KR101879159B1 - Earthquake-proof Hanger device for cable tray - Google Patents

Abstract

The present invention relates to an earthquake proof hanger device for a cable tray. The earthquake proof hanger device for a cable tray comprises: a support channel extending in the longitudinal direction, and supporting a cable tray; a lower rod fixed to both end parts of the support channel, and extending in a vertical upward direction; an upper rod vertically fixed to a vertical upper part of the lower rod; and an earthquake proof damper connecting the upper and lower rods between the upper rod and the lower rod, and supporting the cable tray and the support channel so as to three-dimensionally move. Since the earthquake proof damper attenuating an impact is included, the earthquake proof hanger device for a cable tray of the present invention can effectively absorb the impact when an earthquake occurs as well as fine vibration transmitted from the outside, thereby stably protecting the cable tray.

Description

{Earthquake-proof Hanger device for cable tray}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cable tray for supporting various cables, and more particularly, to a cable tray tremor hanger device capable of safely protecting a cable even in an emergency such as an earthquake.

Communication, power cables, or various power transmission cables installed in, for example, tunnels, factories, various underground facilities, as well as large buildings are supported by cable trays. A cable tray is a facility for bundling and supporting a plurality of cables extending in the longitudinal direction, and is usually disposed close to a corner portion or a wall surface of an inconspicuous ceiling. By applying such a cable tray, it is easy to know the direction and position of the cable, so that it is possible to construct and control an efficient communication and power system.

There are various types of cable trays. Basically, the cable trays are provided with side rails extending in the longitudinal direction and parallel to each other, and a plurality of rungs connecting the side rails, i.e., a cross bar. These side rails have a certain length according to the standard and extend by connecting a plurality of side rails in the longitudinal direction as necessary.

A hanger is also used for fixing the cable tray to a ceiling or a wall surface. There are various types of hanger, such as a bracket for fixing the tray to the wall, a channel on the bottom of the tray, and a channel on the ceiling.

The most important thing in the above hanger is to stably support the cable. If the cable is cut or damaged, the communication network or the power supply network may become paralyzed. For example, even if a building is shaken by an earthquake, the cable must be protected.

Korean Patent Publication No. 10-1436333 discloses an anti-seize cable tray system. The tray system includes a cable tray supporting member having a vertical member fixed to a ceiling of a building, a horizontal member horizontally coupled to the vertical member, a first hinge unit coupled to the horizontal member, And a second hinge part coupled to the connection part and fixed to the ceiling, and has a structure for protecting the cable tray from secondary damage due to breakage of the vertical member or the horizontal member.

However, the tray system has a disadvantage that it does not have a sufficient buffering capacity and can not smoothly cancel the force externally applied. It can easily break or roll by external force. Also, the structure is complicated, the manufacturing cost is high, and the maintainability is not so good.

Korean Patent Registration No. 10-1326806 (Seismic Resistance Device of Cable Tray Supporting Member) Korean Registered Patent No. 10-1436333 (Resistant cable tray system)

An object of the present invention is to provide a seismic resistant hangar hanger device for cable trays which can stably protect a cable tray by effectively absorbing an impact at the time of occurrence of an earthquake as well as a micro vibration transmitted from the outside by applying an earthquake- And the like.

According to an aspect of the present invention, there is provided a seismic resistant hanger device for a cable tray, including: a support channel extending in a longitudinal direction and supporting a cable tray; A lower rod fixed to both ends of the support channel and extending vertically upward; An upper rod vertically fixed to a vertical upper portion of the lower rod; And an earthquake damper connecting the upper and lower rods between the upper rod and the lower rod and supporting the cable tray and the support channel so as to move in three dimensions.

The earthquake-resistant damper may further comprise: A flat plate portion formed by bending a strip-shaped steel plate having a predetermined width and allowing the lower rod of the upper rod to be positioned below the upper rod by passing the upper rod in a thickness direction thereof; and a flat plate portion integrally formed at both ends of the flat plate portion, An upper support nut screwed to the upper rod and positioned at an upper portion of the upper plate, and a lower screw fastened to the lower end of the upper rod, And a spring provided between the upper support nut and the lower support nut; and a connection part located at a vertically lower portion of the flat plate part, And an upper connecting plate part which is upwardly bent and overlaps with the vertical plate part, An X-axis rod passing through the vertical plate portion and the upper connecting plate portion and rotatably supporting the center bracket, and a band-shaped steel plate having a predetermined width, A lower bracket disposed on a lower portion of the connection portion and coupled to the lower rod, and a lower bracket integrally formed on both sides of the lower connection rod portion and having a side plane portion bent perpendicularly and overlapping the lower connection plate; And a Y-axis rod passing through the lower connecting plate portion and the side plane portion, supporting the lower bracket so as to be rotatable, and extending in a direction orthogonal to the X-axis rod.

The earthquake-resistant damper may further comprise: An upper elastic cap which is fixed to a lower end portion of the upper rod and includes a case portion providing a receiving space opened to the lower portion and a flange portion integrally formed with a lower edge portion of the case portion and having a plurality of curved long holes; An upper airbag inserted into the receiving space of the cap and partially protruding to the lower portion of the receiving space, a case portion fixed to the upper end of the lower rod and providing an accommodation space opened to the upper portion, And a lower airbag mounted in the receiving space of the lower elastic cap and contacting the upper airbag in a state that a part of the lower airbag protrudes above the accommodation space, A flange portion of the elastic force cap and a lower elasticity cap, and supports the flange portion so as not to be separated by more than a predetermined interval, Passes through a curved slot on the side of the flange portion may have a curvature that fits the slot of the other holding flange and bolts, nuts screwed at the ends of the holding bolts.

According to another aspect of the present invention, there is provided a seismic resistant hanger device for a cable tray, comprising: a support channel extending in a longitudinal direction and supporting a cable tray; A frame fixed to a vertical upper portion of the cable tray and providing a supporting force; A telescopic column having an upper end fixed to the frame, a lower end coupled to both ends of the support channel, A tension wire whose lower end is fixed to both ends of the support channel and extends above the frame through the interior of the telescopic column; A tension motor supported on the frame and pulling up the support channel and the cable tray by tensioning the tension wire; And an earthquake damper provided at both ends of the support channel and being compressed by the surrounding structure when the support channel reaches the top dead center to attenuate the vibration transmitted through the structure.

In addition, in the ceiling of the space in which the cable tray is installed, a receiving groove is formed to receive the frame and to receive a cable tray reaching the top dead center, and the earthquake- And a sensor unit for sensing a movement of the support channel and generating a sensing signal is provided on the side of the support channel. When a signal is received from the sensor unit, So that the cable tray is hermetically accommodated in the receiving groove.

Since the seismic hanger device for cable trays according to the present invention includes the earthquake-resistant damper for attenuating the impact, the cable tray absorbs shocks when an earthquake occurs, as well as fine vibration transmitted from the outside, thereby stably protecting and maintaining the cable tray.

1 and 2 are views for explaining the construction and operation of a seismic resistant hanger apparatus for a cable tray according to a first embodiment of the present invention.
FIGS. 3 to 5 are views for explaining the construction and operation of a seismic resistant hanger apparatus for a cable tray according to a second embodiment of the present invention.
6 and 7 are views for explaining the construction and operation of a seismic resistant hanger apparatus for a cable tray according to a third embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Basically, the earthquake-resistant hanger device 20 of the present invention is prepared for an earthquake, that is, has a configuration and an effect to prevent cutting or damage of a cable by stably holding a cable tray even if a building is strongly shaken.

The earthquake-resistant hanger apparatus according to the present invention to be described later may be a type provided with a support channel, a lower rod, an upper rod, an earthquake-proof damper, and includes a support channel, a frame, a telescopic column, a tension wire, a tension motor, It is possible.

1 and 2 are views for explaining the construction and operation of a seismic hanger apparatus 20 for a cable tray according to a first embodiment of the present invention.

Referring to the drawings, a seismic resistant hanger device 20 according to the first embodiment includes a plurality of support chan- nels 24 extending in the longitudinal direction and supporting a cable tray 22, fixed to both ends of the support chan- nel 24, An upper rod 26a vertically fixed to a vertical upper portion of the lower rod 26b and an earthquake damper 30 provided between the upper rod and the lower rod 26b .

First, the support channel 24 is a rod-shaped member having a constant cross-sectional shape, and extends in the width direction of the cable tray 22, and has an extended end exposed in the width direction of the cable tray 22. [ A plurality of support channels (24) are arranged at appropriate intervals along the longitudinal direction of the cable tray (22).

The cable tray 22 has side rails 22a extending parallel to each other and a plurality of cross bars 22b connecting the side rails 22a. The cable 14 is supported on the upper portion of the crossbar 22b.

The upper rod 26a and the lower rod 26b are vertically arranged and coincide with each other with a male thread formed on the outer peripheral surface of the upper rod 26a and the lower rod 26b. The upper rods 26a are partly embedded in the ceiling 10 of the building and secured to the ceiling 10. The manner of fixing the upper rod 26a to the ceiling 10 can be variously changed.

The lower rod 26b maintains its engagement with the support channel 24 by engaging with the rod fixing nut 26c with its lower end passing down the support channel 24. The height of the support channel 24 can be adjusted by operating the rod fixing nut 26c.

The earthquake-proof damper 30 includes an upper bracket 32, a resilient force supporting means, a center bracket 34, an X-axis rod 33, a lower bracket 36, and a Y-axis rod 35. As will be described later, the X-axis rod 33 serves as a rotating shaft in a state where the upper bracket 32 and the center bracket 34 are connected. The Y-axis rod 35 links the center bracket 34 and the lower bracket 36 and serves as a pivot.

First, the upper bracket 32 is formed by bending a strip-shaped iron plate having a predetermined width and thickness, and has a flat plate portion 32a and a vertical plate portion 32b. The flat plate portion 32a passes through the upper rod 26a in the thickness direction. It is needless to say that the plate portion 32a is formed with a hole (not shown) for allowing the upper rod 26a to pass therethrough. The upper rod 26a passes downward through the flat plate portion 32a and is supported by the elastic supporting means in a state where the lower end of the upper rod 26a is positioned below the flat plate portion 32a.

The vertical plate portion 32b is a downwardly bent portion having a perpendicular angle to the flat plate portion 32a and is symmetrical with respect to the flat plate portion 32a. The through holes 32c are formed in the both side vertical plate portions 32b.

The elastic support means elastically supports the upper bracket 32 so as to be able to move up and down in the longitudinal direction of the upper rod 26a, that is, the vertical direction. In other words, when an impact is applied from the outside, it lifts up and offsets the impact. The elastic support means includes an upper support nut 37a, a lower support nut 37b, a first spring 31a, and a second spring 31b.

The upper support nut 37a is a nut that is screwed to the upper rod 26a and is located at the upper portion of the flat plate portion 32a and the lower support nut 37b is a nut screwed to the lower end portion of the upper rod. It goes without saying that the lower support nut 37b is positioned below the flat plate portion 32a.

The first spring 31a is a coil spring provided between the flat plate portion 32a and the upper support nut 37a and the second spring 31b is a coil spring provided between the flat plate portion 32a and the lower support nut 37b . The upper bracket 32 is elastically supported in a state of being supported by the first and second springs 31a and 31b and can be moved up and down when an external force is applied.

The center bracket 34 is formed by bending an iron plate having a cross shape and is integrally formed with a connecting portion 34a and a connecting portion 34a located at a vertical lower portion of the flat plate portion 32a, An upper connecting plate portion 34b, and a downwardly bent lower connecting plate portion 34c.

The connecting portion 34a is a rectangular region having the same area as the flat plate portion 32a and is integrated with the upper connecting plate portion 34b and the lower connecting plate portion 34c. The upper connecting plate portion 34b overlaps the outer surface of the vertical plate portion 32b as a portion bent at a right angle to the connecting portion 34a. The lower connecting plate portion 34c is integrally formed with the connecting portion and bent downward at a right angle, and overlaps with a side flat portion 36b described later with a through hole 34d.

The upper connection plate portion 34b is also provided with a through hole 34e. The through hole 34e passes through the male and female rods 33a in a state of being aligned with the through hole 32c formed in the vertical plate portion 32b.

The X-axis rod 33 has a male threaded rod 33a extending horizontally through the through holes 32c and 34e and a support nut 33b screwed to both ends of the male threaded rod 33a. The male and female rods 33a are members for connecting the upper bracket 32 and the central bracket 34 and serve as the turning shafts of the central bracket 34 with respect to the upper bracket 32. [ In other words, the center bracket 34 can rotate in the direction of the arrow a or vice versa by using the male and female rods 33a as the rotating shaft.

The support nut 33b is a nut screwed to the male or female bar 33a and adjusts the frictional force of the upper connecting plate portion 34b with respect to the vertical plate portion 32b. The frictional force of the upper connecting plate portion 34b with respect to the vertical plate portion 32b is increased and the supporting nut 33b is brought into contact with the upper connecting plate portion 34b by pushing the upper connecting plate portion 34b inward by tightening the supporting nut 33b, 34b, the frictional force is minimized. As the frictional force increases, the fixing force of the center bracket 34 with respect to the upper bracket 32 increases.

The lower bracket 36 is formed by bending an iron plate in the form of a band having a constant width, like the upper bracket 32. The lower bracket 36 has a lower rod connecting portion 36a located at the vertically lower portion of the connecting portion 34a and a side flat portion 36b formed at the both ends of the lower rod connecting portion 36a and bent upward at right angles, ).

The lower rod connecting portion 36a is a member in the form of a quadrangular plate and engages with the upper end of the lower rod 26b through a rod fixing nut 26d. It is of course possible to disengage the damper 30 from the lower rod 26b by loosening the rod fixing nut 26d.

The Y-axis rod 35 is provided with a male screw rod 35a and a support nut 35b. The male and female rods 35a extend horizontally through the through holes 34d and 36c, and both ends of the male and female rods 35a protrude to the outside of the side plane portion 36b. The male and female bosses 35a are orthogonal to the male boss 33a of the X-axis rod 33.

The support nut 35b engages with both ends of the male or female thread 35a extending outside the side surface flat portion 36b. The role of the support nut 35b is the same as that of the support nut 33b in the X-axis rod 33. [ By applying the Y-axis rod 35 in this manner, the lower bracket 36 can rotate in the direction of the arrow b or the opposite direction with respect to the male or female bar 35a.

The earthquake-proof damper 30 according to the first embodiment having the above-described configuration enables movement of the support channel 24 in the forward and backward left and right directions as well as the up and down movements. For example, when an earthquake occurs and the building is shaken, the support channel 24 moves in the direction of shaking to cancel the impact. If there is no earthquake-proof damper 30, the structure supporting the cable tray 22 may be bent or cut due to the influence of the external force.

The vertical movement and the longitudinal and lateral movement of the support channel 24 can be varied by adjusting the elastic force of the first and second springs 31a and 31b and the clamping force of the support nuts 33b and 35b.

In addition, the movement in the forward, backward, leftward and rightward directions means two-dimensional movement of the support channel 24. In other words, the rod fixing nut 26d can move in the 360 degree direction with respect to the vertical line.

FIGS. 3 to 5 are views for explaining the construction and operation of a seismic resistant hanger apparatus for a cable tray according to a second embodiment of the present invention.

Hereinafter, the same reference numerals as those of the above-mentioned reference numerals denote the same members having the same function, and a repeated description thereof will be omitted.

The seismic hanger device 20 according to the second embodiment is of a type provided with an airbag. As shown in the figure, the vibration damper 40 according to the second embodiment includes the upper elastic cap 42, the lower elastic cap 46, the upper air bag 44a, the lower air bag 44b, the retaining bolt 48, And a nut 49 is provided.

The upper elastic cap 42 is fixed to the lower end of the upper rod 26a and includes a case portion 42a for providing a lower accommodation space 42b, A flange portion 42c having a plurality of curved long holes 42d and a rod connecting portion 42e positioned at the center of the upper end of the case portion 42a.

The upper elastic cap 42 is integrally formed as a whole and is screwed to the lower end of the upper rod 26a through the rod connection portion 42e. The rod connection portion 42e has a female screw hole 42f therein and is screwed to the upper rod 26a.

The case portion 42a is a cylindrical portion that opens downward and has a predetermined inner diameter and a depth, and houses the upper air bag 44a therein. The upper air bag 44a is partially inserted into the receiving space 42b and exposed downward. The description of the upper air bag 44a will be given later.

The flange portion 42c is a ring-shaped member integrally formed at the lower end portion of the case portion 42a, and includes the curved long hole 42d in the inner region thereof. The curved long hole 42d is an opening for passing the retaining bolt 48 and extends in the circumferential direction of the flange portion 42c. The four curved long holes 42d are symmetrical with respect to the case 42a.

The lower elasticity cap 46 has the same size as the upper elasticity cap 42 and takes the same shape and has a rod connection portion 46e which is threadably engaged with the upper end of the lower rod 26b, And a flange portion 46c integrally formed on the upper end of the case portion 46a. The case portion 46a is formed integrally with the upper portion of the case portion 46a. In addition, four curved elongated holes 46d are formed in the flange portion 46c.

Meanwhile, the upper air bag 44a and the lower air bag 44b are made of rubber or synthetic resin, and air is filled in the upper air bag 44a and the lower air bag 44b. The upper airbag 44a and the lower airbag 44b come into close contact with each other while being inserted into the accommodation spaces 42b and 46b, as shown in Fig.

Part of the upper air bag 44a is inserted into the accommodation space 42b and a part of the upper air bag 44a protrudes to the lower portion of the accommodation space 42b while the lower air bag 44b is mounted on the accommodation space 46b, As shown in Fig. The upper and lower airbags 44a and 44b are spaced apart from each other while the upper and lower airbags 44a and 44b face each other.

The retaining bolt 48 engages the washer 47 with the lower curved long hole 46d and the upper curved long hole 42d and the washer 47 in an upwardly passing state. By inserting the nut 49 into the retaining bolt 48, the gap between the upper elastic cap 42 and the lower elastic cap 46 is maintained. The distance between the upper elastic cap 42 and the lower elastic cap 46 may be adjusted by adjusting the degree of coupling of the nut to the holding bolt 48. [

The upper and lower air bags 44a and 44b elastically hold the relative positions of the lower elastic caps 46 relative to the upper elastic caps 42. [ 5, when a force is applied to the lower rod 26b in the direction of the arrow c and the right side of the lower elasticity cap 46 is heard, it temporarily collapses and receives a force applied to the lower rod to cancel it. When the force in the direction of the arrow c disappears, the upper and lower airbags 44a and 44b are restored to the initial state.

As a result, the seismic damper 40 prevents damage to the cable tray 22 by canceling the impact or force from the outside by the action of the upper and lower airbags 44a, 44b.

6 and 7 are views for explaining the construction and operation of the seismic resistant hanger device 20 for a cable tray according to the third embodiment of the present invention.

As shown in the figure, the earthquake-resistant hanger apparatus 20 according to the third embodiment includes a frame 66 installed in the receiving groove 10a, a frame 66 fixed to the frame 66 and extending vertically downward, A tensile wire 62 connected to the support channel 24 and extending to the top of the frame 66 and a tensile motor 62 for tensioning the tension wire 62 A sensor unit 73, a control unit 70 and an earthquake-resistant damper 64 fixed to both ends of the support channel 24.

The receiving groove portion 10a is a groove formed in the ceiling 10 of the space in which the earthquake-resistant hanger device 20 is installed. The receiving groove 10a may be formed at the time of construction of the building or may be formed to provide the earthquake-proof hanger device 20. The receiving groove 10a has a capacity to accommodate the cable tray 22 in a state in which the support channel 24 is maximally raised as shown in Fig.

Reference numeral 10b denotes an edge portion. As shown in Fig. 7, the corner portion 10b is a peripheral structure that contacts the earthquake-resistant damper 64 and compresses the earthquake-resistant damper 64 in a state where the support channel 24 is maximally raised, that is, in a state of being located at the top dead center. The vibration damper 64 and the earthquake damper 64 attenuate the vibrations and the impact force flowing into the seismic hanger device 20 through the ceiling 10 because the earthquake-resistant damper 64 is pressed on the corner portion 10b.

The frame 66 is made of a metal plate having rigidity and provides a supporting force inside the receiving groove 10a and has two supporting rollers 67 on the upper portion thereof. The support roller 67 supports the tension wire 62 and guides smooth movement of the tension wire 62 when the tension motor 69 pulls the tension wire 62. Reference numeral 66a denotes a wire passage through which the tension wire passes.

The telescopic column 60 is composed of a plurality of unit column cases 61. The unit column case 61 is a hollow pipe having a step diameter and is vertically arranged for each size. The telescopic column 60 having the above-described configuration can be expanded and contracted in length as required. 6, when the support channel 24 is positioned at the top dead center, as shown in Fig. 7, the support column 24 is extended to the unit column case 61 in the state where the support channel 24 is positioned at the top dead center, Are overlapped and become as short as possible.

The tensile wire 62 passes through the inside of the telescopic column 60 and the wire passage 66a while the lower end of the tension wire 63 is fixed to the support channel 24 by the engagement tip 63, 67 and is wound on the dual pulley 69a of the tension motor 69. The dual pulley 69a is a pulley fixed to the drive shaft of the tension motor 69, and moves the two tension wires 62 by the same speed and length.

When the dual pulley 69a hovers the tension wire 62, the tension channel 62 rises and raises the support channel 24 and the support channel 24 is lowered when the tension wire 62 is lowered Of course.

The sensor unit 73 is located between the support channel 24 and the control unit 70 via the connection bracket 75 and has two connection portions 73a and 73b. The fraudulent connection units 73a and 73b detect the movement of the support channel 24 in a state of being connected to each other and transmit the sensed contents to the control unit 70. [

The connection bracket 75 is a support member having a predetermined length, so that the connection portions 73a and 73b are maintained in a connected state. The connection bracket 75 can be made of an iron plate.

The connection portions 73a and 73b of the sensor portion 73 are separated from each other when the support channel 24 is shaken to the left and right and separated from the wall surface 12 during an earthquake. The separation signals of the connection portions 73a and 73b are transmitted to the control section 70. [

The controller 70 drives the tension motor 69 to cause the tension motor 69 to raise the support channel so that the cable tray 22 is moved in the receiving groove 10a Enclosed. At this time, the earthquake-proof damper 64 is in close contact with the corner portion 10b as described above. As a result, the earthquake-proof hanger apparatus 20 according to the third embodiment has a structure in which the cable tray 22 is completely enclosed in the ceiling when the earthquake occurs and the cable tray 22 is more completely protected.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10: ceiling 10a: receiving groove 10b: corner portion
12: wall 14: cable 20: seismic hanging device
22: cable tray 22a: side rail 22b:
24: Support channel 26a: Upper rod 26b: Lower rod
26c: rod fixing nut 26d: rod fixing nut 30: seismic damper
31a: first spring 31b: second spring 32: upper bracket
32a: flat plate portion 32b: vertical plate portion 32c:
33: X-axis rod 33a: male and female bar 33b: support nut
34: center bracket 34a: connecting portion 34b: upper connecting plate portion
34c: lower connection plate portion 34d: through hole 34e: through hole
35: Y-axis rod 35a: male and female bar 35b: support nut
36: lower bracket 36a: lower rod connecting portion 36b:
36c: Through hole 37: Spring fixing nut 37a: Upper support nut
37b: lower support nut 40: seismic damper 42: upper elastic cap
42a: case portion 42b: accommodation space 42c: flange portion
42d: curved long hole 42e: rod connecting portion 42f: female threaded portion
44a: upper air bag 44b: lower air bag 46: lower elastic cap
46a: case portion 46b: accommodating space 46c: flange portion
46d: curved long hole 46e: rod connecting portion 47: washer
48: retaining bolt 49: nut 60: telescopic column
61: Unit column case 62: Tensile wire 63: Jig tip
64: earthquake-proof damper 66: frame 66a: wire passage
67: Support roller 69: Tension motor 69a: Dual pulley
70: control unit 73: sensor unit 73a:
73b: connection part 75: connection bracket

Claims (5)

delete A support channel extending longitudinally and supporting the cable tray;
A lower rod fixed to both ends of the support channel and extending vertically upward;
An upper rod vertically fixed to a vertical upper portion of the lower rod;
And an earthquake damper connecting the upper and lower rods between the upper rod and the lower rod and supporting the cable tray and the support channel so as to move in three dimensions
The earthquake-resistant damper comprising:
A flat plate portion formed by bending a strip-shaped steel plate having a predetermined width and allowing the lower rod of the upper rod to be positioned below the upper rod by passing the upper rod in a thickness direction thereof; and a flat plate portion integrally formed at both ends of the flat plate portion, An upper bracket having a vertical plate portion having a right angle,
A lower support nut screwed to a lower end of the upper rod and a lower support nut screwed to the upper rod so as to elastically support the upper bracket so as to be able to move up and down, Elastic supporting means including a spring provided between the elastic supporting means,
And an upper connecting plate portion which is integrally formed with the connecting portion and is bent upward and overlapped with the vertical plate portion. The lower connecting plate portion is integrally formed with the lower portion of the lower connecting plate portion, A central bracket having a connecting plate portion,
An X-axis rod passing through the vertical plate portion and the upper connecting plate portion and rotatably supporting the center bracket,
A lower rod connecting portion which is located at a vertically lower portion of the connecting portion and engages with the lower rod, and a lower rod connecting portion which is integrally formed at both sides of the lower rod connecting portion and which is bent at a right angle, A lower bracket having a side plane portion overlapping the connecting plate portion;
And a Y-axis rod extending in a direction perpendicular to the X-axis rod, the Y-axis rod passing through the lower connecting plate portion and the side plane portion and supporting the lower bracket so as to be rotatable. delete delete delete

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