KR102373016B1 - Emergency escaping apparatus for high building - Google Patents

Abstract

The present invention relates to an emergency evacuation device for a high-rise building, and more particularly, in the event of a fire in a high-rise building, preparation for evacuation is completed only by simple manipulation, and by automatically detecting ground proximity to supplementally buffer the impact caused by a fall, injuries caused by a fall It relates to an emergency escape device for high-rise buildings that can minimize the
According to the present invention, the escape body is made of a flexible material and forms a space in which a person can be accommodated when charging air; an automatic air injection device unit provided in the escape body portion and configured to fill the escape body portion by automatically injecting air; an injection operation switch for transmitting an execution command for the charging operation of the air injection unit; And, it is provided in the escape body portion and is activated at a predetermined distance with respect to the ground when the escape body portion falls, a fall shock absorber configured to buffer the impact of the fall; characterized in that it comprises a.

Description

EMERGENCY ESCAPING APPARATUS FOR HIGH BUILDING

The present invention relates to an emergency evacuation device for a high-rise building, and more particularly, in case of a fire in a high-rise building, preparation for evacuation is completed with a simple operation, and by automatically detecting ground proximity to supplementally buffer the shock caused by a fall, injuries caused by a fall It relates to an emergency escape device for high-rise buildings that can minimize the

Modern society is a new concept of urban concentration due to the rapid increase in population, urban concentration, increase in energy use, the development of digital industry that supports the pursuit of extreme convenience, and the emergence of a knowledge industrial society. faced, and this caused a variety of new disasters. Moreover, buildings also tend to become super high-rise, high-density, multi-functional and complex due to land use restrictions, land price increases, urban planning and economic-centric ideas.

Although skyscrapers are being built around the world, there is no agreed definition for skyscrapers in each country. Although high-rise buildings have been built and used for a long time, the definition of this has not been uniformly agreed upon because the dangers of disasters such as fires and the vulnerability of life-savings along with evacuation were not paid attention to. However, due to the 911 terrorist attacks on the World Trade Center and the recent increase in the number of skyscrapers around the world, attention has been focused on this.

In general, when a fire occurs in a building, extinguishing the fire with fire-fighting equipment provided in the fire station and rescuing people in the building with an elevated ladder is a method of extinguishing fire and saving lives in case of a fire.

However, the construction of high-rise buildings with more than 20 stories is actively progressing, and in particular, as such high-rise buildings with more than 20 stories, residential and commercial complexes are developed. In this way, residential and commercial buildings are being built.

In spite of the fact that residential-commercial buildings with more than 20 stories are being built, the current firefighting equipment can only extinguish fires up to the 20th floor. Climbing up to the roof of the building and waiting only for rescue by helicopter is the easiest way to save life, and there is a problem that other methods cannot be taken because other methods cannot be used.

In addition, in such high-rise buildings with 20 stories or more, there is an updraft rising along the walls of the building. There is a problem in that human casualties spread exponentially in a short period of time because sufficient evacuation time cannot be given.

Therefore, in the event of a fire in such a high-rise building, it is said that there is little way for the residents of the high-rise building to escape, compared to the rapid spread of the flame. there has been

(Document 1) Republic of Korea Patent No. 10-1290070 (Registered on July 22, 2013) (Document 2) Republic of Korea Patent Registration No. 10-1183058 (Registered on September 10, 2012) (Document 3) Korean Patent Laid-Open Patent No. 10-1995-0002801 (published on February 16, 1995) (Document 3) Republic of Korea Registered Utility Model No. 20-0269302 (Registered on March 11, 2002)

It is an object of the present invention to solve the above problems, and to provide an emergency evacuation device for a high-rise building that allows anyone to evacuate by completing an escape preparation with a simple operation in case of a fire in a high-rise building.

Another object of the present invention is to provide an emergency escape device for a high-rise building capable of automatically detecting ground proximity to supplementally buffer the impact caused by a fall, thereby minimizing injuries due to a fall.

Another object of the present invention is to provide an emergency escape device for a high-rise building that can be stored in a reduced storage and can be kept in sufficient number to ensure maintainability of management.

In order to achieve the above object, the present invention includes: an escape body made of a flexible material and forming a space that can accommodate a person when charging air; an automatic air injection device unit provided in the escape body portion and configured to fill the escape body portion by automatically injecting air; an injection operation switch for transmitting an execution command for the charging operation of the air injection unit; And, it is provided in the escape body portion, and is activated at a predetermined distance relative to the ground when the escape body portion falls, a fall shock absorber configured to buffer the impact of the fall; characterized in that it comprises a.

In addition, the escape body part is made of a flexible resin material or fabric, and the escape body part is provided in the shell and is provided in the shell so as to be expanded to a predetermined shape by injection of air, and is configured to communicate with the shell at one or more locations an endothelium formed to be expanded into a predetermined shape by air injection, and a support tube formed at one or more locations in the space between the outer skin and the endothelium, one end communicating with the endothelium and the other end coupled to the inner surface of the outer skin, and the outer skin and an air injection path communicating the endothelium and the liver.

In addition, the automatic air injection device unit includes an air pump device having a battery and executing an operation by operating the injection operation switch, and a connector connecting the air injection side of the air pump device and the air injection path to be configured in a plurality on the lower side of the shell, and on the inner surface of the endothelium, the handle is configured in two or more places at a symmetrical position, and on one side of the shell and the endothelium, the shell and the endothelium are integrally connected by a predetermined length A connecting portion is formed, and the connecting portion is provided with a zipper (zipper) to provide an entrance through which a user enters and exits.

In addition, a cover strip extending along the formation direction of the doorway and having one end fixed to the outer skin to cover the doorway is formed, and the other end of the cover strip and the outer skin are detachably configured with a belt furnace, and the endothelium In, the seat belt device that can be worn by the user accommodated therein is further configured.

In addition, in the air injection path, an air flow hole is formed on the air injection path, and air flow in the air injection direction is allowed at the end of the endothelial side of the air injection path, and the air flow in the opposite direction to the air injection path is formed with an intermittent one-way membrane film part, and the automatic air injection device further includes a protection chamber to surround and protect the automatic air injection device, wherein the protection chamber is bypassed and connected to the air injection path It is connected through a connecting tube.

In addition, the drop buffer unit includes one or more reverse propulsion air outlets having one end communicating with the inside of the shell and having an open free end at the other end, and a closing member formed at one end of the reverse propulsion air outlet, and the closing member and a control module configured on one side to control to open the closing member at a predetermined height, wherein the reverse thrust air outlet is made of the same material as the outer shell, and one end of the rigid material for stably providing the closing member The frame of the closure member is composed of a plate-type closing member configured to be openable outwardly from one end of the reverse propulsion air outlet, and the control module includes a height detecting means for detecting a predetermined height with respect to the ground. and a locking means for locking the opening of the closing member, and a circuit module for transmitting a control command for unlocking the locking means based on a detection result of the height detection means.

In addition, the control module is configured to receive the required power from the battery unit of the automatic air injection unit, and the reverse thrust air outlet is configured in plurality around the lower central portion of the shell and the lower central portion thereof, and the The height detecting means is composed of an altimeter or a laser distance sensor and is configured to activate the control module when a preset altitude or a predetermined height is reached, and the control module is configured to activate the control module together with a lock release control command of the locking means. It is made so that air is injected by activating the air injection device, it further includes one or more parachute modules configured to be deployed on the upper side of the outer shell and instantly unfold from the receiving unit with a control command of the control module.

As can be clearly seen from the above description, the emergency evacuation device for a high-rise building of the present invention provides the effect of evacuating by completing the shape of the escape body with a simple one-touch operation in the event of a fire in a high-rise building and executing a quick escape.

In addition, in addition to the buffer structure of the escape body unit itself, it automatically detects ground proximity to supplementally buffer the shock caused by the fall, thereby exhibiting the effect of minimizing the injury caused by the fall.

At the same time, by allowing the storage to be reduced on a regular basis, there is an effect that it can be kept in sufficient number according to the number of people in use. This is a very useful invention that can greatly contribute to minimizing human casualties due to fire, etc.

1 is a front view showing the external configuration of an emergency escape device for a high-rise building according to the present invention.
Figure 2 is a front sectional view showing the internal configuration of the emergency escape device for a high-rise building according to the present invention.
Figure 3 is an operational state diagram showing an embodiment of the emergency escape device for a high-rise building according to the present invention and the operation relationship.
4 is a block diagram showing the control relationship between electrical and electronic components constituting the emergency escape device for a high-rise building according to the present invention in blocks.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily practice the present invention.

First, it should be noted that in adding reference numerals to the components of the drawings, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in the description of the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Of the accompanying drawings, FIG. 1 is a front view showing the external configuration of the emergency escape device for a high-rise building according to the present invention, FIG. 2 is a front sectional view showing the internal configuration of the emergency escape device for a high-rise building according to the present invention, and FIG. 3 is this It is an operation state diagram showing an embodiment of the emergency escape device for a high-rise building according to the present invention and an operation relationship, and FIG. 4 is a block showing the control relationship between the electrical and electronic components constituting the emergency escape device for a high-rise building according to the present invention in blocks. It is also

1 to 3, the emergency escape device for a high-rise building according to the present invention is made of a flexible material and forms a space in which a person can be accommodated when air is injected. An automatic air injection device 200 provided in the escape body portion 100 and configured to automatically fill air in the escape body portion 100 by the operation of the injection operation switch 300 below, and the air injection station An injection operation switch 300 that transmits an execution command for the charging operation of the tooth 200, is provided in the escape body portion 100, and is activated at a predetermined distance to the ground when the escape body portion 100 falls and a fall shock absorber unit 400 configured to generate a fall shock absorber.

The escape body part 100 is made of a resin material or fabric, etc., but is made of a flexible material, and can be stored by compression and contraction in usual times, and according to the operation of the injection operation switch 300, the automatic air injection device part ( 200) and is expanded to form a predetermined shape.

Specifically, the escape body portion 100 is provided in the shell 110 and the shell 110 is formed to expand into a predetermined shape (preferably, spherical) by injection of air, the shell 110 at one or more locations. The endothelium 120 is configured to communicate with the 110 and is formed to expand into a predetermined shape (preferably spherical) by air injection, and is formed at one or more locations in the space between the outer shell 110 and the endothelium 120, One end communicates with the endothelium 120 and the other end includes a support tube 130 coupled to the inner surface of the outer skin 110, and an air injection path 140 that communicates between the outer skin 110 and the endothelium 120. .

On the lower side of the shell 110, an automatic air injection device 200 to be described in detail below is configured. As such, the automatic air injection device 200 is configured on the lower side of the escape body 100 to provide a function as a weight.

And, on the inner surface of the endothelium 120, a handle that can be gripped by a user accommodated therein is configured in two or more places at a symmetrical position. In addition, a seat belt device that can be worn by the user accommodated inside the endothelium 120 is further configured. As such, by the configuration of the seat belt device, it is possible to provide more stability to a user who is falling from a high place.

Subsequently, on one side of the shell 110 and the endothelium 120, a connection part for integrally connecting the shell 110 and the endothelium 120 by a predetermined length in the longitudinal direction is formed, and this connection part is a zipper is formed to form an entrance 111 through which the user enters and exits.

Here, on the shell 110 of the portion where the zipper is formed, a cover strip extending along the formation direction of the doorway 111 and having one end fixed to the shell 110 to cover the doorway 111 is formed. . Between the other end of the cover strip and the outer shell 110, it is configured to be detachable with a belt or the like.

In addition, the support tube 130 is filled with air in the space between the outer shell 110 and the endothelium 120 through an air injection path 140 to be described later, and then air is injected into the endothelium 120 to the endothelium. (120) As the inside of the air is filled, the support tube 130 is expanded to stably maintain the space formation between the outer shell 110 and the endothelium 120.

Subsequently, the air injection path 140, an air flow hole is formed on the air injection path 130, and allows air flow in one direction (ie, the air injection direction) to the end of the endothelial side, and the other The air flow in the direction (ie, the reverse direction of the air injection direction) is configured by forming a one-way membrane film portion 141 to intermittently.

By configuring the one-way membrane film part 141, the filling of air into the endothelium 120 is allowed, and the air filled in the endothelium 120 is prevented from escaping to the outside so that the shape of the endothelium 120 is stably maintained. make it possible

Next, the automatic air injection device unit 200 includes an air pump device provided with a battery and performing an operation by operating the injection operation switch 300 , and the air injection side and the air injection side of the air pump device It includes a connector for connecting between the furnaces (140). In addition, it further includes a protection chamber to surround and protect the automatic air injection device 200, the protection chamber is configured to be connected through a bypass connection tube connected to the bypass in the air injection path (140).

Here, when the automatic air injection device 200 further includes a protection chamber as described above, when the emergency escape device of the present invention falls to the ground and collides with the ground, the automatic air injection device 200 is buffered. By providing the castle, it is possible to minimize the transmission of the automatic air injection device 200 and the falling impact of the ground to the user (escaper) inside the endothelium 120 .

And, the injection operation switch 300 is connected to the automatic air injection device 200 and is configured to be exposed to the outside of the outer shell 110 . Preferably, the injection operation switch 300 is electrically connected to the automatic air injection device 200 and is preferably configured to be attached to the outer surface of one side of the shell 110 .

Next, the fall buffer unit 400 is provided in the escape body unit 100 and is activated at a predetermined distance relative to the ground when the escape body unit 100 falls to generate a fall buffer force to prevent collision with the ground. At least one reverse thrust air outlet 410 formed as a free end with one end communicating with the inside of the outer shell 110 and having an open other end, a closing member formed at one end of the reverse thrust air outlet, and It is configured on one side of the closing member and includes a control module 420 for controlling to open the closing member at a predetermined height.

The reverse propulsion air outlet is composed of the same flexible material as the outer shell 110 of the escape body portion 100, one end of which is constituted by a rigid frame for the closure member to be stably provided.

The closing member may be formed of a plate-type closing member configured to be openable in an outward direction (a direction in which air exits to the outside) from one end of the reverse propulsion air outlet.

Subsequently, the control module includes a height detection means for detecting a predetermined height with respect to the ground, a locking means for locking the opening of the closing member (eg, a solenoid type locking device), and a detection result of the height detection means It includes a circuit module for transmitting a control command for unlocking the locking means based on the.

The height detection means, locking means, and circuit module of the control module may be configured to receive the required power from the battery unit constituting the automatic air injection device 200, and may be configured with a separate battery unit. .

The reverse thrust air outlet may be configured in plurality around the lower central portion of the outer shell 110 and the lower central portion thereof.

The height detection means may be composed of an altimeter or a laser distance sensor, and activates the control module when the falling escape body 100 reaches a preset altitude or a predetermined height.

In addition, the control module is configured to activate the automatic air injection device together with a lock release control command of the locking means so that air is additionally injected.

When the fall buffer unit 400 configured in this way reaches the height or height detected by the height detection means, the detected value is transmitted to the circuit module, and the circuit module unlocks the locking means to open the closing member. When this occurs, the air in the escape body 100 is injected through the reverse propulsion air outlet so that the air in the escape body 100 is propelled in the opposite direction to the falling direction of the escape body 100, thereby reducing the falling speed and reducing the impact force on the ground.

At this time, the control module automatically activates the operation of the automatic air injection unit so that the air is continuously charged toward the escape body unit 100 so that the charging air that escapes through the operation of the drop shock absorber unit 400 can be supplemented. do.

On the other hand, the present invention may further include an auxiliary fall shock absorber unit 500 in addition to the fall shock absorber unit 400 , wherein the auxiliary fall shock absorber unit 500 includes the upper side of the outer shell 110 . It may further include a parachute module configured to be instantly unfolded by the control command of the control module.

The parachute module, as shown in FIG. 4, can open the receiving unit in the same manner as the explosion method of the air bag in the state stored in the receiving unit such as an air bag so that the parachute is unfolded to the outside, and is symmetrical to the upper part of the outer shell It is preferable that a plurality of formations are made so as to be activated before the operation of the fall shock absorber unit 400 . Accordingly, after reducing the fall speed, the reverse propulsion function by the fall shock absorber 400 can be more reliably executed.

In summary, according to the emergency escape device for a high-rise building of the present invention, in the event of a fire in a high-rise building, it is possible to evacuate by completing the shape of the escape body part with a simple one-touch operation and executing a quick escape, and in addition to the buffer structure of the escape body part itself By automatically detecting the proximity to the ground, it is possible to minimize the injuries caused by the fall by buffering the shock caused by the fall.

The above description is merely illustrative of the technical idea of the present invention, and a person skilled in the art to which the present invention pertains may make various modifications, changes and substitutions within the scope without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are for explaining, not limiting, the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments and the accompanying drawings . And, the protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: escape body part, 110: outer shell
111: doorway, 120: endothelium
130: support tube, 140: air injection path
141: one-way membrane film unit, 200: automatic air injection device unit
300: injection operation switch, 400: drop buffer unit
410: reverse thrust air outlet, 420: control module
500: auxiliary fall buffer unit

Claims (7)

an escape body made of a flexible material and forming a space that can accommodate a person when charging air;
an automatic air injection device unit provided in the escape body portion and configured to fill the escape body portion by automatically injecting air;
an injection operation switch for transmitting an execution command for the charging operation of the air injection unit; and
It includes a; includes a; is provided in the escape body portion and is activated at a predetermined distance to the ground when the escape body portion falls, and configured to buffer the impact of the fall;
The escape body portion is made of a flexible resin material or fabric,
The escape body portion includes an outer shell formed to be expanded into a predetermined shape by injection of air, an endothelium provided in the shell and configured to communicate with the shell at one or more locations to expand into a predetermined shape by injection of air, the shell and It is formed at one or more locations in the space between the endothelium, and one end communicates with the endothelium and the other end includes a support tube coupled to the inner surface of the outer skin, and an air injection path for communicating between the outer skin and the endothelium,
The air injection path, an air flow hole is formed on the air injection path,
A one-way membrane film part is formed on the end of the endothelial side of the air injection path to allow air flow in the air injection direction and intermittently intermittently air flow in the opposite direction to the air injection,
The automatic air injection device further comprises a protective chamber for protecting the automatic air injection device portion,
The protection chamber is configured to be connected through a bypass connection tube that is bypassed and connected in the air injection path,
The drop buffer unit includes one or more reverse thrust air outlets having one end communicating with the inside of the shell and having an open free end at the other end, a closing member formed at one end of the reverse thrust air outlet, and one side of the closing member and a control module configured to control to open the closing member at a predetermined altitude,
The reverse propulsion air outlet is composed of the same material as the outer shell, and one end of the frame is made of a rigid material for stably providing the closing member,
The closing member is composed of a plate-type closing member configured to be openable in an outward direction from one end of the reverse propulsion air outlet,
The control module includes a height detection means for detecting a predetermined height with respect to the ground, a locking means for locking the opening of the closing member, and a control command for unlocking the locking means based on the detection result of the height detection means Including a circuit module to transmit,
The reverse propulsion air outlet is configured in plurality around the lower central portion of the shell and the lower central portion thereof,
The height detection means is composed of an altimeter or a laser distance sensor and is configured to activate the control module when reaching a preset altitude or a predetermined height,
The control module is an emergency escape device for a high-rise building, characterized in that air is injected by activating the automatic air injection device together with a lock release control command of the locking means. delete According to claim 1,
The automatic air injection device unit includes an air pump device having a battery and executing an operation by operating the injection operation switch, and a connector connecting the air injection side of the air pump device and the air injection path. It is composed of a plurality of pieces on the lower side of the shell,
On the inner surface of the endothelium, the handle is configured in two or more places in a symmetrical position,
A connection part for integrally connecting the shell and the endothelium is formed on one side of the shell and the endothelium by a predetermined length, and a zipper is formed on the connection part to provide an entrance for a user to enter and exit. emergency escape device. 4. The method of claim 3,
A cover strip extending along the formation direction of the doorway and having one end fixed to the shell to cover the doorway is formed, and the other end of the cover strip and the shell are detachably configured with a belt path,
The endothelial, emergency escape device for high-rise buildings, characterized in that the seat belt device that can be worn by the user accommodated therein is further configured.
delete delete According to claim 1,
The control module is configured to receive the required power from the battery unit of the automatic air injection unit,
Emergency escape device for a high-rise building, characterized in that it further comprises one or more parachute modules configured to be deployed on the upper side of the outer shell from the receiving unit in an instant with a control command of the control module.

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