KR20110104602A - Circuit for breathing having endotracheal tube reducing anatomical dead space - Google Patents

Abstract

It prevents the mixture of carbon dioxide and oxygen supplied to the patient in advance, thereby reducing anatomical dead space, reducing the amount of ventilation provided to the patient, and reducing the pressure of air on the patient's lung parenchyma. A respiratory circuit has been disclosed that has a tracheal tube that reduces anatomical dead space that can protect a patient's lungs with reduced purity. In the present invention, the respiratory circuit includes an oxygen breathing apparatus, an upper portion of a tracheal tube exposed to the outside of the trachea, and an breathing breathing tube and an inhalation breathing tube connected to one end of the oxygen breathing apparatus. The other end includes a connector portion directly connected to the tracheal tube. The tracheal tube is formed in the tube body and the upper part of the tube body and is connected to the other end of the aerobic breathing tube and the inhalation breathing tube, and the inside of the tube body and the intake pipe connected to the inside of the tube body; In addition, it is provided with a split diaphragm, which extends along the longitudinal direction of the tube body and divides the inside of the tube body to be provided to the arc pipe and the suction pipe. The breathing circuit having such a tracheal tube has a divided diaphragm inflated to the breathing trachea during inhalation and expands the inhalation trachea while expanding the inhalation trachea. By closing the furnace, it is possible to prevent the mixing of the emitted carbon dioxide and the supplied oxygen and to reduce anatomical dead space.

Description

CIRCUIT FOR BREATHING HAVING ENDOTRACHEAL TUBE REDUCING ANATOMICAL DEAD SPACE}

The present invention relates to a respiratory circuit having a tracheal tube that reduces anatomical dead space, and more particularly, to reduce the anatomical dead space that prevents the supply of carbon dioxide and oxygen supplied from the patient to be provided to the patient. It relates to a respiratory circuit having tracheal tubes.

In general, tracheal insertion tubes are inserted for resuscitation by ventilators in an intensive care unit or under surgery under general anesthesia, and to ensure airway under patient emergency.

FIG. 1A is a view schematically showing a conventional artificial respiration circuit, and FIG. 1B is a view showing a conventional tracheal tube shown in FIG. 1A.

1A and 1B, the conventional artificial respiration circuit 10 includes an oxygen breathing apparatus 20 for supplying exhalation and inhalation to a patient, a tracheal tube 30 inserted into a patient's trachea, and an oxygen breathing apparatus ( 20) and the connecting tube portion 40 for connecting the tracheal tube (30). As shown in the connection pipe part 40, an exhalation breathing tube connecting one end of the Y-piece pipe 42 to the tracheal tube 30, and the Y-piece pipe 42 and the oxygen breathing apparatus 20 (44) and the inhalation breathing tube (46) connecting the Y-piece pipe (42) and the oxygen breathing apparatus (20), and between the oxygen breathing apparatus (20) and the breathing breathing tube (44) 48 is disposed, and an intake valve 50 is disposed between the oxygen breathing apparatus 20 and the intake breathing tube 46.

Meanwhile, the tracheal tube 30 is provided with a tube body 32 having a connector 34 formed at an upper end thereof, and an inflation tube 36 exposed at an upper side thereof. An inflation cuff 38 is provided. The Y-piece tube 42 is connected to the connector 34 of the tube body 32.

However, in the conventional breathing circuit, the Y-piece tube is used to connect the oxygen breathing apparatus and the tracheal tube, and the aerobic and inhalation breathing are performed through the Y-piece tube and one tracheal tube so that the carbon dioxide discharged during exhalation is completely Because it is provided to the patient by being mixed with oxygen that is inhaled in the non-discharged state, there is an anatomical dead space from the Y-piece tube to the end of the tracheal tube, and the anatomical dead space increases the patient's respiratory volume once, Increasing the respiratory volume also increases the air pressure applied to the lung parenchyma, which has a problem of exacerbating the lung condition of the patient by applying pressure to the lung of the patient with the lung disease.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to remove the conventional Y-piece tube, the breathing pipe and the intake pipe on the upper portion of the tube body to be directly connected to the oxygen breathing apparatus And a respiratory circuit having a tracheal tube having a split diaphragm having a stretchable diaphragm for dividing the inside of the tube body into both sides of the tube body so that the tracheal passage and the intake passage are provided inside the tube body. The partition diaphragm blocks the intake duct with the high pressure of exhalation, and during inhalation breathing, the partition diaphragm blocks the exhalation tract with the high pressure of inhalation and prevents the discharge of carbon dioxide and oxygen supplied to the patient. It is to provide a respiratory circuit having tracheal tubes that reduce the anatomical dead space.

In order to achieve the object of the present invention as described above, the present invention,

In a breathing circuit having an organ tube,

The breathing circuit,

An oxygen breathing apparatus for supplying exhalation and inhalation to the patient,

The upper portion inserted into the trachea of the patient is tracheal tube exposed to the outside of the trachea; And

It includes a breathing breathing tube and an inhalation breathing tube is connected to the oxygen breathing apparatus and one end, the other end of the breathing breathing tube and the inhalation breathing tube is connected directly to the tracheal tube without interfering;

Tracheal tube,

It is formed on the tube body, the upper part of the tube body and is connected to the other end of the breathing breathing tube and the inhalation breathing tube, and the inside is connected to the inside of the tube body and the intake pipe and the intake pipe, and formed inside the tube body It provides a respiratory circuit having a tracheal tube to reduce the anatomical dead space provided with a split diaphragm, extending along the longitudinal direction of the tube body to divide the interior of the tube body into the arc trachea and the suction line.

As described above, the respiratory circuit having a tracheal tube to reduce the anatomical dead space according to the present invention, the conventional tracheal tube and the intake pipe on the upper part of the tube body to remove the Y-piece tube, and directly connected to the oxygen breathing apparatus The tube body is formed inside the tube body by dividing the inside of the tube body on both sides, the tube body having a split diaphragm having a stretchable diaphragm to provide an expansible trachea and an intake pipe passage in the tube body. The high pressure of the exhalation blocks the intake line, and during inhalation breathing, the partition diaphragm blocks the exhalation channel with the high pressure of the inhalation, and the carbon dioxide and oxygen supplied are prevented from being provided to the patient. It is possible to reduce the amount of one-time ventilation supplied to the patient. It is possible to reduce the pressure of air applied to the advantage of protecting the lungs of patients with pulmonary disease is pulmonary yusundo reduced.

Figure 1a is a diagram schematically showing a conventional artificial breathing circuit,
Figure 1b is a view showing a conventional tracheal tube shown in Figure 1a,
2 is a view schematically showing a respiratory circuit having a tracheal tube to reduce the anatomical dead space according to the present invention,
3 is a perspective view showing the tracheal tube shown in FIG.
4 is a view showing another embodiment of the divided partition shown in FIG. 3, and
5a and 5b is a view showing the operating state of the partition diaphragm during aerobic and inhalation breathing.

Hereinafter, with reference to the accompanying drawings will be described a breathing circuit having a tracheal tube to reduce anatomical dead space according to an embodiment of the present invention.

Figure 2 is a schematic view of the respiratory circuit having a tracheal tube to reduce the anatomical dead space according to the present invention.

2, the respiratory circuit 100 having a tracheal tube to reduce the anatomical dead space according to the present invention, the oxygen breathing apparatus 110 for supplying breath and inhalation to the patient, and the upper portion inserted into the trachea of the patient The engine tube 120 is exposed to the outside of the organ, the oxygen breathing apparatus 110 and the connecting tube portion 140 for connecting the upper portion of the tracheal tube (120).

The connecting tube part 140, one end is directly connected to the tracheal tube 120 and the other end is connected to the breathing breathing tube 142, which is connected to the oxygen breathing apparatus 110, similarly so that one end does not interfere with the breathing breathing tube 142 Directly connected to the tracheal tube 120 and the other end is provided with an inhalation breathing tube 144 connected to the oxygen breathing apparatus 110 so as not to interfere with the breathing breathing tube 142. At this time, an exhalation valve 142a is disposed between the oxygen breathing apparatus 110 and the exhalation breathing tube 142, and an intake valve 144a is disposed between the oxygen breathing apparatus 110 and the inhalation breathing tube 144.

3 is a perspective view showing the tracheal tube shown in FIG.

As shown, the tracheal tube 120 is a tube body 122 having a cuff 124 that is expanded by a predetermined air pressure on the outer peripheral surface adjacent to the lower portion and pressurizes the airway wall, and the tube body 122 of the tube body 122. It extends along the inner longitudinal direction and has an inflating tube 126 that is connected to the cuff 124 at the bottom and is exposed to the outside of the tube body 122. The inflation tube 125 is equipped with a check valve 125a to prevent backflow of air from the cuff 124.

In addition, the upper part of the tube body 1222 is formed with the arc pipe 126 and the intake pipe 128, the upper portion of the arc pipe 126 and the upper portion of the intake pipe 128 extends from the oxygen breathing apparatus 110 The exhalation breathing tube 142 and the intake breathing tube 144 is directly connected to the exhalation connector 126a and intake connector 128a is mounted. That is, the arc pipe 126 and the intake pipe 128 are formed to protrude above the tube body 122 so as not to interfere with each other, and the inside of the arc pipe 126 and the inside of the intake pipe 128 are formed in the tube body ( And internal to each other.

As described above, the tube body 122 having the arc pipe 126 and the intake pipe 128 further includes a partition diaphragm 130 therein.

As shown, the split diaphragm 130 is formed inside the tube body 122 and is formed along the longitudinal direction of the tube body 122. The split diaphragm 130 is formed with the arc pipe 126 and the intake pipe. Is formed to extend to the lower portion of the tube body 122 in the separate portion of (128). As described above, the inner part of the tube body 122 is connected to the inside of the arc tube 126 by the divided diaphragm 130 which divides the inside of the tube body 122 into both sides. Intake pipe passage 134 is connected to the inside of the) is formed.

The above-described divided diaphragm 130 is preferably made of an ultra-thin material made of an elastic material, for example, rubber or silicon, and the upper and lower portions of the divided diaphragm 130 are formed of the tube body 122. It is fused to the inner side of the.

4 is a diagram illustrating another embodiment of the divided barrier shown in FIG. 3.

On the other hand, as shown in FIG. 4, the partition diaphragm 130 may be fitted to the tube body 122. For this purpose, a pair of guide bars 136 are provided on the upper and lower portions of the partition diaphragm 130. In the tube body 122, a pair of guide grooves 138 to which a pair of guide bars 136 are fitted are formed so as not to interfere with the inflation tube 125.

The pair of guide bars 136 described above are preferably made of the same material as the tube body 122, and the upper and lower portions of the split diaphragm 130 disposed between the pair of guide bars 136 are adjacent guides. It is fused to the bar 136.

On the other hand, the guide bar 136 is provided with a tooth-shaped locking projection 136a so as not to be easily separated from the guide groove 138, the guide groove 138 is a tooth-shaped locking groove that the locking projection 136a is spread over 138a is formed.

Hereinafter, the operation state of the partition diaphragm 130 in the tube body 122 as described above will be briefly described.

  5a and 5b is a view showing the operating state of the partition diaphragm during aerobic and inhalation breathing.

First, the lower part of the tube body 122 is inserted into the trachea of the patient, and the upper part of the arc organ 126, the intake pipe 128, and the inflation tube 125 formed on the upper part of the tube body 122 is outside of the oral cavity. To be exposed.

Under this condition, the cuff 124 is inflated by supplying air to the cuff 124 using a conventional syringe, for example, to eliminate air leakage to the tracheal tube 120 and to effectively ventilate the patient. The exhalation breathing tube 142 is connected to the exhalation connector 126a of the trachea 126, and the inhalation breathing tube 144 is connected to the intake connector 128a of the intake pipe 128 to supply oxygen to the trachea and lung of the patient. To ventilate the patient. As anyone knows, when the cuff 112 described above is inflated, oxygen is supplied to the lungs of the patient through the tube body 110 only because the cuff 112 fills the space between the tube body 110 and the trachea.

On the other hand, when oxygen is supplied by the oxygen breathing apparatus 110, the supplied oxygen is guided to the intake pipe 134 of the tube body 122 through the intake breathing tube 144, the intake pipe 128 to the patient Is provided. At this time, due to the high pressure of the oxygen guided to the intake pipe 134, the partition diaphragm 130 is inflated toward the arc pipe 132, and as a result, the suction pipe 134 is expanded and the arc pipe 132 is inflated. It is closed by the true partition diaphragm 130 (see FIG. 5A). On the contrary, during exhalation breathing, the carbon dioxide discharged is guided through the exhalation trachea 132 and the exhalation trachea 126 inside the tube body 122. Due to the high pressure of carbon dioxide, the partition diaphragm 130 is inflated toward the suction pipe 134. As a result, the arc pipe 132 is expanded and the suction pipe 134 is closed by the inflated partition diaphragm 130 (see FIG. 5B).

As such, the arc pipe 132 and the suction pipe 134 are provided in the tube body 122 by the split diaphragm 130 provided in the tube body 122, and the split diaphragm 130 breathes a breath. When inflated to close the suction pipe 134, and during the inhalation breathing by closing the breathing pipe passage 132, to prevent the carbon dioxide discharged during the breathing breath and the oxygen to be supplied, while mixing the carbon dioxide and oxygen It is possible to reduce the anatomical dead space, which is prevented from being provided to the patient, which reduces the amount of single ventilation supplied to the patient, and decreases the pressure of air applied to the patient's lung parenchyma, The disease makes it possible to protect the lungs of patients whose lung purity is reduced.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims You will understand.

100: respiratory circuit with tracheal tube to reduce anatomical dead space
110: oxygen breathing apparatus 120: tracheal tube
122: tube body 124: cuff
125: inflation tube 126: arc engine
128: intake pipe 130: split diaphragm
132: to the arc pipe 134: to the intake pipe
140: connecting portion 142: breathing breathing tube
144: inhalation breathing tube

Claims (5)

In a breathing circuit having an organ tube,
The breathing circuit,
An oxygen breathing apparatus for supplying exhalation and inhalation to the patient;
The upper portion inserted into the trachea of the patient is tracheal tube exposed to the outside of the trachea; And
And a breathing breathing tube and an inhalation breathing tube having one end connected to the oxygen breathing apparatus, and the other end of the breathing breathing tube and the inhalation breathing tube connected directly to the tracheal tube without interfering with each other.
The tracheal tube,
It is formed in the tube body, the upper body of the breathing tube and the inhalation and intake pipe connected to the other end of the breathing tube and the inhalation breathing tube and the inside of the tube body, the inside of the tube body And a dividing diaphragm extending along the longitudinal direction of the tube body to divide the inside of the tube body into the arc pipe and the suction pipe,
The partition diaphragm is inflated to the breathing tract side during inhalation and closes the breathing tract while expanding the intake tract, and expands the breathing tract and expands to the intake tract while expanding breathing tract. Respiratory circuit having a tracheal tube to reduce the anatomical dead space characterized in that the closing. The anatomical dead space of claim 1, wherein the divided diaphragm is formed to extend from the separated portion of the arc and the intake pipe to the lower portion of the tube body, and is fusion-bonded to the inside of the tube body. A breathing circuit having an organ tube. The method of claim 1, wherein the split diaphragm is provided with a pair of guide bars on the upper and lower portions of the divided diaphragm to be fitted to the tube body, the pair of guide bars are fitted to the tube body. A pair of guide grooves are formed, and the upper and lower portions of the divided diaphragm is a respiratory circuit having an anatomical dead space tube characterized in that the fusion bonding to the adjacent guide bar. According to claim 3, wherein the guide bar is made of the same material as the tube body, the guide bar is formed with a tooth-like engaging projection so as not to be easily separated from the guide groove, the guide groove is the engaging projection Respiratory circuit having a tracheal tube to reduce the anatomical dead space, characterized in that the sawtooth engaging groove is formed. The anatomical dead space of any one of claims 1, 2, 3, and 4, wherein the partition diaphragm is made of an ultra-thin material made of any one of rubber or silicone having an elastic material. Respiratory circuit with tracheal tube that reduces

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