KR102570942B1 - Method for removing escalator - Google Patents

Abstract

The escalator demolition method according to the present invention includes a first step of installing a pair of first running rails in parallel on the left and right sides of the opening of the upper surface of the upper slab; A second step of seating an escalator removal device including a truss structure and a traction hoist on the pair of first running rails; A third step of pulling the escalator cutting part by lowering the hook of the traction hoist; A fourth step of moving the truss structure along the first running rail so that the escalator cut portion pulled in the third step is pulled to a point higher than the upper surface of the upper slab, so that the escalator cut portion is located at a point outside the opening. ; and a fifth step of seating the escalator cutting part on the upper surface of the upper slab. If the escalator demolition method according to the present invention is used, the escalator installed inside the building can be cut and then seated on the upper slab, so the escalator can be more easily removed, and the escalator cut portion can be pulled in the horizontal direction of the escalator cut portion. Since the position can be adjusted, there is an advantage in preventing the escalator cutting portion from colliding with the opening of the slab.

Description

Escalator demolition method {Method for removing escalator}

The present invention relates to a demolition method in which an escalator is disassembled and then removed by a traction method, and more particularly, the dismantled escalator parts are towed to the top slab at once, and then the towed parts are moved in a horizontal direction to the upper surface of the top slab. It relates to an escalator demolition method configured to be seated on.

In general, an escalator is a lifting and lowering device that conveniently transfers passengers between floors of various public buildings such as department stores, airport buildings, subway stations, and hotels.

An escalator moves a step, an endless track type staircase using conveyor technology, up and down by an electric device. It is configured to continuously circulate a number of steps installed on the step chain at regular intervals along the guide rail by mounting a circular step chain.

Since these escalators are very large in overall size and heavy, when removing the escalator, a worker cuts the escalator into several pieces and then withdraws the escalator to the outside of the building. However, even if the escalator is cut into several pieces, it is difficult to tow the cut parts because the cut parts are too heavy for a person to lift directly.

At this time, a method of towing the cut escalator using a crane may be proposed, but currently commercialized cranes have a problem in that they are very large and difficult to install in the interior of a building. In addition, in order to withdraw the cut escalator fragment to the outside of the building, it must be pulled up through the opening of the slab and then moved to the window. , there is a problem that it is impossible to raise the upper slab or move it horizontally on the upper slab.

KR 20-1996-0002232 Y1

The present invention has been proposed to solve the above problems, and the cutting part of the escalator installed inside the building can be seated on the upper slab, and the escalator cutting part can be moved in the horizontal direction when the escalator cutting part is pulled, so that the escalator cutting part can be moved to the slab. The purpose is to provide an escalator demolition method that can prevent hitting the opening of the.

Escalator demolition method according to the present invention for achieving the above object, the first step of installing a pair of first running rails in parallel on the left and right sides of the opening of the upper slab; A second step of seating an escalator removal device including a truss structure and a traction hoist on the pair of first running rails; A third step of pulling the escalator cutting part by lowering the hook of the traction hoist; A fourth step of moving the truss structure along the first running rail so that the escalator cut portion pulled in the third step is pulled to a point higher than the upper surface of the upper slab, so that the escalator cut portion is located at a point outside the opening. ; and a fifth step of seating the escalator cutting part on the upper surface of the upper slab.

Two or more traction hoists are provided in the truss structure, and in the third step, the angle of the escalator cut portion is adjusted by independently controlling the operation of the two or more traction hoists so that the escalator cut portion to be pulled does not interfere with the opening. includes the process of

The truss structure includes two or more transverse trusses arranged in a direction crossing the first running rail, a longitudinal truss integrally connecting the two or more transverse trusses, and from the transverse truss or the longitudinal truss. It is composed of a plurality of vertical trusses extending downward and seated on the pair of first running rails,

A second travel rail arranged in a direction crossing the first travel rail is installed on the transverse truss, and a second travel unit coupled to the traction hoist is mounted on the second travel rail in a reciprocating structure,

The fifth step includes a step of adjusting the seated position of the cutting part of the escalator by moving the second running unit along the second running rail.

The transverse truss is composed of a pair of fixed trusses having one side in the longitudinal direction fixedly coupled to the longitudinal truss and a slide truss having both sides in the longitudinal direction coupled to the pair of fixed trusses in an insertable and withdrawable structure,

The second step includes adjusting the length of the transverse truss according to the distance between the pair of first running rails.

It is installed on the upper surface of the slab and further includes a pair of support beams to which the pair of first running rails are mounted on the upper surface, and a connecting bar connecting the pair of first running rails, wherein the connecting bar has a length It consists of a pair of fixing bars fixedly coupled to each of the pair of support beams at one side in the direction and a slide bar coupled to the pair of fixing bars at both sides in the longitudinal direction in a structure that can be inserted into and withdrawn from the pair of fixing bars,

The first step includes adjusting the distance between the pair of first running rails by adjusting the length of the connecting bar according to the width of the opening.

The vertical trusses are mounted in pairs on one first running rail and coupled to the longitudinal truss in a structure in which the upper part of the pair of vertical trusses is rotatable by a truss hinge orthogonal to the first running rail in the horizontal direction,

A screw bar on one phase, one side of which in the longitudinal direction is rotatably coupled to the middle of the pair of vertical trusses by a screw hinge parallel to the truss hinge, and a rotating body in which the other side in the longitudinal direction of the screw bar is coupled with a screw coupling structure. Further comprising, but the pair of screw bars are formed in the opposite direction of the screw thread,

The second step may further include adjusting an inclination angle of the vertical truss by rotating the rotating body after the truss structure is seated on the pair of first running rails.

If the escalator demolition method according to the present invention is used, the escalator installed inside the building can be cut and then seated on the upper slab, so the escalator can be more easily removed, and the escalator cut portion can be pulled in the horizontal direction of the escalator cut portion. Since the position can be adjusted, there is an advantage in preventing the escalator cutting portion from colliding with the opening of the slab.

1 to 6 sequentially show the process of removing the escalator using the escalator removal method according to the present invention.
7 is a perspective view of an escalator removal device used in the escalator removal method according to the present invention.
8 is a perspective view of a first driving unit included in an escalator removal device.
9 is a front view of the second driving unit included in the escalator removal device.
Figure 10 is a plan view showing the shape of moving the escalator cutting portion in the horizontal direction.
11 and 12 show another embodiment of a connecting bar and a transverse truss.
Figure 13 shows another embodiment of the truss structure used in the escalator demolition method according to the present invention.

Hereinafter, an embodiment of an escalator demolition method according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 sequentially show the process of removing the escalator using the escalator removal method according to the present invention.

The escalator demolition method according to the present invention is a method of pulling the cut part of the escalator (hereinafter referred to as 'escalator cutting part') to the upper surface of the upper slab after cutting the escalator to remove the escalator installed inside the building. Traction work is possible even in a low indoor area, and the biggest feature is that the opening of the slab is prevented from colliding with the escalator cutout and being damaged by towing while moving the escalator cutout in the horizontal direction.

In the case of dismantling the escalator 1 using the escalator demolition method according to the present invention, first, as shown in FIG. 1, a pair of first running rails on the left and right sides of the opening 12 of the upper slab 10 ( 100) in parallel, as shown in FIG. 2, the escalator removal device including the truss structure 200 and the traction hoist 600 is seated on the pair of first running rails 100. At this time, the truss structure 200 is configured to be able to reciprocate linearly on the second running rail 400, and the traction hoist 600 is coupled to the upper part of the truss structure 200 but can move up and down the hook 610. ), The structure and function of the truss structure 200 will be described in detail with reference to FIGS. 7 to 9 below.

When the seating of the escalator removal device is completed, as shown in FIGS. 3 and 4 , the hook 610 is lowered to pull the escalator cutting part 1a. Since the traction hoist 600 is not installed on the upper slab 10 but installed on the top of the truss structure 200, the escalator cutting part 1a pulled by the traction hoist 600 is of the upper slab 10. It can be towed to a point higher than the top surface.

At this time, two or more traction hoists 600 mounted on the truss structure 200 may be provided but configured to be independently controllable. In this way, when each traction hoist 600 is configured to be independently controllable, the hook 610 of the right traction hoist 600 is more than the hook 610 of the left traction hoist 600 in the state shown in FIG. By pulling a lot, it becomes possible to erect the escalator cutting part (1a) to be pulled. When the escalator cutout 1a is erected in this way, when the escalator cutout 1a passes through the opening 12, the distance from the inner end of the opening 12 increases, so that the escalator cutout 1a is the upper slab ( There is an advantage in that interference with the opening 12 of 10) can be prevented.

When the escalator cutting part 1a is pulled to a point higher than the upper surface of the upper slab, as shown in FIG. 5, the escalator cutting part 1a is located at a point outside the opening 12. The first running rail 100 After moving the truss structure 200 along ), the escalator cutting part 1a is seated on the upper surface of the upper slab 10.

In this way, when the escalator demolition method according to the present invention is used, the work of pulling the escalator cutting part and the work of moving the towed escalator cutting part in the horizontal direction can be performed at once, so the time required for removing the escalator is significantly reduced, It has the advantage that various safety accidents can be prevented because manual work of the operator is not required for traction and movement of the cut part of the escalator.

Figure 7 is a perspective view of the escalator removal device used in the escalator removal method according to the present invention, Figure 8 is a perspective view of the first driving unit 300 included in the escalator removal device, Figure 9 is included in the escalator removal device 2 is a front view of the driving unit 500, Figure 10 is a plan view showing the shape of moving the escalator cutting portion in the horizontal direction.

As shown in FIG. 7, the truss structure 200 reciprocating along the first running rail 100 includes two or more transverse trusses 220 arranged in a direction crossing the first running rail 100 and , The longitudinal truss 230 integrally connecting the two or more transverse trusses 220, and the pair of first running rails extending downward from the transverse truss 220 or the longitudinal truss 230 It may be composed of a plurality of vertical trusses 210 seated on (100).

At this time, on the transverse truss 220, the first running rail 100 and the traction hoist 600 are movable in the width direction of the opening 12, that is, in the direction crossing the first running rail 100. Second running rails 400 arranged in a crossing direction are installed, and the second running unit 500 coupled with the traction hoist 600 can be mounted on the second running rail 400 in a reciprocating structure. there is. Therefore, when the second travel unit 500 moves along the second travel rail 400, the traction hoist 600 coupled to the second travel unit 500 follows the second travel unit 500. It moves in the longitudinal direction of the second running rail 400 .

When the second running rail 400 and the second running unit 500 are installed in this way, after towing the escalator cutting part to a point higher than the upper surface of the upper slab 10, the second running as shown in FIG. 10 By moving the second driving unit 500 along the rail 400, the seating position of the escalator cutout can be adjusted in the width direction of the opening 12 (more specifically, in the longitudinal direction of the second running rail 400). there will be

In addition, when the traction hoist 600 is configured to be movable in the width direction of the opening 12, as shown in FIG. 5, when a pair of escalators 1 are installed in parallel, the pair of escalators 1 All can be removed, so workability is remarkably improved.

On the other hand, the truss structure 200 is configured to be transported back and forth along the first running rail 100. When the lower end of the vertical truss 210 directly contacts the first running rail 100, the vertical truss 210 ) and the first running rail 100, the truss structure 200 cannot be smoothly reciprocated because a very large frictional force is generated.

Therefore, in order to minimize the frictional force between the truss structure 200 and the first running rail 100, the plurality of vertical trusses 210 are respectively coupled to the lower ends of the vertical trusses 210 while moving along the first running rail 100, A first driving unit 300 for reciprocating the truss structure 200 may be additionally provided.

At this time, as shown in FIG. 8 , the first travel unit 300 is capable of rotating the first travel bracket 310 coupled to the lower end of the vertical truss 210 and the first travel roller 320 . It may be composed of a first driving roller 320 mounted in a structure and rolling along the first traveling rail 100 and a first driving motor 330 rotating the first traveling roller 320 . When the first travel unit 300 is configured in this way, when the truss structure 200 is moved along the first travel rail 100, the first travel rail 100 has rolling friction of the first travel roller 320. Since only this is generated, the truss structure 200 can be more smoothly transported.

In addition, the first travel bracket 310 is installed so that the first travel unit 300 does not fall in the width direction of the first travel rail 100 while rolling on the upper surface of the first travel rail 100. Both sides in the width direction extend downward and may be configured to contact both sides in the width direction of the first running rail 100 . In this way, when both sides of the first traveling bracket 310 in the width direction are configured to come into contact with both sides of the first travel rail 100 in the width direction, even when an external force is applied to the first travel unit 300 in the width direction, the first travel unit 300 As long as the traveling bracket 310 is not damaged, there is an advantage in that it can be stably reciprocated along the first traveling rail 100 .

The second travel unit 500 is coupled to the second travel bracket 510 to which the traction hoist 600 is coupled, and is rotatably coupled to the second travel bracket 510 to form the second travel rail 400. ), and a second driving motor 530 that rotates the second traveling roller 520, as shown in FIG. 9, the hook of the traction hoist. When the traction hoist 600 pulls the cutting part of the escalator when the 610 is configured to be displaced from the center of the second running rail 400, the second traveling bracket 510 moves the second running rail by the weight of the cutting part of the escalator. There is a risk of falling from (400).

Therefore, even if the weight of the escalator cutting part is applied to the traction hoist 600 side, the second driving unit 500 does not cross over to the traction hoist 600 side and maintains a state stably seated on the second traveling rail 400. It is preferable to be configured so that

For example, as shown in this embodiment, the traction hoist 600 is coupled to one side (right side in FIG. 9) of the second travel bracket 510 in the width direction, and the second travel rail 400 is The lower flange 420 seated on the upper surface of the transverse truss 220, the upper flange 410 on which the second driving unit 500 is seated, and the abdomen connecting the lower flange 420 and the upper flange 410 ( 430), the second travel unit 500 extends downward from the other side in the width direction of the second travel bracket 510 and has a lower end of the guide frame 540 positioned below the upper flange 410. ) and a guide roller 550 coupled to the lower end of the guide frame 540 in a rotatable structure and rolling in the longitudinal direction of the second running rail 400 on the bottom surface of the upper flange 410. can

In this way, when the guide frame 540 and the guide roller 550 are provided in the second traveling bracket 510, the escalator cut portion is hooked to the hook 610 of the traction hoist 600, and the second traveling bracket 510 Even if a clockwise external force is applied to ), since the guide roller 550 is in close contact with the bottom surface of the upper flange 410, the second travel bracket 510 does not tilt to either side and is stable on the upper surface of the upper flange 410. You will be able to maintain a stable state.

11 and 12 show another embodiment of the connecting bar 120 and the transverse truss 220.

When pulling the escalator cutting part (1a), the load is transferred to the first running rail 100 and the support beam 110, a problem in which the pair of first running rails 100 do not remain parallel and twist to one side. may occur. In this way, to prevent the pair of first running rails 100 from being twisted, the pair of first running rails 100 are connected by a separate connecting bar 120 as shown in FIG. 7 . It can be configured so that When the pair of first running rails 100 are mounted on the pair of support beams 110 installed on the upper surface of the slab, the connecting bar 120 may be coupled to connect the pair of support beams 110. there is.

At this time, the opening 12 formed in the slab 10 is manufactured in various sizes according to the specifications of the escalator to be constructed, and the distance between the pair of first running rails 100 depends on the specifications of the opening 12. It is configured to be increased and decreased, and the width of the truss structure 200 should also be configured to be increased and decreased.

Therefore, the length of the connecting bar 120 and the transverse truss 220 can be configured to be able to increase or decrease at the work site. For example, as shown in FIG. 11, the transverse truss 220 includes a pair of fixed trusses 222 having one side in the longitudinal direction fixedly coupled to the longitudinal truss 230, and both sides in the longitudinal direction as described above. It may be composed of a slide truss 224 coupled to a pair of fixed trusses 222 in an insertable and withdrawable structure. Similarly, as shown in FIG. 12, the connecting bar 120 includes a pair of fixing bars 122 having one side in the longitudinal direction fixedly coupled to each of the pair of support beams 110, and both sides in the longitudinal direction having the same It may be composed of a slide bar 124 coupled to a pair of fixing bars 122 in a structure capable of being inserted and withdrawn.

In this way, when the lengths of the connecting bar 120 and the transverse truss 220 are configured to be adjustable in the field, a pair of first running rails 100 are installed in appropriate positions according to the width of the opening 12 And, since the length of the connecting bar 120 and the transverse truss 220 can be adjusted according to the distance between the pair of first running rails 100, the operator can only use the second running rail 400 at a different length. It is possible to dismantle escalators of various standards by installing as a product of

Figure 13 shows another embodiment of the truss structure 200 used in the escalator demolition method according to the present invention.

In order to allow the escalator cutting part 1a having a large standard to be seated on the upper surface of the upper slab 10, it is preferable that the mounting height of the traction hoist 600 is set as high as possible. That is, as the mounting height of the traction hoist 600 increases, the escalator cutout 1a of various sizes can be seated on the upper surface of the upper slab 10. Since the distance is formed differently depending on the type of building, there is a limit to increasing the mounting height of the traction hoist 600.

In order to solve the above problems, it is preferable that the truss structure 200 is configured such that the mounting height of the traction hoist 600 is adjustable.

For example, the vertical trusses 210 are mounted in pairs on one first running rail 100, and the pair of truss hinges 212 orthogonal to the first running rail 100 in the horizontal direction. The top of the vertical truss 210 is coupled to the longitudinal truss 230 in a rotatable structure, and one side in the longitudinal direction is connected to the pair of vertical trusses 210 by a screw hinge 712 parallel to the truss hinge 212. ) It may be configured to further include a screw bar 710 of one phase coupled to the middle in a rotatable structure, and a rotation body 720 to which the other side in the longitudinal direction of the screw bar 710 is coupled to a screw coupling structure. At this time, since the pair of screw bars 710 are formed in the opposite direction of the screw lines, the distance between them becomes closer or farther depending on the rotation direction of the rotating body 720.

Therefore, as shown in FIG. 13, when the rotating body 720 is rotated so that the pair of screw bars 710 come closer to each other, the two vertical trusses 210 seated on one first running rail 100 are lowered. Since they are built close to each other, the height of the transverse truss 220 increases, and the effect of increasing the installation height of the traction hoist 600 installed on the transverse truss 220 can be obtained. Conversely, if the height of the building is low and the installation height of the traction hoist 600 needs to be lowered, the rotation body 720 is rotated so that the pair of screw bars 710 are away from each other to lower the inclination of the vertical truss 210 By this, it is possible to lower the height of the transverse truss 220 and the traction hoist 600 mounted thereto.

In this way, when the height of the truss structure 200 is configured to be adjustable, the operator can freely adjust the mounting height of the traction hoist 600 according to the height of the building to be constructed, so that the escalator removal construction can be more easily performed. there will be

At this time, a rotation motor 730 for rotating the rotation body 720 may be additionally provided so that the height of the truss structure 200 can be automatically adjusted. In this embodiment, only the structure in which the driving force of the rotation motor 730 is transmitted to the rotation body 720 by the worm gear and the worm wheel gear is shown, but the driving force of the rotation motor 730 is transmitted to the rotation body 720 The power transmission structure can be changed and applied in various forms.

In the above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to specific embodiments, and should be interpreted according to the appended claims. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

1: escalator 10: slab
12: opening 100: first running rail
110: support beam 120: connecting bar
122: fixed bar 124: slide bar
200: truss structure 210: vertical truss
212: truss hinge 220: transverse truss
222: fixed truss 224: slide truss
230: longitudinal truss 300: first driving unit
310: first traveling bracket 320: first traveling roller
330: first driving motor 400: second driving rail
410: upper flange 420: lower flange
430: abdomen 500: second driving unit
510: second traveling bracket 520: second traveling roller
530: second drive motor 540: guide frame
550: guide roller 600: traction hoist
610: hook 710: screw bar
712: screw hinge 730: rotation motor
720: rotation body

Claims (6)

A first step of installing a pair of first running rails in parallel on the left and right sides of the opening of the upper slab;
A second step of seating an escalator removal device including a truss structure and a traction hoist on the pair of first running rails;
A third step of pulling the escalator cutting part by lowering the hook of the traction hoist;
A fourth step of moving the truss structure along the first running rail so that the escalator cut portion pulled in the third step is pulled to a point higher than the upper surface of the upper slab, so that the escalator cut portion is located at a point outside the opening. ; and
A fifth step of seating the escalator cutting part on the upper surface of the upper slab;
Escalator demolition method including. The method of claim 1,
The truss structure is provided with two or more traction hoists,
The third step is an escalator demolition method comprising the step of adjusting the angle of the escalator cutting part by independently controlling the operation of the two or more traction hoists so that the escalator cutting part to be pulled does not interfere with the opening. The method of claim 1,
The truss structure includes two or more transverse trusses arranged in a direction crossing the first running rail, a longitudinal truss integrally connecting the two or more transverse trusses, and from the transverse truss or the longitudinal truss. It is composed of a plurality of vertical trusses extending downward and seated on the pair of first running rails,
A second travel rail arranged in a direction crossing the first travel rail is installed on the transverse truss, and a second travel unit coupled to the traction hoist is mounted on the second travel rail in a reciprocating structure,
The fifth step is an escalator demolition method comprising the step of adjusting the seated position of the escalator cutting part by moving the second driving unit along the second running rail. The method of claim 3,
The transverse truss is composed of a pair of fixed trusses having one side in the longitudinal direction fixedly coupled to the longitudinal truss and a slide truss having both sides in the longitudinal direction coupled to the pair of fixed trusses in an insertable and withdrawable structure,
The second step is an escalator demolition method comprising the step of adjusting the length of the transverse truss according to the separation distance of the pair of first running rails. The method of claim 3,
Further comprising a pair of support beams installed on the upper surface of the slab and having the pair of first running rails mounted on the upper surface, and a connecting bar connecting the pair of first running rails,
The connecting bar is composed of a pair of fixed bars having one side in the longitudinal direction fixedly coupled to each of the pair of support beams, and a slide bar having both sides in the longitudinal direction coupled to the pair of fixing bars in a structure capable of being inserted into and withdrawn,
The first step is an escalator demolition method comprising the step of adjusting the distance between the pair of first running rails by adjusting the length of the connecting bar according to the width of the opening. The method of claim 3,
The vertical trusses are mounted in pairs on one first running rail and coupled to the longitudinal truss in a structure in which the upper part of the pair of vertical trusses is rotatable by a truss hinge orthogonal to the first running rail in the horizontal direction,
A screw bar on one phase, one side of which in the longitudinal direction is rotatably coupled to the middle of the pair of vertical trusses by a screw hinge parallel to the truss hinge, and a rotating body in which the other side in the longitudinal direction of the screw bar is coupled with a screw coupling structure Further comprising, but the pair of screw bars are formed in the opposite direction of the screw thread,
The second step, the escalator demolition method further comprising the step of adjusting the inclination angle of the vertical truss by rotating the rotating body after seating the truss structure on the pair of first running rails.

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