KR102171489B1 - Nebulizer device with nebulizer and oxygen feeder - Google Patents

Abstract

The present invention relates to a nebulizer device provided with a nebulizer and an oxygen supply unit capable of using a nebulizer and an oxygen supply unit alone or together. The nebulizer device provided with the nebulizer and the oxygen supply unit according to the present invention provides air from the outside. A main body that is introduced and compresses air introduced through a compressor unit configured therein to generate compressed air; A nebulizer connected to the main body, through which compressed air flows from the main body through the connection, and sprays the stored chemical solution through the introduced compressed air; And an oxygen supply unit that stores oxygen, adjusts the stored oxygen concentration within the set oxygen concentration by introducing air from the outside, and supplies oxygen within the set oxygen concentration to the patient.

Description

Nebulizer device with nebulizer and oxygen feeder

The present invention relates to a nebulizer that can be used alone or in combination with a nebulizer and an oxygen supplier and a nebulizer device provided with an oxygen supplier.

In general, nebulizers are used to aerosolize chemicals used for respiratory diseases so that patients can easily drink them. Using ultrasonic energy, a nebulizer is an ultrasonic method that physically turns into fine particles or blows from a thin nozzle. The chemical liquid is aerosolized by using a method (Venturi-type, Barbington-type) that blows the chemical liquid sucked up by the jet stream at high speed and breaks it by hitting an object. In addition, by inhaling the particles of the chemical liquid configured in this way into the nose or mouth by the patient using a mouthpiece or helmet, the chemical liquid reaches the periphery of the patient's bronchi, thereby enabling rapid treatment of the disease.

Such a nebulizer generally refers to a device that makes a therapeutic drug into fine particles and delivers it to the treatment site to treat respiratory diseases such as asthma and bronchitis.In recent years, it is widely used in various fields such as skin beauty as well as medical use. have.

However, the use of such a nebulizer was limited, and in order to increase the effect, there was a problem in that a device for supplying oxygen by connecting a separate oxygen supply device must be separately provided.

On the other hand, the present applicant has applied for and has been registered as a prior art related to such a nebulizer, Korean Utility Model Registration No. 20-0486755,'nebulizer device'. The nebulizer device discloses a nebulizer device capable of simultaneously using an oxygen supply and a nebulizer function, or each of which can be used alone.

However, in the prior art ('nebulizer device') applied for and registered by the present applicant, each oxygen inlet must be formed for the oxygen supply function and the nebulizer function, and the configuration for the oxygen supply function and the nebulizer function must be formed. As it is integrated into the body, when the oxygen supply function or the nebulizer function is used alone, oxygen must be prevented from flowing into the oxygen inlet for functions that are not used. There is a problem that oxygen can be introduced into the and oxygen supply units respectively.

In addition, the prior art has a problem in that the configuration for treatment requiring heating and the configuration for controlling the inflow of oxygen (compressed air) flowing into the nebulizer are not disclosed.

Republic of Korea Utility Model No. 20-0486755,'Nebulizer device'

The present invention is to solve the above problems, the present invention is provided so that the nebulizer and the oxygen supply can be used alone or together, compressed air in the nebulizer without connection to a separate device or consumables, oxygen in the oxygen supply It is an object of the present invention to provide a nebulizer device capable of providing a heating function according to a patient's treatment method, controlling the inflow of compressed air flowing into the nebulizer, and controlling the oxygen concentration of the oxygen supplier.

On the other hand, the technical problem to be achieved in the present invention is not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. Can be.

As a technical means for achieving the above object, in the nebulizer device provided with the nebulizer and the oxygen supply device according to the present invention, air is introduced from the outside, and compressed air is generated by compressing the air introduced through the compressor unit configured therein. main body; A nebulizer connected to the main body, through which compressed air flows from the main body through the connection, and sprays the stored chemical solution through the introduced compressed air; And an oxygen supply unit that stores oxygen, adjusts the stored oxygen concentration within the set oxygen concentration by introducing air from the outside, and supplies oxygen within the set oxygen concentration to the patient.

And the main body is a power supply that is turned on / off by the patient; A power supply unit for supplying power to the compressor unit for generating compressed air or for blocking the supply of the power according to the on/off state of the power unit; A tubing part connected to the nebulizer to supply compressed air to the nebulizer; A first detachable portion having a groove shape formed on one side so that the nebulizer is detachable; A second detachable part having a protruding shape different from the first detachable part formed on the other side so that the oxygen supplier is detachable; A sensor unit configured to generate detection information by detecting whether the nebulizer is attached or detached and a connection state between the tubing unit and the nebulizer; And determining whether the nebulizer is attached or detached and the connection state between the tubing unit and the nebulizer through the sensing information generated from the sensor unit, and controls to stop the inflow of compressed air or compressed air into the nebulizer according to the determination result. It is configured to include;

Here, when the sensor unit detects that the nebulizer is detached from the first detachable unit and then reattached, or that the connection between the tubing unit and the nebulizer is disconnected or that the connection is defective, the sensor unit generates detection information based on the generated detection information. Controls to stop the inflow of compressed air or the inflow of compressed air into the riser.

Meanwhile, the oxygen supplier includes: an oxygen flow unit for outputting treatment information including a concentration of stored oxygen, a set oxygen concentration, and a time at which the stored oxygen is supplied; And a breathing unit having an oxygen inlet hole formed on one side to allow the inflow of stored oxygen, and having a valve therein to allow the flow of stored oxygen in only one direction.

This oxygen supplier is attached to and detached from the second detachable unit through the oxygen inlet hole.

In addition, the oxygen supply is an oxygen storage unit in which oxygen is stored therein, and an air inlet hole is formed so that the stored oxygen is introduced into the air inlet hole after being attached and detached to one side of the breathing unit, and external air is introduced in one side thereof. It is configured to include more.

At this time, the oxygen flow unit outputs treatment information when the oxygen supply unit is detached from the second detachable unit through the oxygen inlet hole and then the oxygen storage unit is attached to one side of the breathing unit.

Meanwhile, the main body includes an input unit for inputting input information including a treatment method and treatment time of the patient; An output unit for outputting treatment information including a treatment tool to be used according to a treatment method, treatment time, and treatment method when input information is input; And a heating unit for heating the tubing unit by applying heat to a heat source configured therein.

Meanwhile, when the treatment method included in the input information is a treatment method that requires heating, the controller supplies power to the heating unit and controls the heating unit to heat the tubing unit by applying heat to the heat source.

Meanwhile, the nebulizer includes a protrusion having a protruding shape that can be fitted into the first detachable part formed on one side so as to be detachable with the first detachable part.

According to the present invention, it is possible to control the compressed air flowing into the nebulizer through the compressor unit configured in the main body, and by adjusting the concentration of oxygen stored in the oxygen supply through external air, the nebulizer without connection to a separate device or consumables There is an advantage that the device can be used.

Further, according to the present invention, the heating unit heats the tubing unit by applying heat to the heat source according to the patient's treatment method, so that the patient can receive the treatment requiring heating through the nebulizer.

In addition, according to the present invention, by stopping the introduction of compressed air into the nebulizer at the end of the patient's treatment, it is possible to stop the operation of the nebulizer at the end of the patient's treatment.

Meanwhile, the effects obtainable in the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those of ordinary skill in the art from the following description. There will be.

1 is a perspective view of a nebulizer device provided with a nebulizer and an oxygen supplier according to the present invention.
2 is a partial perspective view of a main body in which first and second detachable parts are shown.
3 is a block diagram showing additional components of the main body not shown in FIGS. 1 and 2.
4 is a perspective view of a nebulizer showing components of the nebulizer.
5 is a diagram illustrating the use of an oxygen supplier showing the components of the oxygen supplier.
6 is a block diagram showing input information input to an input unit.
7 is a block diagram showing treatment information output from an output unit.
8 is a block diagram illustrating components of a sensor unit and sensing information of the sensor unit.
9 is a block diagram showing treatment information output from an oxygen flow unit.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The detailed description to be disclosed hereinafter together with the accompanying drawings is intended to describe exemplary embodiments of the present invention, and is not intended to represent the only embodiments in which the present invention may be practiced. The following detailed description includes specific details to provide a thorough understanding of the present invention. However, those of ordinary skill in the art to which the present invention pertains knows that the present invention may be practiced without these specific details. In addition, throughout the specification, when a part is said to "comprising or including" a certain component, this does not exclude other components, but may further include other components unless otherwise stated. Means that. In addition, when it is determined that detailed descriptions of known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

Configuration of the nebulizer device

1 is a perspective view of a nebulizer device provided with a nebulizer and an oxygen supply device according to the present invention, FIG. 2 is a partial perspective view of a main body showing first and second detachable parts, and FIG. 3 is not shown in FIGS. 1 and 2 It is a configuration block diagram showing additional components of the main body, Figure 4 is a perspective view of the nebulizer showing the components of the nebulizer, Figure 5 is an example of use of an oxygen supplier showing the components of the oxygen supply, Figure 6 is an input unit Fig. 7 is a block diagram showing the treatment information output from the output unit, Fig. 8 is a block diagram showing the configuration of the sensor unit and sensing information of the sensor unit, and Fig. 9 is It is a block diagram showing treatment information output from.

A nebulizer device equipped with a nebulizer and an oxygen supply device according to the present invention (hereinafter referred to as a'nebulizer device') is provided so that the nebulizer and the oxygen supply unit can be used alone or together, and connection with a separate device or consumables Provides a nebulizer device capable of supplying compressed air to the nebulizer and oxygen to the oxygen supply without, heating function according to the patient's treatment method, controlling the inflow of compressed air flowing into the nebulizer, and controlling the oxygen concentration of the oxygen supplier. It has its purpose.

When looking in detail with reference to FIG. 1, the nebulizer device 10 includes a main body 100 in which air is introduced from the outside and compresses the air introduced through the compressor unit 110 configured therein to generate compressed air, It is connected to the main body 100, and compressed air is introduced from the main body 100 through the connection, and the nebulizer 200 and oxygen for injecting the stored chemical solution through the introduced compressed air are stored, and air is introduced from the outside. It is configured to include an oxygen supplier 300 that adjusts the stored oxygen concentration within the set concentration and supplies oxygen within the set concentration to the patient.

First, the main body 100 will be described in detail with reference to Figs. 1 to 2, the power supply unit 105, the compressor unit 110, the tubing unit 115, the input unit 120, the output unit 125, and the detachable unit ( 130).

At this time, the power supply unit 105 is turned on/off when pressure is applied from the patient P or external pressure is applied. Here, the on/off of the power supply unit 105 is a criterion for the power supply unit 135 to be described later with reference to FIG. 3 to supply power to the compressor unit 110 or to cut off the supply of power.

The compressor unit 110 includes a compressor (not shown) inside the main body 100, and an air inlet 110-1 for introducing air from the outside and for discharging heat generated while generating compressed air. The heat discharge port (110-2) is formed.

Since the compressor (not shown) has the same configuration as a conventional compressor for generating compressed air, a detailed description of the compressor (not shown) will be omitted.

The air inlet 110-1 is configured with a filter inside so that air filtered from the outside is introduced. In this way, the filter is configured in the air inlet 110-1 to filter the air. The air introduced through the air inlet 110-1 is generated as compressed air through a compressor (not shown), so that the patient ( P) because it is inhaled through the nose or mouth.

It is preferable that the heat discharge port 110-2 is formed in plural as shown in the drawing in order to easily discharge heat generated from the compressor (not shown).

The tubing unit 115 is connected to the body 100 and the nebulizer 200, respectively, and supplies compressed air generated from a compressor (not shown) to the nebulizer 200 through these connections.

Referring to FIG. 6, which is a block diagram showing the input input information 120a and 120b, the input unit 120 includes input information including a treatment method 120a and a treatment time 120b of the patient P. Is entered. Here, the input information (120a, 120b) is preferably input by the patient (P) or by remote control.

Here, the treatment method 120a may mean a method of treating the upper respiratory tract including the nasal cavity, the pharynx, and the larynx, and a method of treating the lower respiratory tract including the trachea, bronchi, and lungs.

The output unit 125 will be described in detail with reference to FIG. 7, which is a block diagram showing the output treatment information 125a, 125b, and 125c. When the input information 120a, 120b is input to the input unit 120, the patient P ), treatment information 125a, 125b, and 125c including a treatment tool 125c to be used according to the treatment method 125a, treatment time 125b, and treatment method 125a are output. Here, the treatment tool 125c is preferably at least one of the nebulizer 200 and the oxygen supplier 300 of the present invention.

The detachable part 130 includes a first detachable part 130a for attaching and detaching the nebulizer 200 and a second detachable part 130b for attaching and attaching the oxygen supplier 300.

Here, the first detachable part 130a is formed in a groove shape on one side of the main body 100, and the second detachable part 130b is formed in a protruding shape on the other side of the main body 100.

Further, the main body 100 will be described in detail with reference to FIG. 3 showing additional components of the main body, the power supply unit 105, the compressor unit 110, the tubing unit 115, and The input unit 120, the output unit 125, and the detachable unit 130, as well as a power supply unit 135, a heating unit 140, a sensor unit 145, and a control unit 150 are further included.

The power supply unit 135 supplies power for the compressor (not shown) to generate compressed air or cuts off the supply of power according to the on/off state of the power supply unit 105. Through this power supply unit 135, the nebulizer 200 causes the compressed air generated by the compressor (not shown) together with the chemical solution to be sucked into the nose or mouth of the patient P, or stops the injection of compressed air.

The heating unit 140 heats the tubing unit 115 by applying heat to a heat source (not shown) configured therein. In addition, it is preferable that the heating unit 140 be positioned as close as possible to the tubing unit 115 inside or outside the main body 100 in order to easily heat the tubing unit 115. In addition, it is preferable that a heat source (not shown) is also located close to the tubing unit 115.

The sensor unit 145 detects whether the nebulizer 200 is attached or detached to the first detachable unit 130a by referring to Fig. 8, which is a block diagram showing the components and detection information 145a and 145b. A first sensor unit 145-1 generating first sensing information 145a and a second sensor generating second sensing information 145b by detecting a connection state between the tubing unit 115 and the nebulizer 200 It consists of a part 145-2.

It is preferable that the first sensor unit 145-1 is configured in the nebulizer 200 or the first detachable unit 130a to generate the first detection information 145a.

The second sensor unit 145-2 is at the end of the tubing unit 115 connected to the nebulizer 200 or at the connection between the main body 100 and the tubing unit 115 to generate second detection information 145b. It would be desirable to be configured.

On the other hand, the sensor unit 145 has been described as belonging to the components of the main body 100, but may be configured not only in the main body 100 but also in the oxygen supplier 300. For a specific example, a sensor unit (not shown) for detecting whether the concentration of oxygen stored in the oxygen storage unit 330 to be described later is within a set oxygen concentration may be configured. Such a sensor unit (not shown) may generate sensing information (not shown) by detecting the concentration of oxygen stored in the oxygen storage unit 330.

The control unit 150 determines whether or not the nebulizer 200 is attached or detached through the first detection information 145a generated from the first sensor unit 145-1, and compresses it in the nebulizer 200 according to the determination result. Controls to stop air inflow or inflow of compressed air. For a specific example, when the nebulizer 200 is detached from the first detachable unit 130a, the control unit 150 may nebulize based on the first detection information 145a generated from the first sensor unit 145-1. Controls the inflow of compressed air into the riser 200. In contrast, when the detached nebulizer 200 is attached to the first detachable unit 130a, the detachable nebulizer 200 is based on the first detection information 145a generated from the first sensor unit 145-1. ) To stop the inflow of compressed air.

And the control unit 150 determines the connection state between the tubing unit 115 and the nebulizer 200 through the second detection information 145b generated from the second sensor unit 145-2, and according to the result of the determination. Controls to stop the inflow of compressed air or the inflow of compressed air into the nebulizer 200. For a specific example, after the nebulizer 200 is detached from the first detachable unit 130a, while the second sensing information 145b is not generated from the second sensor unit 145-2, It controls the compressed air to flow into the nebulizer 200. In contrast, when the second sensor unit 145-2 detects that the connection between the tubing unit 115 and the detached nebulizer 200 is disconnected or is defective, and generates the generated second detection information 145b, nebulizer Control to stop the inflow of compressed air into the riser 200.

In order to control the inflow of compressed air or stop the inflow of compressed air into the nebulizer 200, the control unit 150 is a result of a determination based on the first detection information 145a and the second detection information 145b. It would be desirable to control the compressor (not shown) according to.

Furthermore, the control unit 150 determines whether the treatment method 120a of the patient P input to the input unit 120 is a treatment method requiring heating, and power is supplied to the heating unit 140 according to the result of the determination. Thus, the tubing unit 115 is controlled to be heated. For a specific example, if the control unit 150 determines that the treatment method 120a of the patient P is a treatment method requiring heating, the heating unit 140 supplies power to the heating unit 140 so that the heating unit 140 is a heat source (not shown). ) Is controlled to heat the tubing unit 115. In contrast, if it is determined that the treatment method 120a of the patient P is not a treatment method requiring heating, the process of supplying power to the heating unit 140 is omitted.

On the other hand, the control unit 150 has been described as belonging to the constituent elements of the main body 100, but may be configured not only in the main body 100 but also in the oxygen supplier 300. Through this, it is determined whether the concentration of oxygen stored in the oxygen storage unit 330 to be described later is within the set oxygen concentration through the detection information (not shown) generated from the above-described sensor unit (not shown), and the result of the determination Depending on the air inlet 332 to be described later can be controlled to open or close. For a specific example, if the concentration of oxygen stored in the oxygen storage unit 330 to be described later is an oxygen concentration within the set oxygen concentration, the control unit (not shown) configured in the oxygen supply unit 300 may open an air inlet hole 332 to be described later. It can be controlled to keep the concentration of oxygen closed. In contrast, if the oxygen concentration is an oxygen concentration that exceeds the set oxygen concentration, external air may be introduced through the opening of the air inlet hole 332 to be described later, thereby controlling the oxygen concentration.

If the nebulizer 200 looks specifically with reference to FIG. 4 showing the components, it is connected to the tubing unit 115 and the compressed air generated from the compressor (not shown) is introduced, and the chemical solution together with the introduced compressed air (P) should be inhaled into the eyes or mouth.

Such a nebulizer 200 is a method of physically making fine particles using ultrasonic energy, or a method in which a chemical liquid sucked up by a jet stream blown from a thin nozzle is blown out at high speed to hit an object and break it (Venturi type, Bobington type) ), you can choose any of them.

In addition, although not shown in the drawing, the nebulizer 200 may include an air compressor connected to a front end, and a solution container connected to a discharge port of the air compressor, a nozzle part, and a connector connecting the solution container and the nozzle part.

At this time, the solution container is installed inside the outer cylinder and the outer cylinder, and may include a ventilation pipe connected to the connection hose so as to communicate with the discharge port of the air compressor, and the ventilation pipe is integrally formed inside the outer cylinder to be formed between the inner wall of the outer cylinder and the outer peripheral surface of the ventilation pipe. A space portion of a predetermined volume in which the solution is stored may be formed. In the space portion, for example, a solution or moisture containing beneficial nutrients such as vitamins may be selectively stored. The ventilation pipe may take a nozzle shape in which the width of the pipe passage becomes narrower toward the top so as to generate a predetermined injection pressure.

Furthermore, the nebulizer 200 includes a protruding portion 210 having a protruding shape that can be fitted into a groove shape of the first detachable portion 130a on one side. Through this protrusion 210, the nebulizer 200 is detachable from the first detachable part 130a. In addition, the patient P can easily attach and detach the nebulizer 200 from the first detachable part 130a.

The oxygen supplier 300 is configured to include a breathing unit 310, a hook unit 320, an oxygen storage unit 330, and an oxygen flow unit 340 when looking specifically with reference to FIG. 5 showing the components.

Meanwhile, the oxygen supplier 300 may include a sensor unit (not shown) and a control unit (not shown), as described above.

The breathing unit 310 has an oxygen inlet hole formed on one side to allow the inflow of oxygen, and a valve is formed therein to allow the flow of oxygen in only one direction. The breathing unit 310 may open or close the oxygen inlet hole so as to block the inflow or inflow of oxygen stored in the oxygen storage unit 330. It is preferable that the sensor unit (not shown) and the control unit (not shown) open or close the oxygen inlet hole.

And the oxygen supplier 300 is attached to and detached from the second detachable unit (130b) through the oxygen inlet hole of the breathing unit (310). To this end, the second detachable portion 130b is formed in a protruding shape in which the oxygen inlet hole is detachable.

The hook part 320 is configured so that the oxygen supply device 300 is caught on the head of the patient P, so that the breathing part 310 covers the nose and mouth of the patient P.

The oxygen storage unit 330 is detachable to one side of the breathing unit 310. For a specific example, after the oxygen supplier 300 is detached from the second detachable unit 130b, it may be attached to one side of the breathing unit 310. And as the oxygen storage unit 330 is attached to one side of the breathing unit 310, the oxygen inlet hole of the breathing unit 310 is located inside the storage space 331, and the storage space 331 has a patient (P) Oxygen to be inhaled in your nose or mouth is stored. Accordingly, the oxygen storage unit 330 can allow oxygen stored in the storage space 331 to flow into the oxygen inlet hole of the breathing unit 310. In addition, the oxygen storage unit 330 is formed with an air inlet hole 332 capable of blocking the inflow of external air or the inflow of external air at one side. The oxygen storage unit 330 can adjust the concentration of oxygen stored in the storage space 331 by introducing external air through the air inlet hole 332. Meanwhile, the air inlet hole 332 may be opened or closed to block the inflow of outside air or the inflow of outside air. It is preferable that the sensor unit (not shown) and the control unit (not shown) open or close the air inlet hole 332.

The oxygen flow rate unit 340 is configured on the outside of the oxygen storage unit 330 and is stored in the storage space 331 when looking specifically with reference to FIGS. 5 and 9, the concentration of oxygen 340a and the patient P Treatment information including a set oxygen concentration 340b to be supplied to the patient and a time 340c to be supplied with oxygen stored in the storage space 331 is output.

After the oxygen flow unit 340 is detached from the second detachable unit 130b through the oxygen inlet hole of the breathing unit 310, the oxygen storage unit 330 is When attached to one side, treatment information 340a, 340b, 340c is output. At this time, when the sensor unit (not shown) detects that the oxygen storage unit 330 is attached to one side of the breathing unit 310 and generates detection information (not shown), the control unit (not shown) provides the detection information (not shown). ) May be determined and the treatment information 340a, 340b, and 340c may be output from the oxygen flow unit 340.

The above description of the present invention is for illustrative purposes only, and those of ordinary skill in the art to which the present invention pertains will be able to understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

10: a nebulizer device provided with a nebulizer and an oxygen supplier,
100: main body,
105: power supply,
110: compressor unit,
110-1: air inlet,
110-2: hot air outlet,
115: tubing part,
120: input unit,
120a: treatment modality,
120b: treatment time,
125: output,
125a: treatment modality,
125b: treatment time,
130: detachable part,
130a: first detachable part,
130b: second detachable portion,
135: power supply,
140: heating unit,
145: sensor unit,
145-1: first sensor unit,
145-2: second sensor unit,
145a: first detection information,
145b: second detection information,
150: control unit,
200: nebulizer,
210: protrusion,
300: oxygen supplier,
310: respiratory part,
320: hook,
330: oxygen storage unit,
331: storage space,
332: air inlet,
340: oxygen flow unit,
340a: stored oxygen concentration,
340b: set oxygen concentration,
340c: oxygen supply time,
P: Patient.

Claims (10)

A main body in which air is introduced from the outside and generates compressed air by compressing the introduced air through a compressor unit configured therein;
A nebulizer connected to the main body, through which the compressed air flows from the main body through the connection, and sprays a stored chemical liquid through the introduced compressed air; And
Including; oxygen is stored, an oxygen supply unit for introducing air from the outside to adjust the stored oxygen concentration within a set oxygen concentration, and supplying oxygen within the set oxygen concentration to the patient, and
The main body,
A power supply that is turned on/off by the patient;
A power supply unit configured to supply power for the compressor unit to generate the compressed air or to cut off the supply of the power according to the on/off state of the power unit;
A tubing part connected to the nebulizer to supply the compressed air to the nebulizer;
A first detachable portion having a groove shape formed on one side so that the nebulizer is detachable;
A second detachable part having a different protruding shape from the first detachable part formed on the other side so that the oxygen supplier is detachable;
A sensor unit for generating detection information by detecting whether the nebulizer is attached or detached and a connection state between the tubing unit and the nebulizer; And
It is determined whether the nebulizer is attached or detached and a connection state between the tubing unit and the nebulizer through the sensing information generated from the sensor unit, and the compressed air flows into the nebulizer or the compressed air according to the determination result. Includes; a control unit for controlling to stop the inflow of,
The oxygen supplier,
An oxygen flow unit for outputting treatment information including the stored oxygen concentration, the set oxygen concentration, and the stored oxygen supply time; And
Including; an oxygen inlet hole is formed at one side to allow the inflow of the stored oxygen, and a breathing unit configured to have a valve therein to allow the flow of the stored oxygen in only one direction; and
The oxygen supplier,
It is attached and detached from the second detachable part through the oxygen inlet hole,
The oxygen supplier,
It is detachably attached to one side of the breathing part, and when attached to one side of the breathing part, the oxygen inlet hole is located inside the storage space, and the oxygen to be inhaled by the patient is stored in the storage space, and external air is introduced or An air inlet hole for blocking is formed, and an oxygen storage unit in which the air inlet hole is opened or closed by the sensor unit and the control unit for inflow or blocking of the external air; and
The main body,
An input unit for inputting input information including the treatment method and treatment time of the patient;
An output unit for outputting treatment information including a treatment tool to be used according to the treatment method, the treatment time, and the treatment method when the input information is input; And
A heating unit for heating the tubing unit by applying heat to a heat source configured therein; further comprising,
The control unit,
If the concentration of oxygen stored in the oxygen storage unit through the sensor unit is an oxygen concentration within the set oxygen concentration, the air inlet is closed to maintain the concentration of oxygen stored in the oxygen storage unit,
When the concentration of oxygen stored in the oxygen storage unit through the sensor unit is an oxygen concentration that exceeds the set oxygen concentration, the air inlet hole is opened to introduce external air to the oxygen storage unit, thereby storing oxygen A nebulizer device provided with a nebulizer and an oxygen supplier, characterized in that adjusting the concentration of. delete The method of claim 1,
The control unit,
When the sensor unit detects that the nebulizer is detached from the first detachable unit and then reattached or that the connection between the tubing unit and the nebulizer is disconnected or has a poor connection to generate sensing information, based on the generated sensing information A nebulizer device comprising a nebulizer and an oxygen supply device, characterized in that controlling to stop the inflow of the compressed air or the inflow of the compressed air into the nebulizer. delete delete delete The method of claim 1,
The oxygen flow unit,
After the oxygen supply is detached from the second detachable unit through the oxygen inlet hole, when the oxygen storage unit is attached to one side of the breathing unit, a nebulizer and an oxygen supply unit, characterized in that to output the treatment information, are provided. Nebulizer device. delete The method of claim 1,
The control unit,
When the treatment method included in the input information is a treatment method requiring heating, the power is supplied to the heating unit to control the heating unit to heat the tubing unit by applying heat to the heat source. And a nebulizer device provided with an oxygen supplier. The method of claim 1,
The nebulizer,
A nebulizer device comprising: a protrusion having a protruding shape that can be fitted to the first detachable part formed on one side so as to be detachable from the first detachable part.

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