KR102053083B1 - Device for emergency escape - Google Patents

Abstract

Provided in the present invention is an emergency evacuation device which provides a high space utilization of a building and is easy to use even for children or the elderly. To this end, the emergency evacuation device which is installed at an outer wall of a building is characterized by comprising: an outer wall frame unit which is installed to be foldable so as to switch between a folded state of being close to the outer wall and an unfolded state of protruding from the outer wall to the outside to form a vertical moving space at a gap from the outer wall; a rotating frame unit which is rotatably fixated at a floor of the building and is operated between a standby state of being vertically arranged on the floor and a rotating state of being horizontally laid on an axial line of the vertical moving space; a control unit which operates the outer wall frame unit and the rotating frame unit; and an elevating unit including an elevating plate which is installed at the rotating frame unit to be elevatable along the vertical moving space, and a descending life line which elevates the elevating plate.

Description

Emergency Escape Device {DEVICE FOR EMERGENCY ESCAPE}

The present invention relates to an emergency escape device.

In high-rise buildings such as apartments, devices for emergency escape are being developed. Existing emergency escape devices are mainly installed on the veranda to provide emergency escape routes such as ladders and stairs along the outer wall of the building.

However, the existing emergency escape apparatus occupies a lot of space in the building, thereby reducing the space utilization or providing an emergency escape route by a ladder or a staircase, which makes it difficult for children or the elderly to use.

Accordingly, an object of the present invention is to provide an emergency escape device that can increase the space utilization of the building, and can be easily escaped by children and elderly people.

According to the present invention, in the emergency escape device installed on the outer wall of the building, the folded state in proximity to the outer wall, and unfolding to protrude outward from the outer wall to form a vertical moving space between the outer wall. Between the outer wall frame portion is installed foldable between the state and the rotation state is fixed to the floor of the building rotatably, vertically disposed on the floor and the rotation state lying horizontally lying on the axis of the vertical movement space A rotating frame unit, an operation unit for operating the outer wall frame unit and the rotating frame unit, a lifting plate mounted on the rotating frame unit to move up and down along the vertical moving space, and a lifting device supporting the lifting plate. It is achieved by an emergency escape device having a lifting unit.

Here, a pair of guide rails disposed along the vertical moving space, and a lift guide member installed on the pivot frame to move up and down along the guide rail, and between the guide rail and the lift guide member. The lifting plate can be stably lowered by including a lowering speed adjusting unit for increasing a frictional force of the lifting guide member with respect to the guide rail according to the weight of the user boarding the lifting plate.

In addition, the lowering speed adjustment unit is a frictional friction comprising a plurality of elastic members installed in the lower portion of the elevating plate and the plate spring member which is located inside the elevating guide member having a convex shape toward the guide rail A member is connected to the elevating plate, and the other end thereof includes a wire connected to the pressure friction member. The wire increases the force of the plate spring member to press the guide rail as the descending distance of the elevating plate increases. Through it, it is possible to adjust the descending speed of the lifting plate according to the number of users boarding the lifting plate.

In addition, at the distal end of the outer wall frame portion, there is formed a leaf spring-shaped spreading auxiliary member protruding in the direction of the outer wall plate in the rotational state of the outer wall frame portion, the spreading auxiliary member is provided with an elastic force to the outer wall plate when the rotating frame portion is rotated It can be provided to absorb the shock generated when the rotating frame portion is rotated or to allow the outer wall frame portion to be fully unfolded to fully expand the outer wall frame portion through the expanding auxiliary member or to absorb the shock generated by the rotating state of the rotating frame portion have.

In addition, the emergency escape device is installed for each floor of the building, the lifting plate is installed in the opposite direction for each floor of the building, one end is installed in the rotating frame portion, the other side is in the operation unit installed on the lower floor The operation unit of the lower floor through the operation of the operation unit of the current floor through the interlocking wire installed to operate the operation unit installed on the lower floor by the rotation of the rotating frame unit to operate the outer wall frame unit and the rotating frame unit of the lower floor. The outer wall frame portion and the rotating frame portion can be operated.

The emergency escape apparatus according to the present invention has high space utilization of the building, and can be easily used by children or the elderly.

1 is a view showing an emergency escape apparatus according to the present invention.
FIG. 2 illustrates a state in which the outer wall frame part is unfolded in the drawing of FIG. 1 and the rotating frame part is rotated and laid down.
3 shows when the operation knob is in the standby state.
4 shows when the operation knob is in an operating state.
5 (a) to (c) show a process in which the rotating frame portion is rotated.
6 is a view showing a lifting unit.
7 (a) and 7 (b) show the operation of the lifting plate fixing part.
8 shows the lowering speed control unit.
9 (a) and 9 (b) show the operation of the descending speed control unit.
10 shows a plurality of emergency escape devices installed in the building to operate.

Hereinafter, an emergency escape apparatus according to the present invention will be described in detail with reference to FIGS. 1 to 10.

1 is a view showing an emergency escape apparatus according to the present invention. Emergency escape apparatus according to the present invention comprises a large outer wall frame portion 100, the rotating frame portion 200, the operation unit 400 and the lifting unit (300).

The outer wall frame part 100 corresponds to the outer wall of a building such as an apartment, and is expanded from a folded state and a folded state close to the outer wall of the building, protrudes a predetermined distance to the outside of the outer wall, and extends vertically in a space between the outer wall and the outer wall. It is installed to be able to fold between the expanded state forming a vertical moving space.

2 illustrates a state in which the outer wall frame part 100 is unfolded in the drawing of FIG. 1 and the pivoting frame part 200 is rotated and laid down. As shown, the outer wall frame part 100 is a pair of horizontal frame 120 that can be folded while connecting the outer wall plate 110 and the outer wall plate 110 and the outer wall of the building which are arranged at a predetermined distance from the outer wall of the building. And a pair of guide rails 140 extending in the vertical direction from the vertical frame 130 and the horizontal frame 120 supporting the outer wall plate 110 and the horizontal frame 120. As shown in FIG. 1, the outer wall plate 110 is in a folded state, and when the emergency escape occurs, as shown in FIG. 2 by the outer wall plate spreading unit, the horizontal frame 120 is unfolded and spread out. Is switched.

The outer wall plate 110 is prepared to serve as the outer wall of the building.

The vertical frame 130 and the horizontal frame 120 has a rigid material and structure that can withstand the weight of a person when using the emergency escape device according to the present invention.

The guide rails 140 are fixed to the horizontal frame 120 or the vertical frame 130 and extend along the axis of the vertical moving space to prepare a pair.

The outer wall plate spreading portion is an unfolding spring 101 that applies an elastic force in a direction in which the outer wall plate 110 extends, and one side is fixed to the outer wall plate 110, and a ring portion 103 is formed on the other side, so that the operation unit (to be described later) Fixed to 400 is made of a wire 102 to be fixed to the outer wall frame portion 100 in a folded state. Therefore, when the fixing of the ring part 103 and the operation unit 400 is released, the outer wall plate 110 is pushed to the outside of the building by the unfolding spring 101 and the outer wall frame part 100 is switched to the unfolded state.

 Rotating frame portion 200 is rotatably fixed to the floor (a) of the building, as shown in Figure 1, the air is placed perpendicular to the floor (a) and vertical movement, as shown in Figure 2 It operates between rotational states lying horizontally on the axis of space.

Rotating frame portion 200 in the standby state is approximately perpendicular to the building in the standby state, when the rotating frame portion 200 is lying down to prevent the space utilization of the building is reduced due to the corresponding space, in the rotating state The outer wall plate spreading part is spread out and is disposed in the horizontal direction on the generated vertical moving space to perform a function for emergency escape. The rotating frame unit 200 operates between the standby state and the rotating state by the rotating frame operation unit, the support frame 210, the standby scaffold 220, elevating guide member 230, elevating unit 300, the lifting machine 310.

The support frame 210 is disposed in the outer region of the rotation frame part 200 and is made of a solid material to support the lifting unit 300 and the atmospheric footrest 220.

Atmospheric scaffold 220 is coupled to the support frame 210, occupies about half of the vertical moving space area and the lifting unit 300 is disposed on the other side. Although the atmospheric scaffold 220 and the elevating plate 320 of the elevating unit 300 occupy about half of the vertical moving space in the illustrated state, their area ratio is not limited. The emergency escape apparatus according to the present invention is installed for each floor of the building, wherein the atmospheric scaffold 220 and the elevating unit 300 are installed in a zigzag in opposite directions for each floor of the building as shown in FIG. 10.

The elevator 310 is fixed to the support frame 210 on which the lifting unit 300 is disposed, and the wire drawn out from the inside is coupled to and supported by the lifting unit 300. That is, the lifting device 310 is supported so that the lifting unit 300 can be lifted in a stable manner.

The elevating guide member 230 is installed in the elevating unit 300, the guide portion 231 allowing the passage of the guide rail 140 inward, and the guide rail when the rotating frame portion 200 is switched to the rotating state ( When the lifting unit 300 moves downward in the state in which the expansion unit 232 formed at the lower side and the guide rail 140 is inserted inside the guide unit 231 so that interference with the 140 is not generated, the guide rail ( 140 has a cutout 233 formed to be cut along the longitudinal direction in order to avoid interference by the connecting portion of the horizontal frame 120. The elevating guide member 230 and the guide rail 140, the guide unit 231 of the elevating guide member 230 is able to slide along the guide rail 140 to vertically move the elevating unit 300 is elevating It prevents vibration and shaft shift during exercise and enables stable lifting movement.

Rotating frame operation unit is installed in the region of the hinge rotatably fixing the rotating frame portion 200, the operation spring 203 for applying an elastic force to rotate the rotating frame portion 200 in the horizontal direction, and one end of the rotating frame portion The fixing part 201 which is in contact with the 200 to fix the rotation frame part 200 in a vertical state, and one end is coupled to the other end of the fixing part 201 and the other end is fixed to the operation unit 400 which will be described later. Wire 202.

When the operation of the rotating frame operation unit is pulled the wire 202 through the operation unit 400 to be described later, the wire 202 is pulled the other end of the fixing portion 201, and thus one end of the fixing portion 201 is rotated The contact with the frame part 200 is released and the pivoting frame part 200 is released. At this time, the rotation frame portion 200 is rotated by a predetermined interval by the elastic force of the operating spring 203, after which it is switched to the horizontal rotation state by the weight of the rotation frame portion 200 itself.

3 shows when the operation knob 410 is in the standby state, and FIG. 4 shows when the operation knob 410 is in the operating state. As shown, the operation unit 400 is formed in the lateral region of the outer wall frame portion 100 and the rotation frame portion 200 to operate them.

The operation unit 400 includes a rotation shaft 401 rotatably supported, an operation knob 410 protruding radially from the rotation shaft 401, and a plurality of operation protrusions.

As shown in FIG. 3, the operation knob 410 is rotated after the user grips the operation knob 410 as shown in FIG. 4 and the standby state in which the operation knob 410 is disposed in the vertical direction. It is rotatably fixed between operating states rotated to have a predetermined angle with respect to the vertical direction, the rotating shaft 401 is provided with an elastic member 402 for applying an elastic force so that the operation knob 410 is in the standby state. Accordingly, when the operation knob 410 is not used, the operation knob 410 is always maintained in the vertical state by the elastic member 610. At this time, the elastic member 610 may be prepared by a torsion spring.

The actuating protrusions are the outer wall plate actuating protrusion 420 inserted into the annular region of the annular part 103 formed at the end of the wire 102 of the outer wall plate spreading part, and the wire 202 connected to the fixing part 201 of the rotating frame actuating unit. Rotating frame operation protrusion 430 is coupled to the coupling protrusion 440 is coupled with the interlocking wire 901 of the interlocking drive to be described later.

As shown in FIG. 3, the outer wall plate operation protrusion 420 is formed to protrude in the opposite direction of the operation knob 410 in the standby state and is inserted into the ring region of the ring portion 103 to position the ring portion 103. Fix it. At this time, the other end of the wire 102 coupled with the ring portion 103 is fixed to the outer wall plate 110, and is in a state of being tightly supported by the action of the unfolding spring 101. Therefore, as shown in FIG. 4 by rotating the handle, when the outer wall plate actuating protrusion 420 leaves the ring region of the ring part 103, the outer wall plate 110 is pushed by the action of the unfolding spring 101. The outer wall frame part 100 is switched to the unfolded state.

As shown in FIG. 3, the rotation frame operation protrusion 430 is inclined at a predetermined interval from the lower side of the rotation shaft 401 to the area where the fixing part 201 is formed when the operation knob 410 is in the standby state. It protrudes and is formed. The end of the rotating frame operation protrusion 430 is connected to the wire 202 coupled with the other end of the fixing portion 201. Accordingly, when the operation knob 410 is rotated from the standby state to the operating state, as shown in FIG. 4, the end of the rotation frame operation protrusion 430 shows the wire 202 about the axis of the rotation shaft 401. Is pulled clockwise. Through this process, the fixing part 201 is retracted backward to release the fixing of the rotation frame part 200. At this time, the rotating frame unit 200 is started to rotate by the operating spring 203 and then laid down in the horizontal state by its own weight is converted to the rotating state.

5 (a) to (c) show a process in which the rotation frame unit 200 is rotated.

When the user operates the operation unit 400 in the state shown in Fig. 5 (a), as shown in Fig. 5 (b), the rotation frame unit 200 starts to rotate. At this time, the outer wall frame portion 100 is formed with a spreading guide 150 having a shape corresponding to the rotation curve of the rotating frame portion 200, the side of the rotating frame portion 200 is inserted into the spreading guide 150 An unfolding auxiliary protrusion 250 sliding along the unfolding guide 150 is formed. The unfolding guide 150 and the unfolding auxiliary protrusion 250 are guided so that the rotating frame part 200 can be accurately rotated. That is, even when the horizontal frame 120 is not fully unfolded, the unfolding protrusion 250 is inserted into the unfolding guide 150, and as shown in (c) of FIG. 5, the horizontal frame 120 is perfectly. Unfolded and also assists the rotation operation of the stable rotation frame unit 200.

As described above, the pair of lifting guide members 230 of the rotating frame part 200 are coupled to the pair of guide rails 140 disposed perpendicular to the outer wall frame part 100 due to the rotating operation. At this time, as described above, the elevating guide member 230 has an expansion pipe portion 232 formed to be extended in one direction so as not to interfere with the rotation radius of the rotation frame portion 200, and thus the rotation frame portion 200 is rotated In the process of the interference between the guide rail 140 and the lifting guide member 230 is prevented. Of course, due to the unfolding guide 150 and the unfolding auxiliary protrusion 250 may be guided the correct rotation.

On the other hand, at the end of the rotating frame portion 200 according to the present invention has a spreading auxiliary member 240 formed to protrude in the direction of the outer wall plate 110 in the rotated state. Unfolding auxiliary member 240 may be understood as a member of a kind of leaf spring. The unfolding auxiliary member 240 has a convex shape in the direction of the outer wall plate 110, the rotation frame portion 200 is rotated so that the end of the rotation frame portion 200 at the point of contact with the area of the outer wall plate 110 By providing an elastic force between the end and the inner side of the outer wall plate 110 to absorb the shock generated by the pivoting frame 200 is suddenly rotated, or go through the elastic force when the outer wall frame portion 100 is not fully deployed Assist in perfect unfolding.

6 is a view illustrating the lifting unit 300.

The elevating unit 300 is installed in the rotating frame part 200 to elevate or lower the lifting plate 320 and the lifting plate 320 with respect to the vertical moving space along the vertical moving space, or slowly return to the support frame 210. The lifting device 310 and the lifting plate 320 includes a lifting plate fixing part for fixing and detaching from the outer wall frame part 100.

The elevating plate 320 occupies about half of the bottom surface of the rotation frame unit 200 and is prepared in a rigid structure without problems even when a plurality of users board.

Ladder 310 is composed of a lumber base body and a gangbang string is installed in the rotation frame portion 200. The lanyard has one end coupled to the elevating plate 320 and the other end is received inside the lumber base. The slab basic body slowly lowers the lifting plate 320 downward from the rotation frame part 200 by using a stubborn rope, and then descends and returns to the original position through a device that rewinds the slab by elasticity inside the slab base after descending. Let's do it.

The elevating plate fixing part is formed so as to be protruding inwardly from the fixing column 520 and the operation handle 510 formed on the elevating plate 320, the fixed column 520 coupled to extend upward from the elevating plate 320, It is composed of a fixed block 530 to be fixed to the support frame 210. The fixed block 530 protrudes when the lifting plate 320 is not used and is fixed to the support frame 210 so that the lifting plate 320 is supported by the support frame 210 and manipulates the operation handle 510. When the protrusion is released, the lifting plate 320 is separated from the support frame 210 so as to be lowered.

In more detail, the operation handle 510 is the user is located on the chair (b) or the lifting plate 320 and then pulled toward the user by operating the fixing block 530 to the lifting plate 320 can be lowered movement. Make sure The operation handle 510 is supported by a separate elastic member such as a spring to maintain a standby state perpendicular to the lifting plate 320.

The fixing column 520 extends in a direction perpendicular to the lifting plate 320 and a fixing block 530 is installed at the end thereof so that the fixing column 520 can be mounted. As shown in the figure, a plurality of fixing columns 520 may be installed at both side regions of the elevating plate 320.

The fixed block 530 is installed to be protruding in the direction of the lifting plate 320 from the end of the fixing column 520 and is always prepared to maintain a protruding state by the spring 521. As shown in (a) of FIG. 7, the fixing block 530 contacts the upper surface of the support frame 210 so that the lifting plate 320 may be fixed to the support frame 210 when it protrudes. As shown in 7 (b), the contact with the support frame 210 is released when it is withdrawn so that the lifting plate 320 can move down.

The fixed block 530 is interposed between the spring 521 on the inside, the wire 511 is coupled to the end. The wire 511 is interlocked with the operation handle part 510.

That is, as shown in (b) of FIG. 7, when the user pulls the manipulation handle 510 inwards to rotate the wire 511 coupled to the end of the manipulation handle 510, the spring 521 may be used. Pulling the fixing block 530 while winning the elastic force, which causes the fixing block 530 to release the fixing of the lifting plate 320 to the support frame 210.

The fixed block 530 is made of a curved surface on the upper side when the lifting plate 320 is raised again to be fixed to the support frame 210, the lower surface of the support frame 210 to the curved surface of the upper surface of the fixed block 530 While pressing the fixed block 530 is moved to the inside of the fixed column 520 again and after the fixed block 530 is moved to the upper side of the support frame 210, the fixed block 530 by the spring 521 again Protruding and as shown in Figure 7 (a), the lifting plate 320 is fixed to the support frame 210.

8 shows the lowering speed control unit. The lowering speed adjusting part is installed between the guide rail 140 and the lifting guide member 230 to adjust the frictional force of the lifting guide member 230 with respect to the guide rail 140 according to the weight of the user riding on the lifting plate 320. Increasing the lifting plate 320 is a device for adjusting the speed.

The lowering speed adjusting part includes a plurality of elastic members 610 installed below the elevating plate 320, a wire 601 coupled with the elevating plate 320, and a pressing member 620 installed inside the elevating guide member 230. And a pressure friction member interlocked with the wire 601 and installed inside the elevating guide member 230.

A plurality of elastic members 610 are installed below the lifting plate 320. As shown in the figure, the elastic member 610 may be configured as a spring member installed below the lifting plate 320 to provide an elastic force to the lifting plate 320. The elastic member 610 adjusts the descending distance of the elevating plate 320 in response to the weight of the user riding on the elevating plate 320. That is, as more people board, the distance that the lifting plate 320 descends increases.

One side of the wire 601 is fixed to the elevating plate 320, and the other side of the wire 601 is fixed to the lower side through a through hole formed in an upper side of the pressure friction member. When the lifting plate 320 is moved downward, the wire 601 pulls the lower side of the pressure friction member upward.

The pressing member 620 is located inside the lifting guide member 230 and has a form of a leaf spring. The pressing member 620 partially contacts the side of the guide rail 140 to apply an elastic force toward the side of the guide rail 140.

The pressure friction member has a shape similar to that of the pressure member 620, but is installed separately from the pressure member 620. The pressure friction member is connected to an upper portion fixed to an upper side of the guide portion 231, a lower portion and an upper portion and a lower portion which are installed to be elevated along the guide portion 231 inside the guide portion 231, and guide rails. It is composed of a leaf spring member 621 is formed convex toward (140). 9, the pressure friction member is similar in shape to the pressure member 620 and the pressure friction member when the user does not board the lifting plate 320, but the user lifts the plate 320 as shown in FIG. 9), as shown in (b) of FIG. 9, the lower portion of the pressure friction member is pulled and moved toward the upper portion, and the bending amount of the leaf spring member 621 increases so that the leaf spring member 621 is guide rail. The force and area for pressing 140 are increased. Therefore, the force that the plate spring member 621 presses the side of the guide rail 140 is increased to increase the friction force between the guide rail 140 and the lifting guide member 230.

The wire 601 is coupled to the lower part through the upper part of the pressure friction member, and the lower part is moved upward and downward by pulling the wire 601, and the bending of the leaf spring member 621 increases in the process. Done. That is, as the number of occupants on the elevating plate 320 increases, the force and area for pressing the guide rail 140 by the leaf spring member 621 increases, so that the elevating guide member 230 descends along the guide rail 140. It is reduced, thereby allowing a stable downward movement of the lifting plate 320.

10 shows a plurality of emergency escape devices installed in the building to operate. Emergency escape apparatus according to the invention can be installed for each floor of the building.

In this case, as shown, the components for lifting and lowering the elevating plate 320 and the elevating plate 320 are installed in opposite directions for each floor based on the center of the rotating frame part 200.

Therefore, the user moves to the lower floor by using the lifting plate 320 in one floor, and moves to the lifting plate 320 waiting in the opposite direction from the lower floor, and then to the lower floor again. Through this repetitive movement, they will escape to the ground.

On the other hand, when the emergency escape device is installed for each floor of the building, the operation unit 400 is further operated by using the force of the rotation frame unit 200 is rotated further includes an interlocking drive unit for operating the operation unit 400. can do.

The interlocking drive unit may be composed of interlocking wires 901a and 901b, one end of which is coupled to the upper rotating frame unit 200 and the other side of which is fixed to the interlocking protrusion 440 formed on the manipulation handle 410.

The interlocking wires 901a and 901b are provided over two layers, as shown in FIGS. 3 and 4. That is, one side of the interlocking wire 901a is coupled to the side of the rotating frame part 200 of the current layer, and the other side is coupled to the interlocking protrusion 440 of the operation handle 410 of the lower layer. 3 and 4, the interlocking wire 901b coupled to the interlocking protrusion 440 of the manipulation handle 410 of FIG. 3 and 4 may be coupled to one side of the upper side of the pivoting frame part 200 on the other side. Likewise, it is coupled to the interlocking protrusion 440 of the operation knob 410 of the current floor.

Therefore, when the user operates the operation knob 410 of the upper floor and the rotating frame unit 200 rotates, the interlocking wire of the upper layer pulls the interlocking protrusion 440 of the current floor and rotates the operation knob 410 by the pivot shaft 401. Rotate around the center to operate the outer wall plate spreading part of the current floor and the rotating frame operation unit. If the user rotates the manipulation handle 410 of the current floor and the rotating frame part 200 of the current floor is rotated, the interlocking wire 901a of the current floor is pulled so that the linking protrusion 440 of the lower floor is lowered. The rotating shaft 401 is rotated about the outer wall plate of the lower floor and the rotating frame operation unit is operated. This phenomenon is continuously applied to the lower layer as well. That is, when the user rotates the manipulation handle 410 of a specific floor and the rotating frame part 200 of the specific floor is rotated, both the outer wall frame part 100 and the rotating frame part 200 of the lower floors are operated. .

This, when viewed from the outside has an effect that makes it easy to determine in which floor an emergency situation occurred through the outer wall frame portion 100 is unfolded, the continuous outer wall frame portion 100 and the rotating frame portion ( 200 to enable the operation.

The following describes the operation of the emergency escape apparatus of the present invention with reference to FIG.

FIG. 10 illustrates a state in which an elevating plate of an intermediate layer is lowered to a lower layer in a state in which an operation unit installed at an uppermost part of the city operates to unfold the outer wall frame portions and the rotating frame portions of lower layers. At this time, the upper lifting plate can be understood to return to the upper side after descending to the intermediate layer.

In the event of a disaster such as a fire, the user rotates the operation handle 410 of the operation unit 400 to operate the outer wall frame unit 100 and the rotation frame unit 200. In this process, the operation unit 400 of the lower layer is operated while the rotating frame unit 200 is laid down to operate the outer wall frame unit 100 and the rotating frame unit 200 of the lower layer.

Thereafter, the user moves to the elevating plate 320 of the rotating frame unit 200 and sits on the chair b, and then releases the elevating plate 320 from the support frame 210 through the operation handle unit 510. To the lower floor. At this time, the lifting plate 320 is lowered slowly by the lifting device 310 and the lifting rope, and the lifting guide member 230 is lowered along the guide rail 140, so that it can move downward stably, due to the lowering speed control unit The descent speed is adjusted according to the user's weight.

When the user arrives on the lower floor, the user moves to the lifting plate 320 provided on the opposite side, and is seated on the chair b, and then lowers the lifting plate 320 to the next floor through the operation handle part 510 to perform an emergency escape. do.

On the other hand, the wires according to the present invention can be prepared in the form of a chain, the installation position or the moving direction and the extended direction through the pulley can be adjusted.

On the other hand, the emergency escape device according to the present invention may further include an alarm unit to notify the emergency situation in conjunction with the user to rotate the operation knob 410 of the operation unit 400, or interlocked with the operation knob 410 The fire alarm system in the building can then generate an emergency signal. In addition, the operation handle 410 may be linked to rotate to notify the operation of a nearby police box or fire station to inform the emergency situation.

On the other hand, the guide rail 140 according to the present invention may have an expansion rail portion having a larger diameter than the region of the upper portion than the region of the upper portion. When the elevating plate 320 is lowered due to the expansion rail portion, the surface of the expansion rail portion contacts the pressing member 620 or the leaf spring member 621 in the guide portion 231 and increases their relative frictional force. The elevating plate 320 is adjacent to the expansion rail portion, which is a lower region of the guide rail 140, or lowers the falling speed of the elevating plate 320 when passing through the expansion rail portion can be moved more stably.

a: building floor b: chair
100: outer frame portion 101: unfolding spring
102 wire 103: ring portion
110: outer wall plate 120: horizontal frame
130: vertical frame 140: guide rail
150: unfolding guide 200: rotating frame portion
201: fixing part 202: wire
203: operating spring 210: support frame
220: stand foot 230: lifting guide member
231: guide portion 232: expansion tube
233: cutout 240: unfolding auxiliary member
250: unfolding auxiliary projection 300: lifting unit
310: steel plate 320: lifting plate
400: operation unit 401: rotating shaft
402: elastic member 410: operation handle
420: outer wall operation projection 430: rotation frame operation projection
440: interlocking protrusion 510: operation handle
511: wire 520: fixed pillar
521: spring 530: fixed block
601: wire 610: elastic member
620: pressure member 621: leaf spring member
901, 901a, 901b: interlocking wire

Claims (5)

In the emergency escape device installed on the outer wall of the building,
An outer wall frame portion foldably installed between a folded state proximate to the outer wall and an expanded state protruding outward from the outer wall to form a vertical moving space between the outer wall and the outer wall;
A rotating frame part fixed to the floor of the building to operate between a standby state disposed vertically to the floor and a rotating state lying horizontally on an axis of the vertical moving space;
An operation unit for operating the outer wall frame portion and the rotation frame portion;
An elevating unit installed on the pivot frame and capable of elevating along the vertical moving space, and an elevating unit supporting an elevating plate;
A pair of guide rails disposed along the vertical moving space,
An elevating guide member installed on the pivot frame to move up and down along the guide rail;
Emergency escape characterized in that it is installed between the guide rail and the elevating guide member to increase the frictional force of the elevating guide member relative to the guide rail according to the weight of the user riding on the elevating plate Device. delete The method of claim 1,
The lowering speed control unit and the pressure friction member including a plurality of elastic members installed in the lower portion of the elevating plate, and the leaf spring member which is located inside the elevating guide member and has a convex shape toward the guide rail; One end is connected to the lifting plate and the other end includes a wire connected with the pressure friction member,
The wire is emergency escape apparatus, characterized in that for increasing the descending distance of the elevating plate increases the force that the leaf spring member presses the guide rail. The method of claim 1,
At the end of the outer wall frame portion is formed an auxiliary plate of the leaf spring protruding in the direction of the outer wall plate in the rotation state of the outer wall frame portion,
The spreading auxiliary member provides an elastic force to the outer wall plate when the rotating frame part is rotated to absorb an impact generated when the rotating frame part rotates or to make the outer wall frame part fully unfold. The method of claim 1,
The emergency escape device is installed for each floor of the building,
The lifting plate is installed in opposite directions for each floor of the building,
One end is installed in the rotating frame part, the other side is installed in the operation unit installed on the lower floor to operate the operation unit installed on the lower floor by the rotation of the rotating frame part to operate the outer wall frame part and the rotating frame part on the lower floor. Emergency escape device further comprises a interlocking wire.

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