KR102193208B1 - Choking Prevent Device for Infant - Google Patents

Abstract

Provide suffocation prevention devices. The suffocation prevention apparatus according to the embodiment of the present application includes a front surface 11 in contact with the chest side of the object to be worn, and a rear surface 12 disposed to face the front surface 11, the body portion 10, the body The rear surface 12 of the part, the sensing unit 20 installed on either side 13 of the front surface 11 and the rear surface 12, respectively, the outer side of the front surface 11 of the body 10 The first expansion part 30 installed in, the second expansion part installed outside the front surface 11 of the body part 10, and installed closer to the wearing object than the first expansion part 30 ( 40) and the state change of the wearing object according to a preset method based on the data sensed by the sensing unit 20, and the expansion of the first expansion unit 30 and the It may include a control unit 50 that controls the expansion of the second expansion unit 40.

Description

Choking Prevent Device for Infant

The present application relates to an infant choking prevention device.

Newborns under 4 months of age may die of suffocation due to inability to breathe properly when they go to bed in the wrong posture due to the inability to develop the fine muscles of the neck.

Sudden infant death syndrome is the main cause of death in infants under the age of 1, and 44.7% of them are caused by sleeping infants upside down or lying on their sides.

In particular, infants can't learn defensive reflex behaviors, and even if breathing difficulties occur while sleeping, they become deprived of oxygen without defensive reflex actions such as waking up, changing their posture, or crying, leading to death. In Korea, about 100 newborn babies die annually from such sudden infant death syndrome.

In order to prevent sudden infant death syndrome, the infant must be laid down and put to sleep, and when the infant begins to turn over, a lot of efforts are involved, such as to prevent falling asleep on the face by using an anti-overturn cushion.

As a conventional infant suffocation prevention device, Korean Patent Publication No. 10-2015-0121607 uses Kinect to recognize the sleeping state of infants in real time and immediately alarms when there is a specific motion or foreign substance covering the face. And a technology for transmitting a signal to a smartphone, but regardless of preventing suffocation itself, there is a possibility that a suffocation accident may occur if the recognition of the danger signal is delayed.

Korean Patent Document No. 10-1665916 discloses a technology for generating an alarm signal by receiving information on reversal detection through a motion sensor that detects the movement of infants, but this also recognizes a danger signal regardless of preventing suffocation itself. If this was delayed, there was a possibility of a choking accident.

As such, the conventional suffocation prevention apparatus was limited to transmitting a danger signal to the surroundings, and there was a problem that suffocation itself could not be prevented and an accident could still be caused.

Korean Patent Publication No. 10-2015-0121607 (2015.10.29) Korean Patent Document No. 10-1665916 (2016.10.06) Korean Patent Document No. 10-1798498 (2017.11.10)

The present application was devised to solve the above problems.

Specifically, it is possible to calculate whether the user is overturned using a pressure sensor, and if it is calculated by overturning using an airbag and hydrogel, they expand, thereby preventing the user's body from the floor by a certain distance to prevent suffocation. We want to provide a device that can be used.

An embodiment of the present application for solving the above problems, including a front face 11 in contact with the chest side of the object to be worn, and a rear surface 12 disposed to face the front 11, the body ( 10), the rear surface 12 of the body part, the detection part 20 installed on any one side 13 of the front surface 11 and the rear surface 12, and the body part 10 A first expansion part 30 installed outside the front surface 11, installed outside the front surface 11 of the body part 10, and installed closer to the wearing object than the first expansion part 30 The state change of the wearing object is calculated according to a preset method based on the data sensed by the second expansion unit 40 and the detection unit 20, and the first expansion unit 30 according to the calculated state change. ) And a control unit 50 for controlling the expansion of the second expansion unit 40 and the expansion of the second expansion unit 40.

In one embodiment, the sensing unit 20 includes a pressure sensor that senses pressure, and the control unit 50 is the wearable object according to a preset method based on a pressure value sensed by the pressure sensor. By calculating whether to be overturned, it is possible to control the first expansion part 30 and the second expansion part 40 to expand when it is calculated by being overturned.

In one embodiment, the preset method may be to calculate the overturn when the total sum of the pressure values sensed by the pressure sensor installed on the body 10 is less than or equal to a predetermined value.

In one embodiment, the preset method is calculated as the overturning when the sum of the pressure values sensed by the pressure sensor installed in the body part 10 is less than or equal to a predetermined value, but the pressure value sensed by the pressure sensor When the total sum of is equal to or less than the predetermined value and lasts longer than a preset time, it may be calculated as the flipping.

In one embodiment, the first inflation part 30 includes an airbag, and the second inflation part 40 includes a first accommodation part 41 in which a hydrogel is accommodated, and water therein. And a shielding part 43 for blocking contact of the contents accommodated in the received second receiving part 42 and the first receiving part 41 and the second receiving part 42, and the control unit 50 When it is calculated by being overturned, the airbag is inflated and the shielding part 43 may be opened.

In one embodiment, the expansion speed of the second expansion part 40 may be slower than the expansion speed of the first expansion part 30.

In one embodiment, the body portion 10, the upper side of the front 11 and the upper side of the rear 12, but further includes a shoulder seating surface 14 in contact with the shoulder side of the wearing object And, the first expansion part 30 may be further installed on the shoulder seating surface 14.

In one embodiment, the pressure sensor may be further installed on the front surface 11 of the body portion 10, and the control unit 50 is a pressure detected by the pressure sensor installed on the front surface 11 It may be to calculate whether or not the wearing object is overturned by further using a value.

The above-described present application has the following effects.

It is possible to prevent a suffocation accident by calculating whether or not the wearing object is overturned using a pressure sensor, and when it is calculated by overturning, the expansion parts installed in the front of the body expand and separate the body of the wearing object from the floor.

In addition, it is possible to absorb the physical shock that may be applied to the wearing object as the airbag rapidly inflates by configuring the inflated portion as a double. Therefore, it is possible to prevent injuries to the wearer due to the rapid expansion of the airbag.

In addition, since the pressure sensor is installed on the rear and both sides of the body, it is possible to more accurately calculate whether or not to overturn.

In addition, an alarm unit for outputting a warning sound is further provided around the calculation by reversal, and it is possible to quickly notify the outside of a dangerous situation.

1 is a perspective view of an apparatus for preventing choking according to an embodiment of the present application.
Figure 2 is a front view of the asphyxiation prevention device of Figure 1;
3 is a rear view of the asphyxiation prevention device of FIG. 1.
4 is a schematic plan view of the suffocation prevention apparatus of FIG. 1 for explaining the suffocation prevention apparatus according to an embodiment of the present application.

Hereinafter, the present application will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a suffocation prevention apparatus according to an embodiment of the present application, FIG. 2 is a front view of the suffocation prevention apparatus of FIG. 1, FIG. 3 is a rear view of the suffocation prevention apparatus of FIG. 1, and FIG. 4 is A schematic plan view of the suffocation prevention apparatus of FIG. 1 for explaining the suffocation prevention apparatus according to an embodiment.

Hereinafter, the term "wearing object" refers to a user who wears the suffocation prevention device according to an embodiment of the present application, and specifically, may be an infant under 3 years old, and more specifically, an infant under 1 year old.

Hereinafter, assuming that the wearing object wears the suffocation prevention device, it will be described that the direction away from the wearing object is the outer side, the direction closer to the wearing object is the inner side, the upper portion of the wearing object is the upper side, and the lower portion is the lower side.

1, 3, and 4, the asphyxiation prevention apparatus according to the embodiment of the present application includes a body part 10, a detection part 20, a first expansion part 30, a second expansion part 40, and a control part. (50) may be included.

The body part 10 is a part that forms the overall appearance of the suffocation prevention device, and is a part that contacts the body of the wearer. The shape of the body portion 10 is not limited, but as an example, it may be a vest shape as shown in FIG.

The body portion 10 is a front surface 11 in contact with the chest side of the object to be worn, a rear surface 12 disposed to face the front surface 11, and a shoulder connecting the upper side and the upper side of the rear surface 12 to each other. It includes a seating surface (14).

That is, assuming that the wearing object is wearing the suffocation prevention device, the front 11 is in contact with the chest side, the back 12 is in contact with the back side, and the shoulder seating surface 14 is in contact with the shoulder side.

Although not shown in the drawing, a fixing strap (not shown) is formed on the side of the front 11 or the rear 12 so that the front 11 and the rear 12 continue to contact the chest and the abdominal side even if the wearing object moves Can be. When the fixing strap (not shown) is pulled while holding it, the front surface 11 and the rear surface 12 are more closely attached to the wearing object, so that the body portion 10 can be prevented from being separated from the body of the wearing object.

The sensing unit 20 is a part that provides data for calculating whether the object to be worn on the body 10 is overturned. Specifically, the sensing unit 20 may be a pressure sensor, and more specifically, may be a pressure sensor made of a fiber shape and having flexibility. Hereinafter, it is assumed that the sensing unit 20 is a pressure sensor.

The pressure sensor may be installed on the rear surface 12 of the body portion 10. When the value sensed by the pressure sensor is greater than a predetermined value by being installed on the rear surface 12, the wearing object is in a static position (the distribution of the wearing object is It can be calculated as a contact posture), and if it is less than a predetermined value, it may be calculated as a posture in which the wearer is inverted (a posture in which the chest of the wearer is in contact with the floor).

In addition, a total of two pressure sensors may be further installed on either side 13 of the front 11 or the rear 12 of the body 10, and more specifically, one on the left side and the right side of the object to be worn. have.

The pressure sensor 21 installed on the rear surface 12 can detect the maximum pressure value when the distribution of the object to be worn contacts the floor, and the pressure sensors 22 and 23 installed on each side have the corresponding side of the object to be worn. When touching the floor, it can be detected as the maximum pressure value.

As a total of three pressure sensors are installed on the rear (12) of the body (10), and one on both sides, it is possible to calculate whether or not the pressure is turned over more accurately than when one is installed on the rear (12), and even the direction of the overturn is calculated. You have the advantage that this is possible.

In one embodiment, the pressure sensor may be further installed on the front surface 11 of the body portion 10, in this case, the controller 50 is a pressure sensor installed on the rear surface 12 and both sides, and the front 11 It is possible to calculate whether or not the wearing object is overturned based on the pressure value sensed by it, and it has the advantage of being able to calculate whether the wearing object is overturned by the pressure value detected by the pressure sensor installed on the front surface 11 alone. .

The first expansion part 30 is installed outside the front surface 11 of the body part 10 and expands when it is calculated to be overturned by the controller 50 to be described later.

Specifically, the first expansion unit 30 may be an airbag that expands by injecting gas, and the gas may be carbon dioxide (CO ₂ ). In addition, the time until the first expansion unit 30 reaches the maximum expansion state may be within 0.5 seconds. Hereinafter, description will be made on the assumption that the first inflation part 30 is an air bag.

More specifically, the airbag may include an airbag tube 31 and a cartridge 32, and when it is calculated by being overturned by the control unit 50, the gas in the cartridge 32 is momentarily ejected and the airbag tube 31 Flows into and expands.

Two of the first expansion parts 30 may be installed one by one in each of the left and right sides of the central portion of the front 11 of the body portion 10, and two of the first expansion portions 30 may be installed in the front of each shoulder seating surface 14.

As the first expansion part 30 is installed on the front surface 11 of the body part 10, a suffocation accident that may occur due to the airway being closed due to the neck part of the object to be worn can be prevented. In particular, the shoulder seating surface 14 ) By being further installed on the front side, it is possible to prevent suffocation accidents by spaced apart a predetermined distance from the floor the neck of the object to be worn close to the shoulder seating surface (14).

The first expansion part 30 is detachable from the body part 10, and the expanded first expansion part 30 is detached from the body part 10, and then the new first expansion part 30 is reattached. It is preferable to attach to the body portion 10. In addition, separate installation pockets (not shown) for attaching and detaching the first expansion unit 30 may be further formed on the front surface 11 of the body portion 10 and the front surface of the shoulder seating surface 14.

The second expansion part 40 is installed outside the front surface 11 of the body part 10, and is installed closer to the wearing object than the first expansion part 30 described above, by the control unit 50 to be described later. It is the part that expands when calculated by flipping.

Specifically, the second expansion part 40 includes a first accommodation part in which hydrogel is accommodated, a second accommodation part 42 in which water is accommodated, and a first accommodation part 41 and a second accommodation part. It may include a shielding portion 43 to block the contact of the contents contained in (42).

Hydrogel is a hydrophilic polymer having micropores. It is a material that expands when it contains water, and it has excellent hydrophilicity, softness, and flexibility on the surface, making it suitable for use in living organisms.

In addition, compared to an airbag that rapidly inflates within 0.5 seconds, it inflates somewhat slowly, so it is possible to absorb the shock applied to the wearer due to the rapidly inflating airbag.

When it is calculated as being overturned by the control unit 50, the shielding unit 43 is opened to cause contact between the hydrogel accommodated in the first receiving unit 41 and the water accommodated in the second receiving unit 42. The hydrogel in contact with water contains water and expands to a volume of about 80 to 100 times, and a suffocation accident can be prevented by separating the neck of the wearer a predetermined distance from the floor. In addition, as described above, it is possible to absorb the shock applied from the rapidly expanding airbag.

The hydrogel, which has been expanded, shrinks again by heating or drying, and can be reused by heating or drying.

The control unit 50 calculates whether or not the object to be worn is overturned according to a preset method based on the data sensed by the detection unit 20, and when it is calculated by being overturned, the first expansion unit 30 and the second expansion unit ( This is the part that controls 40) to expand.

Specifically, the control unit 50 may calculate whether the wearing object is overturned according to a preset method based on the pressure value sensed by the pressure sensor, and the preset method is based on the pressure sensors installed in the body part 10. When the total sum of the sensed pressure values is less than or equal to a predetermined value, it may be calculated by reversal.

For example, assuming that the range of the pressure value sensed by the pressure sensor is 0 to 4, and assuming that a total of three pressure sensors are installed in the body part 10, the controller 50 is When the detected pressure value is less than or equal to 2, it can be calculated that the wearing object is upside down.

In addition, the control unit 50 may calculate an overturn when the total sum of the pressure values sensed by the pressure sensors is less than or equal to a predetermined value for a predetermined time or longer. The total pressure values sensed by the pressure sensors must be maintained for a predetermined time or longer to be recognized as a true flipped state, so that even if the object to be worn returns to the normal position immediately from the flipped state, it is recognized as being flipped and the expansion of the expansion parts can be prevented. .

When it is calculated as being overturned by the control unit 50, the gas in the cartridge 32 is momentarily ejected and introduced into the airbag tube 31 so that the first expansion unit 30 can expand, and the shield unit 43 is When the hydrogel is opened and accommodated in the first accommodating part 41 and the water accommodated in the second accommodating part 42 contact with each other, the hydrogel expands, so that the second expandable part 40 may expand. Accordingly, the body of the wearer, in particular, the upper body portion is spaced apart from the floor by a predetermined distance and the neck portion is spaced apart from the floor, thereby preventing a suffocation accident due to airway obstruction.

The alarm part 60 is a part that outputs an alarm toward the outside when the body part 10 is installed and calculated as a backward force by the control part 50. As the alarm output method, a warning sound output method may be applied, but the method is not limited thereto and any method capable of notifying a dangerous state to the outside may be applied.

The above-described present application has the following effects.

It is possible to prevent a suffocation accident by calculating whether or not the wearing object is overturned using a pressure sensor, and when it is calculated by overturning, the expansion parts installed in the front of the body expand and separate the body of the wearing object from the floor.

In addition, it is possible to absorb the physical shock that may be applied to the wearing object as the airbag rapidly inflates by configuring the inflated portion as a double. Therefore, it is possible to prevent injuries to the wearer due to the rapid expansion of the airbag.

In addition, since the pressure sensor is installed on the rear and both sides of the body, it is possible to more accurately calculate whether or not to overturn.

In addition, an alarm unit for outputting a warning sound is further provided around the calculation by reversal, and it is possible to quickly notify the outside of a dangerous situation.

As described above, in the present specification, the present application has been described with reference to the embodiment shown in the drawings so that those skilled in the art can easily understand and reproduce this application, but this is only illustrative, and those skilled in the art can use various modifications and equivalent It will be appreciated that embodiments are possible. Therefore, the scope of protection of the present application should be determined by the claims.

10: body
11: front
12: rear
13: side
14: shoulder seating surface
20: detection unit
21, 22, 23: pressure sensor
30: first expansion part
31: airbag tube
32: cartridge
40: second expansion part
41: first receiving portion
42: second receiving portion
43: shield
50: control unit
60: alarm unit

Claims (8)

A body portion 10 including a front surface 11 in contact with the chest side of the object to be worn, and a rear surface 12 disposed to face the front surface 11;
A sensing unit (20) installed on the rear surface (12) of the body portion (10) and one side surface (13) of the front surface (11) and the rear surface (12) and including a pressure sensor;
A first expansion part 30 installed outside the front surface 11 of the body part 10 and including an air bag;
A second expansion part 40 installed outside the front surface 11 of the body part 10 and installed closer to the wearing object than the first expansion part 30; And
Calculates a state change of the wearing object according to a preset method based on data sensed by the sensing unit 20, and expands the first expansion unit 30 and the second expansion according to the calculated state change Including; a control unit 50 for controlling the expansion of the unit 40,
The second expansion part 40,
A first receiving portion 41 in which a hydrogel is accommodated therein;
A second receiving portion 42 containing water therein; And
And a shielding part 43 that blocks the contact of the contents received in the first accommodation part 41 and the second accommodation part 42,
The control unit 50,
When the total sum of the pressure values sensed by the pressure sensor installed in the body 10 is less than or equal to a predetermined value, it is calculated as overturning,
By the control unit 50, when the airbag is inverted, the airbag is inflated, the shielding part 43 is opened, and the hydrogel accommodated in the first receiving part 41 is transferred to the second receiving part 42 ) And expands in contact with water contained in
The inflation rate of the hydrogel is slower than the inflation rate of the airbag,
Infant choking prevention device.
The method of claim 1,
The pressure sensor,
It is made of fiber and has flexibility,
Infant choking prevention device.
delete The method of claim 1,
The preset method is,
When the total sum of the pressure values sensed by the pressure sensor installed on the body part 10 is less than or equal to a predetermined value, it is calculated as the overturning, but a preset time that the total sum of the pressure values sensed by the pressure sensor is less than the predetermined value If it lasts longer, it is calculated by the overturning,
Infant choking prevention device.
delete delete The method of claim 1,
The body portion 10,
The upper side of the front surface 11 and the upper side of the rear surface 12 are connected, but further comprising a shoulder seating surface 14 in contact with the shoulder side of the object to be worn,
The first expansion part 30 is further installed on the shoulder seating surface 14,
Infant choking prevention device.
The method of claim 7,
The pressure sensor may be further installed on the front surface 11 of the body 10,
The control unit 50 further uses a pressure value sensed by the pressure sensor installed on the front surface 11 to calculate whether the wearing object is overturned,
Infant choking prevention device.

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