KR101489430B1 - Manual operated artificial respiration apparatus - Google Patents

Abstract

[0001] The present invention relates to a manual ventilator, which is capable of controlling the flow rate of exhaust air and automatically controlling the oxygen concentration of intake air while being operable automatically.
To this end, the present invention provides a passive respiratory apparatus including an air bag filled with oxygen gas supplied from an oxygen container, and an oxygen supply pipe through which oxygen in the air bag is supplied to the patient's airway by compressing the air bag, One side of the oxygen supply pipe is provided with an oral connection tube configured to be brought into close contact with the airway of the patient and the other side of the oxygen supply tube is connected to a first branching mechanism branched from the branching pipe and leading to a discharge pipe equipped with an exhaust valve, The inlet / outlet pipe control valve is provided at a branch point between the first branch mechanism and the second branch mechanism, and the intake / exhaust pipe control valve is operated by the pressure of the oxygen gas as the air bag is compressed at the time of intake, And the first minute mechanism is closed while the second minute mechanism is opened.
In the manual ventilator of the present invention, one end of the air bag is provided with an air bag lower end valve connected to the oxygen container connecting tube, and the air bag lower end valve is connected to the oxygen gas connecting pipe And is closed by pressure so that oxygen gas in the air bag is discharged to the oxygen supply pipe.

Description

[0001] The present invention relates to a manually operated artificial respiration apparatus

More particularly, the present invention relates to a passive ventilation apparatus which can control the flow rate of exhaust air and can automatically control the oxygen concentration of the intake air, ≪ / RTI >

Generally, a ventilator is a means of artificially supplying oxygen gas to a patient to maintain life until the patient is recovered. In recent years, while maintaining comfort to the patient during artificial respiration, To minimize structural damage to the skin. In other words, the foreign technology development trends on artificial respiration were studied in the 1980s, and the study on the ventilation supply method in the 1990s has attracted attention.

In recent years, research has been focused on artificial respiration devices that can reduce lung damage and induce efficient spontaneous breathing in accordance with the mechanical principles of the lungs. In addition, there is an interest in reducing the damage of the alveolar-capillary blood vessels and the spontaneous breathing of the apnea patients. Various types of artificial respiration devices are being developed that can be quickly guided.

FIG. 1 is a schematic view showing the configuration of a conventional artificial respiratory apparatus mounted in an emergency room or an ambulance in a hospital. As shown in the figure, a regulator (not shown) for discharging oxygen gas discharged from the oxygen container 1 through an outlet An oxygen supply pipe 3 connected to the regulator 2, a valve 4 provided on the oxygen supply pipe for interrupting the amount of oxygen supplied from the oxygen container 1, a pressure of oxygen passing through the oxygen supply pipe 3 And a control unit 6 for controlling the on / off operation of the valve 4 according to the information sensed by the pressure sensor 5 and the pressure sensor 5 for sensing the flow rate.

The general artificial respiratory apparatus as described above controls the valve 4 in accordance with the information provided from the pressure sensor 5 installed in the oxygen supply pipe 3 so that the amount of oxygen exhausted from the oxygen container 1 and supplied to the output port can be adjusted So that the pressure of the mixed gas tank can not be maintained constant, so that the spontaneous breathing of the apnea patient can not be induced quickly.

Meanwhile, the conventional manual ventilator has a large capacity of 1500 ~ 1600 ml of the air storage bag, which is not only inefficient due to a large amount of oxygen used, The size of the air storage bag is large so that there is a disadvantage of the use which must use two hands in an emergency situation and a problem is caused in the restoration force. In addition, when the manual ventilator is operated by hand, it is necessary to adjust the dose depending on the experience and feeling of the operator, and thus there is a problem that the patient's lung may be inflicted.

In addition, even if the reservoir bag is attached to the intake valve, such a conventional manual ventilator is structured such that it can not maintain a desired level of oxygen concentration when it is mixed with the atmospheric air when the air is introduced. Especially, In order to operate the device, one or two practitioners must carry on the procedure and there is a disadvantage of the use.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a manual ventilation apparatus of a simple structure which is capable of controlling the flow rate of exhaust air and automatically controlling the oxygen concentration of the intake air while being operable automatically.

It is another object of the present invention to provide a manual ventilation device capable of controlling the flow rate of exhaust air and capable of controlling the oxygen concentration of intake air while automatically operating, .
Another object of the present invention is to provide a passive respiratory apparatus including an air bag filled with oxygen gas supplied from an oxygen container, wherein one end of the air bag is connected to an oxygen container connector, A valve is provided and the air bag lower valve is closed by the pressure of the oxygen gas as the air bag is compressed when the air bag is sucked so that the oxygen gas in the air bag is discharged toward the closed channel. will be.

According to an aspect of the present invention, there is provided an oxygen-containing gas supply device for an oxygen-containing gas supply device, including: an air bag filled with oxygen gas supplied from an oxygen container; Wherein one side of the oxygen supply tube is provided with an oral connection tube adapted to be brought into close contact with the airway of the patient and the other side is connected to a first branching device branched from the branching pipe and leading to a discharge pipe equipped with an exhaust valve, And the branch pipe branches to the second branch pipe leading to the air bag connection pipe. The branch pipe of the first branch pipe and the second branch pipe is provided with an inlet / outlet pipe control valve. The inlet / outlet pipe control valve, The first minute mechanism is closed by opening the second minute mechanism by the pressure of the oxygen gas along the first minute mechanism.

In the manual ventilator of the present invention, one end of the air bag is provided with an air bag lower end valve connected to the oxygen container connecting tube, and the air bag lower end valve is connected to the oxygen gas connecting pipe And is closed by pressure so that oxygen gas in the air bag is discharged to the oxygen supply pipe.

According to another aspect of the present invention for achieving the above object, there is provided an oxygen-containing gas supply device for supplying oxygen gas to a patient, comprising: an air bag filled with oxygen gas supplied from an oxygen container; Wherein the oxygen supply pipe includes one closed conduit capable of fluid circulation, and one side of the closed conduit has an oral connection tube configured to be able to be brought into close contact with the airway of the patient, An air bladder connection pipe connected to the air bladder is mounted on the other side of the closed duct, and one of the upper and lower sides of the closed bladder duct is provided with an intake duct control valve so that when the air bladder is compressed And the intake pipe control valve is opened by the pressure of the oxygen gas supplied from the air bag, It consists of a.

The other one of the upper and lower sides of the closed conduit is provided with an exhaust conduit regulating valve so that the exhaust conduit regulating valve is opened by the pressure of air containing carbon dioxide discharged from the patient, Thereby constituting an exhaust pipe passage.

According to the manual ventilator of the present invention, the flow rate of the exhaust air can be adjusted and the oxygen concentration of the intake air can be adjusted, and the automatic operation can be performed.

In addition, the ventilator according to the present invention can store an appropriate amount of intake capacity (for example, about 1000 to 1200 cc) while the size of the airbag can be compressed by one hand, It is possible to control a sufficient amount of intake air required for artificial respiration, and it is possible to use oxygen efficiently by using a circulating oxygen supply pipe, so there is an advantage that consumption of oxygen can be reduced. In addition, by reducing the size of the air bag, the error caused by the restoring force can be reduced.

In addition, the artificial respiratory apparatus according to the present invention can control the amount of oxygen supplied to the patient by adjusting the inflow amount of the atmospheric air using the atmospheric air inlet, and thus has an advantage of being able to solve the problem of excessive injection into pediatric patients .
The present invention also relates to a passive respiratory apparatus including an air bag filled with oxygen gas supplied from an oxygen container, wherein one end of the air bag is provided with an air bag lower valve connected to the oxygen container connector, The bag bottom valve is closed by the pressure of the oxygen gas as the air bag is compressed upon intake, so that the oxygen gas in the air bag is discharged to the closed channel.

1 is a schematic view showing a configuration of a conventional general artificial respiration apparatus
2 is a configuration diagram briefly illustrating a configuration of a respiratory apparatus according to an embodiment of the present invention.
FIG. 3 is a schematic view illustrating a configuration of a respiratory apparatus according to another embodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the configuration and operation of a passive ventilation apparatus with enhanced oxygen efficiency according to each embodiment of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention. Therefore, it should be understood that the embodiments described herein and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and that various equivalents and modifications may be substituted for them at the time of the present application shall.

FIG. 2 is a schematic view illustrating a configuration of a ventilator according to an embodiment of the present invention. As shown in the drawings, the ventilator according to an embodiment of the present invention includes an air bag 12, An open type oxygen supply pipe 14, an intake and exhaust pipe control valve 15, and a pressure control valve 16.

The air bladder 12 is an air bladder of a size and a volume compressible by a practitioner with one hand in an emergency, and is made of an air bladder having an internal space capable of storing an intake capacity of 1 to 1.2 liters, (O ₂ ) gas, which is provided directly from the oxygen container or provided through a regulator or the like, is supplied through the oxygen container connecting tube 37, and the other end is provided with an open- An air bag connecting pipe 35, which is a duct for discharging oxygen, is connected to the air bag 14, so that the intake air stored in the air bag can be supplied to the duct. The air bag lower valve (11) is a unidirectional open valve that opens only toward the air bag (12) only when the oxygen gas supplied from the oxygen container enters. Therefore, the air bag lower valve 11 is closed at the moment of intake (when the operator compresses the air bag), so that the air in the air bag at the time of intake is discharged only toward the open type oxygen supply pipe 14, The intake valve and the regulator valve 15 are pushed up and are supplied to the patient through the open type oxygen supply pipe 14. Immediately after the intake, the intake valve control valve 15 is also lowered, and at the same time, To be supplied with oxygen gas from the oxygen container toward the air bag (12), and is automatically closed when the air bag (12) is filled with a certain amount of air.

The air bag lower valve 11 is located between the oxygen container connecting pipe 37 and the air bag 12 and is provided in the air bag 12 at one side of the inlet of the oxygen container connecting pipe 37, The hinge portion of the oxygen sensor 11 is mounted and is opened by the pressure of the oxygen gas entering through the oxygen container connecting tube 37, and is closed otherwise.

Here, the oxygen container connecting pipe 37 is a pipe for connecting the oxygen (O ₂ ) gas, which is discharged directly from the oxygen container or provided through the regulator, to the air bag 12 through the air bag lower valve 11 It is a pipe.

The open-type oxygen supply pipe 14 is formed with a channel through which a fluid can flow, and is formed in an 'a' shape. One end of the channel is connected to an oral connection pipe 39 And the other end is connected to the exhaust pipe 30 to which the exhaust valve 13 is mounted and the other end is connected to the air bag connection pipe 35 connected to the air bag 12, And an intake / exhaust pipe control valve 15 is provided at the branching point. The two mechanisms are configured such that the respective branch mechanisms are relatively opened and closed by the intake / exhaust pipe adjusting valve (15). That is, when the intake / exhaust pipe adjusting valve 15 is in the intake state, the air bag connecting pipe 35 is opened and the discharge pipe 30 is closed. On the other hand, when the air exhaust pipe 30 is opened, Lt; / RTI > In addition, since the exhaust valve 13 is configured to be closed at the time of intake and open at the time of exhalation (exhaust), the intake pipe of the air bag 12 can be supplied to the internal pipeline of the open oxygen supply pipe 14 And the exhalation gas from the patient can be released to the outside through the exhaust valve 13 at the time of exhalation.

The intake and exhaust pipe control valve 15 is installed at the midway point of the two openings of the open type oxygen supply pipe 14 and is automatically driven by the intake and exhaust operations and is supplied to the inside of the oxygen supply pipe 14 at the time of intake and exhaust, Thereby selectively opening or closing the channel of the fluid to be formed. As shown in FIG. 2, the intake pipe / pipe control valve 15 is formed of a single plate, and one side thereof is connected to the hinge portion so as to be openable up and down. That is, the intake and exhaust pipe control valve 15 is mounted on the side of the inlet of the discharge pipe 30 on the left and right sides, the hinge portion being close to the air bag 12.

The intake and exhaust duct control valve 15 controls the intake and exhaust duct control valve 15 by the pressure of the air (that is, oxygen gas) coming in from the air bag 12 at the time of the inspiration in which the practitioner applies pressure to the air bag 12 Lifts up the vent tube 30 (consequently, cuts off the exhaust valve 13), opens the bladder connector 35, and supplies air (i.e., oxygen gas) to the patient. On the other hand, in the state in which the pressure of the air (i.e., oxygen gas) coming in from the air bag 12 is not applied, the intake and exhaust pipe control valve 15 is moved downward and connected to the air bag connector 35) and opens the discharge pipe 30 (and consequently also opens the exhaust valve 13) so that the gas (i.e., carbon dioxide) discharged by the patient is discharged to the outside. That is, the intake and exhaust pipe adjusting valve 15 closes the branch mechanism connected to the air valve 12 while opening the branch mechanism and connected to the exhaust valve 13, Is a bidirectional valve that closes the branch mechanism connected to the air bag (12) while being opened.

The pressure regulating valve 16 is installed on the open type oxygen supply pipe 14 to regulate the pressure of oxygen supplied from the oxygen container to regulate the oxygen pressure in the channel. The pressure regulating valve 16 may be normally closed and automatically opened by pressure if the pressure in the open type oxygen supply pipe 14 is high.

The exhaust valve 13 is attached to the end of the exhaust pipe 30 and pushes the exhaust valve 13 to discharge the air to the outside when air (that is, carbon dioxide discharged from the patient) enters the exhaust pipe 30.

A method of using the ventilator according to an embodiment of the present invention will now be described.

When the air bag 12 is compressed by the practitioner and the air intake operation is performed, the inlet / outlet pipe adjustment valve 15 installed at the branch point of the open type oxygen supply pipe 14 is driven by the intake operation to be connected to the air bag connection pipe 35 (That is, a branch mechanism connected to the exhaust valve 13) while opening the exhaust valve 13 (that is, the branch mechanism connected to the air bag 12), and thus the exhaust pipe leading to the exhaust valve 13 And the intake pipe leading to the air bag 12 can be opened. When this operation is performed, the air bag bottom valve 11 installed in the air bag 12 is immediately opened to the air bag so that oxygen can be introduced again into the air bag, and when a certain amount of air is filled, The lower valve 11 is closed again.

On the contrary, when the exhaust operation is performed, the intake / exhaust pipe adjusting valve 15 installed at the branching point of the open type oxygen supply pipe 14 is driven opposite to the intake state by the exhalation operation to open the exhaust pipe 30 connected to the exhaust valve 13 The air bag connection pipe 35 is closed so that the air supply duct leading to the exhaust valve 13 is opened and the air intake duct leading to the air bag 12 is closed. In this state, the exhalation gas can be discharged to the outside through the exhaust valve 13.

FIG. 3 is a schematic view illustrating a configuration of a ventilator according to another embodiment of the present invention. As shown in the drawing, the ventilator according to another embodiment of the present invention includes an air bag 12, A circulating oxygen supply pipe 24, intake and exhaust pipe control valves 25a and 25b, a pressure control valve 26, and a carbon dioxide absorbing device 27. [

The air bladder 12 is an air bladder of a size and a volume compressible by a practitioner with one hand in an emergency, and is made of an air bladder having an internal space capable of storing an intake capacity of 1 to 1.2 liters, The air bag lower valve 11 is provided to supply oxygen gas directly supplied from the oxygen container or provided through the regulator or the like to the high oxygen container connecting pipe 37 and to the other end thereof through a circulating oxygen supply pipe 24 (Oxygen gas) can be supplied to the air bag through the air bag lower valve (11). The air bag (35) is connected to the air bag connecting pipe (35) The air bag lower valve (11) is a unidirectional open valve that opens only toward the air bag (12) only when the oxygen gas supplied from the oxygen container enters. Therefore, the air bag lower valve 11 is closed at the time of intake (when the operator compresses the air bag), so that air in the air bag at the time of intake is discharged only toward the circulating oxygen supply pipe 24, Gas is supplied to the patient through the circulating oxygen supply pipe 24 and the air bag upper valve 40 is immediately closed immediately after the air intake and at the same time the air bag lower valve 11 Is opened to allow oxygen gas to be supplied from the oxygen container to the air bag 12, and when the air bag 12 is filled with a certain amount of air, the air bag lower end valve 11 is automatically closed.

The air bag connection pipe 35 may be formed of a corrugated tube to control the air (oxygen gas) delivery speed, and the delivery speed can be adjusted by expanding or reducing the corrugation.

The circulating oxygen supply pipe 24 is divided into an intake pipe 24a through which an intake gas can flow and an exhaust pipe 24b through which an exhaust gas can flow. The intake pipe 24a, The conduit 24b allows the two end portions to communicate with each other to form one closed conduit (ring-shaped conduit) capable of fluid circulation. Particularly, on the intake pipe 24a, an atmospheric inflow port 28 can be further formed to allow inflow of a small amount of atmospheric air for controlling the concentration of oxygen, The inlet port 28 is normally closed when the inlet cover is closed and is opened when necessary.

In addition, at the one end of the closed conduit constructed as described above, an oral connection conduit 39 is provided so as to be adhered to the patient's airway. The other end of the conduit is connected to an air bag connection pipe 35, The air bag upper valve 40 is mounted between the inlet of the pipe 35, that is, between the closed pipe and the air bag connecting pipe 35. Between the intake pipe control valve 25a and the exhaust pipe control valve 25b, there is provided a discharge pipe 30 having an exhaust valve 13 mounted thereon.

An intake pipe control valve 25a and an exhaust pipe control valve 25b are provided on the intake pipe 24a and the exhaust pipe 24b of the circulating oxygen supply pipe 24 so as to open and close the inside of the pipe at the time of intake and exhalation, respectively . Further, a carbon dioxide absorbing device 27 capable of absorbing carbon dioxide contained in the exhalation gas may be further provided at the rear of the exhaust pipe 24b of the circulating oxygen supply pipe 24.

The intake pipe control valve 25a is installed on the intake pipe 24a of the circulating oxygen supply pipe 24 and the intake pipe control valve 25a is opened by the air pressure applied from the air pocket 12 And is closed when air pressure is not applied from the air bag 12. That is, the intake pipe control valve 25a is driven by the intake operation and is opened only to the patient at the time of intake and closed at the time of exhalation (exhaust), and is connected to the oxygen container connection pipe 37, The pouch 12, the inspiratory duct 24a, the oral connecting duct 39 and the inspiratory rod leading to the patient are formed.

The exhaust pipe control valve 25b is provided on the exhaust pipe 24b of the circulating oxygen supply pipe 24 and the exhaust pipe control valve 25b is opened by the air pressure of the patient's breath, It is closed when air pressure by patient's breath is not applied. That is, the exhaust pipe control valve 25b is driven by the exhalation of the patient and is opened only toward the exhaust valve 13 at the time of exhaustion and is closed at the time of exhaustion to the patient, the oral connection pipe 39, the exhaust pipe 24b, An exhaust rod leading to the carbon dioxide absorbing device 27, the exhaust valve 13, or the closed pipe is formed.

The pressure regulating valve 26 is provided on the oral connecting line 39 of the circulating oxygen supply line 24 to regulate the pressure of oxygen supplied from the oxygen container to regulate the pressure of oxygen in the line. The pressure regulating valve 16 is normally closed and is automatically opened if the pressure in the circulating oxygen supply pipe 24 is high and can be located after the oral connection line 39. [

The carbon dioxide absorbing device 27 is installed behind the exhaust pipe control valve 25b on the exhaust pipe 24b to absorb carbon dioxide contained in the exhalation gas generated from the patient at the time of exhalation and to flow through the remaining closed pipe . The carbon dioxide absorbing device 27 may use a carbon dioxide absorbing device such as a soda lime absorbing device or a carbon absorbing device using soda sorbing, which is used in an anesthesia machine or the like.

A method of using the artificial respiratory apparatus according to another embodiment of the present invention will be described as follows.

When the air bag 12 is compressed by the operator and the intake operation is performed, the intake pipe control valve 25a provided on the intake pipe 24a of the circulating oxygen supply pipe 24 is opened by the intake operation, The exhaust pipe control valve 25b and the exhaust valve 13 provided on the conduit 24b are kept closed by the intake operation and therefore the oxygen supplied to the circulating oxygen supply pipe 24 from the air bag 12 side The gas can be supplied to the patient through the intake channel 24a and the oral connection channel 39 in order. In particular, when the artificial respiratory apparatus according to the present invention is used for children or the like, a small amount of atmospheric air can be introduced into the duct by using the air inlet 28 provided on the intake duct 24a, The concentration can be adjusted to prevent excessive injection.

After this operation is performed, the air bag lower end valve 11 provided at the front end of the air bag 12 is immediately opened to the air bag so that oxygen can be introduced again into the air bag in the oxygen container, and when a certain amount of air is filled The air bag lower valve 11 is closed again.

The exhaust pipe control valve 25b provided in the exhaust pipe 24b of the circulating oxygen supply pipe 24 is opened to the exhaust valve 13 by the exhalation operation and is installed on the intake pipe 24a The intake pipe control valve 25a is closed by the exhalation operation and therefore the exhaust pipe 24b and the exhaust pipe 13 connected to the patient, the oral connection pipe 39, the carbon dioxide absorbing device 27 and the exhaust valve 13, The pipeline is opened. In this state, the exhaled gas from which the carbon dioxide has been removed can be circulated through the closed channel as required or can be discharged to the outside through the exhaust valve 13.

The ventilator according to the present invention configured as described above is configured to store a sufficient amount of intake capacity (for example, about 1000 to 1200 cc), such that the size of the airbag can be compressed by one hand It is possible to control a sufficient amount of the intake air required for artificial respiration. By using the circulating oxygen supply pipe, efficient use of oxygen is enabled, so that the consumption of oxygen can be reduced and the size of the air bag can be reduced The error caused by the restoring force can be reduced.

In addition, the artificial respiratory apparatus according to the present invention can control the inflow amount of the atmospheric air using the atmospheric air inlet to adjust the oxygen supplied to the patient to a desired concentration, thereby solving the problem of excessive injection into pediatric patients.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible. Accordingly, it is intended that the scope of the invention be defined by the claims appended hereto, and that all equivalent or equivalent variations thereof fall within the scope of the present invention.

11: air bag lower valve 12: air bag
13: exhaust valve 14: open-type oxygen supply pipe
15: intake / exhaust pipe control valve 16: pressure control valve
24: circulating oxygen supply pipe 24a: intake pipe
24b: exhaust pipe 25a: intake pipe regulating valve
25b: exhaust pipe control valve 27: carbon dioxide absorption device
28: Air inlet 30:
35: air bag connector 37: oxygen container connector
39: Oral connector

Claims (22)

An air bag filled with oxygen gas supplied from an oxygen container, and an oxygen supply tube in which oxygen in the air bag is supplied to the patient's airway by compressing the air bag,
One side of the oxygen supply pipe is provided with an oral connection tube configured to be brought into close contact with the airway of the patient and the other side of the oxygen supply tube is connected to a first branching mechanism branched from the branching pipe and leading to a discharge pipe equipped with an exhaust valve, The branch of the first branch mechanism and the second branch mechanism is installed at the branch point of the second branch,
At one end within the bladder is an air bladder bottom valve connected to the oxygen bladder connector,
The air bag lower valve is closed by the pressure of the oxygen gas as the air bag is compressed when the air bag is sucked so that the oxygen gas in the air bag is discharged to the oxygen supply pipe,
Further comprising a pressure control valve installed on the oxygen supply pipe. The method according to claim 1,
Wherein one end of the intake pipe control valve is connected to the hinge portion so as to open one of the first and second minute mechanisms and close the other,
When the air bag is sucked by the air bag, the regulator valve is lifted upward by the pressure of the air coming from the air bag to shut off the discharge tube and open the air bag connector, thereby supplying air to the patient,
Wherein the inlet and outlet pipe control valve is lowered to shut off the air bladder connector and to open the discharge pipe so that gas released by the patient is discharged to the outside when no pressure is applied to the air bag. . The intake and exhaust duct control valve according to claim 1,
And closes the first minute mechanism while opening the second minute mechanism by the pressure of oxygen gas as the air bag is compressed upon intake. The method according to claim 1,
One side of the oxygen supply pipe is provided with an oral connection tube configured to be brought into close contact with the airway of the patient and the other side of the oxygen supply tube is connected to a first branching mechanism branched from the branching pipe and leading to a discharge pipe equipped with an exhaust valve, In the second quarter,
At the branching point of the first minute mechanism and the second minute mechanism, an intake and exhaust pipe control valve is provided,
Wherein the intake and exhaust duct control valve closes the first minute mechanism while opening the second minute mechanism by the pressure of oxygen gas as the air bag is compressed upon intake. The method of claim 3,
Wherein when the air containing the carbon dioxide discharged from the patient enters into the discharge pipe, the discharge valve is opened to be discharged to the outside. 6. The method of claim 5,
At one end within the bladder is an air bladder bottom valve connected to the oxygen bladder connector,
Wherein the air bag lower valve is closed by the pressure of the oxygen gas as the air bag is compressed when the air bag is sucked so that the oxygen gas in the air bag is discharged toward the oxygen supply pipe. 7. The method according to any one of claims 1 to 6,
Wherein the air bag has an internal space capable of storing an oxygen gas capacity of 1 to 1.2 liters. The method according to claim 1,
Wherein the air bag lower valve is a unidirectional open valve that opens to the air bag only when the oxygen gas provided from the oxygen container enters. 7. The method according to any one of claims 4 to 6,
After the air bag is compressed and the oxygen gas is supplied to the patient, the oxygen gas pressure in the air bag is lowered, so that the intake pipe control valve closes the second minute mechanism and at the same time the air bag lower end valve is opened, So that the oxygen gas can be supplied to the air bag. 10. The method of claim 9,
When the oxygen gas is supplied to the patient as the air bag is compressed, the oxygen gas pressure in the air bag is lowered at the time of exhalation, so that the intake and exhaust pipe control valve closes the second minute mechanism, opens the first minute mechanism, And the exhalation gas from the patient can be released to the outside through the exhaust valve. 10. The intake system according to claim 9, wherein the intake /
Wherein the bi-directional valve is a bidirectional valve that closes the first minute mechanism while opening the second minute mechanism at the time of inspiration and closes the second minute mechanism while opening the first minute mechanism at the time of exhalation. The method according to any one of claims 1, 4, and 8,
Wherein the hinge portion of the air bag bottom valve is mounted to a portion of the air bag that is connected to the oxygen container connecting pipe so that the air bag lower end valve is opened by the pressure of the oxygen gas flowing through the oxygen container connecting pipe. Artificial respiration apparatus. The method according to any one of claims 1, 3, 4, and 6,
Wherein the hinge portion of the intake and exhaust duct control valve is mounted on a side of the inlet of the discharge pipe that is closer to the air bag than the other one of the right and left sides. delete An air bag filled with oxygen gas supplied from an oxygen container, and an oxygen supply tube in which oxygen in the air bag is supplied to the patient's airway by compressing the air bag,
Wherein the oxygen supply pipe includes one closed conduit capable of fluid circulation and has an oral connection tube configured to be in close contact with the patient's airway on one side of the left and right of the closed conduit, And the other side is equipped with an air bag connector connected to the air bag,
Wherein one of the upper and lower sides of the closed conduit is provided with an intake conduit regulating valve to open the intake conduit regulating valve by the pressure of the oxygen gas supplied from the air bag as the air bag is compressed upon intake, Respectively,
And an atmospheric inlet port through which the atmospheric air can be introduced to control the concentration of oxygen,
At one end within the bladder is an air bladder bottom valve connected to the oxygen bladder connector,
Wherein the air bag lower valve is closed by the pressure of the oxygen gas as the air bag is compressed when the air bag is sucked so that the oxygen gas in the air bag is discharged toward the closed channel. 16. The method of claim 15,
The other one of the upper and lower sides of the closed conduit is provided with an exhaust conduit regulating valve so that the exhaust conduit regulating valve is opened by the pressure of the air including the carbon dioxide discharged from the patient, Wherein the ventilation passage is formed in the exhaust passage. delete delete 16. The method of claim 15,
Wherein an air bag top valve is mounted between the closed conduit and the air bag connecting pipe to open the air bag top valve by the pressure of the oxygen gas supplied from the air bag as the air bag is compressed at the time of intake, Artificial respiration apparatus. 17. The method of claim 16,
A discharge pipe equipped with an exhaust valve is provided between the intake pipe control valve and the exhaust pipe control valve. When air containing carbon dioxide discharged from the patient enters the discharge pipe, the exhaust valve is opened and discharged to the outside A manual ventilation device. 17. The method of claim 16,
And a carbon dioxide absorbing device is further installed behind the exhaust pipe adjusting valve in the exhaust pipe. 17. The method of claim 16,
Wherein a pressure regulating valve is provided on the oral connection line of the oxygen supply line to adjust the pressure in the oxygen supply line.

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