KR102617294B1 - Medicine nebulizer, medicine treatment system having the same, and medicine treatment method using the same - Google Patents

Abstract

The present invention relates to a drug nebulizer, a drug treatment system including the same, and a drug treatment method using the same. In more detail, the amount of drug inhaled by the patient can be visually confirmed, and the noise of the motor is alleviated with music to control the patient's health. It relates to a drug nebulizer that can reduce stress and resistance to treatment, a drug treatment system including the same, and a drug treatment method using the same.
The present invention relates to a drug nebulizer 100 of a drug treatment system including a main body 200 that generates compressed air and a drug nebulizer 100 that sprays a drug with the compressed air generated from the main body 200. , the drug nebulizer 100 includes a drug storage portion 110 in which a container for storing the drug is formed; An air delivery tube 120 connected to the main body 200 and the drug storage unit 110 and delivering compressed air generated from the main body 200 to the drug storage unit 110; Combined with the drug storage unit 110, the drug delivery unit 130 delivers the drug sprayed from the drug storage unit 110 to the patient's respiratory tract and measures the patient's breathing using the air introduced by the patient's breathing. Disclosed is a drug nebulizer (100), characterized in that it includes a respiration measuring unit (140).

Description

Drug nebulizer, drug treatment system including the same, and drug treatment method using the same {Medicine nebulizer, medicine treatment system having the same, and medicine treatment method using the same}

The present invention relates to a drug nebulizer, a drug treatment system including the same, and a drug treatment method using the same. In more detail, the amount of drug inhaled by the patient can be visually confirmed, and the noise of the motor is alleviated with music to control the patient's health. It relates to a drug nebulizer that can reduce stress and resistance to treatment, a drug treatment system including the same, and a drug treatment method using the same.

A drug nebulizer, such as a nebulizer, is a drug treatment system used for patients with diseases such as asthma, emphysema, and chronic bronchitis. It uses compressed air to inhale the nebulized drug into the patient's nose or mouth to deliver the drug to the patient's trachea and bronchi. It plays a role in treating diseases by reaching the lungs.

However, because these drug nebulizers spray the drug regardless of the patient's breathing timing, there was a difficulty in measuring the patient's exact drug inhalation amount.

In addition, since drug nebulizers use compressed air to spray drugs, a compressor motor is used to generate compressed air, and at this time, noise from the motor is generated, causing the patient to feel stress during the treatment process.

In particular, in the case of infant patients, treatment was difficult because they were startled by the noise of the compressor motor and refused respiratory treatment, and caregivers complained of guilt, anxiety, and fatigue from caring for the patient.
(Patent Document 1) WO 2019-236896 A1

In order to solve the above problems, the present invention provides a drug nebulizer that can visually confirm the amount of drug inhaled by the patient and reduces the patient's resistance to treatment by converting the noise caused by the motor drive into music, including the same. Provides a drug treatment system and a drug treatment method using the same.

The present invention was created to achieve the object of the present invention as described above, and the present invention includes a main body 200 that generates compressed air, and a drug that sprays the drug with compressed air generated from the main body 200. In the drug nebulizer 100 of the drug treatment system including the nebulizer 100, the drug nebulizer 100 includes a drug storage portion 110 in which a container for storing the drug is formed; An air delivery tube 120 connected to the main body 200 and the drug storage unit 110 and delivering compressed air generated from the main body 200 to the drug storage unit 110; A drug delivery unit 130 that is coupled to the drug storage unit 110 and delivers the drug sprayed from the drug storage unit 110 to the patient's respiratory tract; Disclosed is a drug nebulizer (100) that includes a respiration measurement unit (140) that measures the patient's respiration using air introduced by the patient's breathing.

The drug delivery unit 130 includes a vertical portion 131-1 coupled to the drug storage portion 110, and a horizontal portion extending in a direction perpendicular to the vertical portion 131-1 and open at both ends ( A cylinder portion 131 including 131-2); a respiratory contact portion 132 that is inserted into one end of the horizontal portion 131-2 and is in direct or indirect contact with the patient's respiratory tract; It includes a drug delivery unit 130 including a stopper 133 fitted to open and close the other end of the horizontal portion 131-2; The respiration measuring unit 140 may be installed inside the horizontal portion 131-2.

The respiration measuring unit 140 includes one or more rotary wings 141 that rotate according to the patient's breathing; a rotating shaft 142 that supports the one or more rotating blades and whose both ends are fixed through the horizontal portion 131-2; It may include a rotation sensor unit 143 that is connected to one end of the rotation shaft 142 and measures rotation information of the rotation shaft 142.

The respiration measuring unit 140 may be installed inside the drug delivery unit 130.

In addition, the present invention relates to a drug treatment system including the above-described drug nebulizer 100, wherein the drug treatment system includes a drug intake amount deriving unit 300 for outputting the drug intake amount through the patient's breathing information, ; The drug intake amount deriving unit 300 includes a respiration information conversion unit 310 that converts the signal received from the respiration measurement unit 140 into respiration information; a display unit 330 that visually shows the patient's drug intake amount; A breathing information control unit 320 that obtains the patient's breathing information from the breathing information conversion unit 310, derives the patient's drug intake amount based on the obtained patient's breathing information, and transmits it to the display unit 330. It can be included.

The breathing information may be at least one of the patient's respiratory rate, the patient's respiratory pressure, the patient's respiratory flow, the patient's expiratory volume, the patient's inspiratory volume, the patient's expiration time, the patient's inhalation time, and the patient's exhalation and inhalation interval. there is.

The respiratory information control unit 320 controls at least one of the patient's respiratory information, the compressed air pressure of the main body 200, the size and volume of the drug nebulizer 100, the amount of drug, and the drug injection speed and time. Taking this into account, the amount of drug inhaled by the patient can be derived.

The display unit 330 may output the patient's inhalation curve and exhalation curve and a drug intake curve corresponding to the inhalation curve and exhalation curve.

The drug treatment system includes a noise sensor 400 that measures noise generated when the motor is driven; It includes a noise mitigation unit 500 for purifying the noise detected through the noise sensor 400 into music; The noise mitigation unit 500 includes a noise information conversion unit 510 that converts the noise detected by the noise sensor 400 into noise information; an audio output unit 530 that outputs music; It may include a sound control unit 520 that controls the sound output unit 530 to output music based on the noise information provided from the noise information conversion unit 510.

The noise information may be decibels of motor noise.

The sound control unit 520 may control the sound output unit 530 so that the music output from the sound output unit 530 is output at a decibel higher than the decibel of the motor noise.

Additionally, the present invention discloses a drug treatment method for performing respiratory treatment for a patient, which is performed using the drug treatment system described above.

The present invention has the advantage of aiding in patient treatment by visually showing the amount of drug inhaled by the patient through the drug inhalation amount derivation unit, thereby visually providing the patient, guardian, and medical staff with how much of the drug has been applied to the patient. .

In addition, the present invention has the advantage of reducing the patient's stress and the patient's resistance to treatment by converting the noise of the motor into music through the noise mitigation unit.

In addition, the present invention has the advantage of reducing the fatigue of guardians and medical staff by reducing the patient's resistance to treatment and improving the treatment effect of the patient.

1 is a perspective view showing a drug treatment system according to the present invention.
Figure 2a is a cross-sectional view of the drug nebulizer, and is a side cross-sectional view showing the rotation of the respiration measurement unit when the patient inhales.
Figure 2b is a cross-sectional view of the drug nebulizer, and is a side cross-sectional view showing the rotation of the respiration measurement unit when the patient exhales.
Figure 3 is a cross-sectional view taken in the direction I-I of Figure 2a, showing the front of the respiration measuring unit.
Figure 4 is a conceptual diagram showing the drug intake amount derivation unit according to the present invention.
Figure 5 is a conceptual diagram showing a noise mitigation unit according to the present invention.

Hereinafter, the drug nebulizer according to the present invention, the drug treatment system including the same, and the drug treatment method using the same will be described with reference to the drawings.

The present invention relates to a drug nebulizer 100 of a drug treatment system including a main body 200 that generates compressed air and a drug nebulizer 100 that sprays a drug with the compressed air generated from the main body 200. , the drug nebulizer 100 includes a drug storage portion 110 in which a container in which the drug is stored is formed; An air delivery tube 120 connected to the main body 200 and the drug storage unit 110 and delivering compressed air generated from the main body 200 to the drug storage unit 110; A drug delivery unit 130 that is coupled to the drug storage unit 110 and delivers the drug sprayed from the drug storage unit 110 to the patient's respiratory tract; Disclosed is a drug nebulizer (100) that includes a respiration measurement unit (140) that measures the patient's respiration using air introduced by the patient's breathing.

Here, the main body 200 is a component that generates compressed air, and various configurations are possible.

The main body 200 may include various motors to generate compressed air, for example, a compressor motor.

Meanwhile, the drug nebulizer 100 is a device that helps respiratory treatment by spraying the drug with compressed air generated from the main body 200 and providing it to the patient's respiratory tract. It can be configured in various ways, such as a nebulizer. .

Here, the drug nebulizer 100 includes a drug storage portion 110 in which a container for storing the drug is formed; An air delivery tube 120 connected to the main body 200 and the drug storage unit 110 and delivering compressed air generated from the main body 200 to the drug storage unit 110; A drug delivery unit 130 that is coupled to the drug storage unit 110 and delivers the drug sprayed from the drug storage unit 110 by compressed air to the patient's respiratory tract; It may include a respiration measurement unit 140 that measures the patient's breathing using air introduced by the patient's breathing.

The drug storage unit 110 is a container in which drugs are stored, and various configurations are possible.

Here, the drug storage unit 110 can accommodate various drugs for respiratory treatment such as asthma, pneumonia, and bronchiolitis, as shown in FIGS. 2A to 2B, and may include inflammation regulators and symptom relievers. Of course.

The shape of the drug storage unit 110 may have various shapes and may be made of various materials such as synthetic resin and ceramic.

The air delivery tube 120 is connected to the main body 200 and the drug storage unit 110 and transmits compressed air generated from the main body 200 to the drug storage unit 110. , various configurations are possible.

Specifically, the air delivery tube 120 delivers compressed air generated by the motor of the main body 200 to the drug storage unit 110, thereby converting the drug stored in the drug storage unit 110 into a fine aerosol. You can make it.

Here, the air delivery tube 120 may be made of various materials, for example, may include materials such as rubber and silicon.

The drug delivery unit 130 is combined with the drug storage unit 110 to deliver the drug sprayed from the drug storage unit 110 by compressed air to the patient's respiratory tract. Various configurations are possible. .

Of course, the drug delivery unit 130 may be made of various materials, for example, synthetic resin such as silicone or plastic.

Specifically, the drug delivery unit 130 has a vertical portion 131-1 coupled to the drug storage portion 110, extends in a direction perpendicular to the vertical portion 131-1, and has both ends open. a cylinder portion 131 including a horizontal portion 131-2; a respiratory contact portion 132 that is inserted into one end of the horizontal portion 131-2 and is in direct or indirect contact with the patient's respiratory tract; It may include a drug delivery unit 130 including a stopper 133 that is fitted to open and close the other end of the horizontal portion 131-2.

The cylinder portion 131 is a component that delivers drugs to the patient's respiratory tract and can have various configurations.

Here, the cylinder portion 131 may have various shapes, such as cylindrical or rectangular, and may have a 'T'-shaped structure including a vertical portion 131-1 and a horizontal portion 131-2.

The vertical portion 131-1 is coupled to the drug storage portion 110, as shown in FIGS. 2A and 2B, and various configurations are possible.

Here, the vertical portion 131-1 may be formed integrally with the drug storage portion 110, or may be formed separately and coupled to the drug storage portion 110 in various ways, such as by fitting.

The horizontal portion 131-2 extends in a direction perpendicular to the vertical portion 131-1 and has both ends open, and various configurations are possible.

As shown in FIGS. 2A and 2B, the horizontal portion 131-2 may extend in any direction, such as a horizontal direction or a transverse direction, as well as a direction perpendicular to the vertical portion 131-1. am.

The respiratory contact part 132 is inserted into one end of the horizontal part 131-2 and is in direct or indirect contact with the patient's respiratory tract, and various configurations are possible.

For example, as shown in FIGS. 1 to 2B, the respiratory contact part 132 is formed with a mouthpiece on one side of the drug delivery part 130 that the patient can bite into. It can come into direct contact with the patient's mouth, or indirectly contact the patient's respiratory system as a mask is formed on one side to cover the patient's mouth and nose.

In addition, of course, the respiratory contact part 132 can be detachably coupled to the horizontal part 131-2.

The stopper 133 is a component that is fitted to open and close the other end of the horizontal portion 131-2, and various configurations are possible.

The stopper portion 133 may be inserted into the other end of the horizontal portion 131-2, as shown in FIGS. 2A to 2B, and may be detachably coupled to the cylinder portion 131. Of course it exists.

Meanwhile, during respiratory treatment using a conventional nebulizer, the drug sprayed with the nebulizer is administered only while the patient inhales, while the nebulizer continuously sprays the drug regardless of the patient's breathing timing, so the patient's exact drug is administered. There is a difficulty in measuring the intake amount.

In other words, the drug that is not inhaled when the patient exhales is discharged into the atmosphere in front of the patient, and due to this loss of drug, there is a problem in that it is not possible to accurately measure how much drug the patient has inhaled.

In order to solve the above problems, the present invention additionally includes a respiration measuring unit 140 in the drug nebulizer 100 that measures the patient's breathing and provides more accurately the amount of drug inhaled by the patient.

The respiration measuring unit 140 is a component that measures the patient's respiration using air introduced by the patient's respiration, and various configurations are possible.

At this time, the respiration measuring unit 140 may be installed at any location where air flows due to the patient's respiration in order to use the air introduced through the patient's respiration, but in order to ensure structural stability and effectively transmit the air flow, As shown in Figure 3, it may be installed inside the horizontal portion 131-2 of the cylinder portion 131.

For example, the respiration measuring unit 140 includes one or more rotary wings 141 that rotate according to the patient's breathing; a rotating shaft 142 that supports the one or more rotating blades and whose both ends are fixed through the horizontal portion 131-2; It may include a rotation sensor unit 143 that is connected to one end of the rotation shaft 142 and measures rotation information of the rotation shaft 142.

Here, the rotary blade unit 141 is a component that rotates due to the patient's breathing, and various configurations are possible.

Here, the rotary blade unit 141 is rotated by the patient's inhalation or exhalation, and can be rotated in opposite directions by air generated by the patient's inhalation and exhalation.

The rotating blade portion 141 may have various shapes, and may be formed in a plate shape, rod shape, etc.

In addition, the rotating blade parts 141 may have one or more different numbers, and of course, may be made of various materials such as silicon, synthetic resin, and ceramic.

Here, the rotating shaft 142 supports the one or more rotating blades and is fixed at both ends by penetrating the horizontal portion 131-2, and various configurations are possible.

As shown in FIGS. 2A to 3, the rotation shaft 142 may be fixedly installed through the cylinder portion 131, but is not limited thereto, and may be installed anywhere where air flows due to the patient's breathing. It can be.

The rotation axis 142 may have various shapes and, of course, may be made of various materials such as metal, plastic, and ceramic.

Here, the rotation sensor unit 143 is connected to one end of the rotation shaft 142 and measures rotation information of the rotation shaft 142, and various configurations are possible.

Here, the rotation information of the rotation shaft 142 may include various information related to rotation, such as the number of rotations of the rotation shaft, the direction of rotation, and the rotation speed, and this may be transmitted to the breathing information conversion unit 310, which will be described later.

Moreover, the respiration measurement unit 140 includes a resistor used in a lung examination device, using the pressure difference between both ends of the resistor, using the temperature difference between exhalation and inspiration including an electric heating wire, or using a sound transmission device. By installing it, you can also obtain breathing information using the height and volume difference in sound during exhalation and inspiration.

Meanwhile, a drug intake amount deriving unit 300 may be included to obtain the drug intake amount through the patient's breathing information obtained from the respiration measurement unit 140.

As shown in FIG. 4, the drug inhalation amount deriving unit 300 includes a respiration information conversion unit 310 that converts the signal received from the respiration measurement unit 140 into respiration information; a display unit 330 that visually shows the patient's drug intake amount; A breathing information control unit 320 that obtains the patient's breathing information from the breathing information conversion unit 310, derives the patient's drug intake amount based on the obtained patient's breathing information, and transmits it to the display unit 330. It can be included.

At this time, the drug intake amount deriving unit 300 includes a memory unit capable of storing breathing information and rotation information, a communication unit capable of wirelessly/wiredly communicating with the rotation sensor unit 143 and the display unit 330, etc. Of course, it can be included.

Here, zigbee, Bluetooth, XBee, Wifi, etc. may be used for the wireless communication.

The respiration information conversion unit 310 is a component that converts the signal received from the respiration measurement unit 140 into respiration information, and various configurations are possible.

Specifically, the breathing information conversion unit 310 can convert information such as the number of rotations, direction of rotation, and rotation speed of the rotation axis from the rotation sensor unit 143 into the patient's breathing information.

For example, the respiratory information conversion unit 310 can derive the respiratory flow rate by multiplying the rotation speed and rotation time of the rotation shaft using the principle of a flow meter, and the rotation direction is clockwise through the rotation direction. In this case, it can be deduced that it is an expiratory state, and in the case of counterclockwise, it can be derived that it is an inspiratory state.

Here, the patient's breathing information may be various information related to the patient's breathing, such as the patient's respiratory rate, the patient's respiratory pressure, the patient's respiratory flow, the patient's expiration time, the patient's inhalation time, and the patient's exhalation and inhalation interval.

The display unit 330 is a component that visually displays the amount of drug inhaled by the patient, and can have various configurations.

Here, the display unit 330 may include one or more display devices such as a computer monitor or a smartphone to visually show the patient's drug intake amount, and the display unit 330 is fixed to the drug treatment system or , can be installed movably.

In addition, the display unit 330 outputs the patient's inhalation curve and exhalation curve and the drug inhalation amount curve corresponding to the inhalation curve and exhalation curve as an image to visually show the patient's drug intake amount to the patient, guardian, and medical staff. can do.

Here, the breathing information control unit 320 obtains the patient's breathing information from the breathing information conversion unit 310, derives the patient's drug intake amount based on the obtained patient's breathing information, and displays the patient's drug intake amount on the display unit 330. As a transmission configuration, various configurations are possible.

Specifically, the breathing information control unit 320 is configured to at least one of the patient's breathing information, the compressed air pressure of the main body 200, the size and volume of the drug nebulizer 100, the amount of drug, and the drug injection speed and time. Considering either one, the patient's drug intake amount can be derived.

For example, the respiratory information control unit 320 receives data on the patient's respiratory flow rate and breathing time in the expiratory state, and the respiratory flow rate and breathing time in the inspiratory state, through which the expiratory volume and inspiratory volume can be derived, The injection speed and injection time of the drug can be derived from the pressure of the compressed air of the main body 200, the speed of the compressed air, the size and volume of the inside of the drug nebulizer 100, the amount of drug, etc.

At this time, information such as the pressure of the compressed air of the main body 200, the speed of the compressed air, the size and volume of the inside of the drug nebulizer 100, and the amount of drug can be input in advance into the respiratory information control unit 320. Of course it exists.

That is, the respiratory information control unit 320 displays information on the exhalation curve according to the exhalation time and expiratory volume, information on the inhalation curve according to the inhalation time and amount, and data on the amount of drug through the injection speed and injection time of the drug. By transmitting the data to the unit 330, the display unit 330 can output the patient's inhalation curve and exhalation curve and the drug intake curve corresponding to the inhalation curve and exhalation curve as images.

On the other hand, since the drug injection device uses compressed air to spray the drug, a compressor motor is used to generate compressed air, and at this time, noise from the motor is generated.

This motor noise can cause stress to the patient. In particular, in the case of infant patients, they are startled by the motor noise and refuse treatment, causing difficulty in treatment. Guardians complain of guilt, anxiety, and fatigue from caring for the patient. Problems such as this occurred.

In order to solve the above problems, the present invention includes a noise sensor 400 that measures noise generated when a motor is driven; It may include a noise mitigation unit 500 for purifying the noise detected through the noise sensor 400 into music.

The noise sensor 400 is a component that measures noise generated when a motor is driven, and various configurations are possible.

At this time, the noise sensor 400 may be located anywhere, but it may be preferable to install it in the main body 200.

The noise alleviating unit 500 is a component that purifies the noise detected through the noise sensor 400 into music, and can have various configurations.

Specifically, the noise mitigation unit 500 includes a noise information conversion unit 510 that converts the noise detected by the noise sensor into noise information; an audio output unit 530 that outputs music; It may include a sound control unit 520 that controls the sound output unit 530 to output music based on the noise information provided from the noise information conversion unit 510.

At this time, the noise mitigation unit 500 may include a memory unit capable of storing music and noise information, a communication unit capable of wirelessly/wiredly communicating with the noise sensor 400 and the audio output unit 530, etc. Of course it exists.

Here, zigbee, Bluetooth, XBee, Wifi, etc. may be used for the wireless communication.

The noise information conversion unit 510 is a component that converts the noise detected by the noise sensor into noise information, and various configurations are possible.

Here, the noise information may be various information related to noise, such as the decibel of motor noise and the audible frequency of motor noise.

Here, the sound output unit 530 is a component that outputs music, and various configurations are possible.

At this time, music can be selected in various ways depending on the patient's age, gender, and taste. For example, in the case of infant patients, children's songs, etc. can be selected.

The sound output unit 530 can have any configuration as long as it can output music, and can be, for example, a speaker, headphone, earphone, etc.

Meanwhile, the sound control unit 520 is a component that controls the audio output unit 530 to output music based on the noise information provided from the noise information conversion unit 510, and various configurations are possible.

Specifically, the sound control unit 520 can output the music sound louder than the motor sound or play music at the same audible frequency as the noise, thereby minimizing the patient's stress and feelings of rejection due to the motor noise.

More specifically, the sound control unit 520 may control the sound output unit 530 so that music output from the sound output unit 530 is output at a decibel higher than the decibel of the motor noise.

For example, the motor noise is generally 70dB to 85dB, and in this case, the decibel is a logarithmic function, so in order to output music twice as loud as the decibel of the motor noise, there must be a difference of about 3dB, so the sound control unit 520 adjusts the sound output. Unit 530 can be programmed to output music of 73dB to 88dB.

Meanwhile, the main body 200 may include a soundproof box in which the main body 200 can be accommodated in order to reduce noise generated from the motor.

The soundproof box can be made of various materials to prevent noise generated from the motor from escaping. For example, glass fiber, rock wool, felt, cork, soft fiber board, polyurethane, asbestos felt, rock fiber, and styrene foam. etc. may be used.

In addition, it goes without saying that the drug treatment method for performing respiratory treatment for a patient can be performed using the drug treatment system described above.

Since the above is only a description of some of the preferred embodiments that can be implemented by the present invention, as is well known, the scope of the present invention should not be construed as limited to the above embodiments, and the scope of the present invention described above Both the technical idea and the technical idea underlying it will be said to be included in the scope of the present invention.

10: Drug treatment system 100: Drug nebulizer
200: main body

Claims (14)

delete delete delete delete A drug treatment system comprising a drug nebulizer (100),
The drug nebulizer 100 is a drug nebulizer of a drug treatment system including a main body portion 200 that generates compressed air and a drug nebulizer 100 that sprays the drug with compressed air generated from the main body portion 200 ( 100),
The drug sprayer 100,
a drug storage unit 110 in which a container for storing drugs is formed;
An air delivery tube 120 connected to the main body 200 and the drug storage unit 110 and delivering compressed air generated from the main body 200 to the drug storage unit 110;
A drug delivery unit 130 that is coupled to the drug storage unit 110 and delivers the drug sprayed from the drug storage unit 110 to the patient's respiratory tract;
It includes a respiration measuring unit 140 that measures the patient's breathing using air introduced by the patient's breathing,
The drug treatment system includes a drug intake amount deriving unit 300 for outputting the drug intake amount through the patient's breathing information;
The drug intake amount deriving unit 300,
A respiration information conversion unit 310 that converts the signal received from the respiration measurement unit 140 into respiration information;
a display unit 330 that visually shows the patient's drug intake amount;
A breathing information control unit 320 that obtains the patient's breathing information from the breathing information conversion unit 310, derives the patient's drug intake amount based on the obtained patient's breathing information, and transmits it to the display unit 330. Includes,
The drug treatment system includes a noise sensor 400 that measures noise generated when the motor is driven;
It includes a noise mitigation unit 500 for purifying the noise detected through the noise sensor 400 into music;
The noise mitigation unit 500,
A noise information conversion unit 510 that converts the noise detected by the noise sensor 400 into noise information;
an audio output unit 530 that outputs music;
A drug treatment system further comprising a sound control unit 520 that controls the sound output unit 530 to output music based on the noise information provided from the noise information conversion unit 510. In claim 5,
The breathing information is,
Drug treatment characterized by at least one of the patient's respiratory rate, the patient's respiratory pressure, the patient's respiratory flow, the patient's expiratory volume, the patient's inspiratory volume, the patient's expiratory time, the patient's inspiratory time, and the patient's exhalation and inhalation interval. system. In claim 5,
The breathing information control unit 320,
Deriving the patient's drug intake amount by considering at least one of the patient's breathing information, the compressed air pressure of the main body 200, the size and volume of the drug nebulizer 100, the amount of drug, and the drug injection speed and time. A drug treatment system characterized by: In claim 5,
The display unit 330,
A drug treatment system characterized by outputting a patient's inhalation curve and exhalation curve and a drug intake curve corresponding to the inhalation curve and exhalation curve. delete In claim 5,
A drug treatment system, wherein the noise information is decibels of motor noise. In claim 10,
The sound control unit 520,
A drug treatment system, characterized in that the sound output unit 530 is controlled so that the music output from the sound output unit 530 is output at a decibel higher than the decibel of the motor noise. In claim 5,
The drug delivery unit 130 includes a vertical portion 131-1 coupled to the drug storage portion 110, and a horizontal portion extending in a direction perpendicular to the vertical portion 131-1 and open at both ends ( A cylinder portion 131 including 131-2);
a respiratory contact portion 132 that is inserted into one end of the horizontal portion 131-2 and is in direct or indirect contact with the patient's respiratory tract;
It includes a drug delivery unit 130 including a stopper 133 fitted to open and close the other end of the horizontal portion 131-2;
A drug treatment system, characterized in that the respiration measurement unit 140 is installed inside the horizontal portion 131-2. In claim 12,
The respiration measuring unit 140,
One or more rotary wings 141 that rotate due to the patient's breathing;
a rotating shaft 142 that supports the one or more rotating blades and whose both ends are fixed through the horizontal portion 131-2;
A drug treatment system comprising a rotation sensor unit 143 connected to one end of the rotation shaft 142 and measuring rotation information of the rotation shaft 142. In claim 5,
The respiration measuring unit 140 is a drug treatment system, characterized in that installed inside the drug delivery unit 130.

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