KR101483361B1 - Tube for breath-inducing and apparatus for breath-inducing using the same - Google Patents

Abstract

The present invention relates to a respiration induction tube for assisting a respiration of a patient and a respiration induction device using the same. A respiration induction tube according to the present invention includes: a distributor having a connector, an inlet and an outlet; A connection tube connected to the connector of the dispenser and connected to the patient; An exhaust tube connected to the exhaust port of the distributor to exhaust a respiratory gas of the patient; A suction unit having a first suction tube, one side of which is connected to the suction port of the distributor, and a second suction tube; The other end of the first suction tube is connected to one side and the second suction tube is connected to the other side to communicate the first suction tube and the second suction tube and the second suction tube and the first suction tube And a heating module for heating the breathing gas to be sucked. Accordingly, while the problem of humidification through the suction tube is solved, the structure of the breathing induction tube is simple, the replacement is easy, and the humidity and the temperature can be maintained.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a breathing induction tube,

The present invention relates to a breathing induction tube and a breathing induction device using the same. More particularly, the present invention relates to a breathing induction tube capable of solving the problems caused by humidification in inducing breathing of a patient, The present invention relates to a respiration induction device.

In patients who are operated on by anesthesia during surgery or who are not conscious in the intensive care unit, respiration induction devices such as artificial respirators are used to induce respiration, .

In general, an anesthetic or oxygen is supplied to the patient through an anesthesia machine or an artificial respirator by using a gas supply device embedded in the operating room or the wall of the sickroom. A breathing induction tube is attached to the artificial respiration device, And the like.

Here, the breathing-inducing tube generally includes a suction tube for introducing a breathing gas (hereinafter referred to as "breathing gas") such as an anesthetic gas or oxygen into the patient, a suction tube for sucking the patient, A discharge tube for discharging carbon dioxide or residual anesthetic gases after the gas is discharged, and a distributor connected to the outlet of the patient branching to be connected to the outlet of the suction tube and the inlet of the exhaust tube, respectively.

In this case, the anesthetic agent supplied to the patient is a volatile inhalation anesthetic liquid which is evaporated through a vaporizer and supplied in a gaseous state, and is supplied in a gaseous state even in the case of oxygen gas as a breathing gas. Anesthesia gas or breathing gas to be inhaled has a bad effect on the patient because it is cold enough to give cold to the patient. In addition, both the anesthetic gas and the breathing gas are dry, which does not contain the basic moisture, and can act as a factor for drying the trachea or lung of the patient.

In order to solve the problem of moisture and temperature of the respiratory gas, a technique has been proposed in which the respiratory gas supplied to the patient is warmed and humidified and supplied to the patient. For example, Korean Patent No. 10-1143805 discloses a technique for maintaining a proper temperature and humidity during breathing gas injection for general anesthesia and oxygen supply in a patient's carburetor system for humidifying an anesthetic gas and respiratory gas .

FIG. 1 is a view showing a state in which a heat ray and a temperature / humidity sensor are mounted on a breathing tube in the vaporizer system disclosed in the Korean patent. As shown in FIG. 1, a heat ray 31 is disposed inside the suction tube 30 along the longitudinal direction of the suction tube 30 to heat the breathing gas flowing through the suction tube 30. Also disclosed is a technique for controlling the humidity of breathing gas by vaporizing distilled water charged in a cartridge through ultrasonic vibration.

In addition to the humidification method disclosed in the Korean patent, a method has also been proposed in which a cloth is wound around a hot wire embedded in a suction tube, water is drenched on the cloth, and moisture in the cloth is evaporated by heat generated from the hot wire to maintain the humidity.

However, when the humidified breathing gas is supplied through the suction tube as described above, the water sprayed by the humidification is condensed in the suction tube or the exhaust tube. Such an inflow of water into the anesthesia may cause malfunction or failure of the sensor of the anesthesia apparatus, which is undesirable.

In addition, when the breathing tube is used for a long period of time, the water inside the breathing tube or the breathing tube creates an environment that generates bacteria or bacteria, which not only adversely affects the patient, but also causes frequent replacement of the breathing tube .

As shown in FIG. 1, a heating wire is installed along the inside of the suction tube to warm the respiratory gas. This not only complicates the structure of the breathing tube, but also causes problems such as disconnection of the heat wire. The whole tube must be replaced or the suction tube itself must be replaced, which is not economical.

Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a breathing apparatus which can solve the problem of humidification through a suction tube, An induction tube, and a respiration induction device using the same.

According to the present invention, there is provided a respiration induction tube for assisting respiration of a patient, comprising: a distributor having a connection port, an inlet port and an exhaust port; A connection tube connected to the connector of the dispenser and connected to the patient; An exhaust tube connected to the exhaust port of the distributor to exhaust a respiratory gas of the patient; A suction unit having a first suction tube, one side of which is connected to the suction port of the distributor, and a second suction tube; The other end of the first suction tube is connected to one side and the second suction tube is connected to the other side to communicate the first suction tube and the second suction tube and the second suction tube and the first suction tube And a heating module for heating the breathing gas to be inhaled.

Here, the second suction tube and the warming module are provided in plurality; The heating module and the second suction tube may be sequentially connected.

The first suction tube and the second suction tube may be detachably coupled to the heating module.

The heating module includes a module body having a hollow formed along the connection direction of the first suction tube and the second suction tube; A first connection part and a second connection part provided on both sides of the module main body in a connecting direction of the first suction tube and the second suction tube and connected to the first suction tube or the second suction tube; And a heating member installed in the hollow of the module body to heat the respiratory gas.

The heating module may further include a power connector for supplying external power to the heating member so that the heating member is heated.

In addition, the heating member may have a filament shape to allow a breathing gas to flow through the hollow of the module body.

The apparatus may further include a moisture barrier filter disposed between the connection tube and the distributor to block movement of moisture from the connection tube toward the distributor.

According to another aspect of the present invention, there is provided a respiration induction device for assisting a respiration of a patient, comprising: a respiration induction tube; And a respiratory controller connected to the suction portion of the breathing induction tube and the exhaust tube to induce breathing of the patient through the suction portion and the exhaust tube.

Wherein the temperature sensor further comprises a temperature sensor installed in the dispenser of the breathing induction tube for sensing a temperature of respiratory gas flowing into the dispenser through the suction portion of the breathing induction tube; The respiratory controller may control the heating module so that the temperature of the respiratory gas flowing into the distributor is maintained at a predetermined set temperature based on the detection result of the temperature sensor.

The respiratory controller may further include a temperature display unit for displaying a temperature sensed by the temperature sensor; And a temperature controller for controlling a heating temperature of the heating module according to a user's operation.

According to the present invention, it is possible to provide a breathing induction tube capable of solving the problem caused by humidification through the suction tube while simplifying the structure of the breathing inducing tube, facilitating the replacement and maintaining the humidity and temperature, and A breathing induction device is provided.

1 is a view showing a state in which a heat wire and a temperature and humidity sensor are mounted on a breathing tube in a vaporizer system disclosed in Korean Patent No. 10-1143805,
2 is a view showing a configuration of a respiration induction device according to the present invention,
3 and 4 are views showing a configuration of a breathing induction tube according to a first embodiment of the present invention,
5 is a view showing an example of a configuration of a heating module according to the present invention,
6 is a view showing a configuration of a breathing induction tube according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to the description of the present invention, the breathing induction tube 300 according to the present invention and the respiratory induction device 1 using the same can be applied to general anesthesia and oxygen supply of a patient during surgery, The breathing gas supplied through the breathing induction tube 300 according to the present invention may include an anesthetic gas or a respiratory gas such as oxygen. Hereinafter, an anesthetic gas or oxygen Respiratory gas "is described as" respiratory gas ".

2 is a view showing a configuration of a breathing induction device 1 according to the present invention. 2, the respiratory induction device 1 according to the present invention includes a respiration induction tube 300 and a respiratory controller 100. [

The respiration induction tube 300 is installed in the patient as shown in FIG. 2 to assist the respiration of the patient under anesthesia for surgery or a patient in the intensive care unit, which is difficult to self-breathe, It induces respiration of the patient through respiratory gas.

3 and 4 are views showing the configuration of the breathing-inducing tube 300 according to the first embodiment of the present invention. 3 and 4, a respiration induction tube 300 according to the present invention includes a distributor 330, a connection tube 340, an exhaust tube 320, suction portions 311 and 312, and a heating module 350, .

The distributor 330 is supplied with the respiratory gas sucked through the suction units 311 and 312 through the connection tube 340 and is supplied with the respiratory gas from the patient through the connection tube 340, The intake tubes 311 and 312 and the exhaust tube 320 are connected to each other so that the exhaust tube 320 is discharged through the exhaust tube 320.

Although the distributor 330 has a Y-shape including the connecting portion 331, the inlet 332 and the outlet 333, the connecting tube 340 and the suction portions 311 and 312 And the exhaust tube 320 are mutually connectable, the shape of the exhaust pipe 320 is not limited.

The connection tube 340 is connected to the connection portion 331 of the distributor 330 and connected to the patient side, as shown in Fig. That is, one side of the connecting tube is connected to the connecting portion 331 of the distributor 330, and the other side is connected to a breathing apparatus inserted or installed in the patient's mouth or nose, as shown in Fig.

Here, the breathing apparatus connected to the connection tube 340 may be provided in the form of a mask or a tube inserted into a patient's airway. In the present invention, the connection tube 340 and the breathing apparatus are separated from each other. However, a breathing apparatus, for example, a mask or airway insertion tube may be directly coupled to the connection unit 331 of the dispenser 330 have. That is, the connection tube 340 according to the present invention is defined as a concept including a breathing mechanism connectable to the connection portion 331 of the distributor 330.

One side of the exhaust tube 320 is connected to the exhaust port 333 of the distributor 330 and the other side is connected to the respiratory controller 100 to discharge the exhaust gas through the connection tube 340 and the exhaust port 333 of the distributor 330 The patient's breathing gas is exhausted.

In the present invention, it is assumed that the exhaust tube 320 is provided in a form detachable from the distributor 330 so that only the exhaust tube 320 can be disinfected or replaced. Here, as shown in Figs. 3 and 4, the exhaust tube 320 has a corrugated shape so as to be warped or to be easily stretched and stretched.

One side of the suction portions 311 and 312 is connected to the suction port 332 of the distributor 330 and the other side is connected to the respiratory controller 100 to provide respiratory gas to the patient through the distributor 330 and the connection tube 340 . Here, the suction units 311 and 312 according to the present invention may include a first suction tube 311 and a second suction tube 312.

3 and 4, the second suction tube 312 and the heating module 350 of the suction units 311 and 312 are provided in the present embodiment. In FIGS. 3 and 4, Temperature heating module 350 and three second suction tubes 312 are provided.

One side of the first suction tube 311 is connected to the suction port 332 of the distributor 330 and the other side is connected to the warming module 350. The heating module 350 connected to the other side of the first suction tube 311 is connected to the heating module 350 and the second suction tube 312 in order.

One side of the first suction tube 311 is connected to the suction port 332 of the distributor 330 and the other side of the first suction tube 311 is connected to the first connection portion 352 of the heating module 350, Lt; / RTI > One side of the first second suction tube 312 is connected to the second connection portion 353 of the warming module 350 and the other side of the first suction tube 312 is connected to the second connection portion 353 of the second warming module 350 And is connected to the first connection portion 352.

Likewise, one side of the second second suction tube 312 is connected to the second connection portion 353 of the second warming module 350, and the other side of the second suction tube 312 is connected to the third warming module 350 The first connection portion 352 of the second connector 352 is connected to the first connection portion 352 of the second connector 352. One side of the third second suction tube 312 is connected to the second connection portion 353 of the third warming module 350 and the other side of the third suction tube 312 is connected to the respiratory controller 100 So that the suction side of the suction units 311, 312 for sucking the breathing gas is completed.

Meanwhile, the heating module 350 heats the respiratory gas sucked through the suction units 311 and 312, that is, the first suction tube 311 and the second suction tube 312, so that the breathing gas flowing through the suction units 311 and 312 The temperature of the gas is kept constant.

Here, the first suction tube 311 and the second suction tube 312 are detachably connected to the heating module 350 as an example. Accordingly, when the heating module 350 needs to be replaced due to a failure or the like, only the corresponding heating module 350 can be used. Likewise, in the case of the first connection tube 340 and the second connection tube 340, when only one of them needs to be replaced due to contamination, tearing, or the like, only the corresponding portion can be replaced.

Further, the number of heating modules 350 can be changed as needed to increase or decrease the number of heating points on the suction portions 311 and 312, and the number of the heating modules 350 and the second suction tubes 312 can be increased Or by increasing the length of the second suction tube 312, the lengths of the suction portions 311 and 312 can be more easily varied.

The heating module 350 for heating the suction gas is not installed in the first suction tube 311 or the second suction tube 312 so that the structure of the suction units 311 and 312 is simplified, It is possible to replace only the heating module 350 without changing the first suction tube 311, the second suction tube 312 and the other heating module 350. [

Here, the connection tube 340 and the distributor 330, the first suction tube 311 and the distributor 330, and the exhaust tube 320 and the distributor 330 of the breathing induction tube 300 according to the present invention are both For example, disinfection, replacement, or the like.

5 is a diagram showing an example of the configuration of the heating module 350 according to the present invention. 5 (a) is a side view of the warming module 350, and FIG. 5 (b) is a front view of the warming module 350. FIG.

5, the heating module 350 according to the present invention may include a module body 351, a first connection portion 352, a second connection portion 353, and a heating member 354.

The module main body 351 has a tubular shape in which a hollow is formed along the connection direction of the first suction tube 311 and the second suction tube 312. The first connecting portion 352 and the second connecting portion 353 are disposed on both sides of the module main body 351 and on both sides of the module main body 351 in the connecting direction of the first suction tube 311 and the second suction tube 312 Respectively.

The first suction tube 311 or the second suction tube 312 is connected to the first connection part 352 and the second connection part 353 so that the heating module 350 is connected to the first suction tube 311 and the second suction tube 311. [ Between the suction tubes 312, or between the second suction tubes 312.

The heating member 354 is installed in the inner hollow of the module body 351 to heat the breathing gas. In the present invention, the heating member 354 is provided in the form of a heat line heated by a power source supplied from the outside, and the flow of the breathing gas through the hollow of the module body 351, as shown in FIG. 5 (b) For example, in the form of a filament.

The warming module 350 includes a power connector 355 that supplies power from the outside to the heating member 354 so that the heating member 354 is heated so that the power is supplied to the heating member 354 through the connection of the power cable to the power connector 355 Power can be supplied from the outside.

Hereinafter, the breathing-inducing tube 300a according to the second embodiment of the present invention will be described with reference to FIG. Here, in describing the breathing-inducing tube 300a according to the second embodiment of the present invention, components corresponding to the breathing-inducing tube 300 according to the first embodiment described above are described using the same reference numerals And description of the components corresponding to the first embodiment may be omitted.

Referring to FIG. 6, the breathing-inducing tube 300a according to the second embodiment of the present invention may include a moisture-blocking filter 370. FIG. The moisture barrier filter 370 is installed between the connection tube 340 and the distributor 330 to block the movement of moisture from the connection tube 340 to the distributor 330 side.

Accordingly, moisture released from the patient's body during the breathing of the patient is blocked by the moisture-blocking filter 370 from moving toward the distributor 330 and is maintained in the connection tube 340. When the patient breathe, the heating module 350 The respiratory gas introduced through the distributor 330 is humidified by moisture in the connection tube 340 and flows into the patient's body so that the warmed and humidified respiratory gas can flow into the patient's body.

In addition, moisture generated by the breathing of the patient is blocked by the moisture-blocking filter 370 to the side of the exhaust tube 320, or to the intake portion 311, 312 or the anesthetic gas, It is possible to eliminate problems such as contamination.

Meanwhile, the respiratory induction device 1 according to the present invention may include a temperature sensor 360, as shown in FIGS. 3, 4 and 6. The temperature sensor 360 is installed in the distributor 330 of the respiration induction tube 300 and senses the temperature of the respiratory gas flowing into the distributor 330 through the inlets 311 and 312 of the respiration induction tube 300.

Here, the respiratory controller 100 may control the heating module 350 so that the temperature of the respiratory gas flowing into the distributor 330 is maintained at the predetermined set temperature, based on the detection result of the temperature sensor 360. As a result, the temperature of the respiratory gas flowing into the patient can be maintained at a constant temperature level.

2, the respiratory controller 100 may include a temperature display unit 120 and a temperature control unit 110. [ The temperature display unit 120 displays the temperature sensed by the temperature sensor 360. The physician or the nurse can visually check the temperature of the respiratory gas flowing into the patient, thereby monitoring the current state.

In addition, the doctor or the nurse can control the temperature of the respiratory gas flowing into the patient according to the state of the patient by controlling the heating temperature of the heating module 350 by operating the temperature control unit 110.

In the above-described embodiment, the breathing-inducing tube 300 according to the present invention has three heating modules 350 and three second suction tubes 312 as shown in Figs. 3, 4 and 6 It is needless to say that the heating module 350 and the second suction tube 312 may be composed of one heating module 350 and a second suction tube 312, two or more heating modules 350 and a second suction tube 312.

Although several embodiments of the present invention have been shown and described, those skilled in the art will appreciate that various modifications may be made without departing from the principles and spirit of the invention . The scope of the invention will be determined by the appended claims and their equivalents.

1: respiratory induction device 100: respiratory controller
110: Temperature regulator 120: Temperature indicator
300, 300a: Breath tube
311: first suction tube 312: second suction tube
320: exhaust tube 330: distributor
331: Connector 332: Inlet
333: exhaust port 340: connecting tube
350: heating module 351: module body
352: first connection part 353: second connection part
354: Heating element 355: Power connector
360: temperature sensor 370: moisture barrier filter

Claims (10)

A respiration induction tube for assisting a respiration of a patient,
A distributor in which a connector, an inlet and an outlet are formed;
A connection tube connected to the connector of the dispenser and connected to the patient;
An exhaust tube connected to the exhaust port of the distributor to exhaust a respiratory gas of the patient;
A suction unit having a first suction tube, one side of which is connected to the suction port of the distributor, and a second suction tube;
The other end of the first suction tube is connected to one side and the second suction tube is connected to the other side to communicate the first suction tube and the second suction tube and the second suction tube and the first suction tube And a heating module for heating the breathing gas to be inhaled. The method according to claim 1,
The second suction tube and the warming module are provided in plural;
Wherein the heating module and the second suction tube are sequentially connected to each other. 3. The method of claim 2,
Wherein the first suction tube and the second suction tube are detachably coupled to the heating module. 3. The method of claim 2,
The heating module
A module main body having a hollow formed along a connecting direction of the first suction tube and the second suction tube;
A first connection part and a second connection part provided on both sides of the module main body in a connecting direction of the first suction tube and the second suction tube and connected to the first suction tube or the second suction tube;
And a heating member installed in an inner hollow of the module body to heat breathing gas. 5. The method of claim 4,
The heating module
Further comprising: a power connector for supplying external power to the heating member so that the heating member is heated. 6. The method of claim 5,
Wherein the heating member has a filament shape so that a breathing gas can flow through the hollow of the module body. The method according to claim 1,
Further comprising a moisture barrier filter disposed between the connection tube and the distributor to block the movement of moisture from the connection tube toward the distributor. A respiratory induction device for assisting a respiration of a patient,
A breathing induction tube according to any one of claims 1 to 7;
And a respiratory controller connected to the suction portion of the breathing induction tube and the exhaust tube to induce breathing of the patient through the suction portion and the exhaust tube. 9. The method of claim 8,
Further comprising: a temperature sensor installed in the dispenser of the breathing induction tube for sensing a temperature of respiratory gas flowing into the dispenser through the suction portion of the breathing induction tube;
Wherein the respiration controller controls the warming module so that the temperature of the respiratory gas flowing into the distributor is maintained at a predetermined set temperature based on the detection result of the temperature sensor. 10. The method of claim 9,
The respiratory controller
A temperature display unit for displaying a temperature sensed by the temperature sensor;
And a temperature controller controlling a heating temperature of the heating module according to an operation of the user.

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