KR102009285B1 - Apparatus for air supply measuring using sound of manual ventilator - Google Patents

Abstract

The present invention relates to an air supply measuring device using the sound of a manual ventilator, and more particularly, by measuring the air volume by the sound generated during the air injection, and stably administer and maintain an appropriate tidal volume according to the patient's respiratory volume by weight. The present invention relates to an air supply measuring apparatus using a sound of a manual ventilator.
In the air supply measuring device using the sound of the manual ventilator according to the present invention, one side is connected to the air bag and the other side is installed on one side of the air injection unit is connected to the mask, the sound by the air injected into the air injection unit Sound generating unit for generating; A microphone for obtaining a sound generated by the sound generator; An amplifier for amplifying the analog sound signal applied from the microphone; And a controller configured to calculate an amount of air by comparing the sound amplified by the amplifier with sound information of a database already stored.

Description

Apparatus for air supply measuring using sound of manual ventilator}

The present invention relates to an air supply measuring device using the sound of a manual ventilator, and more particularly, by measuring the air volume by the sound generated during the air injection, and stably administer and maintain an appropriate tidal volume according to the patient's respiratory volume by weight. The present invention relates to an air supply measuring apparatus using a sound of a manual ventilator.

In general, BVM (Bag Valve Mask) is used to force air to help maintain stable breathing of emergency patients or critically ill patients.It provides effects such as CPR by directly supplying air to patients when it is difficult for them to breathe themselves. It is a mechanism for making a bet.

On the other hand, conventional BVMs have a problem in that medical accidents are generated by providing air to the patient and administering the air depending on a general sense such as chest height for accurate air supply.

In addition, until now, the technology for measuring the air supply has not been developed, and the existing equipment is large-scale fixed equipment, which is difficult to use in an emergency site, so it was forced to supply air based on the experience of an operator such as a specialist.

An example of the technique for solving such a problem is disclosed by following patent document 1.

Patent Document 1 is a pressure point for pressing the end of the finger while the user's fingers wrap the airbag to continuously ventilate a certain amount of air to the patient to be artificially breathing, the pressing portion is configured in the airbag, and cut off from the outside A mask configured to be in close contact with the patient's nose and mouth; The air bag containing oxygen or air; And a connecting hose for communicating the mask and the airbag, wherein the airbag is configured such that the oxygen or air received during pressurization is introduced through the airway of the patient through the connecting hose and the mask, and the pressing unit is identified. It is disclosed for a BVM for proper air ventilation, characterized in that formed.

However, the conventional technique as described above should adjust the tidal volume and the ventilation according to the condition of the patient, but since the conventional ventilator can only rely on the experience of a specialist, the patient's condition changes rapidly. There was a problem that the first aid is not properly implemented due to a significant drop in coping ability. In addition, there is an urgent need to develop a device that can provide more accurate tidal volume to pediatric and adolescent patients who need to provide a wide range of ventilation due to various age and body size changes.

Republic of Korea Patent Registration No. 10-1287171 (July 11, 2013 registration)

An object of the present invention is to solve the problems as described above, to evaluate the amount of air produced by amplifying the sound generated during the air injection through the microphone to stably administer an appropriate tidal volume according to the patient's respiratory volume by weight And it is an object to provide an air supply measuring device using the sound of a manual ventilator that can be maintained.

In order to achieve the above object, the air supply measuring device using the sound of the manual ventilator according to the present invention, one side is connected to the air bag 80 and the other side is installed on one side of the air injection unit, the air injection unit A sound generator for generating sound by the air injected into the inside; A microphone for obtaining a sound generated by the sound generator; An amplification unit electrically connected to the microphone 30 to amplify an analog sound signal applied from the microphone; And a control unit electrically connected to the amplifying unit so as to receive the amplified sound through the amplifying unit, and calculating an amount of air by comparing the amplified sound with sound information of an already stored database. It includes, The sound generating unit, and includes a sound member of the tubular form for generating a sound by vibration generated when colliding with the air injected into the air injection unit 10, The sound member is the air injection An inlet through which air is introduced to be connected to the unit, and formed at one side of the air outlet through which the air is discharged by being connected to the mask, and provided to correspond to the microphone at a position proximate to the inlet to be injected through the inlet; And a sound generating groove for inducing sound while inducing air, and the control unit analyzes the decibels or hertz per hour of the received sound, and if the decibel or hertz above the reference level is maintained for more than the reference time, It is characterized by reducing to a set amount of air.

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The display unit may be electrically connected to the control unit to display the air amount calculated by the control unit. And a power supply unit electrically connected to the control unit to supply power to the control unit.

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As described above, according to the air supply measuring device using the sound of the manual ventilator according to the present invention, by using the sound generated during the air injection to calculate the amount of air calculated by the numerical value, according to the patient's respiratory volume by weight once By stably administering and maintaining the respiratory rate, there is an effect of preventing medical accidents caused by the use of a wrong ventilator.

1 is a perspective view showing an air supply measuring device using the sound of the manual ventilator according to the present invention.
Figure 2 is a schematic cross-sectional view of the air supply measuring device using the sound of the manual ventilator according to the present invention.
Figure 3 is a schematic diagram showing an air supply measuring device using the sound of the manual ventilator according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing the air supply amount measurement apparatus using the sound of the manual ventilator according to the present invention, Figure 2 is a cross-sectional view schematically showing the air supply amount measurement apparatus using the sound of the manual ventilator according to the present invention, Figure 3 is a schematic diagram showing an apparatus for measuring air supply amount using the sound of a manual ventilator according to the present invention.

As shown in Figures 1 to 3, the air supply measuring device using the sound of the manual ventilator according to the present invention, the sound generator 20, the microphone 30, the amplifier 40 and the controller 50 Include.

The air injection unit 10 is connected to the air bag 80, one side is supplied with air, the other side is connected to the mask 90 formed to be in close contact with the face of the patient.

The airbag 80 has an accommodation space formed therein to accommodate the air, preferably made of silicon or rubber. The mask 90 is configured to be in close contact with the nose and mouth of the patient to block the outside.

The air injection unit 10 is formed so that the air passes only in one direction of the external air, and when the high concentration of oxygen is required according to the condition of the patient, it is formed to connect the oxygen supply to provide oxygen.

The air injection portion 10 is a tube shape formed with a passage for receiving air, one side is connected to the air bag 80 is supplied with air, the other side is masked to be formed to be closed to the outside and in close contact with the patient's face It is provided to be connected to the air supplied from the air bag 80 to supply to the mask (90).

The sound generator 20 is installed at one side of the air injection unit 10 to generate sound by the air injected into the air injection unit 10.

The sound generating unit 20 is composed of a tubular sound member 21 for generating sound by vibration generated when colliding with the air injected into the air injection unit 10.

The sound member 21 is formed with an inlet 211 through which air is introduced into one side and an exhaust port 212 through which air is discharged from the other side, and formed at a position proximate to the inlet 211. A sound generating groove 213 is formed to guide the sound while the air injected through the) exits.

The sound generating groove 213 is formed by using a principle such as a whistle to generate sound by the wind exiting through the sound generating groove communicated with the space when the air blows into the space formed inside the body by blowing into the mouth. .

That is, when air is introduced into the inlet 211, the air escapes through the sound generating groove 213 formed at a position close to the inlet 211, and at this time, the air is stable through the sound generating groove 213. Sound is generated.

The microphone 30 acquires the sound generated by the sound generator 20 and allows the sound of air to be well received.

The microphone 30 serves to transfer the sound generated by the sound generator 20 as an audio signal, and preferably implements a high performance microphone.
As shown in FIG. 2, the microphone 30 is disposed to correspond to the sound generating groove 213 in a space portion formed inside the main body of the measuring apparatus fixed to the outer surface of the sound member 21. By doing so, the air introduced through the inlet 211 can obtain the sound generated while exiting through the sound generating groove communicating with the space part of the measuring apparatus main body.

The amplifier 40 amplifies an analog sound signal applied from the microphone 30.

The amplifier 40 amplifies the sound applied through the microphone 30 to better recognize the sound obtained through the sound generator 20.

That is, when amplifying and measuring the sound applied from the microphone 30 through the amplifying unit 40, the amount of air can be measured with fine sound.

The control unit 50 calculates the amount of air by comparing the sound amplified by the amplifying unit 40 with sound information of a database already stored.

The controller 50 analyzes the decibels or hertz of the sound per hour of the received sound, and reduces the decibels or hertz to a predetermined amount of air if the decibels or hertz exceeds the reference time.

That is, the controller 50 filters the sound output through the amplifier 40 to extract only the sound of a preset frequency band, and calculates and collects the sound volume for each frequency of the filtered sound to calculate sound energy. Done.

In addition, the control unit 50 has a predetermined sound pattern is stored in advance, information on the conversion criteria between sound energy is stored, and the sound energy calculated based on the information is converted into the amount of air.

In addition, the controller 50 may set the initially detected sound energy as a reference value, and then calculate the current amount of air from the amount of increase or decrease of the sound energy.

On the other hand, the air supply amount measuring apparatus using the sound of the manual ventilator according to the present invention is the display unit 60, the power supply unit for supplying power to the control unit 50, the air amount displayed by the control unit 50 is displayed ( 70) may be further included.

The display unit 60 controls the LED module to lightly display the amount of air calculated by the controller 50 under the control of the controller 50.

The display unit 60 preferably indicates the amount of air provided to the patient, the number of times of supply per unit time, the presence or absence of self-breathing of the patient, the amount of air introduced by end-tidal breathing, and the like.

The power supply unit 70 is a component that provides power to operate the control unit 50, and supplies power by using the constant power supplied to the building, the battery is not supplied due to the power failure It can replace the power supply and can supply power continuously.

That is, the power supply unit 70 supplies power for driving the components of the control unit 50 from a constant power source or a battery disposed at one end of the measuring device main body.

On the other hand, the air supply measuring device using the sound of the manual ventilator according to the present invention is provided so that the power supply unit 70 is automatically operated within a few seconds, a predetermined button or switch, etc. for operating the power supply unit 70 An input means is provided to manually operate the power supply unit 70 through the above input means.

As described above, the air supply measuring device using the sound of the manual ventilator according to the present invention by numerically displaying the calculated air volume using the sound generated during the air injection of the ventilator, according to the patient's respiratory volume by weight By stably administering and maintaining an appropriate tidal volume, medical accidents resulting from the use of the wrong ventilator can be prevented.

Although the present invention has been described with reference to the accompanying drawings, preferred embodiments will be apparent to those skilled in the art that various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the invention should be construed by the claims described to include examples of many such variations.

10: air injection unit 20: sound generating unit
21: sound member 211: inlet
212: exhaust port 213: sound generating groove
30: microphone 40: amplifier
50: control unit 60: display unit
70: power supply 80: air bag
90 mask

Claims (5)

One side is connected to the air bag 80 and the other side is installed on one side of the air injection unit 10 connected to the mask 90, the sound to generate a sound by the air injected into the air injection unit 10 Generating unit 20;
A microphone 30 for obtaining a sound generated by the sound generator 20;
An amplifier 40 electrically connected to the microphone 30 to amplify an analog sound signal applied from the microphone 30; And
A control unit 50 electrically connected to the amplifying unit 40 to receive the amplified sound through the amplifying unit 40 and comparing the amplified sound with sound information of an already stored database to calculate an amount of air; Including,
The sound generator 20 includes a sound member 21 in the form of a tube that generates sound by vibration generated when colliding with the air injected into the air injection unit 10,
The sound member 21 is connected to the air injection portion 10 to form an inlet 211 through which air is introduced, and an exhaust port 212 connected to the mask 90 to discharge air to the other side. And a sound generating groove 213 provided to correspond to the microphone 30 at a position proximate to the inlet 211 so as to generate sound while the air injected through the inlet 211 exits. Forming,
The control unit 50,
An apparatus for measuring air supply using a sound of a manual ventilator, which analyzes decibels or hertz per hour of a received sound and reduces the decibels or hertz to a predetermined amount of air if the decibels or hertz exceeds a reference level. delete delete The method according to claim 1,
A display unit 60 electrically connected to the control unit 50 to display the air amount calculated by the control unit 50;
A power supply unit 70 electrically connected to the control unit 50 to supply power to the control unit 50;
Air supply amount measurement apparatus using the sound of the manual respirator, characterized in that it further comprises. delete

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