KR102539839B1 - Automatic Operating Device For Ambubag Ventilator - Google Patents

Abstract

An automatic operating device (1) for a manual AMBUBAG ventilator is to automatically operate a manual AMBUBAG ventilator. The automatic operating device (1) for a manual AMBUBAG ventilator includes: an AMBUBAG ventilator receiving unit (100) which accommodates an air bag (2) of the AMBUBAG ventilator; and an operating unit (200) which pressurizes the air bag (2) accommodated in the AMBUBAG ventilator receiving unit (100) to suck in air or reduces the air to expel the air. The AMBUBAG ventilator receiving unit (100) includes a sliding unit (140). The AMBUBAG ventilator receiving unit (100) includes a receiving unit insertion unit (240) which is a space which is inserted or withdrawn into the operating unit (200) by the sliding unit (140) in a sliding manner and is included in the lower layer of the operating unit (200). According to the present invention, the operation of the manual AMBUBAG ventilator by the general public can be replaced, a structure can be simplified to facilitate an operation. In addition, the automatic operating device can be easily placed or carried in various places, and can replace expensive hospital AMBUBAG ventilator, such that costs can be saved.

Description

Automatic Operating Device For Ambubag Ventilator}

The present invention relates to an automatic operation device that allows a manual ventilator (arm bag) to be operated automatically without manual operation by a person, and is dedicated to a ventilator that can easily supply oxygen to a patient without the help of ordinary people or medical staff. It's about automatic operation.

A ventilator is an essential medical device that automatically and manually supplies an appropriate amount of oxygen safely and effectively to a patient who has stopped breathing momentarily or suffers from respiratory failure or difficulty breathing, thereby reviving the life of an emergency patient.

The automatic ventilator is mainly used in hospitals, and the automatic ventilator is mainly used in hospitals. When the patient's airway is not secured or spontaneous breathing begins, or when the airway pressure exceeds the maximum airway pressure, the oxygen pressure automatically increases with an alarm sound. It is a relatively expensive equipment for discharging.

In contrast, passive ventilators, often referred to as ambu bags or AMBUs (Artificial Manual Breathing Units), are relatively inexpensive and consist of a rugby ball-shaped air bladder that manually provides pressure to create artificial respiration and , It has a configuration in which connectors are connected before and after the air bag.

The manual ventilator provides artificial respiration by continuously applying pressure to an air bag by a person other than the patient (a general public or medical staff).

Although new technologies are being improved for automatic ventilators, manual ventilators have a difference in that the general public or medical staff must manually and periodically pressurize the air bag. There are possible problems.

Therefore, in order to solve the above problems, various devices that automatically pressurize the air bag in the case of a manual ventilator are disclosed. Patent Literature 1)” is disclosed, Patent Literature 1 discloses that the air bladder of a passive ventilator is connected to a compression arm in order to solve the inconvenience of a person directly compressing the air bladder to supply oxygen or air to the patient. , A drive unit for driving the compression arm is provided on a handle that can be gripped by hand on the rear surface of the compression arm, so that a certain amount of air or oxygen can be stably supplied to the patient by pressurizing the air bag at a predetermined speed and pressure. Disclosed is a driving device for a manual ventilator. However, Patent Document 1 has a complex technical configuration for automatically pressurizing a manual ventilator.

In addition, as a prior art of the Korean Intellectual Property Office, an “automatic pumping device for a ventilator (Patent Document 2)” is disclosed, and Patent Document 2 solves the inconvenience of a person directly squeezing the air bag, and also provides for adults and children. In order to be able to operate simultaneously, a circular crank plate forming a crank pin, a driving means for driving rotation, and a pressurizing means for pumping by pressing the air bag to a certain pressure. The pressurizing means discloses an automatic pumping device composed of a connect rod, a plate-shaped pressurizing plate, a torsion spring, and an air amount adjusting pressurizing plate including pressurizing protrusions. However, Patent Document 2 may also have a more complicated technical configuration than the present invention.

In addition, as a prior art of the Korean Intellectual Property Office, “Ambubaek Automatic Assist Device (Patent Document 3)” is disclosed, Patent Document 3 is a manual ventilator without a separate assistant, Ambubaek, in order to periodically supply oxygen, A housing having a seating portion in which the bag portion is seated and protruding holes formed on both side walls of the seating portion; A push unit including a pair of push bars having a pivot shaft installed in each protruding hole and a pressurizing part for pressing the bag portion, and a driving means for simultaneously rotating and operating the pair of push bars by interlocking; a technical configuration including are starting However, the push unit, which is a technical feature of Patent Document 3, has a complicated configuration.

In addition, as in the present invention, as a prior art of the Korean Intellectual Property Office for automatically pressurizing a manual ventilator, “emergency survival breathing automation device (Patent Document 4)” is disclosed. ) and an upper case 4 provided with; a lower case 8 having a lower case accommodating part 48, a pressure operation part 46, and an ambu-bag seating groove 44 for seating an ambu-bag 20 therein; a pressure operation unit 46 installed inside the lower case 8 and automatically pressurizing the ambu-bag 20 accommodated in the ambu-bag seating groove 44; An automated device including a control panel 22 installed obliquely in a groove formed in a predetermined portion of one side of the lower case 8 and allowing the user to select and operate a condition corresponding to a target patient is disclosed, but the present invention is patented. It was configured to pressurize the manual ventilator with a simpler configuration than Document 4.

In this way, since it is a device that automatically operates a manual ventilator to solve the fundamental limitation that the general public or medical personnel can only perform artificial respiration by manually pressing the manual ventilator, the automatic manual ventilator automatic operating device is It is desirable to configure it so that it can be easily used so that it can be easily operated, and the cheaper the price is, the more advantageous it is, and it is desirable to miniaturize the entire configuration of the automatic operation device including the artificial bag so that it can be installed in various places or easily carried.

On the other hand, in a manual respirator, air and/or oxygen is injected through a mask connected to an air bag, and the air bag must be pressed or released by accurately distinguishing between inhalation and exhalation. It should be used or preferably used by medical personnel.

In addition, when pressurizing the air bag to press or release the ventilator, it is preferable to press the ventilator at an accurate timing and cycle. In addition, it is preferable that the degree of pressurization, the cycle of pressurization, the pressurization speed, etc. can be freely changed according to the patient's initial state, whether he is an adult, and the degree of improvement of the patient's condition.

Patent Document 1. Korean Registered Patent No. 10-2067085 (2020.01.10) Patent Document 2. Korean Registered Patent No. 10-2151159 (2020.08.27) Patent Document 3. Korean Registered Patent No. 10-2263654 (2021.06.04) Patent Document 4. Republic of Korea Patent Publication 10-2022-0058827 (2022.05.10)

The present invention is to solve the problems of the prior art,

When an emergency occurs, it is intended to allow not only medical personnel but also ordinary people to easily operate the manual ventilator manually through an automatic operation device.

In addition, the present invention is to reduce the configuration compared to automatic operation devices for manual ventilators, which are conventional prior art, to be installed in various places and to be easily portable.

In addition, it is intended to be able to operate with precise timing and cycle even through a relatively simple device.

In addition, an object of the present invention is to provide an automatic operation device for a manual ventilator that can freely change the degree of pressurization, the pressurization cycle, and the pressurization speed according to the initial state of the patient, whether he is an adult, and the degree of improvement of the patient's condition.

In addition, unlike expensive hospital ventilators, a device for automatically operating a manual ventilator to meet the purpose of a manual ventilator is also intended to be provided at low cost.

In the manual ventilator automatic operating device (1) for automatically operating the manual ventilator,

The manual ventilator automatic operating device 1 pressurizes the ventilator accommodating part 100 accommodating the ventilator air bag 2 and the ventilator accommodating part 100 to suck in air. It may include an operation unit 200 that discharges air by reducing or reducing it again.

The ventilator accommodating part 100 may include an air bag mounting part 120 and a sliding part 140.

The air bag mounting portion 120 may accommodate the air bag 2 of the artificial respirator.

The ventilator accommodating part 100 may be characterized in that it is inserted into or withdrawn from the operating part 200 by the sliding part 140 in a sliding manner.

The ventilator accommodating part 100 may further include a patient valve exposure part 110, characterized in that fastened to correspond to the patient valve 4 of the ventilator.

The ventilator accommodating part 100 may further include an intake valve fastening part 130 which is fastened to correspond to the intake valve 6 of the ventilator.

The ventilator accommodating part 100 fastens the accommodating part of the operating part 200 when the automatic ventilator operating device 1 is stored, and the ventilator accommodating part 100 is inserted into the lower inside of the operating part 200 and stored therein. An operation part fastening part 150 coupled to the part 290 may be further included.

In addition, the automatic ventilator operating device 1 may further include a cover 300.

One side of the cover 300 is fastened to the respirator accommodating part 100, and the other side of the cover 300 is fastened to the operating part 200, so that the ventilator accommodating part 100 is inside the lower part of the operating part 200. It can be inserted into to increase stability during storage, prevent separation of the air bag 2 by the pressure bar 216 during use, and improve aesthetics.

The operating unit 200 may include a driving unit 210 for pressurizing and compressing the air bag 2 accommodated in the air bag mounting unit 120 or reducing and inflating it again.

The driving unit 210 may include a driving motor 211, and the driving motor 211 may be a step motor.

The operation unit 200 may include a pressure bar exposed portion 220, which is a space through which the pressure bar 216 moves forward or backward toward the air bag 2 accommodated in the air bag mounting portion 120.

The operation unit 200 may include an operation control unit 230 .

The operation control unit 230 may include a speed control unit 231 that controls the speed of compressing and expanding the air bag 2.

The operation control unit 230 may include a cycle control unit 232 that operates several times per minute, stops operation, and adjusts the cycle of operation again.

The operation unit 200 may include an accommodation unit insertion unit 240, which is a space in which the ventilator accommodation unit 100 is included inside the lower layer of the operation unit 200.

The operation unit 200 may include a panel unit 260 .

The panel unit 260 includes a speed control display unit 261 for controlling the speed control unit 231, a cycle control display unit 262 for controlling the cycle control unit 232, and oxygen saturation sensor 271 for displaying the value. The saturation display unit 263, the body temperature display unit 264 displaying the value of the body temperature sensor 272, the pulse display unit 265 displaying the value of the pulse sensor 273, the battery display unit 266 constituting the power supply unit 280 or the power supply A switch display unit 267 may be included.

The operating unit 200 may include an accommodating unit fastening part 290 that is fastened with the operating unit fastening unit 150 when the ventilator accommodating unit 100 is inserted into the lower inside of the operating unit 200 and stored therein. .

The driving unit 210 may further include a deceleration unit 212, a gear unit 213, and a pressure bar 216.

The deceleration unit 212 may be characterized in that it decelerates the rotational force by the driving motor 211 at a constant speed.

The gear unit 213 may include a rotation gear 214 and a drive gear 215 .

The rotating gear 214 may be characterized in that it generates rotational force.

The rotary gear 214 may be characterized in that only one side of the semicircular arc includes a gear 214a based on the radius, and the other side does not include a gear.

The drive gear 215 may be characterized in that it is engaged with the pressure bar 216 to perform forward or backward movement.

In addition, the drive gear 215 is characterized in that it comprises gears 215a on the upper and lower sides of the drive gear 215 by a length corresponding to the length of the arc of the semicircle including the gear 214a of the rotation gear 214 can do.

The pressure bar 216 may compress or expand the air bag 2 through forward or backward movement of the driving gear 215 .

The driving unit 210 may further include a contact cap 217 fastenable to the pressure bar 216 so as to adjust the contact area of the air bag 2 .

The drive unit 210 may include a locking jaw 218 preventing the pressure bar 216 from excessively pressing and compressing the air bag 2 due to malfunction.

When the ventilator accommodating part 100 is withdrawn from the operating part 200 by a sliding method, the gap between the ventilator accommodating part 100 and the operating part 200 is adjusted to be suitable for an adult respirator or an infant ventilator. It may be characterized in that it includes a gap adjustment unit 250 for forming the air bag mounting unit 120.

The operating unit 200 may further include a sensor unit 270 .

The sensor unit 270 may include an oxygen saturation sensor 271 to receive feedback according to the operation of the ventilator and check a correct operating state.

The sensor unit 270 may further include a body temperature sensor 272 for measuring body temperature or a pulse sensor 273 for checking pulse.

The present invention has the effect of replacing the operation of a manual ventilator by a person such as an ordinary person or a non-medical person to pressurize the manual ventilator.

In particular, the present invention has the effect of enabling easy use by ordinary people who are not familiar with how to operate a manual ventilator.

In addition, the present invention can be easily manipulated through the simplification of the structure, and has an effect that it is easy to install or carry in various places.

In addition, there is an effect of increasing the effect of using a manual ventilator by allowing it to operate at an accurate timing and cycle.

In addition, it is possible to adjust according to the initial state of the patient, whether he is an adult, and the degree of improvement of the patient's condition, so that the effect of using a manual ventilator can be maximized.

In order to automatically operate a manual ventilator, a relatively inexpensive automatic operation device is provided, thereby reducing costs that can replace expensive hospital ventilators.

1 shows the external configuration of the automatic ventilator operating device of the present invention.
Figure 2 shows the detailed configuration of the appearance of the automatic ventilator operating device of the present invention.
Figure 3 shows a view in which the ventilator is fastened to the automatic ventilator operating device of the present invention.
4 shows the gear part of the operating part.
Figure 5 shows the operating state of the pressure bar by the operating unit.
6 shows a method of accommodating the ventilator accommodating part inside the lower layer of the operating part.

Hereinafter, if it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, the numbers used in the description process of this specification are only identifiers for distinguishing one component from another component.

In addition, the terms used in this specification and claims should not be construed as limited in a dictionary sense, and based on the principle that the inventor can properly define the concept of terms in order to best explain his/her invention, It should be interpreted as meaning and concept consistent with the technical spirit of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, so various equivalents that can replace them at the time of this application It should be understood that water and variations may exist.

A preferred embodiment of the present invention will be described in more detail, but technical parts that have already been well-known will be omitted or condensed for conciseness of description.

An air bag (2), a mask (3), a patient valve (4), a pressure control valve (5), an intake valve (6), an oxygen storage bag (7), and oxygen The supply tube connection part 8 is for explaining the automatic operation device of the present invention, and it is revealed that it is not an essential component of the scope of rights.

As shown in FIG. 1, the automatic ventilator operating device 1 of the present invention includes a ventilator accommodating part 100 and an operating part 200.

The ventilator accommodating part 100 is formed in a structure for accommodating a known manual ventilator to pressurize or depressurize the air bag 2 by the operating unit 200, and the operating unit 200 accommodates the ventilator. The air bag 2 accommodated in the unit 100 is pressurized to suck in air or reduce it again to provide a driving force for discharging air.

As shown in FIG. 2, the ventilator accommodating part 100 includes a patient valve exposure part 110, an air bag mounting part 120, an intake valve fastening part 130, a sliding part 140, and an operating part fastening part 150. ) may be included.

Although automatic ventilators are already equipped with expensive equipment in hospitals and nursing facilities, the present invention is mainly for automatically operating manual ventilators used in emergencies, so they are provided together with manual ventilators and are small and advantageous for storage or carrying. The more effective it will be.

Therefore, in order to achieve the object of the present invention, the ventilator accommodating part 100 is inserted into the lower inside of the operating part 200 during normal storage or movement to minimize the volume during storage or movement.

Air bag (2), mask (3), patient valve (4), pressure control valve (5), intake valve (6), oxygen storage bag (7), and oxygen supply tube connection part that constitute a generally used artificial respirator. (8), etc.

As shown in FIGS. 2 and 3, the patient valve exposure part 110 is a part that is fastened to correspond to the patient valve 4 of the ventilator, and the ventilator is mounted on the manual ventilator automatic operating device 1 of the present invention When in use, when the air bag 2 is pressurized by the pressure bar 216, this is to prevent the ventilator accommodated in the air bag mounting portion 120 of the ventilator accommodating portion 100 from being separated or turned outside.

The air bag mounting portion 120 forms a space in which the air bag 2 of the artificial respirator is accommodated.

In addition, the intake valve fastening part 130 is a fastening part corresponding to the intake valve 6 of the ventilator, and when the air bag 2 is pressurized by the pressure bar 216, the ventilator accommodating part 100 This is to prevent the ventilator accommodated in the air bag mounting portion 120 from being separated or turned outside.

The sliding part 140 allows the ventilator accommodating part 100 to be inserted into the lower inside of the operating part 200. That is, the sliding part 140 means a part that can be inserted or withdrawn by a sliding method so that the ventilator accommodating part 100 can be inserted into the lower inside of the operating part 200. A space corresponding to the ventilator accommodating part 100 may be included inside the lower side of the operating part 200 based on the sliding part 140 so that the respirator accommodating part 100 can be inserted. In addition, there is no particular limitation on the sliding method.

The operating part fastening part 150 is the ventilator accommodating part 100 when the ventilator receiving part 100 is inserted into the lower inside of the operating part 200 and stored when the automatic ventilator operating device 1 is normally stored. The operating part fastening part 150 and the accommodating part fastening part 290 of the operating part 200 are fastened to each other to prevent the ventilator accommodating part 100 from being separated from the operating part 200 during storage or movement. . The operating part fastening part 150 and the accommodating part fastening part 290 may include various methods including a male and female fastening method or a Velcro method.

The operating unit 200 includes a driving unit 210, a pressure bar exposure unit 220, an operation control unit 230, an accommodation unit insertion unit 240, a spacing adjustment unit 250, a panel unit 260, and a sensor unit. 270, a power supply unit 280, and a receiving unit fastening unit 290 may be included.

The driving unit 210 is configured to pressurize and compress the air bag 2 accommodated in the air bag mounting unit 120 or to inflate it by reducing it again.

The pressure bar exposed portion 220 is a space that allows the pressure bar 216 to move forward or backward toward the air bag 2 accommodated in the air bag mounting portion 120.

The operation control unit 230 is a component that adjusts the degree of pressurization, the pressurization cycle, the pressurization speed, etc. of compressing the air bag 2 by pressurizing it or reducing it and expanding it again.

The accommodating portion insertion portion 240 is a space in which the ventilator accommodating portion 100 is included inside the lower layer of the operating portion 200 when storing or moving the present invention.

The spacing control unit 250 is the operating unit for use after the ventilator accommodating unit 100 is inserted into the accommodating unit insertion unit 240 inside the lower layer of the operating unit 200 when stored based on the sliding unit 140. (200) It is a configuration for adjusting the operating interval of the pressure bar 216 exposed through the pressure bar exposed portion 220 in the process of operating after being withdrawn from the inside of the lower layer.

The panel unit 260 is an operation panel unit for controlling the operation control unit 230 of the operation unit 200 or the sensor of the sensor unit 270 .

The sensor unit 270 can simply check the patient's body temperature, pulse or oxygen saturation in an emergency, and can check the patient's condition through the patient's body temperature, pulse or oxygen saturation after use, as well as non-medical staff In the case of using the automatic operating device 1 of the present invention, it is possible to receive feedback on whether or not it is operated accurately through state changes such as body temperature, pulse rate, or oxygen saturation before and after use.

The power supply unit 280 supplies batteries or power to drive the automatic operation device of the present invention.

The accommodating part fastening part 290 is when the ventilator accommodating part 100 of the present invention is inserted into the lower inside of the operating part 200 and stored, the operating part fastening part 150 and the accommodating part fastening part 290 are fastened to each other. It is a structure for storage.

Hereinafter, each configuration of the operating unit 200 will be described in detail.

The driving unit 210 is a configuration capable of pressurizing and compressing the air bag 2 accommodated in the air bag mounting unit 120 or reducing it again to inflate it. As shown in FIG. 4, the driving unit 210 includes a drive motor 211, It may include a reduction part 212, a gear part 213, a rotation gear 214, a drive gear 215, a pressure bar 216, a contact cap 217, and a locking jaw 218.

In FIG. 4, although some components are omitted in the drawing, the rotational force by the drive motor 211 is reduced by the speed reduction unit 212, and the air bag 2 is pressurized (inhaled) or reduced (discharged). The gear unit 213 is operated to drive the pressure bar 216 for

The gear unit 213 is connected to the rotation gear 214 and the pressure bar 216 generating rotational force through the drive motor 211 and/or the reduction unit 212 to generate forward or backward motion (drive gear) 215).

Meanwhile, in the present invention, a step motor is used as the driving motor 211 . A step motor means a motor that rotates discontinuously. In the present invention, the step motor that rotates discontinuously is used as the drive motor 211 to pressurize and press the air bag 2 of the ventilator to generate inhalation or to expand it again to inhale air in the process of generating exhalation. This is because there must be a difference in the speed at which you breathe in (inhale) or exhale (exhale). This is because the rate of inhalation and exhalation through a manual ventilator must be different.

The deceleration unit 212 is a component for decelerating the rotational force by the driving motor 211 at a constant speed. One of a variety of well-known methods may be adopted, and a detailed description thereof will be omitted.

As shown in FIG. 4, the gear unit 213 generates rotational force by the rotating gear 214 and moves forward or backward by the drive gear 215 coupled to the pressure bar 216 on one side, thereby moving the air The bag 2 is compressed by pressing or expanded by reducing again.

More specifically, when the air bag 2 is mounted on the air bag mounting portion 120, the state of FIG. 5 (a) is obtained, and as the rotary gear 214 rotates half a turn, FIGS. 5 (b) and 5 ( As shown in c), as the drive gear 215 moves forward, the pressure bar 216 presses and compresses the air bag 2, and then, as the rotation gear 214 rotates an additional half turn, FIG. 5 (d) And as shown in FIG. 5(e), as the drive gear 215 moves backward, the pressure bar 216 reduces and inflates the air bag 2 again.

The rotating gear 214 has a configuration in which only one side of the semicircular arc includes a gear based on the radius, and the other side does not include a gear.

In addition, the drive gear 215 may include gears on the upper and lower sides of the drive gear 215 by a length corresponding to the length of the arc of the semicircle including the gear of the rotation gear 214 .

The pressure bar 216 is fastened to one side of the drive gear 215, and the pressure bar 216 simultaneously moves forward or backward by the forward or backward movement of the drive gear, compressing the air bag 2 (inhalation) Or allow it to expand (exhale).

In addition, the pressure bar 216 is a contact cap 217 (not shown) that can be combined with the pressure bar 216 so that the pressure strength can be varied according to the contact area in order to pressurize the air bag 2 to compress or expand it. ) can be additionally configured separately. The contact cap 217 may be configured in various ways such as widening an area, increasing a length, or having a polygonal shape in order to increase a contact surface with the air bag 2.

The locking jaw 218 is a locking jaw that prevents the pressure bar 216 from compressing the air bag 2 by excessively pressing it due to malfunction.

As shown in FIG. 2 or 6, the pressure bar exposed portion 220 is included on one side of the air bag mounting portion 120 of the operating portion 210, and the pressure bar 216 is accommodated in the air bag mounting portion 120. It is a space to move forward or backward in order to pressurize or reduce toward the air bag (2).

Since it is very important to prevent a manual ventilator from malfunctioning, the pressure bar 216 pressurizes or returns the air bag 2 to the correct position at an accurate speed and an accurate cycle through the gear part 213, so that the pressurized part exposure part Through 220, the pressure bar 216 was made movable.

The operation control unit 230 controls the degree of pressurization, the pressurization cycle, the pressurization speed, etc. of pressurizing and compressing the air bag 2 or reducing and inflating the air bag 2, and the speed and expansion of compressing the air bag 2 by pressurizing It may include a speed control unit 231 for adjusting the speed of operation and/or a cycle control unit 232 for adjusting the cycle of operating several times per minute, stopping operation, and operating again.

The speed control unit 231 adjusts the forward speed as shown in 5 (a) to 5 (c) and the reverse speed as shown in 5 (c) to 5 (e) in FIG. In the present invention, the drive motor 211 may rotate discontinuously through a step motor to basically provide intervals between forward movement (inhalation) and backward movement (exhalation) of the pressing bar 216.

On the other hand, it is necessary to differentiate the rate of inhalation by pressurization or exhalation by reduction and expansion according to the condition of the patient.

In addition, the cycle control unit 232 is for adjusting the cycle of providing inhalation and exhalation several times per minute or at an appropriate time. As with CPR, when air is provided by a ventilator, it is necessary to check and change the condition after a few times per minute, rather than a continuous supply. Therefore, basically setting the operation cycle to the most default value, but setting the change value according to the distinction according to adult or child, mild or severe, can be one method for non-experts to respond efficiently.

As shown in FIG. 6, the accommodating portion insertion portion 240 is a space in which the ventilator accommodating portion 100 is included inside the lower layer of the operating portion 200 when storing or moving the present invention. The present invention was intended to enable the use of a manual ventilator to be efficiently automated by an automated method, and to occupy a minimum space during storage or movement as another automatic operation device is added.

The accommodating part insertion part 240 is a space in which the sliding part 140 of the ventilator accommodating part 100 and the air bag mounting part 120 are inserted into the lower inside of the operating part 200 to be stored and taken out, and is a sliding type. A variety of known technologies including a guide portion or a step may be adopted for the insertion or withdrawal method.

Therefore, when storing or moving the ventilator operating device 1 of the present invention, through the sliding part 140 of the ventilator accommodating part 100 to the accommodating part insertion part 240, which is the inner space of the lower layer of the operating part 200. The ventilator receiving part 100 was put in and stored.

At this time, the accommodating part fastening part 290 of the operating part fastening part 150 and the operating part 200 of the ventilator accommodating part 100 may be stored in a state in which they are fastened to each other.

Meanwhile, when the respirator operating device 1 is used, the respirator accommodating portion 100 can be withdrawn from the accommodating portion insertion portion 240 of the operating portion 200 and used.

Since the sizes of the adult respirator and the infant respirator are different, the gap adjusting unit 250 enables the air bag 2 of the ventilator to be accurately accommodated in the air bag mounting unit 120 through the gap adjusting unit 250 and In addition, the pressure bar 216 through the pressure bar exposed portion 220 is to pressurize or expand the air bag 2 accurately.

That is, when storing based on the sliding part 140, the ventilator accommodating part 100 is inserted into the accommodating part insertion part 240 inside the lower layer of the operating part 200, and then the operating part 200 for use. It is a configuration for adjusting the operating interval of the pressure bar 216 exposed through the pressure bar exposed portion 220 in the process of use after being withdrawn from the lower layer.

On the other hand, the gap adjusting portion 250 may be configured by forming a protrusion or a guide on the lower portion of the receiving portion insertion portion 240.

The sliding part 140 of the ventilator accommodating part 100 inserted or pulled out corresponding to the space adjusting part 250 may include a protrusion or a guide.

The protrusion or guide of the sliding part 140 corresponding to the space adjusting part 250 or the protrusion or guide of the space adjusting part 250 of the accommodating part insertion part 240, when using an automatic operation device, the ventilator accommodating part 100 ) and the operation unit 200, the air bag mounting unit 120 space suitable for accommodating an adult respirator or an infant respirator can be formed.

The panel unit 260 is an LCD panel unit for controlling the operation control unit 230 of the operation unit 200 or the sensor of the sensor unit 270 or the power supply unit 280.

Specifically, the speed control display unit 261 for controlling the speed control unit 231, the cycle control display unit 262 for controlling the cycle control unit 232, and the oxygen saturation sensor 271 constituting the sensor unit 270 to be described later. ) Oxygen saturation display unit 263 displaying the value, body temperature display unit 264 displaying the value of the body temperature sensor 272, pulse display unit 265 displaying the value of the pulse sensor 273, battery constituting the power supply unit 280 A display unit 266 or a power switch display unit 267 and the like are included.

The sensor unit 270 simply checks oxygen saturation, body temperature or pulse through an oxygen saturation sensor 271 that checks the patient's oxygen saturation, a body temperature sensor 272 that measures body temperature, or a pulse sensor 273 that checks pulse. After use, the patient's condition can be checked through the patient's oxygen saturation, body temperature or pulse, etc. Through state changes such as saturation, body temperature, or pulse, it is possible to receive feedback on whether or not it is operating correctly.

In particular, checking and comparing oxygen saturation by the oxygen saturation sensor 271 before and after use of the automatic operation device 1 can play an important role in providing feedback on whether the ventilator is operating correctly.

The power supply unit 280 may include a battery 281 or a power supply unit 282 to drive the automatic operation device 1 of the present invention. Since the present invention can be used while being stored in a place such as a home or a nursing home, and can be used in a place where an ambulance or an AED is always available and where there is no power, it is preferable to have a battery 281 or power supply 282 together.

The accommodating part fastening part 290 is stored when the ventilator accommodating part 100 is inserted into the lower inside of the operating part 200 and stored, the operating part fastening part 150 and the accommodating part fastening part 290 are fastened to each other. stability can be improved.

Meanwhile, a cover 300 covering the ventilator accommodating part 100 and the air bag mounting part 120 for improving stability and aesthetics of the automatic ventilator operating device 1 may be further included.

When the cover 300 (not shown) is inserted into the lower inside of the operating part 200 and stored, one side of the cover 300 is fastened to the operating part of the respirator receiving part 100. It is fastened to the surface of the unit 150, and the other side surface of the cover 300 may be fastened to the outer upper surface of the operating unit 200, which is the opposite side of the pressure bar exposed portion 220. In this way, during storage, the cover 300 fastens the entirety of the ventilator accommodating part 100 and the operating part 200, which do not form the air bag mounting part 120, to increase storage stability.

In addition, when the cover 300 is used by withdrawing the respirator accommodating part 100 from the lower inside of the operating part 200, one side of the cover 300 is the operating part fastening part of the respirator accommodating part 100 ( 150), and the other side of the cover 300 may be fastened to the accommodating part fastening part 290 surface of the operation unit 200. In this way, when in use, the cover 300 is fastened to the entire ventilator accommodating part 100 and the operation part 200 forming the air bag mounting part 120, and the air bag 2 due to pressurization by the pressure bar 216 during use. ) can be prevented from coming off, and aesthetics can be improved.

As described above, the detailed description of the present invention has been made by examples, but since the above-described embodiments have only been described with preferred examples of the present invention, it is understood that the present invention is limited only to the above embodiments. It should not be lost, and the scope of the present invention should be understood as the following claims and their equivalent concepts.

1: Ventilator automatic operating device
2: air bag 3: mask
4: patient valve 5: pressure control valve
6: intake valve 7: oxygen storage bag
8: Oxygen supply tube connection
100: ventilator receiving part
110: patient valve exposed part 120: air bag mounting part
130: intake valve fastening part 140: sliding part
150: operating part fastening part
200: operation part
210: driving unit
211: drive motor 212: reduction unit
213: gear unit 214: rotation gear
214a: rotation gear gear 215: drive gear
215a: driving gear gear 216: pressure bar
217: contact cap 218: locking jaw
220: pressure bar exposed part
230: operation control unit
231: speed control unit 232: cycle control unit
240: receiving part insertion part
250: spacing control unit
260: panel part
261: speed control display unit 262: cycle control display unit
263: oxygen saturation display unit 264: body temperature display unit
265: pulse display unit 266: battery display unit
267: power switch display
270: sensor unit
271: oxygen saturation sensor 272: body temperature sensor
273: pulse sensor
280: power supply
281: battery 282: power supply
290: receiving part fastening part
300: cover

Claims (7)

A ventilator accommodating part 100 for accommodating the air bag 2 of the ventilator, and
It includes an operation unit 200 that pressurizes the air bag 2 accommodated in the ventilator accommodating unit 100 to suck in air or to discharge air by reducing it again,

The ventilator accommodating part 100 includes an air bag mounting part 120 and a sliding part 140,
The air bag mounting portion 120 accommodates the air bag 2 of the artificial respirator,
Characterized in that the sliding part 140 and the air bag mounting part 120 can be inserted into or withdrawn from the accommodation part insertion part 240, which is the lower inner space of the operating part 200, through the sliding part 140
Ventilator automatic actuator (1) delete According to claim 1,
The operating unit 200 includes a driving unit 210 for pressurizing and compressing the air bag 2 accommodated in the air bag mounting unit 120 or reducing and inflating it again; and
It includes a pressure bar exposed portion 220, which is a space for the pressure bar 216 to move forward or backward toward the air bag 2 accommodated in the air bag mounting portion 120,
Characterized in that the drive unit 210 includes a drive motor 211, characterized in that the step motor
Ventilator automatic actuator (1) According to claim 3,
The drive unit 210 further includes a deceleration unit 212, a gear unit 213 and a pressure bar 216,
The reduction unit 212 is characterized in that the rotational force by the drive motor 211 is reduced,
The gear unit 213 includes a rotation gear 214 and a driving gear 215,
The rotating gear 214 is characterized in that it generates a rotational force,
The drive gear 215 is engaged with the pressure bar 216 to move forward or backward,
The pressure bar 216 compresses or expands the air bag 2 through the forward or backward movement of the drive gear 215.
Ventilator automatic actuator (1) According to claim 4,
The drive unit 210 further comprises a contact cap 217 fastenable to the pressure bar 216 so as to adjust the contact area of the air bag 2.
Ventilator automatic actuator (1) According to claim 1,
When the ventilator accommodating part 100 is withdrawn from the operating part 200 by a sliding method, the gap between the ventilator accommodating part 100 and the operating part 200 is adjusted to be suitable for an adult respirator or an infant ventilator. Characterized in that it comprises a gap adjusting portion 250 for forming the air bag mounting portion 120
Ventilator automatic actuator (1) According to claim 3,
The operation unit 200 further includes a sensor unit 270,
The sensor unit 270 includes an oxygen saturation sensor 271, characterized in that it can check the correct operating state by receiving feedback according to the operation of the ventilator
Ventilator automatic actuator (1)

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