KR101995847B1 - Seismic connector device for coupling cable tray - Google Patents

Abstract

The present invention relates to a seismic connector device for connecting cable trays which connects side rails of the cable tray to be moved corresponding to an external force applied in a longitudinal direction and in a side direction of the side rail so as to prevent damage to the cable tray in accordance with stress concentration, and effectively absorb shock when an earthquake occurs, thereby stably protecting the cable tray.

Description

{Seismic connector device for coupling cable tray}

More particularly, the present invention relates to a connector device for connecting a unit cable tray in a longitudinal direction, and more particularly, to a connector device capable of absorbing external force when an earthquake occurs, And a connector device.

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

The cable tray is basically composed of a plurality of rungs, that is, transversely connecting the side rails, which extend in the longitudinal direction and are parallel to each other. What is important in the cable tray is to protect the cable stably to prevent damage or breakage of the cable in the event of an earthquake or the like.

These cable trays have a limited length in the longitudinal direction so that they are constructed by longitudinally connecting a plurality of cable trays to fully support the elongated cable. That is to say, connecting the side rails with a suitable connecting member.

However, in the conventional cable tray, since the connecting member connecting the side rails is simply bolted to the side rails via the bolts, for example, when elongation or contraction occurs in the cable after construction, or when a lateral load It is easily broken when applied. If the cable tray is cut, the cables may be broken or damaged, resulting in a large-scale secondary cargo such as fire or gas explosion. Although the cable tray itself is stretchable due to such a problem, most of the structures are complicated and do not have the capability of simultaneously attenuating the longitudinal and lateral loads of the cable tray.

Korean Patent Registration No. 10-0915369 (Expansion joint structure of cable tray) Korean Patent Registration No. 10-1779741 (cable tray) Korean Registered Patent No. 10-1128007 (integrated cable tray with flexible connection)

The present invention has been made to solve the above problems, and it is an object of the present invention to provide a dustproof connector device for cable tray connection, which can prevent breakage of a cable tray due to stress concentration and effectively absorb a shock at the time of an earthquake, The purpose is to provide.

In order to achieve the above object, a dustproof connector device for connecting a cable tray of the present invention comprises a plurality of unit cable trays provided with side rails for relative movement, and disposed between side rails of a cable tray for connection A coupler; The first side link is connected to the coupler and both side rails located on both sides of the coupler so as to be rotatable on both the upper and lower ends of the coupler through the pivot shaft. And a second side link linked to an end of the link and the other end linked to both side rails, wherein the pivot portion includes a first side link, a first side link and a second side link, A fixing bolt to be fitted to the side rail, and a support nut which is engaged with the fixing bolt and whose degree of engagement with the fixing bolt is adjusted.

In addition, the coupler may include: A first turning piece linked to the one side rail and a second turning piece linked to the other side rail and a second turning piece positioned between the first turning piece and the second turning piece, And a hinge portion for rotatably supporting the hinge portion.

The seismic connector device for connecting a cable tray according to the present invention as described above connects the side rails of the cable tray and moves in correspondence with the external force applied in the lateral direction as well as the longitudinal direction of the side rail. And protects the cable tray stably by effectively absorbing the shock when an earthquake occurs.

1 is an exploded perspective view showing a cable tray to which a dustproof connector device for cable tray connection according to a first embodiment of the present invention is applied.
Fig. 2 is an exploded perspective view of the connector device shown in Fig. 1. Fig.
3A, 3B and 3C are plan sectional views for explaining the operation of the connector device shown in Fig.
4 is a plan view for explaining another function of the connector device shown in Fig.
5 is a perspective view illustrating a cable tray to which a dustproof connector device for cable tray connection according to a second embodiment of the present invention is applied.
6 is a partial perspective view showing another example of a cable tray to which a dustproof connector device for cable tray connection according to a second embodiment of the present invention is applied.
7A and 7B are views for explaining the operation of the connector device shown in Fig.
8 is a plan view for explaining another function of the connector device shown in Fig.

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

Basically, the connector devices 30, 60 according to the present embodiment connect cable trays with the unit cable trays 10 to be connected to each other. Especially, since it has an earthquake-proof capability and effectively absorbs the external force applied to the cable tray 10, the cable is stably protected without being damaged or deformed by an external force.

Two types of connector devices are exemplified. One of them is a first link plate fixed to a side rail of one cable tray and partially extending to a side rail side of the other cable tray and a second link plate fixed to a side rail of the other cable tray, And a resilient coupling means for resiliently pressing and sliding the first and second link plates so as to be slidable and preventing separation of the first and second link plates, .

The other type includes a coupler disposed between the side rails of the cable tray to be connected to the coupler, a pair of side rails disposed on both sides of the coupler, And a second side link, one end of which is linked to the end of each first side link via a pivotal shaft portion and the other end is linked to both side rails, A fixing bolt to be fitted to the coupler and the first side link, a first side link and a second side link, a second side link and a side rail, and a support nut coupled to the fixing bolt, Respectively.

FIG. 1 is an exploded perspective view showing a dustproof connector device 30 for connecting a cable tray according to a first embodiment of the present invention together with a unit cable tray, and FIG. 2 is an exploded perspective view of the connector device shown in FIG.

As shown in the figure, the seismic connector device 30 according to the first embodiment connects adjacent end portions of a plurality of unit cable trays 10 arranged in the longitudinal direction, and includes a first link plate 32, 2 link plate 36, and resilient coupling means 71.

The unit cable tray 10 includes side rails 12 extending in parallel and a plurality of cross bars 14 connecting the side rails 12. A cable (not shown) is received and supported between the crossbar 14 and the side rails 12.

Particularly, both end portions of the crossbar 14 are linked to the engaging protrusions 12b of the side rails 12 via the support pins 16 and are rotatable with respect to the side rails 12. The reason why the crossbar 14 is designed to be rotatable as described above is to prepare for an external force coming in the lateral direction. In other words, as shown in Fig. 4, the connector device 30 is bent.

The dimensions of the unit cable tray 10, such as the length and the height of the unit cable tray 10, may vary, and a plurality of units may be used depending on the needs of the user. Reference numeral 12a denotes a mounting hole. The mounting hole 12a is a hole for fixing the connector device 30 to be described later.

The first link plate 32 is fixed to the side rails 12 of the left cable tray 10 in the figure among the two unit cable trays 10 neighboring in the longitudinal direction, Is a member extending to the side rails (12) side of the frame (10).

More specifically, the first link plate 32 is a member composed of a fixing plate portion 34, a rotation plate portion 36, and a hinge portion 37 between the fixing plate portion 34 and the rotation plate portion 36.

The fixing plate 34 is formed by bending an iron plate and has a plurality of fixing holes 34a and is fixed to the side rail 12 through a plurality of connecting bolts 18 and fixing nuts 19. [ Needless to say, the fastening holes 34a correspond to the mounting holes 12a of the side rails 12 one to one. The fixing plate portion 34 is engaged by fastening the connecting bolt 18 with the fastening hole 34a aligned with the mounting hole 12a and fastening the nut on the opposite side.

The rotatable plate portion 36 is a member positioned in parallel with the fixed plate portion 34 and is engaged with the second link plate 38 to be described later. The rotating plate portion 36 is formed with two first long holes 36b in parallel up and down. The rotatable plate portion 36 is rotatable relative to the stationary plate portion 34. In other words, the fixed plate portion 34 is also rotatable relative to the rotation plate portion 36.

The hinge portion 37 enables the rotation of the fixed plate portion 34 and the rotation plate portion 36. The hinge portion 37 includes a support shaft portion 34c formed at an end portion of the fixed plate portion 34 and providing a groove portion 34d at the center thereof and a support shaft portion 34c integrally formed with the rotation plate portion 36, And includes a fitting protrusion 36a and a link pin 35 passing through the supporting shaft portion 34c and the fitting protrusion 36a. And the link pin 35 serves as a rotating shaft of the fixed plate portion 34 and the rotating plate portion 36. [

The second link plate 36 is also manufactured by pressing an iron plate and is fixed to the right side rail 12 through a plurality of connecting bolts 18 and a fixing nut 19. The second link plate 36 is formed with a plurality of fastening holes 38a and two second long holes 38b.

The fastening hole 38a is a hole for fitting the mounting bolt 18 into the mounting hole 12a of the side rail 12. [ The second long hole 38b is a through hole corresponding to the first long hole 36b, and the width thereof is the same as the first long hole 36b. The second long hole 38b overlaps with the first elongated hole 36b in a state where the rotational plate 36 is engaged with the second link plate 36. [ The lengths of the first long hole 36b and the second long hole 38b may be the same or different.

On the other hand, the elastic coupling means elastically brings the rotating plate 36 and the second link plate 38 into contact with each other. The elastic coupling means includes four support bolts 33a, two spacing washers 33b, four sliding washers 33c, four compression springs 33d, support brackets 39 And four pressing nuts 33e.

The gap retaining washer 33b has a substantially band shape and has a fitting hole 33f at both ends thereof. The fitting hole 33f is a hole for receiving the supporting bolt 33a and the distance z is shorter than the length of the first and second long holes 36b and 38b. The length of the first and second long holes 36b and 38b may be at least two times the distance z.

The distance z between the fitting holes 33f is the same as the distance between the left and right bolt holes 39a formed in the support bracket 39. [ As a result, the support bolt 33a is parallel to the fitting hole 33f and the bolt hole 39a, and always maintains a constant spacing.

The support bolt 33a passes through the fitting hole 33f of the gap retaining washer 33b and the first elongated hole 36b and the second elongated hole 38b and thereafter passes through the sliding washer 33c, 33d and the support bracket 39 in order to engage with the pressure nut 33e.

The pressing spring 33d is in contact with the sliding washer 33c and the supporting bracket 39 at both ends thereof while the supporting bolt 33a passing through the sliding washer 33c is wrapped. As will be described later, the pressing spring 33d receives a pressing force from the pressing nut 33e and elastically presses the rotating plate 36 and the second link plate 38 together.

The sliding washer 33c is interposed between the second link plate 38 and the compression spring 33d so that when the adjacent unit cable trays 10 approach or move away from each other, Sliding movement is performed on the surface. A description thereof will be given later with reference to FIGS. 3A, 3B and 3C.

The support bracket 39 is formed by bending a metal plate having a predetermined thickness, and has a plurality of bolt holes 39a as described above. The support bolt 33a is threadedly engaged with the pressure nut 33e in a state of passing through each bolt hole 39a.

(Not shown) of the support bolt 33a is caught by the gap retaining washer 33b, the second link plate 38 (not shown) is fixed to the support bolt 33a in accordance with the degree of screwing of the press- The spacing of the support bracket 39 relative to the support bracket 39 is adjusted. In other words, the pressing nut 33e can be pushed to push the support bracket 39 toward the second link plate 38 or the support nut 33e can be disengaged to move the support bracket 39 to the second link plate 38, As shown in FIG.

The pressing spring 33d interposed between the second link plate 38 and the supporting bracket 39 is compressed by the movement of the supporting bracket 39 toward the second link plate 38 side and the elastic force Is transmitted to the rotating plate portion (36) and the second link plate (38) which are in an interview. That is, the rotating plate portion 36 and the second link plate 38 are pressed with a stronger pressure.

The greater the pressing force, the greater the frictional force of the second link plate 38 relative to the rotation plate 36 is. That is, the demand force for starting the relative movement of the second link plate 38 with respect to the first link plate 32 becomes large. That is, as shown in Figs. 3A and 3B, the required force for moving the first link plate 32 and the second link plate 38 in the direction of arrow a or b increases. Adjustment of the pressing force of the second link plate 38 with respect to the rotation plate portion 36 is appropriately set by the user.

Figs. 3A, 3B and 3C are plan sectional views for explaining the operation of the connector device 30 shown in Fig. 2, and Fig. 4 is a plan view for explaining still another function of the connector device shown in Fig.

FIGS. 3A, 3B and 3C are views showing the operation of the connector device 30 when a longitudinal force of the cable tray 10 is applied to a unit cable tray 10 connected in a straight line. FIG. And a state in which a lateral load is applied to the connector device 30 connecting the cable tray 10 is shown.

In any case, referring to FIG. 3A, it can be seen that the rotation plate 36 and the second link plate 38 are in an interview. Of course, the interview state is maintained via the elastic coupling means 71. In addition, two pressing nuts 33e are located at approximately the center of the first and second long holes 36b and 38b. The press nut 33e is left to move left and right in the first and second slots 36b and 38b.

3A, when the building is shaken by an earthquake and a force in the direction of the arrow a is transmitted from the outside, the rotating plate portion 36 and the second link plate 38 perform friction movement and move in the direction of arrow a do. At this time, the pressing nut 33e appropriately seats in the first and second slots 36b and 38b.

The connector device 30 moves in response to an external force, so that stress concentration in the connector device does not occur. If there is no connector device 30, the cable tray will be deformed or partially cut by an external force.

When a tensile force is applied to the unit cable tray 10, the first link plate 32 and the second link plate 38 are pulled in the direction of arrow b as shown in FIG. 3B. The connector device 30 is stretched in accordance with the tensile action externally applied to prevent the cable tray 10 as well as the connector device 30 from being damaged or deformed. At this time, the pressing nut 33e is properly positioned within the first and second slots 36b and 38b. The pivoting plate portion 36 and the second link plate 38 are fixed by the elastic coupling means 71 so that the pressing nut 33e can be inserted into the first and second slots 36b, There is no fear of separation.

4, when the lateral force in the direction of the arrow F is applied to the connector device 30, the fixing plate portion 34 and the rotation plate portion 36 are bent by the action of the hinge portion 37, do. As the connector device 30 is folded in accordance with the external force, the connector device 30 as well as the cable tray 10 are not damaged or deformed. It is possible to continuously support the cable (not shown).

If the connector device 30 is not provided with a bending function, it is a matter of course that cutting and / or deformation of the connector device 30 or other parts easily occurs when a lateral external force is applied.

5 is a perspective view showing a cable tray to which a dustproof connector device 50 for cable tray connection according to a second embodiment of the present invention is applied.

Hereinafter, the same reference numerals as those of the above-mentioned reference numerals denote the same members having the same function.

The connector device 50 shown in Fig. 5 includes a plurality of cross links 55a and 55b and side links 56a, 56b, 57a and 57b. The connector device 50 is positioned between the side rails 12 adjacent to each other in the longitudinal direction and is prepared for an external force applied in the longitudinal direction of the unit cable tray 10.

The connector device 50 includes a pair of cross links 55a each having a central portion connected to each other via a pivot shaft portion 66 and having an X-shape, one end portion of each cross link 55a, and a left side rail And two second side links 57a connecting the other end of the cross link 55b and the right side rail 12 in the drawing.

The first side link 56a extends to the side rail 12 side in a state of being linked to one end of the cross link 55a through the pivot shaft portion 66 and is connected to the side rail 12 ). The link between the first side link 56a and the side rail 12 is also held by the turning shaft portion 66. [

Likewise, the second side link 57a is extended to the opposite side rail 12 side in a state of being linked to the other end of the cross link 55a and is then supported on the side rail 12 by being extended. The coupling of the second side link 57a to the side rail 12 is also performed through the rotation shaft portion 66. [

The rotating shaft portion 66 has a fixing bolt 51 and a supporting nut 53. The fixing bolt 51 is provided with a pair of cross links 55a, a cross link 55a and a first side link 56a, a cross link 55a and a second side link 57a, a side rail 12, A bolt passing through the double side first side link 56a, the side rail 12 and the double side second side link 57a. Further, the support nut 53 is engaged with the fixing bolt 51, thereby making the fixing bolt 51 closely contact the member passed. The degree of engagement of the support nut 53 with respect to the fixing bolt 51 can be adjusted.

6 is a view showing another example of the dustproof connector device 60 for cable tray connection according to the second embodiment of the present invention together with the unit cable tray 10. [

6 has a rectangular plate-shaped coupler 62 and a first side link 65a and a second side link 65b linking the coupler 62 to the side rails 12 on both sides, 65b, and a rotating shaft portion 66 for maintaining the link state.

First, the coupler 62 includes a first rotating piece 62a, a second rotating piece 62b, and a hinge portion 69. The first rotating piece 62a takes a substantially C shape and provides a groove portion 62d. A pin fitting 62c is formed at the end of the first rotating piece 62a. The link pin 63 inserted into the pin mounting hole 62c crosses the groove portion 62d. The second turning piece 62b is in parallel with the first turning piece 62a and has a fitting protrusion 62e inserted into the groove 62d. A hole (not shown) through which the link pin 63 passes is also formed in the fitting projection 62e.

Therefore, when the link pin 63 is inserted through the pin mounting hole 62c with the fitting protrusion 62e interposed in the groove 62d, the first and second turning pieces 62a and 62b are inserted, Are rotatably linked to each other. The hinge portion 69 includes a groove portion 62d, a fitting protrusion portion 62e, and a link pin 63. The reason why the hinge portion 69 is applied as described above is to absorb a shock coming in the lateral direction at the time of occurrence of an earthquake, similarly to the case described with reference to Fig.

Four first side links 65a and four second side links 65b are provided to connect the coupler 62 and the side rails 12 on both sides of the coupler. The first and second side links 65a and 65b are strip-shaped members having a certain thickness.

The first side link 65a is a member rotatably disposed on the lower and upper ends of the coupler 62 through the pivot shaft portion 66. [ The first side link 65a may rotate freely or may not be freely rotatable in a stiff state in accordance with the pressure provided by the pivot shaft portion 66. [ The pressure provided by the rotating shaft is an adhering force according to the degree of screwing of the support nut 67 to the fixing bolt 68.

One end of the second side link 65b is linked to the end of each first side link 65a via the pivot shaft portion and the other end is linked to both side rails 12. The other ends of the second side links 65b are linked to the side rails 12 in a mutually overlapping state.

The pivot shaft portion 66 includes a first side link 65a and a first side link 65a and a second side link 65b and a second side link 65b and a side rail 12, And a support nut 67 which is engaged with the fixing bolt 68 but whose degree of engagement with the fixing bolt is regulated. The degree of screwing of the support nut 67 with respect to the fixing bolt 68 can be adjusted.

Figs. 7A, 7B and 8 are views for explaining the operation of the connector device shown in Fig. 6. Fig.

7A is a view showing a state in which the side rails 12 on both sides are pushed in the direction of the arrow p. For example, when the building is shaken by an earthquake and the interval of the unit cable trays 10 neighboring in the longitudinal direction is narrowed, the first and second side links 65a and 65b absorb the narrowed interval as shown in FIG. 3B.

7B is a view showing a case where a tensile force is applied to the unit cable tray 10. As the cable tray 10 adjacent in the longitudinal direction is pulled in the opposite direction, that is, in the direction of the arrow s, the angle between the first and second side links 65a and 65b becomes larger and absorbs the change in the gap. 3C as described above.

8, when the lateral force in the direction of the arrow F is applied to the connector device 60, the first and second turning pieces 62a and 62b are moved by the action of the hinge portion 69, Is bent. As the connector device 60 is bent in accordance with the lateral external force, there is no breakage or deformation of the cable tray 10 as well as the connector device 60, so that the cable can be stably supported.

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: Unit cable tray 12: Side rail 12a: Mounting hole
12b: latching jaw 14: crossbar 16: support pin
18: connecting bolt 19: fixing nut 30: connector device
32: first link plate 33a: support bolt 33b: gap retaining washer
33c: a sliding washer 33d: a pressing spring 33e: a pressing nut
33f: fitting hole 34: fixing plate portion 34a: fastening hole
34c: support shaft portion 34d: groove portion 35: link pin
36: rotating plate portion 36a: fitting projection 36b: first slot
37: hinge portion 38: second link plate 38a: fastening hole
38b: second long hole 39: support bracket 39a: bolt hole
50: connector device 51: fixing bolt 53: support nut
55a: Cross link 56a: First side link 57a: Second side link
60: connector device 62: coupler 62a: first rotating piece
62b: second rotating piece 62c: pin mounting hole 62d:
62e: fitting protrusion 63: link pin 65a: first side link
65b: second side link 66: pivot shaft portion 67: support nut
68: fixing bolt 69: hinge 71: elastic coupling means

Claims (1)

A plurality of unit cable trays provided with side rails for relative movement,
A coupler disposed between the side rails of the cable tray for connection;
The first side link is connected to the coupler and both side rails located on both sides of the coupler so as to be rotatable on both the upper and lower ends of the coupler through the pivot shaft. And a second side link linked to an end of the link and the other end linked to both side rails,
Wherein the pivot portion includes a fixing bolt to be fitted to the coupler and the first side link, a first side link and a second side link, a second side link and a side rail, and a fixing bolt coupled to the fixing bolt, Comprising an adjustable support nut,
The coupler comprising: A first rotating piece connected to one side rail and a second rotating piece linked to the other side rail and a second rotating piece positioned between the first rotating piece and the second rotating piece and rotating the second rotating piece with respect to the first rotating piece And a hinge portion for supporting the cable tray.

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