KR102062205B1 - Personal lung Health Management System Based on Artificial Intelligence Using Breathing Measuring Devices - Google Patents

Abstract

The present invention relates to an artificial intelligence-based personal lung health management system using a respiration measurement device, and more particularly, to an artificial intelligence-based personal lung health management system using a respiration measurement device that can be easily used by a user anytime and anywhere, allows the user to check lung health of the user by oneself through respiration volume measurement, and provides a lung exercise method to the user to manage the lung health of the user by oneself by using a respiration measurement device that is miniaturized to measure a respiration volume of a subject anytime and anywhere not just at home or in a hospital, and has a sensor measuring a respiratory air flow and an air passage through which the respiratory air flow moves separately to be detachable so that foreign substances generated in the sensor and the air passage can be easily washed and removed.

Description

Personal lung Health Management System Based on Artificial Intelligence Using Breathing Measuring Devices}

The present invention relates to an individual-based lung health management system based on artificial intelligence using a respiratory measurement device, and more particularly, to miniaturize a respiratory measurement device to measure the respiratory volume of an examinee anytime, anywhere, as well as at home or a hospital, and a respiratory airflow. By separately configuring the sensor to measure the sensor and the air flow path to move the breathing air is removable, by using a breathing apparatus to easily remove and remove foreign substances generated in the sensor and the air flow path to the user easily Regarding AI-based personal lung health management system using a respiratory measurement device that can be used, the user can check his / her lung health by measuring the respiratory rate and manage the lung health by providing the lung exercise method using the same. will be.

In general, the measuring devices used for respiratory rate examination are classified in two ways. The first method is to quantitatively measure changes in lung expansion and contraction, that is, changes in lung volume, and directly measures changes in lung volume during breathing by a subject according to a predetermined form. The second method is to measure the respiratory volume by detecting and measuring the flow of air flowing into and out of the lungs while the examinee breathes.

Conventionally, the first method of directly measuring the change in lung volume, which is a respiratory volume measurement method, has been mainly used, but there is a problem in that the structure of the test apparatus used is complicated and it is inconvenient to use due to movement. Methods and devices for measuring airflow are mainly used.

However, the respiratory measurement device for measuring the air flow is a problem that is generally used only at home or a hospital because the internal shape is complicated, the size is very large and not portable.

Recently, air pollution caused by yellow dust, heavy metals, and fine dust is rapidly increasing. In this environment, infants and the elderly are very vulnerable to respiratory diseases. Therefore, it is very important to continuously check the respiratory health through measurement of respiratory volume.

However, it is pointed out as a problem that it is almost impossible to measure the respiratory volume of the examinee quickly, easily and accurately in the environment outside the hospital or home.

In addition, the conventional respiratory measuring device has a problem that it is difficult to wash because the sensor for measuring the breathing air flow and the air flow path for moving the breathing air is integrally formed, it is difficult to remove the foreign substances generated in the sensor and the air flow path.

In addition, there is a problem that the size is very large and can not be carried as described above used only at home or hospital, it is difficult for the user to easily breathe using it, or to use the same breathing exercise to solve the above problems At the same time, the development of a system that can provide a variety of breathing exercise and lung health management to the user is required.

Korean Patent Registration Publication No. 1070960

The present invention is to solve the above problems, an object of the present invention is to miniaturize the respiratory measurement device to measure the respiratory volume of the examinee anytime, anywhere, as well as at home or hospital, and to measure the respiratory air flow and breathing It is to provide a respiratory measuring device that can be configured to be detachable by configuring the air flow path to which the air flow is moved, to easily wash and remove foreign substances generated in the sensor and the air flow path.

In addition, to provide a breathing apparatus that can simplify the structure and increase the sensing sensitivity.

In addition, while measuring the user's respiratory volume, the user can check the respiratory volume to provide a personal lung health management system that can directly check the lung status of the GS yourself.

In addition, by providing a user with a custom breathing exercise method to provide a personal lung health management system that allows the user to do the breathing exercise on their own to facilitate lung health management.

In addition, it is possible to measure the respiratory volume anywhere using the miniaturized respiratory measuring device, but to provide an artificial intelligence-based individual lung health management system using a respiratory measuring device that can be combined with the breathing exercise.

Artificial intelligence-based individual lung health management system using the present invention breathing apparatus for solving the above problems,

The air generated by the user's breath can be introduced to measure the user's breathing volume, but transmits the measured breathing volume information to the management server 1000 and obtains exercise guide information from the management server 1000 to the user. Respiratory measurement device for guiding the respiratory movement using the 10;

Obtaining respiratory volume information from the respiratory measuring device 10, checking the lung health status of the user using the obtained respiratory volume information, and measures the breathing guide of the user's lung health status information and exercise guide information on the user's lung health status The above-described problem can be solved by including the management server 1000 which is transmitted to the device 10 and provided to the user.

Artificial intelligence based individual lung health management system using the present invention breathing apparatus according to the above configuration,

By miniaturizing the respiratory measuring device, it is possible to measure the respiratory volume of the examinee anytime, anywhere, as well as at home or in the hospital, and by separately configuring the sensor for measuring the respiratory airflow and the air flow path through which the respiratory airflow is moved, the sensor and air It provides an effect that can easily wash and remove foreign substances generated in the flow path.

In addition, the effect of increasing the sensing sensitivity while simplifying the structure is provided.

In addition, while measuring the respiratory volume of the user, the user is able to check the respiratory volume is provided with the effect that can directly check the lung state of the user.

In addition, by providing a user with a custom breathing exercise method, the user can perform the breathing exercise on their own to provide an easy effect on lung health management.

In addition, it is possible to measure the respiratory volume anywhere using the miniaturized respiratory measurement device, it is provided with the effect that can be combined with the breathing exercise.

1 and 2 are perspective views of a breathing apparatus according to the present invention.
Figure 3 is a plan view showing a first body of the breathing apparatus according to the present invention.
4 is a schematic diagram of a respiratory measuring device according to the present invention.
5 is a cross-sectional view of the respiratory measuring device according to the present invention.
6 is a view showing a breathing measuring unit of the breathing measuring apparatus according to the present invention.
7 is a view showing a breathing pressure control unit of the breathing apparatus according to the invention.
8 is a view showing a mouthpiece of the breathing apparatus according to the present invention.
9 is a view showing a filter of the breathing apparatus according to the present invention.
10 is a view showing the principle of measuring the respiratory rate of the respiratory measuring device according to the present invention.
11 is a relationship between the artificial intelligence-based individual lung health management system using the inventor breathing apparatus.
12 is a view showing a detailed configuration of the process module of the configuration of the breathing apparatus of the present invention.
13 is a view showing in detail the configuration of the management server of the present invention.
14 is a view showing various exemplary forms of the control panel of the present invention.

Specific structural or functional descriptions of the embodiments according to the inventive concept disclosed herein are provided only for the purpose of describing the embodiments according to the inventive concept. It may be implemented in various forms and is not limited to the embodiments described herein.

Embodiments according to the inventive concept may be variously modified and have various forms, so embodiments are illustrated in the drawings and described in detail herein. However, this is not intended to limit the embodiments in accordance with the concept of the present invention to specific embodiments, and includes modifications, equivalents, or substitutes included in the spirit and scope of the present invention.

Terms such as first or second may be used to describe various components, but the components should not be limited by the terms. The terms are only for the purpose of distinguishing one component from another component, for example, without departing from the scope of the rights according to the inventive concept, the first component may be called a second component, Similarly, the second component may also be referred to as the first component.

When a component is said to be “connected” or “connected” to another component, it may be directly connected to or connected to that other component, but it may be understood that other components may exist in the middle. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle. Expressions describing relationships between components, such as "between" and "immediately between," or "neighboring to," and "direct neighboring to" should be interpreted as well.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as “include” or “have” are intended to designate that the stated feature, number, step, operation, component, part, or combination thereof exists, but one or more other features, numbers, steps It is to be understood that the present invention does not exclude, in advance, the possibility of the addition or the presence of any operation, components, parts or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and are not construed in ideal or excessively formal meanings unless expressly defined herein. Do not.

Hereinafter, an artificial intelligence-based individual lung health management system using a respiration measuring apparatus according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in Figures 11 to 13, the present invention,

The air generated by the user's breath can be introduced to measure the user's breathing volume, but transmits the measured breathing volume information to the management server 1000 and obtains exercise guide information from the management server 1000 to the user. Respiratory measuring device 10 for guiding the respiratory movement using 10,

Obtaining respiratory volume information from the respiratory measuring device 10, checking the lung health status of the user using the obtained respiratory volume information, and measures the breathing guide of the user's lung health status information and exercise guide information on the user's lung health status The management server 1000 is transmitted to the device 10 and provided to the user.

The breathing apparatus 10, the air generated by the user's breath is introduced to measure the user's breathing volume, and transmits the measured breathing volume information to the management server 1000, exercise from the management server 1000 Acquire guide information to guide the user to the breathing exercise using the breathing apparatus (10).

The respiratory measuring device 10,

As shown in Figures 1 to 4, the air flow path 110 is formed therein so that the air generated by the user's breath is introduced into the movement and the opening 120 formed by opening a portion of the air flow path 110 is provided The first main body 100, the second main body 200, which is formed to be detachable to the first main body 100 and is installed to close the opening 120 formed in the first main body, the air flow path 110 Removably coupled to the breathable measuring unit 300 for measuring the pressure of the moving air, the mouthpiece coupling member 400 and the mouthpiece coupling member 400 installed on the inlet side 111 of the air flow path 110. Mouthpiece 500.

First, the first body 100 is a member in which a hollow air flow path 110 is formed, and one side (left side of FIG. 1, air inlet side) and the other side (right side of FIG. 1, air discharge side) are formed. Open to the air flow path 110 is formed to interlock with the outside. In addition, an opening 120 is formed to remove a portion of the upper side of the first main body 100 so that a portion of the upper side of the air passage 110 is opened.

The second main body 200 is formed to have a length corresponding to the length of the first main body 100, and a lower portion thereof is detachably coupled to the first main body 100.

Meanwhile, as illustrated in FIGS. 4 to 6, the respiration measurement unit 300 is formed to correspond to the opening of the air passage so as to close the opening of the air passage by coupling the first body and the second body. The breath measurement sensor module 310 is installed, the first differential pressure generating block 320 is formed to extend from the breath measurement sensor module to the inner center side of the air flow path and is disposed on the inner surface of the air flow path, The second differential pressure generating block 330 extends from an inner side to an inner center side of the air flow path and is disposed to face each other to correspond to the first differential pressure generating block.

The respiration measurement sensor module 310 is a member formed to correspond to the opening 120 of the first body 100, and when the first body 100 and the second body 200 are coupled to the respiration measurement sensor module 310. ) Closes the opening 120. That is, the respiration measurement sensor module 310 covers the opening 120 by the combination of the first body 100 and the second body 200, so that the air passage 110 is sealed. As described above, the first main body 100 and the second main body 200 are formed to be completely separated, and a part of the air flow path 110 may be opened by the separation of the first main body 100 and the second main body 200. Therefore, it is possible to easily remove the foreign matter inside the air passage 110 by washing the first body. At this time, the bottom surface of the respiration measurement sensor module 310 is disposed to be located on a straight line with the upper outer surface of the air flow path (110).

The first differential pressure generation block 320 is a member having a predetermined thickness and height, and is disposed at the center of the respiration measurement sensor module 310, and the first differential pressure generation block 320 is configured to measure the respiration measurement sensor module 310. It is formed to protrude from the surface toward the inner center side of the air flow path (110).

The respiration measurement sensor module 310 is formed to penetrate the inside of the respiration measurement sensor module, the inlet and outlet includes a sensing unit for sensing the sensing flow path and the pressure difference respectively formed on both sides of the first differential pressure generating block. Can be. More specifically, the sensing flow sensor module 310 has a sensing flow passage 311 for measuring the pressure of the air passing through the air flow passage is formed inside the breathing measurement sensor module 310, the inlet of the sensing flow passage 311 And outlets are respectively formed at both sides with the first differential pressure generating block 320 therebetween in the air flow direction. The sensing unit 312 is disposed inside the sensing flow path 311. The sensing unit 312 may detect a pressure difference between the inlet side and the outlet side of the sensing flow passage 311 as a differential pressure sensor and calculate a respiratory volume based on the pressure difference.

The respiration measurement sensor module 310 is installed on the circuit board 340, and the circuit board 340 is mounted inside the second body 200. The respiration measurement sensor module 310 is installed to be exposed to the second body so that the respiration measurement sensor module 310 can close the opening 120 of the first body when the second body and the first body are coupled. (See Figures 4 and 5)

In addition, the second differential pressure generating block 330 is formed as a member having a predetermined thickness and height formed to correspond to the first differential pressure generating block 320 and is disposed on the inner surface of the air flow path 110. In this case, the second differential pressure generation block 330 is disposed to face each other with the first differential pressure generation block 320.

In addition, the respiration measurement unit 300 of the present invention may further include a third differential pressure generation block 350 and a fourth differential pressure generation block 360. The third differential pressure generation block 350 and the fourth differential pressure generation block 360 may be formed at both sides of the air flow path 110, as shown in FIG. 5.

Although the first to fourth differential pressure generating blocks are members having a predetermined thickness and height, the first to fourth differential pressure generating blocks are formed in a rectangular shape in the present invention. However, the first to fourth differential pressure generating blocks are not necessarily rectangular and may generate differential pressures with a predetermined thickness and height as described below. If so, the shape can be configured in various ways.

The breathing unit 300 configured as described above is to measure the breathing of the user.

Hereinafter, the principle of measuring the breathing amount of the user of the breathing measuring unit 300 of the present invention will be described in detail.

FIG. 10 is a view illustrating a change in pressure of an orifice tube installed in a general flow path.

Referring to FIG. 10, the Bernoulli equation and the continuous equation are established between the upstream end face a of the orifice tube and the narrowed end face b.

(V: average flow rate, P: pressure, ρ: density of fluid)

The relationship between the volume flow rate Q through the orifice tube and the differential pressure (P ₁ -P ₂ ) is as follows.

Therefore, by knowing P ₁ and P ₂ , the flow rate Q can be obtained.

In the present invention, since the first differential pressure generating block 320 and the second differential pressure generating block 330 replace the orifice tube of the above-described measurement principle, the sensing located inside the sensing flow path 311 of the respiratory measurement sensor module 310. P ₁ and P ₂ can be obtained based on the detection result of the unit 312.

Substituting P ₁ and P ₂ obtained as described above into the above equation enables the user's breathing volume to be measured.

Meanwhile, a mouthpiece coupling member 400 may be included between the first body and the mouthpiece. Mouthpiece coupling member 400 is provided as a plate having a predetermined thickness is installed on the inlet side 111 of the air flow path 110 of the first body is coupled to the mouthpiece. In this case, a metal body 410 for coupling with the mouthpiece 500 is formed at one side of the mouthpiece coupling member 400, and a filter 420 is formed to interlock with the inflow side 111 of the air flow path 110. (See FIG. 9). The filter 420 is provided as a general metal net, a pre-filter, etc. and is installed to filter foreign matter from the inflow side 111 of the air flow path 110. The mouthpiece coupling member 400 may exist as a separate component from the first body, but may be integrally formed with the first body as necessary.

As shown in FIG. 8, the mouthpiece 500 is a member in which a breathing ball 520 is connected to the air flow path 110 so that a user can breathe and breathe into the mouth, and the magnetic body 510 is formed at one side thereof. ) Is installed to be detachably coupled to the metal body 410 of the mouthpiece coupling member 400. Since the mouthpiece 500 is detachably coupled as described above, the inside of the breathing ball 520 and the filter 420 can be easily cleaned. Herein, the magnetic body and the metal body may be cross-located between the mouthpiece coupling member and the mouthpiece.

On the other hand, the respiratory measurement device may further include a respiratory pressure control unit 600 to adjust the respiratory pressure introduced as needed.

The breathing pressure regulating unit 600, as shown in FIG. 7, includes a rotating member 610, a rotating shaft 620, and a plurality of pressure adjusting balls 630.

The rotating member 610 is a circular plate having a predetermined thickness and may be disposed between the inflow side 111 of the air flow path 110 and the mouthpiece coupling member 400. At this time, a rotating shaft 620 is formed at the center of the rotating member 610 so that the rotating member 610 is rotatable by the rotating shaft 620.

The pressure adjusting ball 630 is a hole formed to penetrate the rotating member 610, and is provided in plural and is formed radially about the rotating shaft 620. At this time, each of the pressure adjusting holes 630 is formed so that their cross-sectional area is different.

In the respiratory pressure control unit 600 configured as described above, different pressure control balls 630 are interlocked with the air flow path 110 by the rotation of the rotating member 610, according to the cross-sectional area of each pressure control ball 630. The pressure of the breath flowing into the air passage 110 is adjusted.

The respiratory measurement device according to the present invention configured as described above is capable of measuring the respiratory volume of the examinee anytime, anywhere as well as at home or in the hospital by miniaturizing the respiratory measurement device, and measuring the respiratory airflow module 310. And by separately configuring the air flow path 110 to move the breathing air flow is removable, there is an effect that can be easily washed to remove the foreign substances generated in the respiration measurement sensor module 310 and the air flow path (110). In particular, since the first body through which the user's breath passes directly is removable, the cleaning is very easy, and since the respiration measurement sensor module of the second body is integrally formed with the sensing unit, a sensing error hardly occurs even if the detachment is repeated. There is a unique effect.

In addition, at least one differential pressure generating block is formed inside the air passage to replace the existing orifice tube, thereby simplifying the structure and increasing the sensing sensitivity.

On the other hand, the respiratory pressure control unit 600 may adjust the pressure of the respiratory inflow into the air flow path 110 according to the cross-sectional area of each pressure control ball 630, so that the user to adjust the respiratory pressure according to the user's health during respiratory exercise It can provide a respiratory exercise effect of the individual user.

The respiratory measuring device 10 is located on one surface of the second body 200, it is characterized in that it comprises a control panel 700 is formed as a touch panel is operable by the user and performs a display role .

14 is a view showing various exemplary forms of the control panel of the present invention.

Referring to FIG. 14, the control panel 700 is described. The control panel 700 is located on one surface of the second main body 200. However, the control panel 700 is similar to FIGS. 1 and 2. As shown in [a] of FIG. 14, the second main body 200 may be integrally formed and may be formed in a separate form as shown in [b] and [c].

In addition, the second main body 200 may be separated from the second main body 200 and may be used alone without being located in the second main body 200.

The respiratory measuring device 10,

Using the control panel 700 receives the user's personal information of any one or more of the user's name, gender, age, height, weight, phone number, disease presence information from the user, the user's personal information and breathing apparatus ( User information input means 2010 for storing user information including any one or more of the serial number of 10), and transmitting the stored user information to the management server 1000,

Respiratory volume measuring means 2020 for transmitting the respiratory volume information of the user measured in the respiratory measurement unit to the management server 1000,

When the user measures the respiratory volume using the respiratory measurement device 10, respiration measurement guide means 2030 for guiding the respiration measurement using the control panel 700,

Respiratory movement guide information is obtained from the management server 1000, the breathing exercise guide providing means for guiding the user's breathing movement to the object of the animation type using the control panel 700, the obtained breathing movement guide information (2040) ,

A process module including any one or more of user health information providing means 2050 for receiving lung health status information from the management server 1000 and providing the lung health status information to the user using the control panel 700 ( 2000) further comprises.

The serial number described above means a unique serial number assigned to the respiratory measurement device 10 when the respiration measurement device 10 is manufactured, and the inclusion of the information in the user information corresponds to the user and the respiration measurement device 10. This is to easily manage the user's lung health and breathing exercise.

Respiratory measurement device 10 of the configuration of the present invention is located on one end of the second body 200, characterized in that it may further include a speaker module 800 for providing sound information to the user.

On the other hand, the process module 2000, using the speaker module 800, when the breathing exercise guide providing means 2040 guides the breathing exercise to the user in addition to sound information to the user to perform audible breathing exercise When guided by the breathing measurement guide means 2030, the user may further include a sound guide control means 2060 that can guide the user to audibly measured breathing sound information when the user guides the breath measurement in 2030 It is characterized by.

Accordingly, the respiratory measuring device is capable of measuring the breathing or guide the breathing exercise in a visual as well as an audio method to the user.

The method of exchanging data between the respiration measuring device 10 and the management server 1000 may transmit and receive data using a data network, and in this case, the present invention provides the respiration measuring device 10 and the management server. Characterized in that it may further include a user terminal 900 that can perform a data communication relay role to perform data communication between (1000).

The management server 1000,

Obtaining respiratory volume information from the respiratory measuring device 10, checking the lung health status of the user using the obtained respiratory volume information, and measures the breathing guide of the user's lung health status information and exercise guide information on the user's lung health status The device 10 transmits the information to the user.

In this regard with respect to the management server 1000 in detail,

A user information DB 1010 for generating a key number, generating a table by mapping user information from the respiration measuring apparatus 10 to the generated key number, and storing and managing user information corresponding to the key number.

Respiratory volume is obtained by obtaining the user's respiratory volume information from the respiratory measurement device 10, generating a table by matching the acquired respiratory volume value with the key number, and storing and managing the respiratory volume information of the user corresponding to the key number Information DB (1020),

Lung health diagnosis means 1030 for diagnosing lung disease health state using the user's respiratory volume information stored in the basic data DB, and transmitting to the respiratory measurement device 10 matching the respiratory volume information using the diagnosed lung health state information. ,

 Respiratory exercise guide information for storing the respiratory exercise method using the respiratory measurement device 10, the respiratory exercise guide to improve the user's health in accordance with the lung health status information diagnosed by the lung health diagnostic means (1030) And at least one of exercise guide information generating means 1040 for generating information and transmitting the generated respiratory exercise guide information to the respiratory measurement apparatus 10 matching the diagnosed lung health state information. .

By measuring the respiratory volume of the user using the breathing apparatus 10 by such a configuration, using the respiratory rate measured by the management server 1000 to diagnose the health state of the user and provide it to the user, the corresponding By transmitting the respiratory exercise guide information, the user can perform the respiratory exercise using the respiratory measurement device 10 and at the same time check the user's own health.

The management server 1000,

Providing breathing method guide information for measuring lung health status information including any one or more of the lung capacity (VC), forced lung capacity (FVC) by using the respiratory measuring device 10 to the respiratory measuring device (10) In addition, the respiratory measuring device 10 is characterized in that it further comprises a special breathing method guide means 1050 for obtaining the respiratory volume information measured by using the provided breathing method.

Accordingly, the breathing measuring device 10 obtains the breathing method guide information transmitted from the special breathing method guide means of the management server 1000 to guide the breathing measurement to the user, the user's breathing volume information measured according to the guide Characterized in that it further comprises a special breath measurement means 2070 to transmit to the management server (1000).

The special breathing method guide means 1050,

In order to measure the lung capacity (VC), a guide to perform breathing using the breathing apparatus 10 by inducing the inhalation and maximum exhalation of the user, the lung capacity to guide to perform at least one to three breaths Measurement guide,

In order to measure the forced lung capacity (FVC), the exhalation time of at least 5 to 15 seconds is set, the maximum exhalation after the maximum inspiration of the user according to the set exhalation time to inhale breathing using the breathing apparatus 10 It is characterized by providing any one or more breathing method guide information of the forced spirometry guide to guide to the respiratory measurement device (10).

Accordingly, the lung health diagnosis means 1030,

According to the breathing method guide information provided by the special breathing method guide means 1050, using the breathing measuring device 10 to obtain the breathing volume information that the user breathed,

Spirometry (1031), which measures the spirometry (VC) using the obtained breathing volume information,

According to the breathing method guide information provided by the special breathing method guide means 1050, using the breathing measuring device 10 to obtain the breathing volume information that the user breathed,

Forced lung capacity measurement unit 1032 for measuring the forced lung capacity (FVC) by using the acquired breath volume information,

Among the breathing method guide information provided by the special breathing method guide means 1050, when the user performs breathing to measure the forced lung capacity, the user obtains the breathing volume information for 1 second by using the obtained breathing volume information 1 second air flow measurement unit 1033 for measuring a 1 second air flow (FEV1),

Among the breathing method guide information provided by the special breathing method guide means 1050, when the user performs breathing to measure the forced lung capacity, the user obtains the maximum exhalation volume information, and uses the obtained maximum exhalation volume information. It characterized in that it further comprises any one or more of the maximum exhalation flow rate measuring unit 1034 for measuring the flow rate (PEF).

Accordingly, the lung health diagnosis means 1030,

Spirometry (VC) measured by the spirometry unit 1031, Forced spirometry (FVC) measured by the forced spirometry 1031, 1st tidal volume (FEV1) measured by the 1st tidal flow measurement unit 1033, maximum breath It further comprises a detailed disease measuring unit 1035 for measuring the lung health status information of the user using any one or more respiratory volume information of the maximum exhalation flow rate (PEF) measured by the flow measurement unit (1034).

The lung health status information of the user determined by the detailed disease measuring unit 1035 is characterized by determining obstructive airway diseases including any one or more of asthma, chronic bronchitis, emphysema, chronic obstructive pulmonary disease.

Accordingly, the user is not only able to recognize the information about his or her breathing volume, but also lung health status information including lung capacity (VC), forced lung capacity (FVC), 1 second expiratory volume (FEV1), and maximum exhalation flow rate (PEF). You will be able to check and additionally check the status of your airway disease.

The lung health diagnosis means 1030,

Regarding the lung health state information of the user determined by the detailed disease measuring unit 1035, the disease presence standard setting unit 1036 for setting the lung health state information step is characterized in that it further comprises.

The airway disease step set by the disease presence reference setting unit 1036 is set to 0 to 10,

Stage 0: no disease

Steps 1 and 2: There is a probability of developing disease

Steps 3-4: Introduction to Disease

Stage 5-6: early stage of the disease

Stages 7-8: Mid-Term Disease

Steps 9 to 10: disease risk stage

It is characterized by setting the detailed steps as described above.

The initiation stage of the disease refers to a stage in which the disease may develop when the state of health persists, although the disease does not develop.

The initial stage of the disease means a state in which the disease develops, or a step that can be easily treated when taking measures for the disease,

The middle stage of the disease is a condition in which the disease develops, and means a step of performing treatment by taking continuous measures for the disease,

The disease risk stage refers to a stage in which the disease development state is very serious and the inpatient intensive care should be performed immediately.

At this time, the lung health diagnosis means 1030,

 By using the step set in the disease presence reference setting unit 1036, the disease state of the user according to the step of the disease presence reference setting unit 1036 for the disease of the user measured by the detailed disease measurement unit 1035 It is characterized in that it further comprises a disease state primary determination unit 1037 to determine.

The disease state primary determination unit 1037,

The disease state reference setting unit 1036 may be divided into 0 to 4 steps and 5 to 10 steps to determine the disease state of the user.

The lung health diagnosis means 1030,

When the result determined by the disease state primary determination unit 1037 for the user's disease corresponds to 0 to 4 stages, the disease to determine the disease state of the user by dividing into 0 ~ 2 stages and 3 to 4 stages in detail It characterized in that it further comprises a state secondary safety determination unit 1038.

In addition, the lung health diagnostic means 1030,

When the result determined by the disease state primary determination unit 1037 for the user's disease corresponds to 5 to 10 steps, the disease to determine the disease state of the user by dividing into 5 to 8 steps and 9 to 10 steps in detail It characterized in that it further comprises a state secondary risk determination unit 1039.

Accordingly, the lung health diagnosis means 1030, by measuring the user's breathing side in accordance with the breathing method provided by the special breathing method guide means 1050, and determines the disease state of the user using the measured respiratory volume However, the detailed disease is measured by using the user's breathing amount, and the disease level of the user may be determined according to the measured disease level.

The management server 1000,

When the airway disease state step of the user's lung health state information measured by the detailed disease measurement unit 1035 is determined to be the range of the disease state secondary safety determination unit 1038, the disease state secondary safety determination unit 1038 ) Is treated as 'prevention' when 0 ~ 2 steps and 'exercise parallel' when 3 ~ 4 steps,

When it is determined that the airway disease state secondary risk determination unit of the lung health state information is in the range of 5 to 8 according to the stages detailed in the disease state secondary risk determination unit 1039, 'Caution', 9 ~ When the step 10 is treated as 'danger', characterized in that it further comprises a state-specific information providing means 1060 for transmitting the processed detailed state information to the respiratory measuring device (10).

Accordingly, the respiratory measuring device 10,

Warning information for acquiring detailed state information transmitted from the state-specific information providing means 1060 of the management server 1000, and visually providing the obtained detailed state information to the user using the control panel 700. Characterized in that it may further comprise a means (2100).

Accordingly, the user's health status can be checked by the user by providing the user's own condition easily based on the airway disease state level of the lung health status information.

The exercise guide information generating means 1040 stores the respiratory exercise guide information on the respiratory exercise method using the respiratory measuring device 10, and the user according to the lung health state information diagnosed by the lung health diagnosing means 1030. To generate breathing exercise guide information that can improve your health.

Respiratory exercise guide information on the respiratory exercise method using the respiratory measurement device 10, the exercise conditions including the total respiratory exercise time, inhalation time, exhalation time, inhalation intensity, exhalation intensity using the respiration measurement device 10 Respiratory exercise guide information that includes, and generating the respiratory exercise guide information that can improve the user's health in accordance with the lung health state information diagnosed by the lung health diagnosis means 1030, the exercise conditions in accordance with the lung health state Combining each of the means means to create a user lung health customized breathing exercise guide information.

The exercise guide information generating means 1040,

The respiratory exercise guide information management unit 1041 further stores and manages respiratory exercise guide information corresponding to each step in accordance with the stages set by the disease presence standard setting unit 1036.

In addition, in accordance with the lung health status information of the user diagnosed by the lung health diagnosis means 1030, but the respiratory movement guide information to the respiratory measurement device 10,

The detailed respiratory exercise guide information management unit 1041 uses the result processed by the state-specific information providing means 1060 and when the result processed for the airway disease state step for the user's lung health state information is 'prevention'. Of the respiratory exercise guide information stored in the respiratory exercise guide information corresponding to the 'preventive' step is transmitted to the respiratory measuring device 10, the result processed by the information providing means for each state (1060) is' parallel exercise The detailed respiratory movement guide for transmitting the respiratory movement guide information corresponding to the 'parallel exercise' step among the respiratory movement guide information stored in the detailed respiratory movement guide information management unit 1041 at one time to the respiratory measurement device 10. An information transmitter 1042 is further included.

Accordingly, rather than simply providing a consistent breathing exercise method (breathing exercise guide information) to the user, it is possible to provide a breathing exercise method according to the user's state, thereby enabling a customized service.

The management server 1000,

Hospital information management means for storing hospital information including any one or more of medical treatment information, specialist information, location information, telephone number information, business hours information, and transmits hospital information to the respiratory measurement device (10) (1070). It further comprises a).

At this time, the hospital information management means 1070,

The respiratory measurement is performed using the result processed by the state-specific information providing means 1060, and when the result processed for the airway disease state step for the user's lung health status information is treated as 'caution' or 'danger' The hospital information is first transmitted to the device 10, characterized in that it further comprises a treatment notification transmission unit 1071 for transmitting a message including a message that the user should take treatment.

Accordingly, the respiratory measuring device 10 obtains the hospital information transmitted from the hospital information management means 1070 of the management server 1000, the user using the control panel 700 obtained the hospital information It is characterized in that it further comprises a hospital information guide means 2080 to visually provide.

Accordingly, the present invention can provide the user with a variety of information, including the health status, diagnostic information, as well as hospital information to provide the user with a variety of convenience.

The management server 1000,

Stores lung disease information including chronic obstructive pulmonary disease, interstitial lung disease, inorganic lung, asthma, chronic bronchitis, and pulmonary disease, wherein the lung disease information includes lung disease details including symptoms, causes, and prevention methods of lung disease. It is stored, including, and further comprises a lung disease information DB (1080) can transmit the lung disease information to the respiratory measurement device (10).

Accordingly, the respiratory measurement device 10 obtains the lung disease information transmitted from the lung disease information DB 1080 of the management server 1000, the obtained lung disease information using the control panel 700 Characterized in that it may further comprise a lung disease information guide means 2090 that can be provided to the user visually.

The management server 1000,

Acquire the lung health state information of the user first diagnosed by the lung health diagnosis means 1030 by using the user information stored in the user information DB (1010) and the respiratory rate information stored in the respiratory rate information DB (1020),

Basic diagnosis information is generated by matching the user information with the lung health status information and the key number of the first diagnosed user,

The lung health diagnosis means 1030 continuously obtains the lung health state information of the user with respect to the respiratory volume information obtained from the respiratory measurement device 10 that matches the user information stored in the user information DB 1010. Characterized in that it further comprises a user diagnostic information updating means 1090 for matching and continuously updating and storing it in the diagnostic information.

The breathing exercise guide providing means 2040 of the breathing apparatus 10,

When the user performs the breathing exercise using the breathing exercise guide information provided to the user, the execution confirmation information transmitting unit 2041 for transmitting the execution confirmation information including whether the facts and the number of executions to the management server 1000 Characterized in that it may further include.

The management server 1000,

Acquire the execution confirmation information transmitted from the breathing exercise guide providing means 2040 of the respiratory measurement device 10, and the user's lung health status information and the hospital information is updated and stored in the user diagnostic information updating means 1090 In the management means 1070 using a log file (log file), which transmits the hospital information to the breathing apparatus 10,

Based on one or more user information and basic diagnosis information of the user,

When the user performs the respiratory exercise according to the respiratory exercise guide information provided by the management server 1000, whether or not the development or deterioration of the pulmonary health state information of the user who has been diagnosed afterwards and the hospital information are transmitted from the management server 1000. After that, analyze whether or not the development or deterioration of lung health status information of the diagnosed user is changed,

Based on the analysis result may further include a learning update means 1100 for learning the number of cases to provide breathing exercise guide information or hospital information that can increase the development potential in accordance with the basic diagnosis information of the user, characterized in that do.

The management server 1000,

Respiratory volume information of the user stored in the respiratory volume information DB 1020 and user information stored in the user information DB 1010 and the lung health diagnosis means 1030 using the number of cases learned by the learning update means 1100. The exercise guide information generating means 1040 or the hospital information management means to provide the user with the respiratory exercise guide information or the hospital information that can develop the user's health state according to the lung health state information of the user diagnosed in Characterized in that it may further include a learning-based system control means 1110 to control 1070.

Accordingly, the management server 1000 of the present invention does not simply provide the above-described service or information to the user by the administrator or simply set conditions, but learns the processing result by the management server 1000 itself, and the continuous data result. Based on the learning base, the user can be guided to provide the most ideal exercise method.

Artificial intelligence based individual lung health management system using the present invention breathing apparatus according to the above configuration,

By miniaturizing the respiratory measuring device, it is possible to measure the respiratory volume of the examinee anytime, anywhere, as well as at home or in the hospital, and by separately configuring the sensor for measuring the respiratory airflow and the air flow path through which the respiratory airflow is moved, the sensor and air It provides an effect that can easily wash and remove foreign substances generated in the flow path.

In addition, the effect of increasing the sensing sensitivity while simplifying the structure is provided.

In addition, while measuring the respiratory volume of the user, the user is able to check the respiratory volume is provided with the effect that can directly check the lung state of the user.

In addition, by providing a user with a custom breathing exercise method, the user can perform the breathing exercise on their own to provide an easy effect on lung health management.

In addition, it is possible to measure the respiratory volume anywhere using the miniaturized respiratory measurement device, it is provided with the effect that can be combined with the breathing exercise.

It has been described above with respect to the preferred embodiment of the breathing apparatus according to the present invention.

The above-described embodiments are to be understood in all respects as illustrative and not restrictive, the scope of the invention being indicated by the claims that follow, rather than the foregoing detailed description. And it is to be understood that all changes and modifications derived from the equivalent concept as well as the meaning and scope of the claims are included in the scope of the present invention.

100: first body 110: air flow path
120: opening 200: second body
300: respiration measurement unit 310: respiration measurement sensor module
311: sensing euro 312: sensing unit
320: first differential pressure generation block 330: second differential pressure generation block
340: substrate 350: third differential pressure generating block
360: fourth differential pressure generating block 400: mouthpiece engaging member
410: metal body 420: filter
500: mouthpiece 510: magnetic material
520: breathing ball 600: breathing pressure control unit
610: rotation member 620: rotation axis
630: pressure control ball 900: user terminal
1000: management server 10: breathing apparatus

Claims (5)

In the artificial lung based personal health care system using a breathing apparatus,
A respiratory measurement device 10 for measuring a respiratory volume of the user, transmitting the measured respiratory volume information to the management server 1000, and guiding a respiratory exercise to the user by using respiratory exercise guide information transmitted from the management server 1000;
Management server 1000 for analyzing the lung health status of the user based on the respiratory rate information transmitted from the respiratory measurement device 10 to provide the respiratory measurement device 10 with respiratory health status information or respiratory exercise guide information according to the lung health status. ),
The respiratory measurement device 10 includes a control panel 700 is formed of a touch panel that can be operated by the user and performs a display role,
The respiration measuring device 10 receives the user's personal information of any one or more of the user's name, gender, age, height, weight, phone number, disease presence information from the user using the control panel 700, the user User information input means 2010 for storing user information including any one or more of personal information of the personal information and the serial number of the respiratory measurement device 10 and transmitting the stored user information to the management server 1000; Respiratory volume measuring means 2020 for transmitting the respiratory volume information of the user measured in the respiratory measurement unit to the management server 1000; Respiration measurement guide means 2030 for guiding the respiration measurement using the control panel 700 when the user measures the respiratory volume using the respiratory measurement device 10; Respiratory movement guide information is obtained from the management server 1000, the breathing exercise guide providing means for guiding the user's breathing movement to the object of the animation type using the control panel 700, the obtained breathing movement guide information (2040) ; User health information providing means 2050 for receiving lung health status information from the management server 1000 and providing lung health status information to a user using the control panel 700; Further comprising a process module 2000 including any one or more of
The management server 1000 generates a key number, generates a table by mapping the user information from the respiration measuring apparatus 10 to the generated key number, and stores and manages user information corresponding to the key number. DB 1010; Respiratory volume is obtained by obtaining the user's respiratory volume information from the respiratory measurement device 10, generating a table by matching the acquired respiratory volume value with the key number, and storing and managing the respiratory volume information of the user corresponding to the key number Information DB 1020; Lung health diagnosis means for diagnosing lung disease health condition using the user's respiratory volume information stored in the respiratory volume information DB 1020, and transmitting to the respiratory measurement device 10 matching the respiratory volume information using the diagnosed lung health status information AI-based personal lung health management system using a respiratory measurement device, characterized in that it further comprises (1030).
The method of claim 1,
The respiratory measuring device 10,
A first main body 100 having an air flow path formed therein to allow the air generated by the user's breath to flow in, and having an opening formed by opening a portion of the air flow path;
A second main body including a respiration measurement unit 300 for measuring a pressure of air moving through the air flow path, the second main body being formed to be detachable from the first main body and installed to close the opening formed in the first main body ( AI-based individual lung health management system using a breathing apparatus comprising a).
delete delete The method according to claim 1 or 2,
The management server 1000 stores the respiratory exercise guide information on the respiratory exercise method using the respiratory measuring device 10, and adjusts the user's health according to the lung health state information diagnosed by the lung health diagnosis means 1030. Further comprising a movement guide information generating means 1040 for generating respiratory exercise guide information that can be improved, and transmitting the generated respiratory exercise guide information to the respiratory measurement device 10 matching the diagnosed lung health state information. AI-based individual lung health management system using a breathing apparatus characterized in that.

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