KR20230057757A - Humidification module for ventilator breathing circuit - Google Patents

Abstract

The present invention relates to a humidification module for a breathing circuit of a ventilator, and in particular, it is possible to supply moisture to breathing gas through a natural vaporization method, so that a power source for humidification is not required and the generation of condensate can be remarkably reduced. A humidifying body for discharging humidified breathing gas by replenishing moisture by receiving the supplied breathing gas, wherein the humidifying body has a humidifying filter for naturally evaporating sterilized water therein. Respirator, characterized in that It relates to a humidification module for a breathing circuit.

Description

Humidification module for ventilator breathing circuit}

The present invention relates to a humidifying module for a breathing circuit of a ventilator, and more particularly, to a humidifying module for a breathing circuit of a ventilator capable of supplying moisture to breathing gas without power.

In general, a ventilator (ventilator) is a device that helps patients who cannot breathe on their own due to respiratory failure, and breathing gas generated from the ventilator passes through an intake pipe connected to the patient's airway. The exhaust gas, including carbon dioxide exhaled by the patient, flows back into the ventilator through the exhaust pipe or is discharged to the outside.

In order to form such a circulation of breathing, as shown in FIG. 1, between the ventilator 1 and the patient, an intake pipe 2, an exhaust pipe 3, a filter 4, and moisture are supplied to the breathing gas. A breathing circuit consisting of a humidifier and a chamber 5 for cleaning and a water trap 6 for removing condensate is provided.

The humidifier and chamber 5 constituting the conventional breathing circuit are configured to heat sterilized water by power supply and convert it into water vapor. ) is difficult to use, and there is a problem that sufficient moisture cannot be supplied as breathing gas.

In addition, since condensate is generated according to the supply of moisture according to heating, the water trap 6 is essential, and if the condensate collected in the water trap 6 is not removed periodically, ventilator-related pneumonia may occur, Condensate may clog the sensor line or increase resistance, causing errors or failures.

Korean Patent Publication No. 10-2020-0143822 'Breathing tube device for artificial respirator'

The present invention is to solve the above problems, and provides a humidification module for a ventilator breathing circuit that can significantly reduce the generation of condensate without requiring a power source for humidification by supplying moisture to breathing gas through a natural vaporization method. has a purpose

In order to achieve the above object, the humidification module for a breathing circuit of a ventilator according to the present invention includes a humidifying body that receives the breathing gas generated from the ventilator and replenishes moisture to discharge the humidified breathing gas. The main body is provided with a humidifying filter that naturally vaporizes sterilized water therein.

In addition, while the humidifying body has a tubular shape, an inlet for breathing gas is introduced at one end and an outlet for humidified breathing gas is discharged at the other end. It is provided spaced apart from the side wall so that a passage is formed between the connecting side walls, and can be wetted in multiple directions by the sterilized water supplied to the passage.

In addition, the humidifying body is formed in the form of a square cylinder, and the side wall is formed so as to form two side surfaces, an upper surface and a lower surface, and a flow path forming wall is spaced apart from the corresponding side wall by a predetermined interval on the inside of the side wall forming the two side surfaces. A flow path is provided, and the sterilized water may be supplied to the flow path formed between the humidifying filter and a side wall constituting the upper or lower surface of the humidifying body.

In addition, the humidifying filter has a square cylinder shape, both sides of which are adjacent to the flow path forming wall facing each other, and upper and lower surfaces extend outward to be attached to and fixed to upper and lower ends of the flow path forming wall.

In addition, the sterilized water is supplied from a sterilized water pack provided outside the humidifying body,

The sterilized water pack is provided inside the pressure pack filled with a certain amount of air, and at one end or the other end of the humidifying body, an air discharge pipe through which a part of the air inside the humidifying body is discharged is formed, and the air discharge pipe and the pressure pack are Connected with a hose, the air discharged through the air discharge pipe flows into the pressurization pack and pressurizes the sterilized water pack, so that the sterilized water contained in the sterilized water pack can be supplied to the humidifying body.

According to the present invention, since the humidifying filter can naturally vaporize sterilized water to supply moisture to the breathing gas, it does not require a power source for humidification, so that the patient is provided with breathing gas containing sufficient moisture even outside where power supply is difficult. It can solve the power shortage problem when using ambulances and emergency helicopters.

In addition, as the breathing circuit device to which the present invention is applied is simplified, it is convenient to use in a narrow space or when moving, and the burden of medical staff or caregivers in dealing with emergency situations and managing the breathing circuit is reduced, and the connection parts between components Not only is there less risk of leakage due to the reduction, but also turbulence of the gas is reduced so that the rectified gas can be provided to the patient.

Furthermore, since there is no temperature change in the breathing circuit, the generation of condensate is significantly reduced, preventing malfunction due to clogging of the sensor line or increase in resistance due to condensate, and the use of sterilized water through effective moisture management such as prevention of excessive moisture. can save

1 is a schematic diagram showing a conventional breathing circuit device for a ventilator;
2 is a perspective view showing a humidifying module for a ventilator breathing circuit according to the present invention;
3 is a perspective view showing a state in which a humidifying filter is provided in a humidifying body applied to a humidifying module for a breathing circuit of a ventilator according to the present invention;
4 is a cross-sectional side view showing a humidifying module for a breathing circuit of a ventilator according to the present invention;
5 is an exploded perspective view showing a humidifying module for a ventilator breathing circuit according to the present invention;
6 is a front cross-sectional view showing a humidifying module for a ventilator breathing circuit according to the present invention;
7 is a schematic diagram showing a breathing circuit device to which a humidifying module for a breathing circuit of a ventilator according to the present invention is applied;
8 is an exemplary view showing the supply of sterilized water and the flow of some air in the humidifying module for the ventilator breathing circuit of the present invention.

In the present invention, moisture can be supplied to the breathing gas through the natural vaporization method, so that condensate generation can be significantly reduced without the need for a power source for humidification. A humidification module for a ventilator breathing circuit is proposed, wherein the humidifying body includes a humidifying filter for naturally evaporating sterilized water therein.

The scope of the present invention is not limited to the embodiments described below, and can be variously modified and implemented by those skilled in the art within the scope of not departing from the technical gist of the present invention.

Hereinafter, a humidifying module for a ventilator breathing circuit according to the present invention will be described in detail with reference to FIGS. 2 to 8 attached.

The humidifying module for a breathing circuit of a ventilator according to the present invention includes a humidifying body 100 and a humidifying filter 200 as shown in FIGS. 2 to 6 .

The humidifying body 100 is configured to receive the breathing gas generated by the respirator 10 and replenish moisture in the breathing gas to discharge the humidified breathing gas. It is made by the humidifying filter 200 provided in the 100.

Specifically, the humidifying body 100 may be formed in a tubular shape and laid down, and may be formed in a cylindrical or polygonal tubular shape, for example. In addition, the shape of the humidifying body 100 may vary in consideration of the shape of the humidifying filter 200 provided therein, but is not necessarily limited thereto. Hereinafter, the humidifying body 100 of the present invention will be described on the premise that it has a square cylinder shape.

And, as shown in FIGS. 2 to 5, the humidifying body 100 has an inlet 110 through which breathing gas is introduced at one end and an outlet 120 through which the humidified breathing gas is discharged at the other end. can That is, the breathing gas introduced into the humidifying body 100 through the inlet 110 is replenished with moisture by the humidifying filter 200 and discharged to the outside of the humidifying body 100 through the outlet 120 . One end and the other end of the humidifying body 100 may be formed to have a gradually narrower width toward the outside for smooth movement of the gas, and the inlet 110 and the outlet 120 extend from the point having the narrowest width to the outside. may protrude.

The humidifying body 100, for example, for convenience of production and assembly, as shown in FIGS. 2, 5 and 6, the first humidifying body 100a, the second humidifying body 100b, and the third It may be configured to include a humidifying body (100c), a first cover body (100d), and a second cover body (100e). The first humidifying body 100a may be formed to include the other end of the humidifying body 100 from which the outlet 120 protrudes and a side wall constituting a part of the side surface of the humidifying body 100. That is, the first humidifying body 100a may have a frame shape with upper and lower openings so that the humidifying filter 200 can be located inside. The second humidifying body (100b) may be formed to include a side wall constituting a part of the side of the humidifying body (100), and may form a frame with upper and lower openings so that the humidifying filter (200) can be located inside. . For example, in the first humidifying body 100a and the second humidifying body 100b, the upper and lower edges of the two side walls facing each other to form the side of the humidifying body 100 are connected by a joint bar, Gas may be moved through the joint bars arranged vertically.

The third humidifying body 100c may be formed to include one end of the humidifying body 100 in which the inlet 110 protrudes, and is combined with the assembled first humidifying body 100a and the second humidifying body 100b, or can be attached In addition, a bacteria filter 400 may be provided at a point adjacent to the first humidifying body 100a and the second humidifying body 100b in the third humidifying body 100c. For example, the bacteria filter 400 may be formed in a plate shape, and a filter receiving jaw may be formed along an inner side of the edge of the third humidifying body 100c so that the bacteria filter 400 is accommodated inside. Accordingly, the respiratory gas generated in the respirator 10 and introduced through the inlet 110 is fine dust components such as dust and bacteria contained therein before moisture is replenished by the humidifying filter 200. It is filtered by the bacteria filter 400.

The first cover body (100d) may be formed to include a side wall constituting the lower surface of the humidifying body (100), and is configured to seal the open lower side of the first humidifying body (100a). In addition, the second cover body (100e) may be formed to include a side wall constituting the upper surface of the humidifying body (100), and is configured to seal the open upper side of the second humidifying body (100b).

In the specific example of the above-described humidifying body 100, the first humidifying body 100a and the second humidifying body 100b describe/show that two humidifying filters 200 are provided inside, but the humidifying body ( 100) is not limited to having two humidifying filters 200, and one or a plurality of humidifying filters 200 may be provided.

The humidifying filter 200 is provided inside the humidifying body 100 and is configured to naturally vaporize sterilized water. Accordingly, the humidifying filter 200 may be made of a material such as polyester or 3D mesh for easy natural evaporation, but is not limited thereto and may be made of various materials for effective natural evaporation. In addition, the humidifying filter 200 may be formed in various forms in consideration of the shape of the humidifying body 100 and the installation structure within the humidifying body 100.

For example, the humidifying filter 200 may be provided to be spaced apart from the sidewall of the humidifying body 100 so that a flow path 130 is formed between one end and the other end of the humidifying body 100 and a sidewall connecting the other end. Therefore, the sterilized water vaporized in the humidifying filter 200 can be supplied to the flow path 130 from the outside of the humidifying body 100, and moves along the flow path 130 to wet the humidifying filter 200 in multiple directions. This can increase the humidification effect.

In order to separate the humidifying filter 200 from the sidewall of the humidifying body 100, when the humidifying body 100 is formed in the shape of a square cylinder and the sidewall is formed to form an upper surface and a lower surface, two sidewalls, FIGS. 5 and 6 As shown in , a passage forming wall 140 may be provided on the inside of the side wall forming the two side walls at a predetermined distance from the corresponding side wall to form a passage 130 . For example, a flow path forming wall 140 is formed inside the side wall of the first humidifying body 100a and the side wall of the second humidifying body 100b, and the sterilized water is moved between the corresponding side wall and the flow path forming wall 140. A flow path 130 may be formed.

The passage forming wall 140 formed in the first humidifying main body 100a is formed to be spaced apart from the first cover body 100d, and the passage forming wall 140 formed in the second humidifying main body 100b is It is preferable that the passage 130 is formed between the sidewalls forming the upper and lower surfaces of the humidifying body 100 and the humidifying filter 200 by being formed to be spaced apart from the cover body 100e. And the flow path forming wall 140 formed on the first humidifying body 100a and the flow path forming wall 140 formed on the second humidifying body 100b are formed to be spaced apart from each other, inside the first humidifying body 100a It is preferable that the passage 130 is also formed between the provided humidifying filter 200 and the humidifying filter 200 provided inside the second humidifying body 100b.

At this time, the sterilized water is preferably supplied to the passage 130 formed between the side wall forming the upper or lower surface of the humidifying body 100 and the humidifying filter 200. Therefore, a sterilized water inlet pipe 160 for supplying sterilized water may protrude from one end or the other end of the humidifying main body 100, and the sterilized water inlet pipe 160 forms the upper or lower surface of the humidifying main body 100. It is formed to communicate with the passage 130 formed between the side wall and the humidifying filter 200. For this reason, as in the example shown in FIG. 6 , the sterilized water supplied through the flow path 130 formed between the side wall constituting the lower surface of the humidifying body 100 and the humidifying filter 200 passes through the lower part of the humidifying filter 200. In addition to allowing the side to be wet, the side wall forming the upper surface of the humidifying body 100 and the humidifying filter 200 through the passage 130 formed between the side wall forming the side surface of the humidifying body 100 and the humidifying filter 200 The upper side of the humidifying filter 200 may be wetted while moving the passage 130 formed therebetween.

In the humidifying body 100 having a flow path forming wall 140 in the form of a square cylinder, the humidifying filter 200 can be firmly fixed in a state of being spaced apart from the sidewall of the humidifying body 100, the humidifying filter 200 As shown in FIGS. 3 to 6, it is adjacent to the flow path forming wall 140 facing both sides while forming a square cylinder shape, and the upper and lower surfaces extend outward and are attached to the top and bottom of the flow path forming wall 140. and can be fixed.

On the other hand, the sterilized water supplied into the humidifying body 100 may be supplied from the sterilized water pack 310 provided outside the humidifying body 100, as shown in FIGS. 7 and 8, and the sterilized water pack 310 ) and the sterilized water inlet pipe 160 may be connected by a hose. For continuous and smooth inflow of sterilized water from the sterilized water pack 310 to the humidifying body 100, it is preferable that some of the air in the humidifying body 100 is discharged to the outside. Accordingly, an air discharge pipe 150 through which some of the air inside the humidifying body 100 is discharged may be protruded from one end or the other end of the humidifying body 100, as shown in FIG.

At this time, the air discharged through the air discharge pipe 150 may pressurize the sterilized water pack 310 so as to be easily discharged from the sterilized water pack 310 . To this end, the sterilized water pack 310 may be provided inside the pressure pack 320 filled with a certain amount of air, as shown in FIGS. 7 and 8, and the air discharge pipe 150 and the pressure pack 320 are Can be connected with a hose. Therefore, the air discharged through the air discharge pipe 150 flows into the pressure pack 320 and pressurizes the sterilized water pack 310 so that the sterilized water contained in the sterilized water pack 310 is smoothly supplied to the humidifying body 100. can

On the other hand, the breathing circuit device to which the humidification module for the breathing circuit of the present invention is applied connects the ventilator 10 and the patient, the breathing gas generated in the ventilator 10 is supplied to the patient, and the patient exhales It is configured so that the exhaust gas including carbon dioxide flows into the ventilator 10, and as shown in FIG. 7, the ventilator 10, the intake pipe 20, the branch pipe 30, and the exhaust pipe (40) may be included.

First, the branch pipe 30 has one end connected to the patient, and a suction port and an exhaust port formed at the other end branched into two branches, respectively, and may be formed in a 'Y' tube shape, for example. Therefore, the breathing gas introduced into the manifold 30 through the inlet is supplied to the patient through one end, and the exhaust gas introduced into the manifold 30 through one end as the patient exhales is discharged through the exhaust port. .

The intake pipe 20 has a tube shape having a predetermined length, and one end communicates with the outlet of the ventilator 10 through which breathing gas comes out, and the other end is connected to the inlet of the branch pipe 30. Accordingly, the breathing gas generated and discharged from the ventilator 10 is moved toward the intake port along the intake pipe 20 . In addition, the exhaust pipe 40 has a pipe shape having a predetermined length, and one end is connected to the ventilator 10 and the other end is connected to the exhaust port of the branch pipe 30. Accordingly, the exhaust gas generated from the patient passes through the branch pipe 30 and moves toward the ventilator 10 along the exhaust pipe 40 .

The branch pipe 30, the intake pipe 20, and the exhaust pipe 40 described above may be made of a hard material, but for convenience of use, the whole or part is made of a soft material, or the whole or part is a bendable structure It can be done. For example, both ends of the intake pipe 20 and the exhaust pipe 40 connected to other components may be made of a hard material, and the remaining parts may be made of a soft material. As another example, the intake pipe 20 and the exhaust pipe 40 may have a corrugated structure in which the length of the intake pipe 20 and the exhaust pipe 40 is increased or decreased while remaining portions other than both ends are bendable.

The humidification module of the present invention naturally vaporizes sterilized water to replenish moisture in the warm and dry breathing gas generated from the ventilator 10, so that the breathing gas discharged from the ventilator 10 can contain sufficient moisture. To be, it is preferable to be provided at a point adjacent to the ventilator (10). Therefore, as an example, in the humidification module of the present invention, as shown in FIG. 7 , the inlet 110 may be connected to the outlet of the ventilator 10 and the outlet 120 may be connected to the intake pipe 20.

As described above, in the humidification module of the present invention, the humidification filter 200 naturally vaporizes sterilized water to supply moisture to breathing gas. It can provide breathing gas to the patient and solve the power shortage problem when using ambulances and emergency helicopters. In addition, as the breathing circuit device to which the present invention is applied is simplified, it is convenient to use in a narrow space or when moving, and the burden of medical staff or caregivers in dealing with emergency situations and managing the breathing circuit is reduced, and the connection parts between components Not only is there less risk of leakage due to the reduction, but also turbulence of the gas is reduced so that the rectified gas can be provided to the patient. In addition, as the generation of condensate is significantly reduced, it is possible to prevent malfunction due to clogging of the sensor line or increase in resistance due to condensate, and the use of sterilized water can be reduced through effective moisture management such as prevention of excessive moisture.

10: ventilator 20: intake pipe
30: branch pipe 40: exhaust pipe
100: humidifying body 100a: first humidifying body
100b: second humidifying body 100c: third humidifying body
100d: first cover body 100e: second cover body
110: inlet 120: outlet
130: flow path 140: flow path forming wall
141: spacing maintenance piece 150: air discharge pipe
160: sterilized water inlet pipe
200: humidification filter
310: sterilized water pack 320: pressurized pack
400: bacteria filter

Claims (5)

A humidifying body 100 that receives the breathing gas generated by the ventilator 10 and replenishes moisture to discharge the humidified breathing gas;
The humidifying body 100 is a humidifying module for a ventilator breathing circuit, characterized in that a humidifying filter 200 for naturally vaporizing sterilized water is provided therein. According to claim 1,
The humidifying body 100 has an inlet 110 into which breathing gas flows in at one end while forming a tubular shape, and an outlet 120 through which humidified breathing gas is discharged at the other end.
The humidifying filter 200 is provided to be spaced apart from the side wall so that a flow path 130 is formed between one end of the humidifying body 100 and a side wall connecting the other end, so that the sterilized water supplied to the flow path 130 A humidifying module for a ventilator breathing circuit, characterized in that it is moistened in multiple directions by the. According to claim 2,
The humidifying body 100 is formed in the form of a square cylinder, and the side wall is formed to form an upper surface and a lower surface, and two side surfaces,
On the inside of the side walls constituting the two side walls, a flow path forming wall 140 is provided at a predetermined interval from the side wall to form a flow path 130,
The sterilized water is supplied to the flow path 130 formed between the humidifying filter 200 and the side wall forming the upper or lower surface of the humidifying body 100. Humidifying module for a ventilator breathing circuit. According to claim 3,
The humidifying filter 200 has a square cylinder shape, both sides are adjacent to the flow path forming wall 140 facing each other, and the upper and lower surfaces extend outward to the upper and lower ends of the flow path forming wall 140. Attached and fixed A humidification module for a ventilator breathing circuit, characterized in that it can be. According to claim 1,
The sterilized water is supplied from the sterilized water pack 310 provided outside the humidifying body 100,
The sterilized water pack 310 is provided inside the pressure pack 320 filled with a certain amount of air,
An air discharge pipe 150 through which some of the air inside the humidifying body 100 is discharged is formed at one end or the other end of the humidifying body 100,
The air discharge pipe 150 and the pressurization pack 320 are connected by a hose, and the air discharged through the air discharge pipe 150 flows into the pressurization pack 320 and pressurizes the sterilized water pack 310 so that the sterilized water pack 310 ) A humidifying module for a ventilator breathing circuit, characterized in that the sterilized water accommodated in is supplied to the humidifying body (100).

Images