KR20210128546A - Apparatus for respiration rehabilitation - Google Patents

Abstract

According to an embodiment of the present invention, a portable respiration rehabilitation device comprises: an exhalation inlet unit through which exhalation of a user is inputted; an exhalation sensing unit having one side coupled to the exhalation inlet unit to detect the exhalation of the user transmitted from the exhalation inlet unit and discharge it to the outside; and a body formed to surround the exhalation sensing unit, having an open area formed to expose an upper side of the exhalation sensing unit on one side thereof, and having a button formed with which the user can input and a display for outputting a sensing result of the exhalation sensing unit.

Description

Portable respiratory rehabilitation device {APPARATUS FOR RESPIRATION REHABILITATION}

The present invention relates to a respiratory rehabilitation apparatus, and more particularly, to a portable respiratory rehabilitation apparatus configured to control a load generated during exhalation of a user and to be easily portable by a user.

With industrial development, many pollutants are emitted from factories and automobiles, and the number of people suffering from respiratory diseases such as lung and bronchial diseases due to yellow or fine dust containing heavy metals is rapidly increasing every year.

In order to treat these respiratory diseases, not only drug therapy but also comprehensive respiratory rehabilitation such as chest physical therapy and psychotherapy are received.

At this time, through the exhalation breathing and relaxation exercise, it is possible to receive a lot of help in removing secretions in the bronchus, alleviating bronchial stiffness, and expanding lung tissue or increasing lung capacity. This can lead to increased performance in daily life.

In particular, the exhalation respiration and relaxation exercise is one of the essential treatments for correcting the breathing pattern through exhalation respiration, strengthening the respiratory muscles, increasing alveolar ventilation, and improving the cough function for discharging secretions in the airways.

In addition, many people practice breathing methods that are suitable for their constitution and environment on a regular basis or as needed for the purpose of treating a particular disease, but for mental and physical stability.

However, since the user has to purchase an expensive breathing training device in order to perform the exhalation breathing and relaxation exercise, it is not only economically burdensome, but also has a problem of inconvenient portability.

Moreover, the conventional breathing training apparatus has a problem in that it is not possible to selectively adjust the load acting on exhaled breathing according to the user's health condition or lung capacity, etc., resulting in inconvenience during use.

On the other hand, the following prior art documents disclose a respiratory trainer for lung disease patients and a chest physical therapy system using the same, but the technical gist of the present invention is not disclosed.

Republic of Korea Patent Publication No. 1999-001682

Portable respiratory rehabilitation apparatus according to an embodiment of the present invention aims to solve the following problems in order to solve the above-described problems.

It is to provide a portable respiratory rehabilitation device that can easily control the load during the user's breathing, and further accurately and easily grasp the user's breathing state.

In addition, it is possible to easily discharge the user's sputum by generating a vibration based on the user's exhalation pressure and delivering it to the user's oral cavity, and to provide a portable respiratory rehabilitation apparatus configured in a compact size and easy to carry.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those of ordinary skill in the art from the following description.

A portable respiratory rehabilitation apparatus according to an embodiment of the present invention includes an exhalation inlet unit through which the user's exhalation is introduced; an exhalation sensing unit having one side coupled to the exhalation inlet unit to detect the user's exhalation transmitted from the exhalation unit and discharge to the outside; and a button formed so as to surround the exhalation sensing unit, an open area is formed on one side to expose the upper side of the exhalation sensing unit, and a button formed so that a user can input it on the other side, and outputting the detection result of the exhalation sensing unit and a body provided with a display.

The exhalation sensing unit may include: a first connection part coupled to one side of which is communicated with the exhalation inlet unit; a seating part disposed inside the first connection part; a vibration generating ball seated on the seating portion and generating vibration based on the user's exhalation pressure transmitted from the exhalation inlet unit; a rotary rotor disposed on the seating portion and rotating based on the user's exhalation pressure transmitted from the exhalation inlet unit; and a second connection part in which one side is coupled to communicate with the other side of the first connection part, and a first discharge hole for discharging the exhaled air transmitted from the first connection part is formed on a part of the side surface.

The rotary rotor may include: a lower support part disposed non-rotatably on the upper part of the seating part and including a rotation shaft formed in the center and a plurality of first through-holes radially disposed about the rotation shaft; a rotary blade inserted into the lower support part's rotational shaft and comprising a plurality of blades configured to rotate about the rotational shaft based on the user's exhalation flowing in through the first through hole; It is preferable to include; an upper support portion disposed on the upper portion of the rotary blade and having a receiving groove for accommodating the end of the rotary shaft.

The body includes a proximity sensor for sensing the number of rotations or the rotational speed of the rotor blade, a sensing hole is formed in a side surface of an area in which the rotation blade is disposed among the first connection parts, and the proximity sensor is located inside the body Among them, it is preferable to be disposed in an area adjacent to the sensing hole.

The exhalation detecting unit further includes; a discharge control unit rotatably coupled to the other side of the second connection unit and disposed to be exposed through an open area of the body, and the first discharge unit is provided in a partial area on the side of the discharge control unit. It is preferable that the second discharge hole corresponding to the ball is formed.

The body may include: a first housing formed to surround the exhalation sensing unit and having an open area to expose an upper side of the exhalation sensing unit; a first substrate disposed inside the first housing and having a proximity sensor mounted on one side; a second board disposed to be spaced apart from the other side of the first board and on which an external terminal connector, a display, and a switch are mounted; a battery for supplying power to the first and second substrates; and a second housing coupled to the first housing to accommodate the first substrate, the second substrate, and the battery, wherein the second housing has an open area such that the display and the button are exposed to the outside, respectively. It is preferable to be

A respiration state determination unit for diagnosing the user's respiration state based on the detection result sensed by the exhalation detection unit on the first substrate or the second substrate; an output unit for outputting the determination result of the respiration state determination unit to the display; and a communication unit for transmitting the determination result of the respiration state determination unit to an external terminal.

Portable respiratory rehabilitation device according to an embodiment of the present invention is provided with a vibration generating ball for generating vibration based on the user's exhalation pressure therein, and using this to transmit vibration to the user's oral cavity, the user's airway sputum efficiently There is an ejection effect.

In addition, there is an effect of easily grasping the user's rehabilitation status by having an expiration detection means capable of accurately and efficiently measuring the user's expiratory volume therein.

In addition, it is configured to transmit the user's respiration condition detected by the exhalation detection means to an external terminal such as a smart phone or PC as well as a display provided therein, thereby continuously managing the user's respiration rehabilitation condition.

Furthermore, since it is configured to easily control the load during exhalation, there is an effect that customized rehabilitation treatment according to the user's breathing ability is possible.

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

1 and 2 are perspective views of a portable respiratory rehabilitation apparatus according to an embodiment of the present invention.
3 and 4 are exploded perspective views of a portable respiratory rehabilitation apparatus according to an embodiment of the present invention.
5 is a cross-sectional view of a portable respiratory rehabilitation apparatus according to an embodiment of the present invention.
6 is an exploded perspective view of a rotating rotor configuration among configurations of a portable respiratory rehabilitation device according to an embodiment of the present invention.

A preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings, but the same or similar components are assigned the same reference numerals regardless of reference numerals, and overlapping descriptions thereof will be omitted.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easy understanding of the spirit of the present invention, and should not be construed as limiting the spirit of the present invention by the accompanying drawings.

Hereinafter, a portable respiratory rehabilitation apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.

The portable respiratory rehabilitation apparatus according to an embodiment of the present invention is configured to include an exhalation inlet unit 100 , an exhalation sensing unit 200 and a body 300 as shown in FIGS. 1 to 6 .

The exhalation inlet unit 100 is inserted into the user's oral cavity to allow the user's exhalation to flow, and the end is preferably formed so that the left and right widths are relatively longer than the upper and lower heights so that the user can easily bite into the mouth.

The exhalation detecting unit 200 performs a function of detecting the user's exhalation transmitted from the exhalation inlet unit 100 and discharging to the outside.

As shown in FIGS. 3 to 5 , the exhalation detection unit 200 includes a first connection part 210 , a seating part 220 , a vibration generating ball 230 , a rotating rotor 240 , and a second connection part 250 ). And it is configured to include a discharge control unit (260).

The first connection unit 210 is configured such that one side is coupled to communicate with the above-described exhalation inlet unit 100, and for easy cleaning of the exhalation inlet unit 100, the exhalation inlet unit 100 and the first connection unit 210) are preferably coupled to each other to be detachable.

In particular, it is possible to prevent the exhalation inlet unit 100 from being easily detached from the exhalation sensing unit 200 by coupling both components to each other in an interference fitting manner.

The seating unit 220 is configured to be disposed inside the first connection unit 210 , and the vibration generating ball 230 performs a function of generating vibration based on the user's exhalation pressure transmitted from the exhalation inlet unit 100 . do.

The seating portion 220 and the vibration generating ball 230 repeatedly regulate the flow of exhaled air passing along the inside of the first connecting portion 210 by the pressure change of the exhaled air, and through the vibration generated according to the interruption, the trachea, bronchus And it helps to separate the sputum attached to the lungs and discharge them out of the body.

To this end, the seating part 220 has an opening/closing hole through which exhaled air passes in the center, is formed in a downwardly inclined shape from the outside to the center, and the vibration generating ball 230 is seated to block the opening/closing hole of the seating part 220 . It is seated in the upper center of the part 220 .

That is, the vibration generating ball 230 is seated on the upper part of the seating part 220 by its own weight and the shape of the seating part 220 to block the opening and closing holes of the seating part 220 when exhaled from the first connection part 210 ) It can generate vibration while repeatedly ascending and descending according to the pressure change that occurs when passing through the interior.

The vibration generated by the seating unit 220 and the vibration generating ball 230 is transmitted to the user's body to vibrate the trachea, bronchial tubes and lungs, through which the sputum attached to the trachea, bronchial tubes and lungs is discharged outside the body. can

The rotary rotor 240 is disposed on the upper portion of the above-described seating unit 220 and rotates based on the user's exhalation pressure transmitted from the exhalation inlet unit 100. To detect the exhalation state such as the user's exhalation pressure. configuration for it.

As shown in FIG. 6 , the rotary rotor 240 includes a lower support part 243 , a rotary blade 241 , and an upper support part 242 .

The lower support part 243 is disposed on the seating part 220 and is formed to include a rotation shaft formed in the center and a plurality of first through holes.

In particular, the lower support part 243 should be disposed so as not to be rotated by the user's exhalation, and for this purpose, a rotation preventing protrusion may be formed on one side of the outside, and a plurality of first through holes to ensure uniform movement of the exhalation It is preferable to be formed radially around the rotation axis.

The rotary blade 241 has a hollow in the center so that the rotation shaft of the lower support part 243 can be inserted, and is formed to include a plurality of blades configured to rotate about the rotation shaft.

These wing parts may be formed so that the lower part is inclined in one direction as shown in FIG. 6 in order to ensure smooth rotation by the exhaled air flowing in from the downward direction, and a plurality of wing parts are formed to be spaced apart from each other at the same distance, so that the correct user It is possible to measure the expiratory volume or exhalation rate of

The upper support part 242 is disposed on the upper portion of the rotary blade 241 and has a receiving groove in the center to accommodate the end of the rotation shaft of the lower support part 243 .

That is, the lower and upper portions of the rotary blade 241 are supported by the lower support portion 243 and the upper support portion 241, so that the movement of the rotary blade 241 in the vertical direction due to the inhalation of exhalation can be restricted.

On the other hand, the inside of the body 300 to be described later includes a proximity sensor 321 for detecting the number of rotations or the rotational speed of the rotary blade 241, and through this, the user's exhalation state can be identified. to be described later.

The second connection part 250 is coupled such that one side communicates with the other side of the first connection part 210 , and the other side is formed to be closed, and a first discharge for discharging the exhaled air transmitted from the first connection part 210 to a side part of the second connection part 250 . A ball 251 is formed.

Therefore, the user's exhalation flowing in from the exhalation inlet unit 100 passes through the first connection part 210 and drives the vibration generating ball 230 and at the same time rotates the rotary blade 241 of the rotary rotor 240 and then the second It flows into the second connection part 250 and is discharged through the first discharge hole 251 .

The discharge control unit 260 is configured to be rotatably coupled to the second connection unit 250 , and is specifically formed in a cylindrical shape to surround the outer circumferential surface of the second connection unit 250 .

The discharge control unit 260 is disposed so as to be exposed to the outside through the open area 311 of the first housing 310 among the body 300 to be described later, and has a plurality of external surfaces on the outer circumferential surface so as to be easily rotated by the user. Protrusions and grooves are formed.

In addition, a second discharge hole 261 corresponding to the first discharge hole 251 is formed in a partial region of the side of the discharge control unit 260 , and through this, the amount of exhaled air discharged through the first discharge hole 251 is adjusted. be able to

In particular, the first discharge hole 251 and the second discharge hole 261 are preferably formed to be long in the horizontal direction, and the user can set the second discharge hole 261 to be the same as the position of the first discharge hole 251 . When the discharge control unit 260 is rotated, the user can most easily exhaled because the load is the smallest.

Conversely, when the user rotates the discharge control unit 260 to minimize the overlapping area between the second discharge hole 261 and the first discharge hole 251, the load is the largest, so exhalation breathing training with high difficulty from the user's point of view This is possible.

The body 300 is configured to support the exhalation sensing unit 200 and accommodate various functional means, the first housing 310, the first substrate 320, the battery 330, the second substrate 340, It includes a second housing 350 , a button 360 , an external terminal 380 , and the like.

One side of the first housing 310 is formed to accommodate the exhalation sensing unit 200 , and the other side is formed to accommodate a first substrate 320 , which will be described later, a battery 330 , and the like.

Specifically, as shown in FIGS. 3 to 4 , one side of the first housing 310 is formed in a cylindrical shape so that an upper region of the first connection part 210 and a lower region of the second connection part 250 can be inserted. In the upper part, an open area 311 is formed so that a part of the discharge control unit 260 of the exhalation sensing unit 200 can be exposed to the outside.

In addition, a plurality of scales may be displayed on the lower portion of the open area 311 of the first housing 310 , so that the amount of opening of the first discharge hole 251 through the discharge control unit 260 can be visually checked. do.

The first substrate 320 is disposed inside the first housing 310 and has a configuration in which the proximity sensor 321 is mounted, and the proximity sensor 321 is the rotary blade 241 of the rotary rotor 240 as described above. It is a means of detecting the rotational speed of

For this purpose, the position in the vertical direction of the proximity sensor 311 and the rotary blade 241 should be the same, and furthermore, a sensing hole 211 is formed in the area where the rotary blade 241 is disposed among the first connection parts 210. .

The second board 240 is configured to be spaced apart from the other side of the first board 320 , and an external terminal connector 343 , a display 341 , and a switch 342 are mounted on the second board 240 . .

The external terminal connector 343 is connected to the external terminal 380 formed on the outside of the body 300 and is configured to charge a battery or perform wired communication with an external terminal to be described later, and the display 341 is the user's breathing It performs a function of outputting the state, the state of the portable respiratory rehabilitation apparatus, etc. to the outside, and the switch 342 performs a function of driving by the button 360 exposed to the outside so that the user can operate it.

The battery 330 performs a function of supplying power to the above-described first substrate 320 and second substrate 340 , and the second housing 350 is coupled to the first housing 310 to form the first substrate ( 320 ), the second substrate 340 , and a configuration for accommodating the battery 330 .

In particular, the second housing 350 may have an open area so that the display 341 and the button 360 can be exposed to the outside, respectively.

The cover 370 is configured to protect a portion of the front surface of the second housing 350, and is specifically configured to cover the upper surface of the display 341, thereby preventing damage to the display 341 due to external impact. Not only that, but also an aesthetic effect can be realized.

Accordingly, the cover 370 is preferably formed of a transparent material, and an open area should be formed in a portion corresponding to the button 360 so as not to interfere with the user's operation of the button 360 .

On the other hand, at least one of the first substrate 320 or the second substrate 340 according to an embodiment of the present invention has a breathing state for diagnosing the user's breathing state based on the detection result detected by the exhalation detection unit 200 A judgment unit may be provided.

Specifically, when the rotary blade 241 of the rotary rotor 240 is rotated by the user's exhalation, the proximity sensor 321 may detect the number of rotations or the rotation speed of the rotary blade 241, and the proximity sensor 321 ) based on the detection result of the respiration state determination unit may diagnose the user's respiration state.

In addition, the number of rotations or rotational speed of the rotary blades 241 of the rotary rotor 240 may be affected by the user's exhalation amount as well as the opening degree of the first discharge hole 251 of the second connection part 250 .

Therefore, the portable respiratory rehabilitation apparatus according to an embodiment of the present invention may further include an opening amount detection sensor for detecting the opening amount of the first discharge hole 251 by the discharge control unit 260, at this time breathing The state determination unit is preferably configured to diagnose the user's breathing state in consideration of both the detection contents of the proximity sensor 321 and the detection contents of the opening degree detection sensor.

In addition, the first substrate 320 or the second substrate 340 may include an output unit and a communication unit.

The output unit performs a function of outputting the determination result of the respiration state determination unit to the display 341, and the communication unit performs a function of transmitting the determination result of the respiration condition determination unit to an external terminal.

In particular, the communication unit is configured to be able to communicate with an external terminal wirelessly or by wire, so that the user's respiration state result measured by the portable respiratory rehabilitation device can be transmitted to a smart phone possessed by the user.

Furthermore, it is possible to install an application corresponding to the portable respiratory rehabilitation device according to an embodiment of the present invention in an external terminal such as a smart phone, and thereby, the user can check the respiratory rehabilitation state according to the lapse of time at a glance, and further play the game Through this, it is possible to induce active respiratory rehabilitation of the user.

As mentioned above, although the present invention has been described in detail using preferred embodiments, the scope of the present invention is not limited to specific embodiments and should be construed according to the appended claims. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

100: exhalation inlet unit
200: exhalation detection unit
300: body

Claims (7)

an exhalation inlet unit through which the user's exhalation is introduced;
an exhalation sensing unit having one side coupled to the exhalation inlet unit to detect the user's exhalation transmitted from the exhalation inlet unit and discharge to the outside; and
Is formed to surround the exhalation sensing unit, an open area is formed to expose the upper side of the exhalation sensing unit on one side, and a button formed so that a user can input it on the other side, and a display for outputting the detection result of the exhalation sensing unit a body provided with;
A portable respiratory rehabilitation device comprising a.
The method according to claim 1, The exhalation sensing unit,
a first connection part having one side coupled to communicate with the exhalation inlet unit;
a seating part disposed inside the first connection part;
a vibration generating ball seated on the seating portion and generating vibration based on the user's exhalation pressure transmitted from the exhalation inlet unit;
a rotary rotor disposed on the seating portion and rotating based on the user's exhalation pressure transmitted from the exhalation inlet unit; and
a second connection part having one side coupled to communicate with the other side of the first connection part, and a first discharge hole for discharging the exhaled air received from the first connection part on a part of the side surface;
A portable respiratory rehabilitation device comprising a.
The method according to claim 2, The rotary rotor,
a lower support part disposed non-rotatably on the upper part of the seating part and including a rotation shaft formed in the center and a plurality of first through-holes radially disposed about the rotation shaft;
a rotary blade inserted into the lower support part's rotational shaft and comprising a plurality of blades configured to rotate about the rotational shaft based on the user's exhalation flowing in through the first through hole;
an upper support portion disposed on the upper portion of the rotary blade and having a receiving groove for accommodating the end of the rotary shaft;
A portable respiratory rehabilitation device comprising a.
4. The method according to claim 3,
The body includes a proximity sensor for detecting the rotation speed or rotation speed of the rotary blade,
A sensing hole is formed in a side surface of an area in which the rotary blade is disposed among the first connection parts,
The proximity sensor is a portable respiratory rehabilitation device disposed in an area adjacent to the sensing hole of the inside of the body.
The method according to claim 2, The exhalation sensing unit,
It further includes; a discharge control part that is rotatably coupled to the other side of the second connection part and is disposed to be exposed through the open area of the body,
A portable respiratory rehabilitation device in which a second discharge hole corresponding to the first discharge hole is formed in a partial region of the side of the discharge control unit.
The method according to claim 2, The body,
a first housing formed to surround the exhalation sensing unit and having an open area to expose an upper side of the exhalation sensing unit;
a first substrate disposed inside the first housing and having a proximity sensor mounted on one side;
a second board disposed to be spaced apart from the other side of the first board and on which an external terminal connector, a display, and a switch are mounted;
a battery for supplying power to the first and second substrates;
a second housing coupled to the first housing to accommodate the first substrate, the second substrate, and a battery;
including,
The second housing is a portable respiratory rehabilitation device in which an open area is formed so that the display and the button are exposed to the outside, respectively.
7. The method of claim 6,
A respiration state determination unit for diagnosing the user's respiration state based on the detection result sensed by the exhalation detection unit on the first substrate or the second substrate;
an output unit for outputting the determination result of the respiration state determination unit to the display; and
a communication unit for transmitting the determination result of the respiration state determination unit to an external terminal;
A portable respiratory rehabilitation device comprising a.

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