KR101899855B1 - Earthquake resistant type cable tray - Google Patents

Abstract

The present invention relates to a cable tray, and more particularly, to a cable tray having a pair of side frames continuously arranged in the longitudinal direction and at least one lug which is coupled to the inner side of the pair of side frames, Disclosed is a seismic cable tray which can reduce the possibility that a cable will be severed or damaged, thereby causing a very large electrical damage, by protecting it from an earthquake or a strong impact.
In addition, the present invention is not only to elastically support the spherical portion and the spherical portion, which are three-dimensionally rotatable to absorb vibrations in various directions, by using the first and second springs to absorb vibration in the longitudinal direction, It is possible to obtain an effect that the cable tray can be perfectly protected from an earthquake or a strong impact by deviating from the excellent cycle period of the earthquake.

Description

Earthquake resistant type cable tray

The present invention relates to a cable tray, and more particularly, to a cable tray having a pair of side frames continuously arranged in the longitudinal direction and at least one lug which is coupled to the inner side of the pair of side frames, Is a technical field related to an anti-seize cable tray that can protect against the earthquake or strong impact, thereby reducing the possibility that the cable will be cut or damaged and cause very great electrical damage.

In general, large and small diameter cables are arranged along the ceiling and floor or wall for supply of power, fluid, etc. to tunnels, factories, and offshore structures. The cables thus placed should not be aesthetically pleasing to the passengers. Therefore, a cable tray is used to support and fix the cable in an organized state.

The cable tray is a support made of a non-combustible or metallic material for supporting the cable. The cable tray has a pair of side rails having a predetermined length and forming left and right side surfaces, and a horizontal connecting member (rung) .

Here, the cable tray can be installed while being extended to other cable trays along the longitudinal direction of the side rails through connecting members, joints, which are called joints.

The connection structure of the cable tray according to one embodiment of the present invention is characterized in that the side rails of the cable tray to be connected are adjacent to each other in the longitudinal direction and then the connectors are disposed to cover the outside of the cable rails. When the brace hole and the flange nut are fastened to the fastening hole formed in the fastening hole and the flange nut, the pair of cable trays can be interconnected while the side rails are fastened to the fastening hole.

In another conventional example, Korean Patent Registration No. 0993138 has a feature that a first cable tray and a second cable tray which are adjacent to each other are connected to each other by using a connecting member and a fixing member. More specifically, Four perforations are formed at the ends of the side rails of the tray and the second cable tray, respectively, and four annular protrusions are protruded from the right and left sides of the vertical plate portion of the connecting member. Further, four reinforcing holes are formed in the lower part of the perforations, and four reinforcing protrusions are protruded from the bottom of the annular protrusions.

At this time, when the side rails and the connecting member are brought into close contact with each other so that the annular projection of the connecting member is inserted into the perforations of the side rails and the reinforcing projection is inserted into the reinforcing hole and then the fixing member of the fixing member is inserted into the annular hole, The tray and the second cable tray are connected to each other, and a ground jumper plate made of copper can be attached to the inside of the vertical plate portion connecting the fixing member of the fixing member.

The conventional cable tray as described above is focused on simplifying the manufacturing process and the installation method, saving time and cost of manufacturing and installing, and showing excellent insulation performance while maintaining a stable state after installation. However, There is a problem in that the connecting portion or the side rail may be damaged by the occurrence of an earthquake due to lack of seismic performance against the earthquake.

Korean Patent No. 10-0993138. Korean Patent No. 10-1307486.

SUMMARY OF THE INVENTION [0006] The present invention is directed to solve the above-described problems in the prior art, and a conventional cable tray is used for directly fixing the side rails and the ends of the transverse connecting members by welding or the like, There is a fear that the cable tray may be broken or the cable may be cut or damaged when an earthquake or an impact is generated. The main object of the present invention is to provide an anti-seizing cable tray which can actively move the connecting part in case of an earthquake or an impact to minimize damage.

In order to realize the above-described object, the present invention provides a pair of side frames, each having at least one fastening hole formed on each side thereof, an upper portion and a lower portion bent inwardly, At least one lug to be coupled to the inner side of the side frame of the side frame and a first coupling hole corresponding to the coupling hole formed at one side of the side frame are formed and the upper and lower portions are respectively bent in the inner direction, And a second coupling hole corresponding to the coupling hole formed on the other side of the side frame, and the upper and lower portions are respectively bent in the inward direction and coupled to the outer side surface of the side frame The second connection frame and the other side are connected to the outer surface of the first connection frame so as to be three-dimensionally rotatable, In doedoe coupled so as to be movable in one direction and the other direction, it presents a seismic cable tray, characterized in that comprises a flow member that is elastically supported in both side directions.

In addition, the first connection frame of the present invention is formed integrally with the other side of the outer side surface and includes a spherical engagement portion formed with a spherical groove, the second connection frame is formed integrally with the outer side surface, And a rail portion formed on the groove outer side in the longitudinal direction.

In addition, the flow member of the present invention is characterized in that the sphere coupled to the spherical groove of the spherical coupling portion is integrally formed at the other end, and the spherical portion having the threads formed on one side thereof, and the rail coupling portion coupled to the rail groove of the rail portion, A moving part formed on the other side of the moving part, and a throttle part having one side of the spherical part and the other side of the moving part respectively screwed to each other, and a moving part provided on one side of the moving part, And a second spring provided on the other side of the moving part and provided on the other side of the rail coupling part.

Further, the present invention is characterized in that the present invention further comprises a seismic member to which the other side of the first connection frame and the other side of the second connection frame are coupled to each other.

The seismic resistant cable tray according to the present invention described above can be used not only to elastically support the spherical portion and the first and second springs to absorb vibration in various directions, , It is possible to obtain an effect that the cable trays can be perfectly protected from earthquakes or strong impacts by making the natural period of the cable tray deviate from the excellent periodic period of the earthquake by using the seismic member.

1 is a perspective view of a cable tray according to a preferred embodiment of the present invention;
2 is an exploded perspective view of a cable tray according to a preferred embodiment of the present invention;
3 is a partially exploded perspective view of a cable tray according to a preferred embodiment of the present invention.
4 is a partial perspective view of a cable tray according to a preferred embodiment of the present invention;
5 is a partially exploded perspective view of a cable tray according to a preferred embodiment of the present invention.
6 is a cross-sectional perspective view of a base member according to a preferred embodiment of the present invention.
7 is a partial side view of a cable tray except for a flow member according to a preferred embodiment of the present invention;
8 is a partial side view of a cable tray according to a preferred embodiment of the present invention.
Figure 9 is a partial top cross-sectional view of a cable tray according to a preferred embodiment of the present invention.
10 is a perspective view illustrating a cable tray having a ground frame according to a preferred embodiment of the present invention.

The present invention relates to a cable tray, and more particularly, to a cable tray having a pair of side frames (100) arranged continuously in the longitudinal direction and at least one side frame (100) Is a technique relating to an anti-seize cable tray that can protect a cable tray made of a lug (200) of a lug (200) from an earthquake or a strong impact, thereby reducing the possibility that a cable is severed or damaged,

In addition, when connecting the ends of the side rails and the transverse connecting members to each other, the conventional cable trays are used for fixing them directly by welding or the like, and for the convenience of assembly and disassembly, joint structures are used. If this happens, the cable tray may be broken, or the cable may be cut and damaged, resulting in very great electrical damage.

Accordingly, the present invention provides a method of manufacturing a vibration absorbing structure, which includes a spherical portion 510 and a first and second springs 540 and 540 for absorbing vibrations in the longitudinal direction, (Not shown) of the cable tray by using the seismic member 600 to avoid the resonance between the seismic vibration and the behavior of the cable tray, The seismic force is relatively weakly transmitted to the continuous cable tray, so that the cable tray can be perfectly protected from earthquake or strong impact.

In order to accomplish the above-described object, the present invention is characterized in that at least one fastening hole 102 is formed on both sides, a pair of side frames 100 At least one lug 200 to which both sides are coupled to the inner side surfaces of the pair of side frames 100 and at least one lug 200 to be coupled to the coupling holes 102 formed at one side of the side frames 100, A first connection frame 300 formed with a coupling hole 302 and having an upper portion and a lower portion bent inward and connected to an outer surface of the side frame 100 and a second connection frame 300 coupled to the other side of the side frame 100 A second connection frame 400 formed with a second coupling hole 402 corresponding to the formed coupling hole 102 and having an upper portion and a lower portion bent inwardly and coupled to an outer surface of the side frame 100, And the other side is rotatable three-dimensionally on the outer surface of the first connection frame 300 And a fluid member 500 coupled to the outer surface of the second connection frame 400 so as to be movable in one side direction and the other side direction and being elastically supported in both lateral directions, And presents a padded cable tray.

The first connection frame 300 of the present invention is integrally formed on the other side of the outer side of the first connection frame 300 and has a spherical groove 312 formed therein, 400 are integrally protruded from the outer side surface and have a rail groove 412 formed on the outer side surface in the longitudinal direction.

The flow member 500 of the present invention further includes a spherical portion 510 formed integrally with the other end of the spherical groove 312 of the spherical coupling portion 310 and having threads formed on one side thereof, A moving part 520 formed at one side thereof with a rail engaging part 522 coupled to the rail groove 412 of the rail 410 and formed with a thread on the other side thereof, And a guide member 530 which is provided at one side of the moving unit 520 and is disposed between the throttle unit 530 and the rail coupling unit 522, A first spring 540 disposed on the first shaft 540; And a second spring 550 provided on the other side of the moving part 520 and provided on the other side of the rail coupling part 522.

The present invention is further characterized in that the present invention further comprises an isometric member 600 having both sides connected to the other side of the first connection frame 300 and one side of the second connection frame 400.

Hereinafter, the present invention will be described in detail with reference to the drawings 1 to 10 showing embodiments of the present invention.

The side frame 100, which is a main component for achieving the present invention,

At least one fastening hole 102 is formed on each side, and the upper and lower portions are respectively bent inward and are continuously arranged in the longitudinal direction. One or both sides of the lug 200, which will be described later, And a pair of side frames 100 coupled to the other side or one side of the lug 200 to form a pair. The pair of side frames 100, to which the lugs 200 are coupled, It is a unit of.

That is, the side frame 100 of the present invention is formed to have a predetermined length. As shown in FIG. 2, at least one fastening hole 102 is formed on both sides of the side frame 100, (Not shown) is installed on the upper part of the lug 200 by the fluid member 300 and the fluid member 500 and the seam member 600. 1 to 10 shown in the present invention, a pair of side frames 100, which show one side and the other side of the side frame 100 in order to omit a length of the side frame 100, Respectively.

It is obvious that the number of formed holes and forming positions of the fastening hole 102 of the side frame 100 according to the present invention can be changed by considering the length and height of the side frame 100, And is formed in the shape of a long hole as shown in the figure so as to facilitate the fastening.

In addition, a lug 200, which is a main component for achieving the present invention, supports a cable, and both sides of the side frames 100 are coupled to each other by welding, bolts, nuts, or the like And any number of lugs used in the related art may be used, and a detailed description thereof will be omitted.

The first connection frame 300, which is a main component for achieving the present invention,

A first coupling hole 302 corresponding to the coupling hole 102 formed at one side of the side frame 100 is formed and the upper and lower portions are respectively bent in the inward direction, As a result, a pair of side frames 100, that is, a cable tray, can be continuously arranged in connection with the second connecting member 400, which will be described later in detail.

Specifically, in the first connection frame 300 of the present invention, a first coupling hole 302 corresponding to a coupling hole 102 formed in one side of the side frame 100 is formed at one side, And the spherical groove 312 is formed integrally with the other side of the outer surface of the first connection frame 300 so that the spherical groove 312 of the fluid member 500 may be coupled with the spherical groove 312. [ And the like.

That is, the first connection frame 300 of the present invention has a structure in which the ball 512 of the fluid member 500, which will be described in detail later, is coupled to the old coupling portion 310 protruding from the other side of the outer surface, It is possible to minimize the damage caused by the shaking.

As shown in FIG. 3, the old coupling part 310 is formed on the other side of the first coupling frame 300, and is coupled to the external side of the old coupling body. The first connection frame 300 and the flow member 500 are coupled to each other by coupling the spherical portion 512 of the spherical portion 510 to the old connection member body and then the old connection portion cover is coupled to the first connection frame 300 do.

The first connection frame 300 of the present invention is coupled to the outer side of one side of the side frame 100 so that the other side of the isolation member 600 to be described later can be engaged, And at least one third engagement hole (not shown) is formed in the projected portion.

The second connection frame 400, which is a main component for achieving the present invention,

A second engagement hole 402 corresponding to the fastening hole 102 formed on the other side of the side frame 100 is formed and the upper and lower portions are respectively bent in the inward direction, As a result, the pair of side frames 100, that is, the cable tray, can be continuously arranged in connection with the first connecting member 300 described above.

Specifically, in the second connection frame 400 of the present invention, a second coupling hole 402 corresponding to the coupling hole 102 formed on the other side of the side frame 100 is formed on the other side, The first connection frame 400 and the second connection frame 400 are integrally formed on the outer surface of the second connection frame 400 so that the rail coupling portion 522 of the flow member 500 can be engaged, And a rail part (410).

That is, in the second connection frame 400 of the present invention, the rail engaging portion 522 of the flow member 500, which will be described later in detail, is joined to the rail portion 410 protruding from the outer side surface, The flow member 500 is moved along the rail groove 412 of the rail 410 when the shake occurs, thereby minimizing damage due to shaking.

3, the rail 410 includes a rail body (not shown) protruded from the other side of the outer surface of the second connection frame 400 and a rail cover (not shown) coupled to one side of the rail body, And one end of the rail coupling part 522 is coupled to the rail groove 412 in the other direction of the rail body and then the rail cover is coupled to the second connection frame 400 and the puddle member 500 ) Are combined.

In addition, the second connection frame 400 of the present invention is coupled to the other outer side surface of the side frame 100 so that one side of the isolation member 600, which will be described in detail later, can be engaged, , And at least one fourth engagement hole (not shown) is formed in the protruding portion.

As shown in FIGS. 1 and 2, the second connection frame 400 of the present invention has a larger protruded length than the first connection frame 400 after being coupled to the side frame 100 This is because the second coupling hole 402 and the fourth coupling hole can not be formed by the rail 410.

The flow member 500, which is a main component for achieving the present invention,

And the other side is coupled to the outer surface of the first connection frame 300 so as to be three-dimensionally rotatable, one side of which is coupled to the outer side surface of the second connection frame 400 so as to be movable in one direction and the other direction, That is, it is resiliently supported in one direction and the other direction, and absorbs the movement of the cable tray in the longitudinal direction when an earthquake or an impact occurs, thereby minimizing the flow.

Specifically, the flow member 500 of the present invention includes a sphere 512 integrally formed at the other end of the flow member 500 to be coupled to the spherical groove 312 of the former coupling part 310 of the first connection frame 300, A spherical portion 510 having a thread on one side thereof and a rail engaging portion 522 engaging with the rail groove 412 of the rail portion 410 of the second connecting frame 400 are formed on one side, A rectilinear section 520 formed at one side of the moving section 520 and a rectilinear section 530 at which the rectilinear section 510 and the moving section 520 are screwed on both sides of the moving section 520, A first spring 540 provided between the throttle portion 530 and the rail engaging portion 522 and a second spring 540 provided on the other side of the moving portion 520. The second spring 540 is provided on the other side of the rail engaging portion 522, And a spring (550).

The spherical portion 510 is formed integrally with the other end of the spherical portion 510 and is coupled to the spherical groove 312 formed in the coupled portion 310 of the first connection frame 300 described above, And the cable tray arranged in one direction is three-dimensionally rotated so as to absorb vibrations in various directions.

In addition, the spherical portion 510 is threaded on one side, and the cable tray disposed in the other direction by the tightening portion 530, which will be described in detail later, is moved in the direction of the cable tray arranged in one direction.

The moving part 520 is coupled to the rail groove 412 formed in the rail 410 of the second connection frame 400 with the rail engaging part 522 formed on one side thereof to move along the rail groove 412 .

In addition, the moving part 520 is provided at one side, and a first spring 540 is provided between the throttle part 530 and the rail coupling part 522, which will be described in detail later, And absorbs the movement along the rail groove 412 by the second spring 550 provided on the other side of the rail engagement portion 522.

At this time, the moving unit 520 includes a moving unit body 530 having a screw thread formed on the other side and a supporting unit 532 integrally formed at one end thereof, and the moving unit body 530, And a rail coupling part 522 coupled vertically in the longitudinal direction of the body 530.

The second spring 520 is supported at one end of the second spring 520 by the support portion 532 formed at one end of the moving body 530, So that the portion 522 is elastically supported.

That is, the other end of the first spring 540 is supported by the tightening portion 530 to be described later in detail so that the moving portion 520 elastically supports the rail engaging portion 522 in one direction, The rail coupling part 522 is elastically supported in the other direction and the rail coupling part 522 is moved in the rail groove 412 to absorb the longitudinal movement of the cable tray arranged in one direction.

3, the rail coupling portion 522 includes a locking portion 522a coupled to the rail groove 412 formed in the rail 410 of the second connection frame 400 at one side thereof, A first rotating shaft 522b protruding from the other side of the latching part 412 and a second end of the first rotating shaft 522b are inserted and coupled to one side and the moving body 530 is pierced And a second rotation axis 522d coupled to the other side of the vertical coupling portion 522c. The vertical coupling portion 522c has a through hole (not shown) do.

That is, the rail coupling portion 522 is formed in a state in which the cable tray (cable tray positioned on the right side in FIG. 1) disposed in the one direction is connected to the moving body body 530 of the moving portion 520 by earthquake or shock So as to minimize movement, thereby minimizing the flow.

The rail coupling portion 522 further includes a bearing 522e coupled to the inside of the vertical coupling portion 522c and installed at the outer circumference of the first rotation shaft 522b and the second rotation shaft 522d 8, the bearing 522e rotates the moving body 530 in the up and down direction, thereby widening the movement range of the cable tray disposed in one direction, To realize the effect that can be moved to.

The rectilinear part 510 and the moving part 520 are screwed to the other side of the rectilinear part 510. In other words, And the other side of the moving part 520 is drawn into both sides and screwed together.

That is, as the throttle unit 530 is rotated, the spherical portion 510 is moved in one direction and the moving unit 520 is moved in the other direction so that the cable tray arranged in one direction and the other direction The first spring 540 is pressed and the rail coupling portion 522 presses the second spring 550 by the pressurized first spring 540. In this way, So that the elastic force of the first and second springs 540 and 550 can be exerted.

The base member 600, which is a main component for achieving the present invention,

The first connection frame 300 is coupled to one side of the second connection frame 400 and the other side of the second connection frame 400 is coupled to the other side of the side frame 100, One side of the second connection frame 400 coupled to one side of the frame 300 and coupled to protrude in the other direction of the side frame 100 disposed in one direction is coupled to one side of the vibration- The resonance is avoided so that the seismic force is relatively weakly transmitted to the continuous cable tray, thereby realizing the effect that the cable tray can be perfectly protected from earthquake or strong impact.

6, the insulator 600 of the present invention includes an elastomeric body 602 made of a synthetic resin material and a plurality of elastic members 602 arranged inside the elastomeric body 602 perpendicularly to the longitudinal direction of the elastomeric body 602 A flexible member 606 provided on the inner side of the elastic body 602 and provided between the elastic body 602 and the pillar member 604 in a laminated structure, And a member (608).

In other words, the base member 600 of the present invention is provided with the flexible member 606, the rigid member 608, the elastic body 602, and the pillar member 604, And the natural period of the cable tray is deviated from the excellent periodic period of the earthquake to realize the above effect.

At this time, the elastic body 602 and the pillar member 604 may be made of a synthetic resin material having elasticity generally used in the past, but it is preferable to use a synthetic resin material based on polyurethane, The elastic member 606 and the rigid member 608 may be made of a synthetic resin material having elasticity, but a synthetic resin material based on polyurethane may be used. The elastic body 602 and the pillar member 604 It is preferable that it is made of a material having a weaker rigidity or a material having a higher rigidity.

10, the ground frame 700 may further include a ground frame 700 connected to both sides of the cable tray that is continuously disposed. In more detail, One side of which is coupled to the inside of the side frame 100 of the cable tray disposed in the other direction and the other side is coupled to the inside of the side frame 100 of the cable tray disposed in the one direction.

The ground frame 700 may be disposed between the side frame 100 and the face member 600 so as to be supported by the face member 600.

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, It is possible to carry out various changes in the present invention.

100: side frame 102: fastening hole
200: lug 300: first connecting frame
302: first coupling hole 310:
312: spherical groove 400: second connecting frame
402: second coupling hole 410: rail part
412: Rail groove 500: Flow member
510: spherical portion 512: spherical portion
520: moving part 522: rail coupling part
530: Tightening part 540: First spring
550: second spring 600: seismic member

Claims (4)

A pair of side frames 100 each having at least one fastening hole 102 formed on both sides thereof and each of which is bent in an inward direction and continuously arranged in the longitudinal direction and a pair of side frames 100 At least one lug 200 to which both sides are coupled to the inner side of the side frame 100 and a first coupling hole 302 corresponding to the coupling hole 102 formed at one side of the side frame 100, A first connection frame 300 which is folded inward in a lower direction and which is coupled to an outer surface of the side frame 100 and a second connection frame 300 which is formed in the other side of the side frame 100, A second connection frame 400 formed with a coupling hole 402 and having an upper portion and a lower portion bent inward and coupled to an outer surface of the side frame 100 and a second connection frame 400 coupled to the first connection frame 300 , One side of which is rotatably connected to the second connection frame 400, and a fluid member 500 elastically supported in both directions so as to be movable in one side direction and the other side direction,
The first connection frame 300 is integrally protruded from the other side of the outer surface and includes a spherical groove 312,
Wherein the second connection frame (400) is formed integrally with the outer side surface, and the rail groove (412) is formed in the longitudinal direction on the outer side surface of the second connection frame (400) tray.
delete The method according to claim 1,
The flow member (500)
A spherical portion 510 integrally formed at the other end of the spherical portion 512 to be coupled to the spherical groove 312 of the old coupling portion 310 and having a thread formed on one side thereof;
A moving part 520 having a rail engaging part 522 coupled to the rail groove 412 of the rail 410 at one side and forming a screw thread at the other side;
A throttle portion 530 to which both sides of the spherical portion 510 and the moving portion 520 are screwed, respectively;
A first spring 540 provided at one side of the moving part 520 and provided between the throttle part 530 and the rail coupling part 522; And
And a second spring (550) provided on the other side of the moving part (520) and provided on the other side of the rail coupling part (522).
The method according to claim 1,
The first connection frame (300)
The side frame 100 is coupled to an outer side of one side of the side frame 100,
The second connection frame (400)
The side frame 100 is coupled to the outer side of the other side of the side frame 100,
The seismic cable tray
Further comprising: an isolation member (600) having both sides of the first connection frame (300) coupled to one side of the second connection frame (400).

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