KR20110008408U - Divce for practicing artificial respiration - Google Patents

Abstract

The apparatus for resuscitation exercise according to an embodiment of the present invention may provide an artificial respiration environment such as performing artificial respiration to a real person by providing a resistance similar to that of a human lung, and the valve unit may be artificial. It is possible to prevent backflow of air introduced into the breathing apparatus.

Description

Ventilation Practice Device {DIVCE FOR PRACTICING ARTIFICIAL RESPIRATION}

The present invention relates to an apparatus for resuscitation, and more particularly, to an apparatus for resuscitation, which helps to effectively acquire artificial respiration of CPR.

In general, cardiopulmonary resuscitation (CPR) is an emergency treatment used when the heart stops functioning or breathing stops due to an accident such as a heart attack or drowning. CPR involves artificial respiration and chest compressions.

The procedure of CPR is as follows. First, lay the patient on a hard surface, remove any debris from the mouth and airways, and tilt the head back to open the airways with the chin up. In addition, the air is blown into the patient's airway, and then artificial breathing is performed to exhale naturally. If there is no pulse, the blood is artificially circulated by compressing the chest from the outside. Chest compressions are about 100 times per minute in adults, and chest compressions and breathing are recommended at a ratio of 30: 2. This cardiopulmonary resuscitation should be continued until normal breathing and heart rate are restored or can be assisted by a healthcare professional.

Recently, many cases have been reported in the media that have saved the lives of patients who are in emergency by CPR, or who have lost the life that can be saved due to the inability to perform CPR in a timely manner. Therefore, in developed countries, CPR is widely used for general people such as students or office workers.

In addition, various companionships and equipment have been developed for the spread of CPR. In particular, a practice apparatus for practicing CPR directly using a mannequin has been released. Such a device for practicing CPR also includes a device for practicing resuscitation. This respiratory exercise device is being developed to be similar to actually performing artificial respiration on a patient in order to enhance the practical effect of resuscitation.

Embodiment of the present invention, even when there is no subject to practice in the practice of artificial respiration provides an artificial respiratory exercise device that can effectively practice artificial respiration in the same environment as the actual environment.

In addition, an embodiment of the present invention provides a respiratory exercise device that can prevent the backflow of the air to the practitioner to perform artificial respiration during the practice of artificial respiration.

In addition, an embodiment of the present invention, the structure is simple and easy to manufacture provides a respiratory exercise apparatus that can be widely used without any cost.

According to an embodiment of the present invention, in place of the role of the patient in need of artificial respiration provides an artificial respiration practice apparatus used for the practice of artificial respiration. That is, the artificial respiratory exercise device includes an inlet part for blowing air into the mouth during resuscitation, an outlet part for discharging air entering the inlet part to the outside, and a connection part connected to a middle of a flow path connecting the inlet part and the outlet part Formed body; A bag unit mounted in communication with the connection part and elastically inflated by the air discharged from the connection part and then elastically restored when the pressure of the air discharged from the connection part decreases, thereby returning air to the connection part; And a first flow path for guiding air introduced through the inlet part from the inlet part to the connecting part when air is introduced into the inlet part, and when the air is introduced into the connecting part, air introduced through the connecting part from the connecting part. And a valve unit forming a second flow path leading to the outlet portion.

That is, when air is blown into the inlet, the air may flow along the first flow path and then be discharged through the connection part, and the bag unit may be inflated by the air. In addition, if air is not blown into the inlet, air in the bag unit may be introduced into the second flow path through the connection part, and the air may flow along the second flow path and then be discharged through the outlet part. Can be.

Therefore, in the artificial respiratory exercise device, a phenomenon in which air blown into the inlet portion is prevented from flowing back to the inlet portion can be prevented, and the air is discharged to the outlet portion so that artificial respiration can be repeatedly performed.

The bag unit may be formed of an elastic material having the same elasticity as that of the lung in order to provide the same resistance as that of the human lung during artificial respiration. Indeed, when artificial respiration is performed on a person's mouth, there is a difficulty in injecting air due to lung resistance. Therefore, the respiratory exercise device may be formed in a structure that provides resistance of the lungs by the bag unit to create an environment similar to the actual respiration situation.

An inlet passage may be formed in the inlet, an outlet passage may be formed in the outlet, and a connection passage may be formed in the connection. The valve unit may be provided to be movable at a connection portion between the inlet passage, the outlet passage, and the connection passage.

Here, the valve unit may be moved to a first position that closes the outlet flow path by the pressure of air flowing into the inlet and connects the inlet flow path and the connection flow path to form the first flow path. Can be. The valve unit may be moved to a second position that closes the inlet flow path by the pressure of the air flowing into the connection part and connects the connection flow path with the outlet flow path to form the second flow path. have.

For example, the valve unit may be formed as a partition wall that is moved to a first position or a second position by the pressure of air flowing into the inlet portion or the connection portion, and the inlet portion moves the partition wall to the second position. It may be formed on one side of the main body so that the pressure of the air is provided, the connecting portion may be formed on the other side of the main body so that the pressure of the air is provided in the direction to move the partition wall to the first position. Therefore, the partition wall may be moved to the first position or the second position according to the pressure direction of the air provided through the inlet portion or the connecting portion.

As another example, the valve unit may be formed as a partition wall that is moved to a first position or a second position by the pressure of air flowing into the inlet portion or the connecting portion, and the inlet portion moves the partition wall to the second position. It may be formed in the main body so that the pressure of the air in the direction, and the partition wall may be formed with a pressure plate for interfering with the air flowing into the connecting portion to change the direction provided by the pressure of the air in the first position direction. Therefore, the partition wall may be moved to the first position according to the pressure direction of the air provided through the inlet portion, and the air provided through the connection portion may be moved to the second position according to the pressure direction provided to the pressure plate. have.

On the other hand, unlike the above, the valve unit is moved to a first position for communicating the inlet passage and the connection passage by the pressure of air provided in the main body and the inlet portion to form the first passage The barrier rib is disposed between the barrier rib and the main body, and when the pressure of the air flowing into the inlet portion is removed, the barrier rib is returned to a second position where the connecting portion passage and the outlet passage communicate with each other to form the second passage. It may be provided with an elastic member. That is, the partition wall may be moved to the first position by the pressure of the air flowing through the inlet, and may be returned to the second position by the elastic force of the elastic member.

The artificial respiratory exercise device according to the embodiment of the present invention provides an environment similar to that of actually performing artificial respiration in a person's oral cavity, so that the artificial respiration can be effectively practiced even when there is no subject to practice during artificial respiration. You can practice resuscitation smoothly regardless of time and place.

In addition, the artificial respiratory exercise apparatus according to the embodiment of the present invention, since the air blown into the inlet during the artificial respiration is temporarily stored in the bag unit and discharged to the outlet, it is present in the body or the back unit during the practice of artificial respiration It is possible to prevent the backflow of the air to the inlet, and to prevent the discomfort and contamination caused by the backflow of air during artificial respiration. Therefore, it is possible to continuously practice artificial respiration while continuously injecting air into the respiratory exercise device.

In addition, the artificial respiratory exercise device according to the embodiment of the present invention, because it is formed in a very simple structure as a whole, it is easy to manufacture, the manufacturing cost can be low. Therefore, the respiratory exercise device is advantageous for mass production, and can be widely distributed at low cost.

1 is a perspective view showing a respiratory training device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the respiratory training apparatus shown in FIG. 1.
3 and 4 are views showing the operating state of the respiratory exercise apparatus shown in FIG.
5 and 6 is an operating state diagram showing the respiratory exercise device according to another embodiment of the present invention.
7 and 8 is an operating state diagram showing a respiratory exercise device according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. Like reference numerals in the drawings denote like elements.

1 is a perspective view showing a respiratory training device according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing the respiratory training device shown in FIG. 3 and 4 are views showing an operating state of the respiratory exercise device shown in FIG. 2.

Referring to FIG. 1, the apparatus 100 for resuscitation training according to an embodiment of the present invention may include a main body 110, a bag unit 120, and a valve unit 130. Such a respiratory exercise device 100 is a teaching material used in the practice of artificial respiration, it is preferable to be made as close as possible to the actual situation. For example, the respiratory training device 100 may be disposed inside the mouth of a mannequin formed in a human shape. Therefore, when artificial respiration is performed through the oral cavity of the mannequin, the air blown into the oral cavity of the mannequin may be introduced into the artificial respiration training apparatus 100.

1 and 2, the main body 110 is a cylindrical member, and the inlet portion 112, the outlet portion 114, and the connecting portion 116 are formed at different positions. The inlet part 112 is a port through which the practitioner blows air into the mouth during the practice of artificial respiration, and the outlet part 114 is a port that completely discharges the air introduced into the inlet part 112 to the outside, and the connection part 116. Is a port to which the back unit 120 is mounted in communication.

In addition, an inlet passage 112a may be formed in the inlet 112, an outlet passage 114a may be formed in the outlet 114, and a connection portion may be formed in the connection unit 116. The flow path 116a may be formed. The inlet part 112, the outlet part 114, and the connecting part 116 have a main body 110 such that the ends of the inlet part flow path 112a, the outlet part flow path 114a, and the connection part flow path 116a are connected to each other. Can be formed on. On the other hand, the valve unit 130 may be provided to be movable in the portion connected to the end of the inlet flow path (112a), the outlet flow path (114a) and the connection portion flow path (116a).

1 and 2, the bag unit 120 is a bag-shaped member mounted in communication with the connection portion 116. The bag unit 120 may be formed of an elastic material to elastically expand or contract. That is, when the air flowing into the inlet portion 112 is discharged through the connecting portion 116 above the set pressure, the bag unit 120 may be elastically expanded. On the other hand, if air does not flow into the inlet 112 or if the air flowing into the inlet 112 is less than the set pressure, the bag unit 120 may be elastically contracted. Therefore, the air in the bag unit 120 may be introduced back into the main body 110 through the connecting portion 116.

The bag unit 120 may be formed of an elastic material having the same elasticity as that of the lung in order to provide the same resistance as that of the human lung during artificial respiration. Indeed, when artificial respiration is performed on a person's mouth, there is a difficulty in injecting air due to lung resistance. Therefore, the respiratory exercise device 100 may be formed in a structure that provides resistance of the lungs by the bag unit 120 to create an environment similar to the actual situation of resuscitation. Material and elasticity of the back unit 120 may be manufactured to have a variety of elasticity in a variety of materials according to the design conditions of the respiratory training device 100.

1 to 4, the valve unit 130 guides the air from the inlet portion 112 to the connecting portion 116 according to the pressure of the air flowing into the inlet portion 112 or exits from the connecting portion 116. It is a member for guiding air to the unit 114. The valve unit 130 may be provided to be movable in the body 110.

That is, when air flows into the inlet 112 at a predetermined pressure or more, the valve unit 130 may be moved to the first position P1 such that the first flow paths 112a and 116a are formed inside the main body 110. Can be. In addition, when air is introduced below the set pressure or the air is not introduced into the connecting portion 116, the second flow paths 114a and 116a may be moved to the second position P2 to form the inside of the main body 110. . The first flow paths 112a and 116a are flow paths that guide air introduced through the inlet part 112 from the inlet part 112 to the connection part 116. The first flow paths 112a and 116a may be formed of an inlet flow path 112a and a connection part flow path 116a. The second flow paths 114a and 116a are flow paths that guide air in the bag unit 120 introduced through the connection part 116 from the connection part 116 to the outlet part 114. The second flow paths 114a and 116a may be formed as a connection part flow path 116a and an exit part flow path 114a.

For example, the valve unit 130 may include a partition 132 and an elastic member 134.

The partition wall 132 may be movably disposed at an end portion of the inlet passage 112a, the outlet passage 114a, and the connection passage 116a. The partition wall 132 is formed of a first position P1 or a second flow path 114a or 116a forming the first flow paths 112a and 116a according to the pressure of the air flowing into the inlet portion 112. It may be selectively disposed at any one of the two positions (P2).

Hereinafter, in the present embodiment, for convenience of description, the initial position of the partition wall 132 will be described as the second position P2, and the partition wall 132 will be described as being arranged in a structure that is movable to the outlet 114. However, the initial position and arrangement structure of the partition wall 132 may be variously changed according to the design conditions and the situation of the respiratory exercise device 100. For example, the initial position of the partition 132 may be a first position P1, and the partition 132 may be disposed to be movable in the main body 110 or the inlet 112.

Here, when the partition wall 132 is disposed at the first position P1, an end portion of the outlet flow path 114a may be shielded by the partition wall 132, and the inlet flow path 112a and the connection part flow path 116a may be separated. The ends may be connected in communication with each other. In addition, when the partition wall 132 is disposed at the second position P2, an end portion of the inlet flow path 112a may be shielded by the partition wall 132, and the connection path flow path 116a and the outlet flow path 114a may be separated. The ends may be connected in communication with each other.

The elastic member 134 is a member that elastically supports the partition 132 and may provide an elastic force to the partition 132 toward an initial position of the partition 132, that is, the second position P2. The elastic member 134 may be disposed between the partition wall 132 and the main body 110. The elastic member 134 may be a variety of elastic bodies such as coil springs or leaf springs.

In addition, the elastic member 134 may be formed to have a smaller elastic force than the pressure of the air flowing into the inlet 112 when artificial respiration is normally performed. Therefore, when the air is not blown or blown at a pressure less than the set pressure to the inlet portion 112, the partition wall 132 may be moved to the second position P2 by the elastic force of the elastic member 134.

Looking at the operation of the artificial breathing apparatus 100 according to the embodiment of the present invention configured as described above are as follows.

Referring to FIG. 3, when practicing artificial respiration using the artificial respiratory exercise device 100, air is blown into the inlet 112. At this time, the practitioner of artificial respiration should blow air at a pressure sufficiently higher than the elastic force of the elastic member 134.

When air flows into the inlet 112 at a pressure higher than the elastic force of the elastic member 134, the partition 132 is moved to the first position P1 by the pressure of the air. At this time, the inlet flow passage 112a is opened, and the outlet flow passage 114a is shielded by the partition wall 132. The first flow paths 112a and 116a are formed by the inlet flow path 112a and the connection part flow path 116a.

Therefore, the air flowing into the inlet part 112 flows along the first flow paths 112a and 116a and then is discharged through the connection part 116, and the bag unit 120 is discharged by the air discharged to the connection part 116. It is elastically inflated.

Referring to FIG. 4, when the inlet 112 blows air at a pressure lower than the elastic force of the elastic member 134 or does not blow air, the partition wall 132 is formed by the elastic force of the elastic member 134. It is moved to two positions P2. At this time, the inlet flow passage 112a is shielded by the partition wall 132, and the outlet flow passage 114a is opened. The second flow paths 114a and 116a are formed by the connection part flow path 116a and the exit part flow path 114a.

If air does not flow into the bag unit 120 as described above, the air in the bag unit 120 flows into the connection part 116 because the bag unit 120 is elastically contracted. The air flowing into the connection part 116 flows along the second flow paths 114a and 116a and then is discharged to the outside of the main body 110 through the outlet part 114.

By repeating the operations of FIGS. 3 and 4 as described above, the artificial respiration can be practiced regardless of time and place by the artificial respiratory exercise device 100, and blows into the artificial respiratory exercise device 100. It is also possible to prevent the air flowing back into the air. In particular, due to the elastic resistance of the back unit 120 can feel like blowing air into the oral cavity of a real person can maximize the practical effect of artificial respiration.

5 and 6 is an operating state diagram showing the respiratory exercise device according to another embodiment of the present invention. 5 and 6, the same reference numerals as those shown in Figs. 1 to 4 denote the same members. Hereinafter, description will be made with respect to points different from the artificial respiratory exercise apparatus 100 illustrated in FIGS. 1 to 4.

5 and 6, the ventilator 200 according to another embodiment of the present invention differs from the ventilator 100 shown in FIGS. 1 to 4 in that the valve unit 230 is different from the valve unit 230. The configuration and the forming position of the connecting portion 216 are different.

The valve unit 230 may be moved to the first position P1 by the pressure of the air flowing through the inlet 112, and may be moved to the second position by the pressure of the air flowing through the connecting portion 116. It can be moved to (P2). That is, the valve unit 230 may be moved to any one of the first position P1 and the second position P2 according to the pressure direction of the air flowing through the inlet 112 or the connection 116.

For example, the valve unit 230 may be provided with the partition wall 232 and the moving rod 234. Here, the partition wall 232 may be movably disposed at a portion where the end of the inlet flow path 112a, the outlet flow path 214a and the connection flow path 216a is connected. The air introduced into the inlet 112 may exert pressure on one surface of the partition wall 232 in the first direction P1. Since the partition wall 232 is similar to the partition wall 132 illustrated in FIGS. 2 to 4 except that the partition wall 232 is connected to the moving rod 234, a detailed description thereof will be omitted.

In addition, the moving rod 234 may be provided to be movable in the rod guide 215 formed at the end of the outlet 214. One end of the moving rod 234 is connected to the partition wall 232, and the other end of the moving rod 234 is disposed to be movable in the rod guide 215. The rod guide 215 is a member for movably supporting the movable rod 234 in the first direction P1 and the second direction P2, and may be integrally formed at an end of the outlet portion 214. A plurality of air inlet holes 214b may be provided at an end portion of the outlet portion 214 where air is introduced into the outlet passage 214a at a portion where the rod guide 215 is not formed.

On the other hand, the connecting portion 216 may be formed on the main body 110 to act on the other surface of the partition wall 232 the pressure of the air flowing through the connecting portion flow path (216a). That is, the connection part 216 may be formed at a position moved a predetermined distance in the direction opposite to the second position P2 about the first position P1. Therefore, the pressure of the air flowing into the connecting portion 216 may act on the other surface of the partition wall 232, and the partition wall 232 and the moving rod 234 are moved to the second position P2 along the rod guide 215. Can be moved.

As such, the partition wall 232 may be moved to the first position P1 or the second position P2 by the pressure of the air flowing into the inlet portion 112 or the connection portion 216. Therefore, the partition wall 232 and the moving rod 234 is preferably formed of a light material. Hereinafter, in the present exemplary embodiment, one end of the moving rod 234 is connected to the center of the partition 232, and the rod guide 215 is integrally formed at the end of the outlet 214, but the partition 232 is moved. The supporting structure is not limited to this, and various structures may be used.

7 and 8 is an operating state diagram showing a respiratory exercise device according to another embodiment of the present invention. 7 and 8, the same reference numerals as those shown in FIGS. 1 to 4 denote the same members. Hereinafter, description will be made with respect to points different from the artificial respiratory exercise apparatus 100 illustrated in FIGS. 1 to 4.

7 and 8, the ventilation unit 300 according to another embodiment of the present invention is different from the artificial respiratory apparatus 100 shown in FIGS. 1 to 4 in that the valve unit 330 ) Configuration is different.

The valve unit 330 may be moved to the first position P1 by the pressure of the air flowing through the inlet 112, and may be moved to the second position by the pressure of the air flowing through the connecting portion 116. It can be moved to (P2). That is, the valve unit 330 may be moved to any one of the first position P1 and the second position P2 according to the pressure direction of the air flowing through the inlet 112 or the connection 116.

For example, the valve unit 330 may be provided as a partition wall 332 and a pressure plate 334. The partition wall 332 may be movably disposed at an end portion of the inlet passage 112a, the outlet passage 114a, and the connection passage 116a. Since the partition wall 332 is similar to the partition wall 332 shown in FIGS. 2 to 4 except that the partition wall 332 is movably disposed at the end of the inlet part 112, a detailed description thereof will be omitted. .

On the other hand, the pressure plate 334 is a member for converting the partition 332 to a moving force for moving the partition 332 to the second position (P2) by receiving the pressure of the air flowing into the connecting portion 116. The pressure plate 334 may be formed at one side of the partition wall 332 facing the connecting portion 116. Hereinafter, although the pressure plate 334 is described as being inclined on one side of the partition 332 in this embodiment, various structures capable of converting the pressure of air flowing into the connecting portion 116 into the moving force of the partition 332 are provided. Can be used.

That is, in this embodiment, since the moving direction of the partition wall 332 and the air direction flowing into the connecting portion 116 are perpendicular to each other, the pressure plate 334 moves the moving direction of the partition wall 332 and the air direction flowing into the connecting portion 116. It may be formed to be inclined therebetween. In particular, in order to move the partition wall 332 to the second position P2 by the air flowing into the connecting portion 116, the pressure plate 334 is inclined toward the second position P2 on one side of the partition wall 332. Can be.

The weight of the valve unit 330 as described above, the inclination angle of the pressure plate 334, and the pressure of the air flowing into the connecting portion 116 may be appropriately changed according to the design conditions and the situation of the respiratory exercise device 300. For example, the weight may be changed by changing the material and shape of the valve unit 330, and the pressure of air flowing into the connection part 116 may be changed by changing the diameter shape of the connection part path 116a. Alternatively, the nozzle may be disposed at the connecting portion 116 toward the pressure plate 334.

In the embodiment of the present invention as described above has been described by specific embodiments, such as specific components and limited embodiments and drawings, but this is provided only to help a more general understanding of the present invention, the present invention is limited to the above embodiment Various modifications and variations are possible to those skilled in the art to which the present invention pertains. Therefore, the spirit of the present invention should not be limited to the embodiments described, and all the things that are equivalent to or equivalent to the claims as well as the following claims will belong to the scope of the present invention. .

100, 200, 300: respiratory exercise device
110:
120: back unit
130, 230, 330: valve unit
132, 232, 332: bulkhead
134: elastic member
234: pressure plate

Claims (7)

In the artificial respiratory exercise device used for the practice of artificial respiration in place of the role of the patient who needs artificial respiration,
A main body having an inlet for blowing air into the mouth during resuscitation, an outlet for discharging air entering the inlet, and a connection part connected to a middle of a flow path connecting the inlet and the outlet;
A bag unit which is mounted in communication with the connection part and is elastically inflated by the air discharged from the connection part and then elastically restored when the pressure of the air discharged from the connection part decreases, thereby returning air to the connection part; And
When air is introduced into the inlet, a first flow path is formed to guide air introduced through the inlet from the inlet to the connecting part.When air is introduced into the connecting part, the air introduced through the connecting part is transferred from the connecting part. A valve unit forming a second flow path leading to the outlet portion;
Ventilation practice device comprising a.
The method of claim 1,
The back unit is a respiratory exercise device formed of an elastic material having the same elasticity as the lungs to provide the same resistance as the human lungs during artificial respiration.
The method according to claim 1 or 2,
An inlet passage is formed in the inlet, an outlet passage is formed in the outlet, and a connection passage is formed in the connection.
The valve unit is provided with a respiratory exercise device is provided to be movable in the connection portion of the inlet passage, the outlet passage and the connection passage.
The method of claim 3,
The valve unit,
The outlet flow path is closed by the pressure of the air flowing into the inlet, and the inlet flow path is connected to the connection part flow path to move to a first position forming the first flow path.
Respiratory exercises characterized in that the inlet flow passage is closed by the pressure of the air flowing into the connecting portion, and the connection portion flows to the second position forming the second flow path by connecting the flow passage with the outlet flow passage. Device.
The method of claim 4, wherein
The valve unit is formed as a partition wall is moved to the first position or the second position by the pressure of the air flowing into the inlet or the connecting portion,
The inlet portion is formed on one side of the main body so that air pressure is provided in a direction of moving the partition wall to the second position, and the connection part is provided so that the air pressure is provided in a direction of moving the partition wall to the first position. Ventilation practice device, characterized in that formed on the other side of the.
The method of claim 4, wherein
The valve unit is formed as a partition wall is moved to the first position or the second position by the pressure of the air flowing into the inlet or the connecting portion,
The inlet portion is formed in the main body to provide a pressure of air in a direction for moving the partition wall to the second position,
The barrier rib is provided with a pressure plate for interfering with the air flowing into the connecting portion to change the direction provided by the pressure of the air to the first position direction.
The method of claim 3,
The valve unit,
A partition wall provided in the main body and moved to a first position in which the inlet passage and the connection passage communicate with each other by the pressure of air introduced into the inlet portion to form the first passage; And
An elastic member disposed between the partition wall and the main body and returning the partition wall to a second position communicating the connection part flow path and the exit part flow path when the pressure of air flowing into the inlet part is removed; absence;
Ventilation practice device equipped with.

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