nerve and cognitive function disorders when inhaled, making it difficult to escape the fire scene.

In the case of casualties caused by fire, suffocation due to toxic gas and smoke accounts for most of the accidents rather than accidents directly exposed to flame.

Also, in case of fire, it is important to quickly escape the fire site. The so-called golden time, which is the time to evacuate from the moment a fire is recognized, is known to be about 5 to 7 minutes.

According to one survey result, the survival rate decreases by 7~10% for every 1 minute after a fire occurs, and the survival rate drops to 25% after 5 minutes and less than 5% after 10 minutes. Therefore, in the event of a fire, it is important to quickly evacuate the fire site to avoid smoke.

On the other hand, evacuation equipment such as fire extinguishers and descenders are provided in buildings and apartments according to relevant laws and regulations.

However, the above-mentioned evacuation equipment cannot prevent suffocation due to toxic gas and smoke.

In particular, when a fire breaks out in a place used by a large number of passengers, such as a subway, it leads to a large-scale disaster.

In order to solve this problem, there are cases in which emergency gas masks are provided, but these gas masks have limitations in completely filtering toxic gases.

In addition, the gas mask has a disadvantage in that it is difficult for ordinary people to wear it easily in case of an emergency, so that the golden time can be missed when the gas mask is worn at an emergency fire site.

In particular, when the amount of oxygen in the air is insufficient due to a fire, there is a disadvantage in that it is difficult to breathe stably after wearing a gas mask.

In addition, gas masks are provided in small quantities only in certain places according to the Fire Protection Act, so a large number of people cannot use them at the same time, and there is a problem that they are bulky and inconvenient to carry.

In order to solve these problems, a portable oxygen respirator that can be used at a fire site has been developed.

In general, an oxygen respirator has been used as a device for supplying oxygen to an emergency patient or a patient suffering from breathing difficulties requiring an artificial supply of oxygen, but there is also a small portable oxygen respirator that can be used at a fire site.

The portable oxygen respirator described above can be usefully used to supply oxygen to people having difficulty breathing at fire sites or various disaster sites.

In addition, the portable oxygen respirator can be used for patients who have difficulty in repeatedly using large oxygen respirators in hospitals or nursing homes.

As an example of such a portable oxygen respirator, there is a "emergency rescue respirator" of Korean Patent Registration No. 10-1222684.

As shown in FIG. 1, the conventional portable oxygen respirator described above includes a pipe-shaped storage case 100 for storing any one of oxygen, air, or a mixture of oxygen and air as a filler; A filler discharge unit 50 coupled to one end of the storage case 100; A filler filling part 90 coupled to the other end of the storage case 100; and a mask unit 200 that is directly connected to the filler discharge unit 50 and closely adhered to the periphery of the respirator so that the filler discharged from the filler discharge unit can be injected through the human respiratory system.

In the oxygen respirator having the above structure, when an external button installed on the filler discharge unit 50 is pressed, the filler in the storage case 100 is ejected to the outside of the storage case through the mask unit 200.

As a result, the user can inhale fresh air or oxygen at a fire site where oxygen is scarce by pressing a button while the mask unit 200 is applied to the nose and mouth.

Accordingly, it is possible to quickly escape the fire scene by putting the respirator on the face at a fire scene or the like.

However, conventional oxygen respirators have the following disadvantages.

First, conventional oxygen respirators are mostly disposable and must be discarded after one use, and are relatively expensive.

On the other hand, there is also an oxygen respirator that can be recharged as shown in FIG. 1, but it is inconvenient to use because it is a structure that can be charged after being separated from the filling cap container body.

Second, in conventional oxygen respirators, most of the oxygen storage container bodies are made of cast material, so the charging capacity is reduced in the same size and it is somewhat heavy to carry.

Accordingly, it is inconvenient for the elderly or children to carry, and since the inside of the body cannot be coated, there are disadvantages in that it is easily corroded by oxygen.

In addition, there is a concern about the generation of bubbles during casting, and it may be damaged when high-pressure oxygen is injected due to the bubbles.

Third, conventional oxygen respirators have a disadvantage in that they are inconvenient to use because the oxygen outlet is fixed. In other words, it is inconvenient to use while escaping in an emergency.

Fourth, conventional oxygen respirators, which are rechargeable, have only a pressure gauge and no oxygen level indicator. Accordingly, there is a disadvantage in that the remaining amount of oxygen inside the container body cannot be visually checked.

Korean Patent Publication No. 10-0143087 (published on November 26, 2021) Korean Patent Registration No. 10-2231592 (Announced on March 23, 0921) Korean Patent Registration No. 10-1944697 (2019. 02. 01. Announcement) Korean Patent Registration No. 10-1750660 (Announced on June 26, 2017)

The present invention is to solve the problems of the prior art, the oxygen respirator can be easily recharged and used, and the object of the present invention is to enable the elderly or children to easily use it in an emergency.

Another object of the present invention is to be able to be used for emergency evacuation as well as CPR (cardiopulmonary resuscitation) for inducing self-sustaining breathing.

Another object of the present invention is to easily check the amount of oxygen remaining inside the container body with the naked eye.

Another object of the present invention is to improve the convenience of use during emergency evacuation by allowing the oxygen outlet to rotate.

Another object of the present invention is to reduce the weight of the oxygen respirator so that it is easy to carry and can be easily used in an emergency.

Another object of the present invention is to prevent corrosion due to oxidation from occurring inside the oxygen container body.

In order to achieve the above object, the present invention provides a cylindrical container body for storing compressed high-pressure oxygen, an oxygen discharge unit provided in a horizontal direction from the top of the container body, and an oxygen discharge unit provided on the top of the oxygen discharge unit. In a rechargeable oxygen respirator comprising a button for discharging, an oxygen filling part provided at the lower end of the container body, a nozzle guide assembled on the upper part of the container body to guide oxygen discharge, and an upper part of the nozzle guide A spray nozzle cap to be assembled, a rotation cap to be assembled on top of the spray nozzle cap, a switch member assembled inside the rotation cap to move up and down a certain distance, and an oxygen discharge unit formed on one side of the rotation cap It is configured so that oxygen inside the container body is discharged through the oxygen discharge unit by the vertical movement of the switch member.

In addition, the charging unit includes a charging cap provided with a charging hole at the center and assembled to the lower end of the container body, a snap ring and a washer provided at the upper center of the charging cap, and an elastic member assembled to the lower portion of the washer, It is characterized in that it is configured to include a sealing member assembled to the lower portion of the elastic member.

In addition, the charging cap is formed in a structure with an open bottom, is directly detachably mounted to the oxygen filling device, and is characterized in that a ring-shaped groove for accommodating an O-ring is formed on the top.

In addition, the elastic member is formed of a urethane material having a certain elasticity and is compressed toward the top during charging, and the sealing member descends downward when the container body is removed from the charging device to seal the lower charging hole. do.

In addition, the nozzle guide is configured to include a lower body portion formed at the bottom, an intermediate body portion formed with an outer diameter smaller than the lower body portion, and an upper body portion formed with an outer diameter smaller than the intermediate body portion. do.

In addition, a lower nozzle ring and an upper nozzle ring are assembled inside the intermediate body, and a nozzle pin is assembled on the upper nozzle ring.

In addition, the lower nozzle ring is characterized in that a through hole is formed in the center to allow oxygen to pass through, and a spring is assembled to an outer circumferential surface of the nozzle pin.

In addition, an oxygen remaining amount gauge displaying the remaining amount of oxygen inside the container body is assembled on one side of the outer surface of the middle body portion.

In addition, an upper discharge pin and a lower discharge pin are assembled to the inside of the upper body, a switch member is assembled to an upper portion of the upper discharge pin, and a spray nozzle cap is assembled to an outer surface of the upper body.

In addition, a through hole is formed in the center of the upper discharge pin to allow oxygen to pass therethrough.

In addition, a switch member moving up and down a certain distance is assembled inside the spray nozzle cap, and the switch member opens and closes the space formed on the spray nozzle cap while moving up and down a certain distance by pressing the pressing portion provided in the center of the button. characterized by

In addition, the switch member is characterized in that it is configured to include a first passage provided in the axial direction therein, and a second passage formed in a circumferential direction at an end of the first passage.

In addition, a horizontal space portion is formed on the upper outer circumference of the spray nozzle cap, and a rotating cap capable of rotating 360 degrees is assembled to surround the space portion on the upper outer circumferential surface of the spray nozzle cap, and on one outer circumferential surface of the rotating cap, It is characterized in that an oxygen discharge unit having an oxygen discharge hole formed horizontally is assembled so that the oxygen discharge unit can rotate 360 degrees.

In addition, when the button is pressed, the second passage of the switch member, the space of the spray nozzle cap, and the oxygen discharge hole of the oxygen discharge unit communicate with each other to discharge oxygen.

In addition, the container body is manufactured by drawing a pipe, and the inside of the container body is coated with an eco-friendly paint.

In addition, a CPR combined mask is assembled to the oxygen discharge unit, and it is characterized in that CPR can be performed after wearing it to a patient having difficulty self-breathing.

In addition, it is characterized in that an emergency evacuation mask is assembled to the oxygen discharge unit and used for emergency evacuation in which a user directly wears and evacuates in case of an emergency.

According to the present invention, since the charging unit provided at the bottom of the container body is configured in an open type, there is an effect that it can be easily charged by being seated in a charger dedicated to the oxygen respirator.

In addition, there is an effect that the oxygen charge state and the oxygen remaining amount can be easily checked with the naked eye by the oxygen remaining amount gauge.

In addition, since the outlet through which oxygen is discharged freely rotates, there is an effect of improving the convenience of use when escaping from a fire scene.

In addition, by assembling a CPR combined mask on an oxygen respirator, there is an effect of performing CPR on a person who is unable to breathe on their own.

In addition, the weight of the oxygen respirator can be reduced by drawing the pipe instead of manufacturing the container body by casting.

As a result, it can be easily carried and used, and there is an effect that the elderly or children can easily use it.

In addition, by coating the inside of the container body with an eco-friendly paint, there is an effect of preventing corrosion due to oxidation.

1 is a perspective view showing an example of an oxygen respirator according to the prior art.
Figure 2 is a state diagram in which the CPR combined mask is assembled to the oxygen respirator according to the present invention.
Figure 3 is a state of use of assembling a CPR combined mask to the oxygen respirator according to the present invention.
Figure 4 is a cross-sectional view of the oxygen respirator according to the present invention.
Figure 5 is an enlarged cross-sectional view of the main part of the oxygen respirator according to the present invention.
Figure 6 is a cross-sectional view for explaining the case of discharging oxygen from the oxygen respirator according to the present invention.
7 is a view showing a state in which an emergency evacuation mask is attached to the oxygen respirator according to the present invention.

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

As shown in FIGS. 4 and 5, the oxygen respirator according to the present invention includes a cylindrical container body 17 for storing compressed high-pressure oxygen, and oxygen provided in the horizontal direction at the top of the container body 17. In the rechargeable oxygen respirator comprising a discharge unit (10) and a button (3) provided on the upper part of the oxygen discharge unit (10) to discharge oxygen, the charging unit provided at the lower end of the container body (17). And, a nozzle guide 12 assembled on the top of the container body 17 to guide oxygen discharge, a spray nozzle cap 6 assembled on the top of the nozzle guide 12, and the spray nozzle cap 6 ), a rotary cap 5 assembled on top of the rotary cap 5, a switch member 4 assembled inside the rotary cap 5 and moving up and down a certain distance, and oxygen discharge formed on one side of the rotary cap 5 It is configured to include a portion 10, so that oxygen inside the container body 17 is discharged through the oxygen discharge portion 10 by the vertical movement of the switch member 4.

Here, the container body 17 is manufactured not by casting but by drawing or extruding a pipe, and the inside of the container body 17 is coated with an eco-friendly paint.

With the above structure, the weight of the container body 17 is reduced, making it easy to carry, and various defects associated with casting can be prevented.

In addition, by coating the inside of the container body 17 with an eco-friendly paint harmless to the human body, oxidation and corrosion can be prevented and oxygen can be maintained in a clean state.

In addition, an upper cap 1 is provided on the top of the container body 17 to protect each part.

And the filling part according to the present invention is provided in the lower part of the container body 17, the filling cap 18 is provided with a filling hole 23 in the central portion and assembled to the lower end of the container body 17, The snap ring 21 and the washer 19 provided at the upper center of the filling cap 18, the elastic member 20 assembled to the lower part of the washer 19, and the elastic member 20 Assembled to the lower part It is configured to include a sealing member (22).

Here, the charging cap 18 is formed in a structure with an open bottom and is detachably mounted to a separate oxygen filling device (not shown).

In addition, a ring-shaped groove for accommodating the O-ring 9 is formed on the top of the charging cap 18. Thereby, airtightness can be improved.

In addition, the elastic member 20 is formed of a urethane material having a certain elasticity and is compressed toward the top during charging, and the sealing member 22 descends downward when the container body 17 is removed from the charging device, The filling hole 23 of is sealed.

Owing to the structure described above, it is possible to easily charge oxygen by simply attaching the charging unit to a separate oxygen charging device.

In addition, by the elastic member 20 and the sealing member 22, the airtightness can be improved while configuring the charging unit in an open state.

At this time, it is preferable to compress oxygen to about 290 bar and charge the container body 17, and to charge an amount that can be used for about 10 to 20 minutes at a time.

However, it is not limited thereto, and the charging capacity of the container body 17 may be appropriately increased or decreased.

In addition, the nozzle guide 12 includes a lower body portion 12a formed at a lower portion, an intermediate body portion 12b formed with an outer diameter smaller than that of the lower body portion 12a, and a smaller outer diameter than the intermediate body portion 12b. It is configured to include an upper body portion 12c formed with a small outer diameter.

In addition, the lower nozzle ring 15 and the upper nozzle ring 14 are assembled inside the middle body part 12b, and the nozzle pin 13 is assembled on the upper nozzle ring 14.

Here, a through hole 15a is formed in the center of the lower nozzle ring 15 to allow oxygen to pass therethrough, and a spring 13a is assembled to an outer circumferential surface of the nozzle pin 13.

In addition, in the present invention, an oxygen remaining amount gauge 11 displaying the remaining amount of oxygen inside the container body 17 is assembled on one side of the outer surface of the intermediate body portion 12b.

Accordingly, when oxygen is charged and used, the remaining amount of oxygen can be easily checked with the naked eye.

An upper discharge pin 7 and a lower discharge pin 8 are assembled inside the upper body portion 12c.

In addition, the switch member 4 is assembled to the top of the upper discharge pin 8, and the spray nozzle cap 6 is assembled to the outer surface of the upper body portion 12c.

Here, a through hole 7a is formed in the center of the upper discharge pin 7 to allow oxygen to pass therethrough.

In addition, a switch member 4 moving up and down a certain distance is assembled inside the spray nozzle cap 6.

The switch member 4 opens and closes the space 6a formed in the spray nozzle cap 6 while moving up and down a certain distance by pressing the pusher 2 provided at the center of the button 3.

As a result, oxygen is discharged to the outside through the oxygen discharge unit 10 .

In addition, an O-ring (9) is assembled on the contact surface between the upper part of the switch member (4) and the spray nozzle cap (6) and the assembly portion of the spray nozzle cap (6) and the rotating cap (5).

Here, the O-ring 9 is preferably made of a fluorocarbon material having excellent chemical resistance.

Meanwhile, the switch member may be configured in a two-stage manner so that the oxygen discharge hole is opened when pressed once and returned to the original state when pressed again.

And the switch member 4 is configured to include a first passage 4a provided in an axial direction therein, and a second passage 4b formed in a circumferential direction at an end of the first passage 4a. .

In addition, a horizontal space portion 6a is formed on the outer circumference of the upper portion of the spray nozzle cap 6, and a rotating cap 5 capable of rotating 360 degrees is formed on the outer circumferential surface of the upper portion of the spray nozzle cap 6. It is assembled to cover (6a).

In addition, an oxygen discharge unit 10 having an oxygen discharge hole 10a formed horizontally is assembled on an outer circumferential surface of one side of the rotary cap 5 so that the oxygen discharge unit 10 can rotate 360 degrees. It consists of

That is, since the present invention has a structure in which the rotary cap 5 rotates 360 degrees, user convenience can be improved in case of an emergency.

With the above structure, when the button 3 is pressed, the second passage 4b of the switch member 40, the space 6a of the spray nozzle cap 6, and the oxygen discharge hole of the oxygen discharge unit 10 10a communicate with each other to discharge oxygen.

And as shown in FIG. 3 , a CPR combined mask M1 may be assembled to the oxygen discharge unit 10 .

In this way, after putting on a mask (M1) combined with CPR (Cardiopulmonary resuscitation), the patient who has difficulty breathing on their own can be put on, and then CPR is performed by compressing the chest to induce spontaneous breathing of the patient.

That is, when performing CPR, the CPR mask (M1) can be used as a substitute for artificial respiration.

In general, if oxygen supply is stopped for more than 3 to 4 minutes, brain function begins to be damaged, consciousness is lost, and breathing and pulse stop, leading to death.

Therefore, when breathing is stopped due to electric shock or suffocation due to fire, oxygen supply through an oxygen respirator becomes more important than anything else.

According to the present invention, after the patient is laid down and the CPR combined mask (M1) is worn, first aid can be performed while chest compressions are performed.

Meanwhile, as shown in FIG. 8 , an emergency evacuation mask M2 may be assembled to the oxygen delivery unit 10 .

The emergency evacuation mask M2 is used when a user inhales oxygen by pressing a button after wearing it directly in case of an emergency.

The oxygen respirator according to the present invention may be provided in an emergency rescue box installed in a subway station or the like, or may be carried by an individual and used in an emergency.

Hereinafter, with reference to FIGS. 5 and 6, the effect of the oxygen respirator according to the present invention will be described.

First, as shown in FIG. 5, the button 3 is raised upward in normal times.

In this case, the second passage 4b formed in the switch member 4 is positioned above the space 6a formed in the spray nozzle cap 6. As a result, the second passage 4b is closed.

That is, since the second passage 4b formed in the switch member 4 and the space 6a formed in the spray nozzle cap 6 do not coincide with each other, oxygen flows into the oxygen discharge unit 10 through the space 6a. does not discharge

When the button 3 is pressed in this state, as shown in FIG. 6, the switch member 4 descends downward to form the second passage 4b formed in the switch member 4 and the spray nozzle cap 6. The space portions 6a coincide with each other.

Then, the oxygen inside the container body 17 flows through the lower nozzle ring 15 → the upper nozzle ring 14 → the through hole 7a of the upper discharge pin 7 → the first passage 4a of the switch member 4 → Second passage (4b) → Oxygen is discharged toward the mask side through the oxygen discharge hole (10a) of the oxygen discharge unit (10).

Accordingly, the user can inhale oxygen through the mask assembled with the oxygen discharge hole 10a.

In the above, preferred embodiments of the present invention have been described by way of example, and the scope of the present invention is not limited to the above specific embodiments. Those skilled in the art to which the present invention pertains will understand that various modifications and changes are possible without departing from the scope of the technical idea of the present invention.

1: top cap 2: press part
3: Button 4: Switch member
4a: first passage 4b: second passage
5: rotation cap 6: spray nozzle cap
6a: space part 7: upper discharge pin
7a: through hole 8: lower discharge pin
9: O-ring 10: Oxygen discharge unit
10a: Oxygen discharge hole 11: Oxygen remaining amount gauge
12: Nozzle Guide 12a: Lower Body
12b: middle body portion 12c: upper body portion
13: Nozzle Pin 13a: Spring
14: upper nozzle ring (Nozzle Ring) 15: lower nozzle ring
15a: through hole 16: O-ring
17: container body 18: filling cap
19: washer 20: elastic member
21: snap ring 22: sealing member
23: charging hole
M1: CPR combined mask M2: Emergency evacuation mask

Claims (17)

A cylindrical container body 17 for storing compressed high-pressure oxygen, an oxygen discharge unit 10 provided in a horizontal direction from the top of the container body 17, and provided on the top of the oxygen discharge unit 10 In the rechargeable oxygen respirator comprising a button (3) for discharging oxygen,
An oxygen filling part provided at the lower end of the container body 17;
A nozzle guide 12 assembled on the top of the container body 17 to guide oxygen discharge;
A spray nozzle cap 6 assembled on the top of the nozzle guide 12;
A rotary cap 5 assembled on the upper part of the spray nozzle cap 6;
A switch member 4 assembled inside the rotating cap 5 and moving up and down a certain distance;
It is configured to include an oxygen discharge unit 10 formed on one side of the rotary cap 5,
By the vertical movement of the switch member 4, oxygen inside the container body 17 is discharged through the oxygen discharge unit 10,
The nozzle guide 12,
A lower body portion 12a formed at a lower portion;
An intermediate body portion 12b having an outer diameter smaller than that of the lower body portion 12a;
It is configured to include an upper body portion (12c) formed with a smaller outer diameter than the middle body portion (12b),
A lower nozzle ring 15 and an upper nozzle ring 14 are assembled inside the intermediate body portion 12b,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that the nozzle pin 13 is assembled on the upper part of the upper nozzle ring 14. According to claim 1,
The oxygen filling unit,
A filling cap 18 having a filling hole 23 in the center and assembled to the lower end of the container body 17;
A snap ring 21 and a washer 19 provided at the upper center of the charging cap 18,
An elastic member 20 assembled under the washer 19,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that it comprises a sealing member 22 assembled to the lower portion of the elastic member 20. According to claim 2,
The filling cap 18,
It is formed in an open structure at the bottom and is detachably mounted directly to the oxygen filling device,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that a ring-shaped groove for accommodating the O-ring (9) is formed at the top. According to claim 2,
The elastic member 20 is formed of a urethane material having a certain elasticity and is compressed toward the top during charging,
The sealing member 22 is a rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that when the container body 17 is removed from the charging device, it descends downward to seal the charging hole 23 at the bottom. delete delete According to claim 1,
The lower nozzle ring 15 has a through hole 15a formed in the center to allow oxygen to pass through,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that the spring (13a) is assembled on the outer circumferential surface of the nozzle pin (13). According to claim 1,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that an oxygen remaining amount gauge 11 displaying the remaining amount of oxygen inside the container body 17 is assembled on one side of the outer surface of the intermediate body portion 12b. According to claim 1,
The upper discharge pin 7 and the lower discharge pin 8 are assembled inside the upper body portion 12c,
A switch member 4 is assembled on the top of the upper discharge pin 7,
Rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that the injection nozzle cap (6) is assembled on the outer surface of the upper body portion (12c). According to claim 9,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that a through hole (7a) is formed in the center of the upper discharge pin (7) to allow oxygen to pass through. According to claim 9,
A switch member 4 moving up and down a certain distance is assembled inside the spray nozzle cap 6,
The switch member 4 is characterized in that the space portion 6a formed in the spray nozzle cap 6 is opened and closed while moving up and down a certain distance by pressing the pressing portion 2 provided at the center of the button 3 Rechargeable oxygen respirator for emergency evacuation with CPR. According to claim 11,
The switch member 4,
A first passage (4a) provided in the axial direction therein;
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that it comprises a second passage (4b) formed in the circumferential direction at the end of the first passage (4a). According to claim 11,
A horizontal space portion 6a is formed on the upper outer circumference of the spray nozzle cap 6,
On the upper outer circumferential surface of the spray nozzle cap 6, a rotating cap 5 capable of rotating 360 degrees is assembled to surround the space portion 6a,
An oxygen discharge unit 10 having an oxygen discharge hole 10a formed horizontally is assembled on an outer circumferential surface of one side of the rotary cap 5 so that the oxygen discharge unit 10 can rotate 360 degrees. A rechargeable oxygen respirator for emergency evacuation with CPR. According to claim 11,
When the button 3 is pressed, the second passage 4b of the switch member 40, the space 6a of the spray nozzle cap 6, and the oxygen discharge hole 10a of the oxygen discharge unit 10 communicate with each other. A rechargeable oxygen respirator for emergency evacuation combined with CPR, characterized in that it discharges oxygen. According to claim 1,
The container body 17 is manufactured by drawing a pipe,
Rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that the inside of the container body (17) is coated with an eco-friendly paint. 15. The method of claim 14,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that a CPR combined mask (M1) is assembled to the oxygen discharge unit (10), so that CPR can be performed after wearing it to a patient having difficulty breathing on their own. 15. The method of claim 14,
A rechargeable oxygen respirator for emergency evacuation with CPR, characterized in that the emergency evacuation mask (M2) is assembled to the oxygen discharge unit (10) and used for emergency evacuation in which the user directly wears it and evacuates in the event of an emergency.

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