KR101796556B1 - pulley having earthquake-proof for stage setting apparatus - Google Patents

Abstract

The present invention relates to a pulley, installed in a stage device for various stage performances such as play, dancing, and opera to guide movement of a wire rope. More specifically, the pulley is designed to be firmly fixated to the stage device to prevent the pulley installed in an upper portion of a stage from being shaken by vibration to be broken or fall in case of earthquake.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a pulley having an earthquake-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pulley installed in a stage apparatus for performing various stages such as drama, dance, and opera and guiding the movement of a wire rope, and more particularly to a pulley installed on an upper part of a stage, And to be fixed firmly to the stage apparatus to prevent falling down.

The stage device for setting stage background in performances such as drama, dance, opera, etc. is composed of a wire rope hook connected to a hanging rack for a stage background, a wire rope wound on a drum, Up and down. At this time, the moving direction of the wire rope is switched by the pulley mounted on the support frame installed on the stage.

The pulley guides the smooth operation of the wire rope connected to the bracket when the bracket is raised or lowered. Such a pulley for the stage apparatus includes a plurality of row pulleys having a plurality of guide grooves for guiding a plurality of wire ropes, And a single-row pulley having only one guide groove for guiding the wire rope of the wire rope. The multi-row pulley includes a two-row pulley in which two guide grooves are formed, a three-row pulley in which three guide grooves are formed, and a four-row pulley in which four guide grooves are formed.

The single row pulley has a simple structure, a small volume, a light weight and a low cost compared to a multi-row pulley, so that a single row pulley is usually used in the stage apparatus.

Korean Patent Laid-Open No. 10-2010-0098175 discloses a stage device having a wire-supporting pulley.

In the above stage apparatus, a pulley is fixed to a pair of grids by bolts. However, since the pulley is fixed only to the outside of the grid, it is vulnerable to vibration. The stage device is required to be safe at the same time as it can quickly replace the stage background.

Recent earthquakes in Gyeongju province have confirmed that Korea is no longer safe from earthquakes. Therefore, although the pulley installed in the air requires higher stability, the pulley applied to the conventional stage apparatus is not designed to be earthquake-resistant, and therefore, it is inevitably vulnerable to an earthquake.

Korean Patent Publication No. 10-0645892 discloses a stage device capable of slightly improving the above-described problems.

In the stage apparatus, the hanging hooks 2 are connected to one end of each of the plurality of wire ropes 1 at regular intervals, so that the hanging hangs for a stage background. The movable sheave 10 is movable left and right along the longitudinal direction of the auxiliary frame 4 provided on the grid frame 3 on the work hanging table 2 and switches the directions of the respective wire ropes.

A bracket 12 is mounted on both sides of the rotary shaft 13 of the pulley 11 so that the base portion 12a of the bracket and the auxiliary frame 4 are connected to each other through a clip 14, And the support frame 17 fastened to the base portion 12a by bolts is supported by the auxiliary frame 4. [

As described above, the movable pulley applied to the stage apparatus has an advantage that the support force of the pulley is relatively increased because the support is mounted on one of the grids.

However, there is a problem that the coupling state is unstable because the support is installed only on one side. Therefore, there is a problem that when the earthquake occurs, it may fall, break or fail due to vibration or horizontal force.

Also, since the support bracket is designed to fit the gap between the brackets, there is a problem that the same support bracket can not be used when the spacing of the brackets is widened. The pulley is a single-row pulley that spans a single wire rope. However, in the case of a multi-row pulley, the width of the pulley is twice as thick as that of the single row. Therefore, it can not be installed on a multi-row pulley as a support applied to one row pulley.

Further, since the bolts for fixing the support brackets are fixed at specific positions of the brackets, there is a problem that installation can not be performed when the interval between the pair of auxiliary frames is changed.

Korean Patent Laid-Open No. 10-2010-0098175: Stage device having a wire-supporting pulley 2. Korean Registered Patent No. 10-0645892: Stage Device

It is an object of the present invention to provide an earthquake-resistant design pulley that can be applied to a single-row pulley or a plurality of multi-row pulleys and can be firmly supported on a stage apparatus even when an earthquake occurs.

Another object of the present invention is to provide an earthquake-resistant design pulley which can be installed even when the gap between a pair of grids on which a pulley is installed differs from place to place.

In order to achieve the above object, the present invention provides an earthquake-resistant design pulley for a stage device, the pulley installed on a stage device for guiding the movement of a wire rope, the stage device comprising a support frame installed on a stage, A pair of first and second grids installed on the upper portion of the support frame and coupled to the pulley through which the wire rope passes, a pair of hooks provided below the support frame, and a plurality of hooks And a plurality of wire ropes connected to a point of the wire rope are simultaneously wound or unwound to move the wire rope up and down, wherein a plurality of the wire ropes are sequentially arranged in descending order of distance from the driving portion, A roller provided on at least one side of the roller, A first fixing means for fixing one side of the supporting bracket to the first grid; a second fixing means for fixing the other side of the supporting bracket to the second grid; A first earthquake-resistant means which is in close contact with the first grid so as to prevent the support bracket from being disengaged when the support frame is vibrated, and to support the support bracket; And a second earthquake-resistant means which is in close contact with the second grid to support the support bracket and can change the distance between the first and second grid members in accordance with the distance between the first and second grids.

The first and second grids include a lower plate fixed to the upper portion of the support frame, an upper plate positioned at the upper portion of the lower plate and fixed to the lower portion of the support bracket by the first or second fixing means, And a vertical plate that connects the lower plate and the upper plate and is in close contact with the first or second vibration-isolating means, wherein the support bracket is provided with first and second fasteners A first and a second support through-hole are formed, which are respectively coupled to the through-hole, the first and second earthquake-resistant means and the first fixed through-hole and the second fixed through-hole, A first contact member which is in close contact with a vertical plate of the first grid and passes through the first support through-hole, and a second contact member which is screwed with the first contact member, Wherein the second earthquake-resistant means comprises: a second contact member which is in close contact with the vertical plate of the second grid and passes through the second support through-hole; And a second fastening member screwed to fix the second contact member to the support bracket.

At least one of the first and second support through-holes is formed as a long hole so as to adjust the distance between the first contact member and the second contact member.

Wherein the first contact member has a first contact head portion having a contact surface so as to be in surface contact with the vertical plate of the first grid and a second contact head portion extending upwardly from the first contact head portion and passing through the first support through- And a second threaded portion that is threadedly engaged with the first fastening member. The second contact member has a second contact head portion having a contact surface for surface contact with the vertical plate of the second grid, And a second screw portion extending upwardly from the second contact head portion and passing through the second support through-hole and having a thread formed on the outer circumferential surface thereof and screwed to the second fastening member.

The first earthquake-resistant means further comprises a first supporting force reinforcing portion coupled to the first screw portion and contacting the vertical plate of the first grid to increase the supporting force of the first earthquake-resistant means with respect to the first grid, And the second earthquake-resistant means further includes a second supporting force reinforcing portion coupled to the second screw portion and contacting the vertical plate of the second grid to increase the supporting force of the second earthquake-resistant means with respect to the second grid.

The first and second supporting force reinforcing portions may have at least one contact surface formed on the outer side and a circular through hole may be formed on the inner side to allow the first or second screw portion to pass therethrough.

The first and second earthquake-resistant means are further provided with a damping member for damping vibration transmitted from the support frame.

As described above, according to the present invention, since the pulley is provided with the earthquake-resistant means, the pulley can be securely fixed to the stage apparatus, so that the pulley can be effectively prevented from being shaken by vibration when the earthquake occurs.

Further, the present invention is advantageous in that the position of the second support means can be easily adjusted, so that the pulley can be constructed even if the gap between the first and second grids is changed.

Fig. 1 is a front view showing a stage apparatus equipped with an earthquake-resistant design pulley according to the present invention,
Fig. 2 is a front view of the one-row pulley applied to Fig. 1,
3 is a plan view showing a state in which the fixing means and the supporting means are removed from the pulley of FIG. 2,
Fig. 4 is an exploded perspective view of the pulley of Fig. 2,
Fig. 5 is a front view showing the main portion for showing the use state of the pulley shown in Fig. 2,
FIG. 6 is a cross-sectional view showing a state of the four-row pulley applied to FIG. 1,
7 is a front view showing a state of a single row pulley according to another embodiment of the present invention,
FIG. 8 is an exploded perspective view of FIG. 7,
9 is a cross-sectional view illustrating a four-row pulley according to another embodiment of the present invention.

Hereinafter, a seismic design pulley for a stage apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 shows a stage device in which an earthquake-resistant design pulley according to the present invention is installed.

The illustrated stage apparatus includes a support frame 200 installed on the stage, a pair of first and second grids 300 and 350 installed on the support frame 200, And a plurality of wire ropes 120 provided at one side of the support frame 200 and connected to a plurality of points of the work hanging table 110 are wound or unwound simultaneously to move the work hanging table 110 up and down And a plurality of pulleys 10, 20, 30, and 400 through which the wire rope 120 passes.

The material hanging table 110 is provided with materials for a stage background in the lower part and is connected to the wire rope 120 by a wire joint 111 installed on the upper part.

One end of the wire rope 120 is connected to the wire joint 111 and the other end is connected to the drum 130 of the driving part 125. The wire rope 120 is required to bear the weight of the hanging rack 110 on which the objects for the stage background are installed, so that it is preferable to use a material having a high tensile strength.

A plurality of wire ropes 120 are provided. In the illustrated example, the wire rope 120 is provided in a total of four lines. Each wire rope 120 is connected to a plurality of points of the wire rack 100 by a wire joint 111, respectively.

The driving unit 125 simultaneously winds or unwinds the plurality of wire ropes 120 to move the wire rack vertically.

The driving unit 125 includes a drum 130 on which a plurality of wire ropes are wound, and a motor 140 for rotating the drum 130. The driving unit 125 is configured to receive the power through the motor 140 while integrally connecting the decelerator and the brake to the shaft of the drum 130. Such a driving unit 1250 is a known structure as disclosed in Korean Patent Publication No. 10-0645892, and a detailed description thereof will be omitted.

The first and second grids 300 and 350 are installed on the upper portion of the support frame 200. The first and second grids 300 and 350 are installed to cross the support frame 200. The first and second grids 300 and 350 are spaced apart from each other and arranged in a pair. In the illustrated example, a total of four pairs of the first and second grids 300 and 350 are installed. Each pair is installed at regular intervals, and one pulley is installed for each pair. Accordingly, a plurality of pulleys 10, 20, 30, and 400 are provided on one support frame.

A plurality of pulleys 10, 20, 30, and 400 are sequentially arranged in descending order from the driving unit 125. In the illustrated example, a total of four pulleys 10, 20, 30, and 400 are installed. One or more rows of pulleys are applied depending on the distance from the driving unit 125. [ For example, a pulley 10 having the closest distance to the driving part 125 is applied with a four-row pulley, a pulley 20 positioned next to the pulley 10 is applied with a three row pulley, A pulley is applied, and the farthest pulley 400 is a one-row pulley.

Therefore, the four wire ropes 120 wound on the drum 130 of the driving unit 125 are first passed through the four-row pulley 10, and one wire rope extends downward, And is connected to the first point. The three wire ropes passing through the four row pulleys extend linearly and pass through the three row pulley 20 where one wire rope extends downward and connects to the second point of the hanging table 110 do.

The two wire ropes passing through the three-row pulley 20 extend in a straight line and pass through the two-row pulley 30. At this time, one wire rope extends downward to form the third Point.

The other one of the wire ropes passing through the three-row pulley 20 extends linearly and extends downward through the one-row pulley 400 to be connected to the fourth point of the work hanging table 110.

2 to 5 show the shape of the one-row pulley 400. FIG. The two to four rows of pulleys differ only in the number of guide grooves on which the wire rope runs, all of which are the same as the one row pulley. Hereinafter, the single row pulley 400 will be described as an example.

2 to 5, one side of the pulley 400 is fixed to the upper part of the first grid 300 and the other side of the pulley 400 is fixed to the upper part of the second grid 350.

The pulley 400 fixed to the upper portions of the first and second grids 300 and 350 is movable along the longitudinal direction of the first and second grids 300 and 350.

The pulley 400 includes a roller 410, support brackets 420 installed on both sides of the roller 410 to support the rollers 410 so as to be rotatable and one side of the support brackets 420 connected to the first grid 300 A second fixing means 440 for fixing the other side of the supporting bracket 420 to the second grid 350 and a second fixing means 440 for fixing the other side of the supporting bracket 420 to the first grid 300, An earthquake-proofing means 450 and a second earthquake-proofing means 460 which is in close contact with the second grid 350.

The first grid 300 includes a lower plate 320 fixed to the upper portion of the support frame 200 and a lower plate 320 located at the upper portion of the lower plate 320. The first grid 300 supports the lower portion of the support bracket 420 And a vertical plate 310 which connects the lower plate 320 and the upper plate 330 and is in close contact with the first vibration-proofing unit 450.

The upper plate 330 of the first grid 300 is referred to as a first upper plate for convenience of explanation and the lower plate 320 of the first grid 300 is referred to as a first lower plate for convenience of description, 300 is referred to as a first vertical plate for convenience of explanation.

The second grid is fixed to the lower portion of the supporting bracket 420 by the second fixing means 440 located at the upper portion of the lower plate 370 and the lower plate 370 fixed to the upper portion of the supporting frame 200 And a vertical plate 360 connecting the lower plate 370 and the upper plate 380 and coming in close contact with the second vibration-proofing means 460.

The lower plate 370 of the first grid 350 is referred to as a first lower plate for convenience of description and the upper plate 380 of the second grid 350 is referred to as a first upper plate 350 is referred to as a first vertical plate for convenience of explanation.

The roller 410 of the pulley 400 includes a roller body 411 and a fixing bolt 412.

A guide groove on which the wire rope 120 is wound is formed on the outer peripheral surface of the roller body 411. In the illustrated example, one guide groove 411a is formed. And one guide groove formed in one roller body 411 is referred to as a one-column pulley. Although not shown, two rows of pulleys are formed in the roller body so as to be parallel to each other, and the three rows of pulleys are formed in such a manner that three guide grooves are arranged in parallel on the roller body, Respectively.

The roller body 411 is formed with a fixing bolt coupling hole to which the fixing bolt 412 is coupled.

The fixing bolt 412 passes through the support bracket and is screwed into the fixing bolt coupling.

The support bracket 420 is installed on both sides of the roller 410 to support the roller body 411 in a rotatable manner.

The support bracket 420 is provided with a roller support portion 421, a skirt portion 422, and a gap fixing portion 429.

The roller support portion 421 is provided with a fixing bolt through-hole through which the fixing bolt 421 passes. The roller supporting portions 421 are spaced apart from each other so as not to interfere with the roller main body 411.

The skirt portion 422 is provided with first and second fixed through holes 421 and 423 to which the first and second fixing means 430 and 440 are coupled respectively and first and second earthquake- The first and second support through-holes 425 and 427 are formed.

The first fixed through hole 421 is formed in a portion where the end of the first upper plate 330 and the skirt portion 422 are in contact with each other and the second fixed through hole 423 is formed in the end of the second top plate 380 And the skirt portion 422 are in contact with each other.

The first support through hole 425 is formed at a portion where the first upper plate 330 and the first vertical plate 310 are connected to each other and the skirt portion 422 is in contact with the second support through hole 427, 2 upper plate 380 and the second vertical plate 360 are connected and the skirt portion 422 is contacted.

Both ends of the gap fixing portion 429 are respectively engaged with the roller supporting portions 421 to fix the separation distance.

The first earthquake-proofing means 450 includes a first tightening member 451, a first fastening member 455, a first supporting-force reinforcing portion 457 and a first pressure-distributing member 456.

The first contact member 451 includes a first contact head portion 452 of a polygonal shape having a contact surface to be in surface contact with the first vertical plate 310 and a second contact head portion 452 extending upwardly from the first contact head portion 452 And a first threaded portion 453.

The first threaded portion 453 is threaded on the outer circumferential surface and passes through the first support through hole 425 and is screwed to the first fastening member 455.

The first supporting force reinforcing portion 457 is intended to increase the supporting force of the first earthquake-resistant means with respect to the first grid. The first support force reinforcing portion 457 is engaged with the first screw portion 453 and is in surface contact with the vertical plate 310 of the first grid.

The first supporting force reinforcing portion 457 increases the contact area with the first vertical plate 310 to increase the supporting force. The first supporting force reinforcing portion 457 is formed on the outer side with at least one contact surface for contacting the first vertical plate 310 and a circular through hole is formed inside the first supporting force reinforcing portion 457 so that the first screw portion 453 can pass through. The first supporting force reinforcing portion 457 may be formed of a hexagonal metal material.

The first earthquake-proofing means 450 may not be provided with the first supporting force reinforcing portion 457 but may be brought into contact with the first vertical plate 310 only with the first contact head portion 452.

The first pressure-dispersing member 456 passes through the first screw portion 453 and is installed below the first fastening member 455. The fastening of the first screw portion 453 and the first fastening member 455 becomes firm due to the first pressure dispersion member 456. [ The first pressure-dispersing member 456 is preferably formed larger than the area of the lower surface of the first fastening member 455.

The second earthquake-proofing means 460 includes a second tightening member 461, a second fastening member 465, a second supporting-force reinforcing portion 467, and a second pressure-distributing member 466.

The second contact member 461 includes a second contact head portion 462 having a polygonal shape with one side being in contact with the second vertical plate 360 and a second contact portion 462 extending upward from the second contact head portion 462, (463).

The second screw portion 463 is threaded on the outer circumferential surface thereof and passes through the second support through-hole 427 and is screwed to the second fastening member 465.

The second supporting force reinforcing portion 457 is for increasing the bearing force of the second earthquake-resistant means with respect to the second grid. The second supporting force reinforcing portion 457 is engaged with the second threaded portion and contacts the vertical plate of the second grid.

The second support force reinforcing portion 457 widens the contact surface with the second vertical plate 310 to increase the supporting force. The second support force reinforcing part has at least one contact surface on the outer side and a circular through hole is formed on the inner side so that the second screw part can pass through. The second support force reinforcing portion may be formed of a hexagonal metal material.

The second earthquake-proofing means 460 may not be provided with the second supporting force reinforcing portion 467 but may be brought into contact with the second vertical plate 360 with only the second contact head portion 462. [

The second pressure-distributing member 466 passes through the second screw portion 463 and is installed below the second fastening member 465. The engagement of the second screw portion 463 and the second fastening member 465 becomes firm due to the second pressure-distributing member 466. [ The second pressure-distributing member 466 is preferably formed larger than the area of the lower surface of the second fastening member 465.

The first support through-hole 425 is formed in a circular shape having a diameter corresponding to the first screw portion 453 so that the first contact member 451 does not flow when it is in close contact with the side surface of the first vertical plate 310.

The second support through hole 427 extends in the width direction of the second upper plate 380 so as to adjust the second contact member 461 according to the interval between the first and second vertical plates 310 and 360 And is formed as a long hole.

The second contact member 461 is adjusted in the width direction of the second upper plate 380 with respect to the first contact member 451.

The first fixing means 430 includes a first bolt 431 passing through the first fixing through hole 421, a first nut 433 screwed to the first bolt 431, a first bolt 431 A first clip 435 and a third pressure-dispersing member 434 which are coupled to each other.

The third pressure-dispersing member 434 passes through the first bolt 431 and is installed under the first nut 433. [

The third pressure-distributing member 434 makes the fastening of the first bolt 431 and the first nut 433 firm.

The third pressure-dispersing member 434 is preferably formed larger than the area of the lower surface of the first nut 433.

The first clip 435 is formed so as to surround the end of the first upper plate 330 and is coupled to the support bracket 420 by a first bolt 431 and a first nut 433.

The second fixing means 440 includes a second bolt 441 passing through the second fixing through hole 423, a second nut 443 threaded to the second bolt 441, a second bolt 441 A second clip 445 through which the first pressure distribution member 444 and the fourth pressure distribution member 444 are coupled to each other.

The fourth pressure-distributing member 444 passes through the second bolt 441 and is installed under the second nut 443.

The fourth pressure-distributing member 444 tightens the fastening of the second bolt 441 and the second nut 443.

The fourth pressure-dispersing member 444 is preferably formed larger than the area of the lower surface of the second nut 443.

The first clip 445 is formed to enclose an end of the second upper plate 380 and is coupled to the support bracket 420 by a second bolt 441 and a second nut 443.

The first fixing through hole 421 is formed as a slot extending in the width direction of the first upper plate 330 so as to adjust the first fixing means 430 according to the width of the first upper plate 330.

The second fixed through-hole 423 is formed as a slot extending in the width direction of the second upper plate 380 so as to adjust the second fixing means 440 according to the width of the second upper plate 380.

The present invention can be applied to the first and second vertical plates 310 and 360 by adjusting the second vibration-proofing means 460 coupled to the second support through-hole 427 formed as a long hole in the skirt portion 422 The construction of the pulley 400 can be efficiently performed without replacing or deforming the bracket 420.

The first and second fastening means 430 and 440 coupled to the first and second fastening holes 421 and 423 formed in the skirt portion 422 as long holes may be used to adjust the first and second fixing means 430 and 440, The installation of the pulley 400 can be efficiently performed without changing or deforming the support bracket 420 according to the size of the second upper plates 380 and 330. [

On the other hand, FIG. 6 shows the state of the four-row pulley 10. The four-row pulley 10 is different from the one-row pulley described above in that the number of guide grooves formed in the roller body 411 is four. In the case of the four-row pulley 10, since the width of the roller body 411 is much larger than that of the single row pulley, the distance between the left and right support brackets 420 becomes larger. Even if the distance between the left and right support brackets 420 varies in each pulley, the first and second earthquake-proofing means 450 and the earthquake-resistant means applied to the present invention can secure the pulley firmly to the first grid 300 and the second grid. Can be supported.

7 and 8 show another one-stroke pulley according to another embodiment of the present invention.

The illustrated one-row pulley is the same as the one-row pulley shown in FIG. 2 except for the first and second vibration-isolating means 450 and 460.

Referring to FIGS. 7 and 8, the pulley according to the present invention further includes a damping member in the first and second vibration-proofing means 450 and 460.

The illustrated first vibration proofing means 450 includes a first contact member 451, a first fastening member 455, a first supporting force reinforcing member 457, a first pressure dispersing member 456, (458).

The first contact member 451 includes a first contact head portion 452 of a polygonal shape having a contact surface to be in surface contact with the first vertical plate 310 and a second contact head portion 452 extending upwardly from the first contact head portion 452 And a first threaded portion 453.

The damping member 458 is disposed between the first contact head portion 452 and the first supporting force reinforcing portion 457. At least one contact surface for contacting the first vertical plate 310 is formed on the outer side of the damping member 458, and a circular through hole is formed on the inner side for allowing the first screw 453 to pass through. The damping member 458 is formed in a quadrangular shape and has a structure in which four contact surfaces are formed on the outside.

The damping member 458 may be formed of a flexible, highly durable synthetic resin, or a material capable of being elastically deformed. This damping element 458 increases the bearing force and at the same time effectively damps the vibration transmitted from the support frame.

The second earthquake-proofing means 460 includes a second tightening member 461, a second fastening member 465, a second supporting force reinforcing portion 467, a second pressure-distributing member 466, and a damping member . The second contact member 461 includes a second contact head portion 462 having a polygonal shape with one side being in contact with the second vertical plate 360 and a second contact portion 462 extending upward from the second contact head portion 462, (463).

The damping member 468 is disposed between the second contact head portion 462 and the second support force reinforcing portion 467. The damping member 468 is formed with at least one contact surface for contacting the second vertical plate 360 on the outer side and a circular through hole is formed on the inner side for allowing the second screw portion 463 to pass through. The damping member 468 is formed in a quadrangular shape and has a structure in which four contact surfaces are formed on the outside. This damping element 468 is identical to the damping element 458 provided in the first to the means.

FIG. 9 shows a four-row pulley having the first and second means described above. The four row pulleys differ from the one row pulley described above in that four guide grooves are formed in the roller body 411. In the case of the four-row pulley 10, since the width of the roller body 411 is much larger than that of the single row pulley, the distance between the left and right support brackets 420 becomes larger. Even if the distance between the left and right support brackets 420 varies in each pulley, the first and second earthquake-proofing means 450 and the earthquake-resistant means applied to the present invention can secure the pulley firmly to the first grid 300 and the second grid. Can be supported.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110: Cloth hook 200: Support frame
300: first grid 350: second grid
400: pulley 450: first earthquake-resistant means
460: second earthquake-proof means

Claims (7)

delete A pulley installed on a stage device for guiding the movement of a wire rope,
The stage device includes a support frame installed on the stage, a pair of first and second grids installed on the support frame and coupled to a pulley through which the wire rope passes, And a driving unit installed on one side of the support frame for simultaneously winding and unwinding a plurality of wire ropes connected to a plurality of points of the building hangers to move the building hangers upward and downward,
Wherein the plurality of pulleys are sequentially arranged in descending order of distance from the drive unit,
Wherein the pulley includes a roller having at least one guide groove on which the wire rope is wound, a support bracket installed on both sides of the roller to support the roller rotatably, and a support bracket having one side of the support bracket attached to the first grid A second fixing means for fixing the other side of the support bracket to the second grid and a second fixing means for fixing the support bracket to the first grid so as to prevent the support bracket from being detached when the support frame is vibrated A first vibration-proofing means for supporting the support bracket; and a support member for supporting the support bracket in close contact with the second grid so as to prevent the support bracket from being detached when the support frame is vibrated, And a second earthquake-proofing means capable of changing a distance from the first earthquake-proofing means in accordance with the first earthquake-
The first and second grids include a lower plate fixed to the upper portion of the support frame, an upper plate positioned at the upper portion of the lower plate and fixed to the lower portion of the support bracket by the first or second fixing means, And a vertical plate which connects the lower plate and the upper plate and is in close contact with the first or second vibration-isolating means,
The support bracket is provided with first and second fixed through-holes through which the first and second securing means are coupled, respectively, and the first and second earthquake-resistant means are coupled to each other, and between the first fixed through- The first and second support through-holes are formed in the first and second support holes,
The first earthquake-proofing means includes a first contact member which is in close contact with the vertical plate of the first grid and penetrates the first support through-hole, and a second contact member which is screwed with the first contact member to connect the first contact member to the support bracket And a second fastening member for fastening the first fastening member,
The second earthquake-proofing means includes a second contact member which is in close contact with the vertical plate of the second grid and penetrates the second support through-hole, and a second contact member which is screwed with the second contact member to connect the second contact member to the support bracket And a second fastening member for fastening the first fastening member to the first fastening member. The straddle-type straddle-type straddle-type straddle-type straddle-type straddle-type straddle-type straddle type straddle type straddle type straddle type straddle type straddle type straddle type straddle type straddle type straddle type straddle block. 3. The apparatus according to claim 2, wherein the first contact member has a first contact head portion having a contact surface for surface contact with a vertical plate of the first grid, and a second contact head portion extending upward from the first contact head portion, And a first screw portion passing through the through hole and having a thread formed on an outer circumferential surface thereof and screwed to the first fastening member,
Wherein the second contact member has a second contact head portion having a contact surface so as to be in surface contact with the vertical plate of the second grid and a second contact head portion extending upwardly from the second contact head portion and passing through the second support through- And a second threaded portion formed with a thread on the first fastening member and screwed to the second fastening member. [6] The apparatus according to claim 4, wherein the first earthquake-proofing means comprises: a first earthquake-proofing means, coupled to the first screw portion, for reinforcing a first supporting force to contact the vertical plate of the first grid, Further,
And the second earthquake-resistant means further comprises a second supporting force reinforcing portion coupled to the second screw portion and contacting the vertical plate of the second grid to increase the bearing force of the second earthquake-resistant means with respect to the second grid Seismic design pulley for stage equipment. 6. The staging device according to claim 5, wherein the first and second supporting-force reinforcing portions are formed with at least one contact surface on the outer side and a circular through hole is formed on the inner side so that the first or second threaded portion can pass therethrough. Seismic design pulley for. 6. The earthquake-resistant design pulley for a stage device according to claim 5, wherein the first and second earthquake-resistant means further comprise a damping member for damping vibration transmitted from the support frame.

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