KR102112588B1 - Auto self swing out evacuation structure - Google Patents

Abstract

The present invention relates to an automatic self-swing-out evacuation structure. An objective of the present invention is to provide an automatic self-swing-out evacuation structure which is folded in a state of being tightly attached to a guardrail of a high-rise building, and is spread to be perpendicular to the guardrail of the high-rise building to form an evacuation space in an emergency. To achieve the objective, the automatic self-swing-out evacuation structure comprises: a fixed frame which includes a first rotating shaft and a second rotating shaft separated from each other in an erected position, and is installed on the outside of a guardrail; a first rotating frame of which the inner end is fixed on the first rotating shaft to rotate with the first rotating shaft; a second rotating frame of which the inner end is fixed on the second rotating shaft to rotate with the second rotating shaft; a connection frame wherein one end thereof is coupled to the outer end of the first rotating frame in a foldable structure, and the other end thereof is coupled to the outer end of the second rotating frame in a foldable structure; a bottom frame positioned between the first rotating frame and the second rotating frame, wherein the lower end thereof is coupled to the second rotating frame by a hinge to be tightly attached to the second rotating frame or to be spread to close a lower portion of a space between the first and second rotating frames to form an evacuation space of a passage form with the first and second rotating frames; a binding means to bind the second rotating frame to the guardrail; a rotation inducing means to rotate the first and second rotating frames to allow the first and second rotating frames to be perpendicular to the guardrail; and a wire installed to connect the bottom frame and the first rotating frame to be tensioned in a process in which the first and second rotating frames rotate in a direction perpendicular to the guardrail to induce the bottom frame to be spread in a horizontal position.

Description

Auto self swing out evacuation structure

The present invention relates to a contrast structure provided to safely evacuate and escape from flames and smoke in a high-rise building, and more specifically, it is folded around a high-rise building railing while rotating around a rotating axis of a standing posture, or folded in a high-rise building railing It is made to provide a space that allows the user to evacuate to the ground and evacuate from the flames and smoke while spreading in an orthogonal posture. It relates to an auto-self swing-out preparation structure made to guide evacuation and escape.

In general, high-rise buildings have the advantage of increasing the efficiency of land use, but have the disadvantage that it is difficult for residents to quickly evacuate when a disaster such as a fire occurs.

Accordingly, high-rise buildings are equipped with a variety of evacuation equipment that allows residents to evacuate safely out of high-rise buildings or evacuation spaces where residents can safely evacuate in the event of a disaster such as a fire.

As the evacuation equipment, the most commonly used elevator is to assist in escaping to the ground by riding on the outer wall of a building using a rope when it is difficult to escape using a stairway or an emergency passage in a disaster situation. It is an evacuation device designed to descend to the ground.

When a user attempts to escape from a building using a descender in a disaster situation, the user escapes to the ground by using the descender in a fixed state by hanging the descender on a descender mount provided in the building.

As described above, in order to escape using a descender, installation and wearing of the descender must be performed first, so there is a disadvantage that rapid escape is difficult.

In other words, in the urgent situation due to the occurrence of a fire, you can find a separately stored elevator and install it on the elevator platform, and then wear the elevator belt to the body and rotate the elevator platform to the outside of the building before you can escape from the building. There was a fear of missing the golden time to escape from suffocation due to the delay of time, such as preparing for after an accident, in the rapid escape.

In addition, as the user approaches the outer wall of the building in the process of descending to the ground by using a descender, there is a problem of being easily exposed to flame or smoke.

In addition, the forearm is a young, powerful, fear-resistant person, or a trained person, but there is a problem that is not easy to use.

Registered Patent Publication No. 10-0555965 (announced March 3, 2006)

The present invention has been made in consideration of the problems described above, and the object of the present invention is to fold in a state in close contact with a high-rise building railing and, in case of an emergency, auto-self swing-out evacuation made to form an evacuation space while spreading orthogonally to the high-rise building railing. In providing a structure.

Another object of the present invention is configured to be unfolded in a posture orthogonal to the railing through a simple operation to release the binding with the high-rise building railing, and is easy to use. In the event of a fire, evacuation within a very short time before flame and smoke spread It is to provide an auto self swing out evacuation structure that can be made.

Another object of the present invention is to provide an auto self swing-out evacuation structure capable of prompt and safe evacuation from flames and smoke, even for the elderly and children.

Another object of the present invention is to provide an auto self swing-out evacuation structure that can minimize damage to the exterior of a high-rise building due to installation of evacuation equipment by being in close contact with the veranda when not in use.

The present invention for achieving the above object and performing the task of removing the conventional defects includes a first rotating shaft and a second rotating shaft spaced apart from each other in a standing position, and fixedly installed outside the railing of a high-rise building frame; A first rotating frame having an inner end fixed to the first rotating shaft and being rotated with the first rotating shaft to be in close contact with the railing or to be orthogonal to the railing; A second rotating frame having an inner end fixed to the second rotating shaft and rotating with the second rotating shaft to be in close contact with the railing or to be orthogonal to the railing; One end is coupled in a foldable structure to the outer end of the first rotating frame, and the other end is coupled in a foldable structure to the outer end of the second rotating frame to connect the outer ends of the first and second rotating frames. Connection frames that connect to each other; Located between the first rotating frame and the second rotating frame, the lower end is hinged to the second rotating frame to be in close contact with the second rotating frame or unfolded to close the lower portion of the space between the first and second rotating frames. A floor frame forming a passage-type evacuation space together with the 1,2-rotating frame; Binding means for binding the second rotating frame to the railing; Rotation induction means for rotating the first and second rotating frames such that the first and second rotating frames are orthogonal to the railing; And a wire that is installed to connect the bottom frame and the first rotating frame and induces the bottom frame to expand in a horizontal posture while being tensioned in the process of rotating the first and second rotating frames in a direction perpendicular to the railing. It provides an auto self swing out evacuation structure.

On the other hand, in the auto-self swing-out evacuation structure, the rotation inducing means is installed to be positioned between the fixed frame and the railing, and supports the fixed frame in an inclined position so that the upper end of the fixed frame moves away from the railing to the binding means. When the binding of the second rotating frame is released, the first and second rotating frames may be formed of an inclined frame that induces the first and second rotating frames to rotate in a direction perpendicular to the railing by the weight of the first and second rotating frames and the bottom frame and the connecting frame. .

On the other hand, in the automatic self-swing out evacuation structure, the rotation induction means may be formed of a first rotational shaft and a second rotational shaft, and may be formed of a torsion spring rotating the first rotational frame and the second rotational frame in a direction perpendicular to the railing. have.

delete

On the other hand, in the auto self swing-out evacuation structure, the first rotating frame and the second rotating frame are made of a plurality of first and second reinforcing members installed in the inside of the square frame, and the first and second reinforcing materials are first and second reinforcing members. It is preferable that the rotating frame is configured to coincide with the frame of the railing at a position in close contact with the railing.

On the other hand, in the auto self-swing out evacuation structure, one or more support jaws supporting the lower end portion of the bottom frame spread out so as to close the lower portion between the first and second rotating frames are further formed in the first rotating frame. desirable.

On the other hand, in the auto-self swing-out evacuation structure, the bundling means is formed of a rope extending from the outer end of the second rotating frame and being bound to the railing, and the rope is installed to be attached to the railing at a position close to the fixed frame. It is desirable to be.

According to the present invention having the above characteristics, since it maintains the state of being in close contact with the railing of the high-rise building in a folded state at normal times, it is possible to minimize the effect on the appearance of the high-rise building, and evacuate in a posture orthogonal to the railing in case of emergency. As it spreads out to form a space, it can be expected to have the effect of minimizing human damage caused by fire by allowing a large number of people to evacuate safely from flames and smoke.

In addition, the elderly and children and women, who are not easy to use evacuation equipment, can evacuate within a very short time before the spread of flames and smoke, thereby minimizing human damage caused by disasters such as fire.

1 is a perspective view showing a state in which the first and second rotating frames are folded so as to be in close contact with a high-rise building railing as an evacuation structure according to a preferred embodiment of the present invention,
Figure 2 is a side view showing a folded state so that the first and second rotating frames are in close contact with the railing of a high-rise building as an evacuation structure according to a preferred embodiment of the present invention,
3 is a perspective view showing a state in which the first and second rotating frames are unfolded to be orthogonal to a high-rise building railing as an evacuation structure according to a preferred embodiment of the present invention,
Figure 4 is a side view showing a state in which the first and second rotating frames as the evacuation structure according to the preferred embodiment of the present invention is spread so as to be orthogonal to the high-rise building railing,
5 is a plan view showing a state in which the first and second rotating frames are unfolded to be orthogonal to a high-rise building railing as an evacuation structure according to a preferred embodiment of the present invention,
6 is a perspective view of an evacuation structure in which the rotation guiding means according to the present invention is composed of a torsion spring;
7 is an exemplary view showing a state in which a floor frame according to the present invention is installed.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

1 is a perspective view showing a state in which the first and second rotating frames are folded so as to be in close contact with a high-rise building railing as an evacuation structure according to a preferred embodiment of the present invention, and FIG. 2 is a first evacuation structure according to a preferred embodiment of the present invention , A side view showing a state in which the two rotating frames are folded so that they are in close contact with the high-rise building railing, and FIG. 3 is a perspective view showing a state in which the first and second rotating frames are unfolded so as to be orthogonal to the high-rise building railing according to a preferred embodiment of the present invention 4 is a side view showing a state in which the first and second rotating frames are extended so as to be orthogonal to a high-rise building railing as an evacuation structure according to a preferred embodiment of the present invention, and FIG. 5 is an evacuation structure according to a preferred embodiment of the present invention The first and second rotating frames are plan views showing a state in which they are spread so as to be orthogonal to a high-rise building railing, and FIG. 6 is a torsional soup in which the rotation inducing means according to the present invention is twisted A perspective view of the evacuation structures composed, Figure 7 shows an exemplary view showing a state the floor frame is installed in accordance with the present invention.

The auto self swing-out evacuation structure according to the present invention is folded and stored in a state of being in close contact with the railing 10 of a high-rise building at normal times, and is expanded to be orthogonal to the railing 10 in the event of an emergency such as a fire, causing the user to evacuate and emergency It is made to form an evacuation space for escape, the fixed frame 110, the first rotating frame 120, the second rotating frame 130, the connecting frame 140, the bottom frame 150, and the binding means 160 , It is composed of a rotating induction means (170).

Meanwhile, the railing 10 of the high-rise building may be a safety railing installed on the outside of the balcony or balcony formed in the high-rise building.

The fixed frame 110 is installed on the outside of the railing 10 to support the rotation of the first rotating frame 120 and the second rotating frame 130, the first coupled to the first rotating frame 120 It is configured to include a rotating shaft 111 and a second rotating shaft 112 coupled to the second rotating frame 130.

On the other hand, the first rotating shaft 111 and the second rotating shaft 112 have a standing posture and are installed on the fixed frame 110 so as to have a structure that rotates independently while being spaced apart from each other.

The fixed frame 110 is stably fixed to the railing 10, stably supports the first and second rotating shafts 111 and 112, and may be variously configured within a range that does not interfere with the user's escape operation.

The first rotating frame 120 is made of a plurality of first reinforcing materials 121 installed inside a rectangular frame having a structure extending in a horizontal direction, and the inner end is fixed to the first rotating shaft 111. While rotating together with the one rotation shaft 111, it is folded so as to be in close contact with the railing 10 or unfolded to be perpendicular to the railing 10.

On the other hand, the first reinforcing material 121 installed on the first rotating frame 120 is configured to match the frame 111 of the handrail 10 when the first rotating frame 120 is folded to be in close contact with the handrail 10 In this case, when the evacuation structure is not used, the first rotating frame 120 has a structure visually integrated with the railing 10, thereby reducing damage to the exterior of the building by the evacuation structure.

The second rotating frame 130 is made of a plurality of second reinforcing materials 131 installed inside a rectangular frame having a structure extending in a horizontal direction, and the inner end is fixed to the second rotating shaft 112. While rotating together with the two rotating shafts 112, it is folded so as to be in close contact with the railing 10, or unfolded to be perpendicular to the railing 10.

Meanwhile, the second reinforcing material 131 installed on the second rotating frame 130 may be configured to match the frame of the handrail 10 when the second rotating frame 130 is folded to be in close contact with the handrail 10, In this case, when the evacuation structure is not used, the second rotating frame 130 visually has a structure integrated with the railing 10, thereby reducing the damage to the exterior of the building by the evacuation structure.

The connecting frame 140 connects the outer ends of the first rotating frame 120 and the outer ends of the second rotating frame 130 to each other so that the first rotating frame 120 and the second rotating frame 130 move together. By doing so, one end is coupled in a foldable structure to the outer end of the first rotating frame 120 via the first hinge 141, and the other end is the second rotating frame via the second hinge 142 It is coupled to the outer end of 130 in a collapsible structure.

The connection frame 140 may be configured as a stretchable structure so that the length can be changed in response to the rotational operation of the first and second rotating frames 120 and 130.

That is, the connection frame 140 is a first rotating portion 120a coupled to the first rotating frame 120 via the first hinge 141 and the second rotating frame 142 via the second hinge 142 ( It is divided into a second portion (140b) coupled to 130, the end of the first portion (140a) is inserted into the second portion (140b) to have a structure to be coupled, the connection frame 140 to a stretchable structure Can be configured.

The bottom frame 150 closes the lower portion of the space between the first and second rotating frames 120 and 130 to form a passage-type evacuation space together with the first and second rotating frames 120 and 130, and is made of a flat plate. It is located between the first rotating frame 120 and the second rotating frame 130, but the lower end is coupled to the lower end of the second rotating frame 130 by a third hinge 151, and the third in a horizontal posture. While rotating around the hinge 151, it is folded to be in close contact with the second rotating frame 130, or unfolded in a horizontal posture to close the space between the first and second rotating frames 120 and 130.

That is, when the first and second rotating frames 120 and 130 are folded in close contact with the handrail 10, the bottom frame 150 is in close contact with the second rotating frame 130 while standing in a vertical posture. When the rotating frames 120 and 130 are spread out to be orthogonal to the railing 10, they are converted into a horizontal posture to form the bottom of the evacuation space.

On the other hand, the wire 122 induces the floor frame 150 in a standing posture to be smoothly converted into a horizontal posture in response to the movement of the first and second rotating frames 120 and 130, and the posture is converted into a horizontal posture. The support jaw 123 supporting the bottom frame 150 may be further installed or formed in the first rotating frame 120.

The wire 122 is connected to the first rotating frame 120 and the bottom frame 150, but the first and second rotating frames 120 and 130 are tensioned in the process of rotating in the direction orthogonal to the railing 10 and the bottom frame ( While pulling 150), the floor frame 150 is induced to spread in a horizontal position.

More specifically, one end of the wire 122 is fixed to the first rotating frame 120 and the other end is installed to be fixed to the bottom frame 150, the first and second rotating frames 120 and 130 are railings 10 ), When the bottom frame 150 is in a standing position, the separation distance between one end and the other end is the shortest, and the first and second rotating frames 120 and 130 rotate in a direction orthogonal to the railing 10. One end of the wire 122 and the other end are gradually moved away from each other to be tensioned and configured to pull the bottom frame 150.

The support jaw 123 is formed to protrude in the direction of the second rotating frame 130 from the lower end of the first rotating frame 120 and is configured to support the bottom frame 150 spreading in a horizontal posture from the bottom. One or more support jaws 123 may be formed at the lower end of the first rotating frame 120.

The binding means 160 is to bind the first and second rotating frames 120 and 130 folded tightly to the handrail 10 to the handrail 10, from the outer end of the second rotating frame 130 to the handrail 10 It is made of a rope extended to be bound, but the rope is installed to be attached to the handrail 10 at a position close to the fixed frame 110.

Meanwhile, the rope constituting the binding means 160 may be configured to extend from the outer end of the second rotating frame 130 to the railing 10 while extending in a straight structure, and the outer side of the second rotating frame 130. It may be configured in a curved shape to be fixed to the railing 10 around the fixing frame 110 via the support 12 provided on the railing 10 from the end.

In addition, the end of the rope is formed of a ring 161 in the form of a ring, and is configured to be engaged with the railing 10 in a form of fastening the hook 161 to the binding rod 13 provided on the railing 10. In the event of a fire, the user releases the binding of the rope by lifting the hook 161 of the rope bound to the binding rod 13 near the fixed frame 110 to thereby bind the second rotating frame 130. After release, evacuation to the evacuation structure is possible on the spot, so evacuation is possible within a very short time before the flame and smoke spread.

The rotation induction means 170 rotates the first and second rotation frames 120 and 130 in a direction orthogonal to the railing 10 when the binding of the second rotation frame 130 by the binding means 160 is released. The first and second rotating frames 120 and 130, and the bottom frame 150 and the connecting frame 140 by the self-weight of the first and second rotating frames 120 and 130 are configured to be inclined frame 171 to induce rotation, or Or it may be composed of a torsion spring 172 installed on the first rotating shaft 111 and the second rotating shaft 112 to rotate the first and second rotating frames 120 and 130 using elastic energy.

The inclined frame 171 is installed to be positioned between the fixed frame 110 and the handrail 10 to support the fixed frame 110, but the upper end of the fixed frame 110 is from the handrail 10 than the lower end It is configured to fix the fixed frame 110 in an inclined posture away.

According to the inclined frame 171, when the restraint of the second rotating frame 130 by the binding means 160 is released, the first and second rotating frames 120 and 130, the bottom frame 150 and the connecting frame 140 ), The load acting on the first and second rotating shafts 111 and 112 acts to rotate the first and second rotating frames 120 and 130 in a direction orthogonal to the railing 10, so that the first and second rotating frames (120,130) is spread in a direction orthogonal to the railing (10).

On the other hand, the torsion springs 172 installed on the first and second rotating shafts 111 and 112, respectively, have one end fixed to the fixed frame 110, and the other end of the first rotating frame 120 or the second rotating frame 130. ) Is installed fixedly, the first and second rotating frames 120 and 130 accumulate elastic energy in the process of being folded to be in close contact with the handrail 10, and the binding of the second rotating frame 130 by the binding means 160 is prevented. When released, the first and second rotating frames 120 and 130 are rotated in the direction orthogonal to the railing 10 using the accumulated elastic energy.

The auto self swing-out evacuation structure according to the present invention configured as described above is installed on the outside of the railing 10 provided in the high-rise building, and the first and second rotating frames 120 and 130 are folded so that they are in close contact with each other, so that they adhere to the railing 120 Are kept.

Meanwhile, when the user releases the binding of the rope constituting the binding means 160 to release the restraint of the second rotating frame 130, the first and second rotating frames 120 and 130 are rotated by the rotating induction means 170. It will rotate in the direction orthogonal to the railing (10).

As such, in the process of rotating the first and second rotating frames 120 and 130, the first rotating frame 120 and the second rotating frame 130 gradually move away, and at this time, the first rotating frame 120 and the bottom frame 150 ), The wire 122 connecting the tension pulls the bottom frame 150 as it is tensioned, and accordingly the bottom frame 150 is rotated around the third hinge 151 to switch to a horizontal posture, and the first and second rotation The lower portion of the space formed between the frames 120 and 130 is closed.

After all, the first and second rotating frames 120 and 130 form the left and right handrails, and the bottom frame 150 forms the bottom connecting the left and right handrails, so that the evacuation passageway allowing the user to move away from the handrail 10 Is formed.

As described above, the evacuation structure according to the present invention allows the user to provide an evacuation space through a simple operation for releasing the binding of the rope in an urgent situation due to the occurrence of a fire, so that evacuation within a very short time before flame and smoke spread It is possible to minimize the casualties caused by fire.

In addition, the end of the formed evacuation route is far away from the building, so that it is possible to prevent human damage caused by exposure of the user to flames or smoke.

On the other hand, if a descender holder or a descender is installed in the connecting frame 140 positioned at the end of the evacuation route, it is possible to escape to the ground.

In addition, when the evacuation structures according to the present invention are installed on each layer of the high-rise building, the evacuation structures are arranged so that the evacuation structures spread in an orthogonal position to the railing 10 are not located on the same vertical line, or the first and second evacuation structures are arranged. It is preferable that the rotation frames 120 and 130 are rotated to have different angles.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be implemented by anyone who has ordinary knowledge in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, such changes are within the scope of the claims.

<Explanation of reference numerals for main parts of drawings>
110: fixed frame 111: first rotating shaft
112: second rotating shaft 120: first rotating frame
121: first reinforcement 122: wire
123: support jaw 130: second rotating frame
131: second reinforcement 140: connecting frame
150: bottom frame 160: binding means
170: rotation guide means 171: inclined frame
172: torsion spring

Claims (7)

A fixed frame 110 including a first rotating shaft 111 and a second rotating shaft 112 spaced apart from each other in a standing position and fixedly installed on the outside of the railing 10 of a high-rise building;
A first rotating frame 120 having an inner end fixed to the first rotating shaft 111 and being rotated with the first rotating shaft 111 to be in close contact with the handrail 10 or to be orthogonal to the handrail 10;
A second rotating frame 130 having an inner end fixed to the second rotating shaft 112 and being rotated with the second rotating shaft 112 to be in close contact with the handrail 10 or to be orthogonal to the handrail 10;
One end is coupled to the outer end of the first rotating frame 120 in a collapsible structure, and the other end is coupled to the outer end of the second rotating frame 130 in a collapsible structure, the first rotating frame 120 And a connecting frame 140 connecting the outer ends of the second rotating frame 130 to each other;
Located between the first rotating frame 120 and the second rotating frame 130, the lower end is hinged to the second rotating frame 130 to be in close contact with the second rotating frame 130 or the first and second A bottom frame 150 that expands to close the lower portion of the space between the rotating frames 120 and 130 and forms a passage-shaped evacuation space together with the first and second rotating frames 120 and 130;
Binding means 160 for binding the second rotating frame 130 to the railing 10;
A rotation induction means 170 for rotating the first and second rotating frames 120 and 130 such that the first and second rotating frames 120 and 130 are orthogonal to the railing 10; And
It is installed to connect the bottom frame 150 and the first rotating frame 120, the first and second rotating frames 120 and 130 are tensioned in the process of rotating in a direction orthogonal to the railing 10 and the bottom frame 150 Auto-self swing-out evacuation structure, characterized in that consisting of; wire 122 to induce to unfold in a horizontal position.
The method according to claim 1,
The rotation induction means 170 is installed to be positioned between the fixed frame 110 and the handrail 10, and the fixed frame 110 in a tilted posture so that the upper end of the fixed frame 110 is away from the handrail 10 ) To remove the binding of the second rotating frame 130 by the binding means 160 by the weight of the first and second rotating frames 120 and 130, the bottom frame 150 and the connecting frame 140. Auto swing swing-out evacuation structure, characterized in that the first and second rotating frames (120,130) are made of an inclined frame (171) to induce rotation in a direction orthogonal to the railing (10).
The method according to claim 1,
The rotation induction means 170 is installed on the first rotation shaft 111 and the second rotation shaft 112 in a direction orthogonal to the first rotation frame 120 and the second rotation frame 130 and the railing 10 Automatic self-swing out evacuation structure, characterized in that consisting of a rotating torsion spring (172).
delete The method according to claim 1,
The first rotating frame 120 and the second rotating frame 130 are made of a plurality of first and second reinforcing materials 121 and 131 installed inside the square frame, wherein the first and second reinforcing materials 121 and 131 are first and second. Auto-swing out evacuation structure, characterized in that the two rotating frames (120,130) are configured to match the frame (11) of the handrail (10) in a position in close contact with the handrail (10).
The method according to claim 1,
One or more support jaws 123 supporting the lower portion of the bottom frame 150 spread to close the lower portion of the space between the first and second rotating frames 120 and 130 are further formed in the first rotating frame 120. Auto self swing out evacuation structure.
The method according to claim 1,
The binding means 160,
It is made of a rope extending from the outer end of the second rotating frame 130 and bound to the handrail 10, wherein the rope is installed to be attached to the handrail 10 at a position close to the fixed frame 110. Auto self swing-out evacuation structure.

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