KR102293850B1 - Earthquake-resistant type cable tray system - Google Patents

Abstract

The present invention relates to a seismic cable tray system, which can protect a cable tray unit from vibration, comprising: a mounting anchor unit (100) installed at regular intervals on a ceiling (10) of a building; a computation bolt unit (200); and a vibration response unit (300) installed to connect the mounting anchor unit (100) and the computation bolt unit (200).

Description

Earthquake-resistant cable tray system {EARTHQUAKE-RESISTANT TYPE CABLE TRAY SYSTEM}

The present invention relates to a seismic-resistant cable tray system, and more particularly, to a seismic-resistant cable tray system capable of effectively absorbing multidirectional vibrations generated by earthquakes, etc. to protect the cable tray unit from vibrations.

In general, various types of cable trays are used in large buildings or factories so that cables such as electric wires and communication lines can be intensively arranged and wired in a safe space.

These conventional cable trays are manufactured to be connected as many as necessary according to the length and route of cables installed inside the building, and are usually installed on the ceiling of the building in order not to cause inconvenience to the occupants of the building.

Accordingly, a cable tray capable of loading cables, a connection member for connecting a plurality of cable trays, a plurality of supporting members supporting the cable trays connected to a plurality of cables, and several vertical members fixed to the ceiling of a building and connected to each supporting member A cable tray system consisting of rods is provided.

However, when the ground is shaken due to an earthquake, the structure is shaken, and the vibration generated while the structure is shaken is transmitted to the cable tray as it is, causing a problem in that the cable tray is damaged or the loaded cable is damaged and cut.

As the background technology of the present invention, the seismic type cable tray system of Republic of Korea Patent Registration No. 10-1436333 is disclosed.

The present invention has been devised in view of the above circumstances, and an object of the present invention is to install a vibration response unit between the mounting anchor unit installed on the ceiling and the computerized bolt unit extending upward from the cable tray unit to be generated by earthquakes, etc. It is to provide a seismic-resistant cable tray system that allows the tray member of the cable tray unit to be connected through the tray displacement response part as a medium to protect the cable tray unit from vibrations caused by earthquakes, etc. while allowing directional vibration to be effectively absorbed.

The present invention for achieving the above object is a mounting anchor part 100 installed at regular intervals on the ceiling 10 of a building, and the mounting anchor part 100 in the cable tray unit 400 for supporting the wire cable. The computerized bolt part 200 installed to extend to the In the cable tray system configured including The body sphere 360 installed to be connected to the chain unit 310 and having an accommodating space 362 therein, and the computerized bolt part 200 extending into the body sphere 360 are coupled to the upper side in the longitudinal direction. The binding nut sphere 370 to be used, and an elastic spring 380 installed to surround the computerized bolt part 200 extending into the body sphere 360 in a state positioned below the binding nut sphere 370 . ) and a vibration-proof rubber 390 that is installed on the lower side of the inner side of the body sphere 360 and supports the elastic spring 380 in a state in which a through-hole 393 for penetrating the computerized bolt 200 is formed. The moving pressing unit is connected to the moving pressing unit 371 that is installed to be seated on the upper side in the longitudinal direction of the elastic spring 380 in a state of being installed outside the lower side of the body sphere 360 and is rotated through the moving pressing unit. (371) is characterized in that it is configured to further include an elastic adjustment unit (500) to adjust the elastic force by pressing the elastic spring (380).

In addition, the chain unit 310 is installed to be connected to the upper connector 320 fastened to the mounting anchor part 100 by screwing, and the body part 360 via the easy fastening hole 340 . It is configured to include a lower connector 330 to be used, and a link chain part 350 installed so that both sides are connected to the upper connector 320 and the lower connector 330 .

In addition, in the cable tray unit 400, a plurality of tray members 410 are installed to be interconnected via a tray displacement corresponding portion 420, and the tray displacement corresponding portion 420 is an adjacent tray member ( It is configured to include a mounting unit 430 mounted on each of the 410, and a flexible copper portion 440 that is fixedly installed on both sides in the longitudinal direction to the mounting unit 430 to respond to fluctuations of the tray member.

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According to the present invention, it is possible to effectively absorb horizontal and vertical vibrations generated by earthquakes, etc. by the vibration-response part installed between the mounting anchor part and the electric wire bolt part and the tray displacement-response part connecting the tray member, so that the cable tray It is possible to prevent damage to the unit.

1 is a state diagram showing the state of the seismic type cable tray system according to the present invention,
Figure 2 is a state diagram showing the state of the computer bolt unit according to the present invention,
Figure 3 is an enlarged view showing an enlarged portion A of Figure 1,
4 is a state diagram showing a state in which an elastic spring is installed on the inside of the body sphere according to the present invention;
5 is a state diagram showing the separation state of the elastic spring and the anti-vibration rubber according to the present invention;
Figure 6 is a state diagram showing a state in which the tray member according to the present invention is connected via a tray displacement response unit;
7 is a state diagram showing an installation state of the elastic control unit according to the present invention;
8 is a state diagram showing a cross-sectional state of the elastic control unit according to the present invention;
9 is a state diagram showing a state in which an orthogonal hole portion is formed in the mounting guide according to the present invention;
10 is a state diagram showing the connection state of the joint moving stick and the connector operation tool according to the present invention;
11 is a state diagram showing another embodiment of the mounting anchor unit according to the present invention.

Hereinafter, an earthquake-resistant cable tray system according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, in the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, the terms to be described later are terms set in consideration of the function in the present invention, and these terms may vary according to the intention or custom of the producer or manufacturer producing the product, and the thickness of the lines shown in the drawings or the size of the components etc. may be exaggerated for the sake of clarity and convenience of explanation, and the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical spirit of the present invention. Therefore, it should be understood that there may be various equivalents and modifications that can be substituted for them at the time of filing the present application.

In addition, when a part is 'connected' to another part throughout the specification, this includes not only 'directly connected' but also 'indirectly connected' with another element interposed therebetween. do. In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

1 is a state diagram showing the state of the seismic-proof cable tray system according to the present invention, FIG. 2 is a state diagram showing the state of the computerized bolt unit according to the present invention, and FIG. 3 is an enlarged view showing part A of FIG. 4 is a state diagram showing a state in which the elastic spring is installed inside the body according to the present invention, FIG. 5 is a state diagram showing the separation state of the elastic spring and the dustproof rubber according to the present invention, and FIG. 6 is a tray member according to the present invention It is a state diagram showing a state in which the tray displacement response part is connected as a medium, FIG. 7 is a state diagram showing an installation state of the elastic adjustment unit according to the present invention, and FIG. 8 is a state diagram showing a cross-sectional state of the elastic adjustment unit according to the present invention. , Figure 9 is a state diagram showing a state in which an orthogonal hole is formed in the mounting guide according to the present invention, Figure 10 is a state diagram showing the connection state of the joint moving stick and the connector operation tool according to the present invention, Figure 11 is It is a state diagram showing another embodiment of the mounting anchor part.

As shown in FIGS. 1 to 11, the earthquake-resistant cable tray system according to the present invention includes a mounting anchor unit 100 installed at regular intervals on the ceiling 10 of a building, and a cable tray unit for supporting the electric cable ( The computerized bolt part 200 installed to extend in the direction of the mounting anchor part 100 in 400), and the mounting anchor part 100 and the computational bolt part 200 are installed to connect the horizontal vibration and vertical vibration In the cable tray system configured to include a vibration-response unit 300 configured to correspond to A body part 360 installed to be connected to the chain unit 310, and a binding nut part 370 coupled to the upper side of the computerized bolt part 200 extending into the body part 360, and the binding It is configured to include an elastic spring 380 and a vibration-proof rubber 390 installed on the lower side of the nut sphere 370 .

That is, the earthquake-resistant cable tray system according to the present invention effectively absorbs vertical and horizontal vibrations generated by earthquakes, etc. to have seismic characteristics, thereby protecting the cable tray from vibrations of buildings, and simple combination of each technical configuration. method to achieve installation advantages.

First, the mounting anchor part 100 is to be installed at regular intervals on the ceiling 10 of a building, and the mounting anchor part 100 as an embodiment is an anchor body installed so as to be embedded in the ceiling 10 ( 110) and the anchor body 110, which is formed to protrude in the direction of the ground, and may be formed of a screw coupling hole 120 having a screw thread formed on the outer periphery.

In addition, the computer bolt part 200 extends in the direction of the mounting anchor part 100 from the support hanger 450 mounted on the lower side of the cable tray unit 400 and is installed to be connected to the vibration response part 300 . As a result, the lower side in the longitudinal direction is connected to the support hanger 450 via the flange nut 220 . For this reason, the flange nut 220 supports the support hanger 450 .

Here, the computational bolt part 200 as an embodiment includes a main stick 210 extending in the vibration response part 300 direction with the flange nut 220 installed on the lower side in the longitudinal direction, and the extension stick With a connecting rod 230 screwed to the upper side of the 240, and an extension stick 240 extending to the other side in the longitudinal direction in a state in which the lower side in the longitudinal direction is screwed to the connecting rod 230, and extending to the vibration counteracting unit 300. it can be done

That is, by allowing the depth at which the main stick 210 and the extension stick 240 are screwed to the connecting rod 230 can be adjusted, the total length of the computerized bolt unit can be easily adjusted according to the field conditions. At this time, it is preferable that a stopper nut 250 is installed on the extension stick 240 at a position spaced upward from the connecting rod 230 .

In addition, the vibration response unit 300 connects the mounting anchor unit 100 and the computerized bolt unit 200 and is configured to respond to horizontal and vertical vibrations when vibration occurs due to earthquakes, etc., in one embodiment The vibration response unit 300 as a chain unit 310 is installed so as to be fastened to the mounting anchor unit 100 to respond to horizontal vibration, and the upper side is installed to be connected to the chain unit 310 A body sphere 360 having an accommodating space 362 formed therein, and a binding nut sphere 370 coupled to the upper side in the longitudinal direction of the computerized bolt part 200 extending into the body sphere 360, An elastic spring 380 installed to surround the computational bolt part 200 extending inside the body sphere 360 in a state positioned below the binding nut sphere 370, and the body sphere 360 It is installed on the inner lower side of the doedoe configured to include a vibration-proof rubber 390 for supporting the elastic spring 380 in a state in which a through hole 393 for penetrating the computational bolt part 200 is formed.

Here, as for the chain unit 310, the upper side in the longitudinal direction is connected to the mounting anchor part 100, and the lower side in the longitudinal direction is connected to the body sphere 360, the chain unit 310 as an embodiment. is an upper connector 320 fastened to the mounting anchor part 100 by screw coupling, and a lower connector 330 installed to be connected to the body part 360 via an easy fastening hole 340, and both sides It may be configured to include a link chain unit 350 installed to be connected to the upper connector 320 and the lower connector 330 .

That is, the upper connector 320 includes an acid-resistant bolt hole 321 into which the screw-in hole 120 is screwed and fitted, and a circular upper ring portion 322 formed on the lower side of the acid-resistant bolt hole 321 . The lower connector 330 may be made of an external bolt sphere 331 having a thread formed on the outer periphery, and a circular lower collar sphere 332 formed on the upper side of the external bolt sphere 331. will be.

Here, it should be noted that the chain unit 310 may be installed to be connected to the mounting anchor unit 100 to perform a grounding function.

In addition, the easy fastening hole 340 is formed on the lower side of the nut body 341 and the nut body 341 having a pitch binding hole 343 for screw coupling of the external bolt hole 331, and the body It may be made of a body coupling piece 342 screwed to the upper side of the sphere 360 .

In addition, the link chain unit 350 is formed by sequentially connecting a plurality of circular rings, and it is preferable that the link chain unit of the present invention has a structure in which 3 to 4 circular rings are connected.

Due to the chain unit 310 configured in this way, when vibration occurs due to an earthquake, etc., the cable tray unit 400 connected through the computer bolt unit 200 can be oscillated in multiple directions, so that it can easily respond to vibration. there will be

In addition, the body sphere 360 has an insert hole 361 for the easy fastening sphere 340 to be screwed on the upper side in the longitudinal direction, and the computerized bolt part 200 to extend in the lower side in the longitudinal direction. made to form

In addition, the binding nut sphere 370 is coupled to the upper side in the longitudinal direction of the computerized bolt part 200 extending to the inside of the body sphere 360 , and the elastic spring 380 is the binding nut sphere 370 . It is installed so as to surround the computational bolt part 200 extending inwardly of the body sphere 360 in a state located on the lower side of the .

That is, in the state where the binding nut sphere 370 is screwed to the upper side in the longitudinal direction of the extension stick 240 extending inwardly of the body sphere 360 , the extension stick is located on the lower side of the binding nut sphere 370 . The elastic spring 380 is installed so as to surround the 240 . At this time, a moving pressing unit 371 may be installed between the binding nut sphere 370 and the upper end of the elastic spring 380 .

In addition, the anti-vibration rubber 390 is installed to be connected to the lower side of the elastic spring 380 , and the anti-vibration rubber 390 as an embodiment is seated on the inner lower surface of the body sphere 360 . A support piece 391 for supporting the lower end of the elastic spring 380, and a joint piece 392 formed on the upper side of the support piece 391 to wrap the elastic spring 380 can be configured to include There will be.

That is, by supporting the lower end of the elastic spring 380 by the support piece 391 , the elastic spring 380 continuously strikes the body sphere 360 when vertical vibration due to an earthquake occurs. it was made to do

At this time, the through-hole 393 formed in the vibration-proof rubber 390 is made to have a diameter corresponding to the insert hole 361 formed in the body sphere 360, and the extension stick of the computerized bolt part 200 ( 240) is preferably made to have an outer diameter smaller than the diameters of the through hole 393 and the insert hole 361, which is an extension stick of the computerized bolt part 200 when the cable tray unit 400 swings back and forth. This is so that the 240 can swing within the diameter of the through hole 393 and the insert hole 361 .

As described above, in the present invention, when vibration occurs due to an earthquake, etc. by the chain unit 310, the elastic spring 380, and the vibration-proof rubber 390 of the vibration response unit 300, multi-directional vibration for forward, backward, left and right and up and down. It is possible to easily respond to the damage or damage of the cable tray unit 400 can be effectively prevented.

On the other hand, the cable tray unit 400 is installed so that a plurality of tray members 410 are interconnected via the tray displacement response unit 420, when vibration occurs due to an earthquake, each tray member 410 is individually subjected to vibration It is made to prevent damage to the cable tray unit 400 by making it possible to respond.

At this time, looking at the tray displacement response part 420 as an embodiment, the tray displacement response part 420 includes a mounting unit 430 mounted on an adjacent tray member 410, respectively, and both sides in the longitudinal direction are the It is fixedly installed on the mounting unit 430 and is configured to include a flexible copper part 440 to respond to fluctuations of the tray member.

The mounting unit 430 includes a close contact piece 431 that is installed in close contact with the inner side wall of the tray member 410 and a fixture 434 in close contact with the outer side wall of the tray member corresponding to the close contact piece 431 . ) may be made of a corresponding fixing piece 432 that is fixedly installed through the medium.

In addition, the flexible copper part 440 may be formed of a fixing sphere 441 fixedly installed to the fixing sphere 434 and a copper sphere 442 configured to interconnect the fixing sphere 441 . At this time, the copper sphere 442 is preferably formed in which a plurality of wire strands are entangled, but the present invention is not limited thereto. it's put

In addition, in the present invention, an elastic control unit 500 for adjusting the elastic force of the elastic spring 380 of the vibration response unit 300 may be installed.

That is, the elastic control unit 500 is connected to the moving pressing unit 371 installed to be seated on the upper side in the longitudinal direction of the elastic spring 380 in a state installed outside the lower side of the body sphere 360 to perform a rotation operation. Through the moving pressing part 371 presses the elastic spring 380 to adjust the elastic force.

The elastic adjustment unit 500 as an embodiment has an upper side in the longitudinal direction on the mounting piece 372 formed in the moving pressing unit 371 in a state that the extension stick 240 of the computerized bolt unit 200 is wrapped. A hollow joint moving stick 510 that is screwed, the lower side in the longitudinal direction is formed to extend to the outside of the body sphere 360, and the tooth sphere 511 is formed along the longitudinal direction on the outer periphery, and the joint moving stick A mounting guide 520 having an orthogonal hole 521 that is fitted on the lower side in the longitudinal direction of the 510 and communicated in an orthogonal state, and the joint moving stick in a state installed in the mounting guide 520 It may be configured to include a connector operation tool 530 that is coupled with the toothed sphere 511 of the 510 to move the joint moving stick 510 in the downward direction during a one-way rotation operation.

Here, the orthogonal hole portion 521 is formed to be orthogonal to a passing hole 522 through which the joint moving stick 510 penetrates in the vertical direction, and one side of the passing hole 522, and the connector operation tool 530 . It may be made of an operation tool installation hole 523 in which is installed.

In addition, the connector operation tool 530 is installed to be inserted into the operation tool installation hole 523, the operation piece 531 formed with a corresponding toothed hole 532 corresponding to the toothed hole 511 on the outer periphery; It may be formed of a gripper 533 formed at the end of the manipulation piece 531 so that the user can grip it.

That is, when the joint moving stick 510 is installed to pass through the passing hole 522 , a part of the toothed sphere 511 of the joint moving stick 510 is exposed in the direction of the operation tool installation hole 523 , and such When the connector operation tool 530 is installed in the operation tool installation hole 523 in the state, the toothed tool 511 and the corresponding toothed piece 532 are toothed together to hold the gripping tool 533 When rotating in one direction, the joint moving stick 510 is pulled downward to adjust the elastic force of the elastic spring 380 located inside the body sphere 360 .

In addition, the mounting guide 520 may be installed to be connected to the body sphere 360 via the swing counter 525, and the swing counter 525 is preferably made of an elastic spring having an elastic force. However, the present invention is not limited thereto, and it should be noted that there may be various embodiments such as a wire of a certain length and a stick of a certain length.

In addition, in the mounting guide 520 or the connector manipulator 530, the joint moving stick 510 is pulled downward by the rotation operation of the connector manipulator 530, and the elastic spring 380 is It should be noted that a stopper (not shown) may be installed to prevent the connector manipulation tool 530 from being rotated by the elastic force and the joint moving stick 510 to be returned to its original position.

That is, to fix the connector manipulator 530 so as not to be rotated by the stopper in a state in which the connector manipulator 530 is rotated at a certain number of revolutions, the stopper as an embodiment forms a plurality of holes in the mounting guide, and the connector There may be various embodiments, such as a structure in which a pin inserted into the hole is installed in the operation tool so that the pin is inserted into the hole in a state where the connector operation tool is rotated at a predetermined number of revolutions to prevent rotation of the connector operation tool. It is revealed

On the other hand, the support hanger 450 is mounted on the tray member 410 via the support clip 451, and has a "∪"-shaped structure in cross-section or a "a"-shaped structure in cross-section. It should be noted that there may be examples.

In addition, the mounting anchor part 100 may be installed at regular intervals on the ceiling 10 of the building and have a structure in which bolt coupling holes 130 are formed on the lower side in the longitudinal direction, in which case the upper connector 320 is the bolt coupling. It may be made to have a structure that is screwed into the hole 130 .

Although specific embodiments of the present invention have been described in detail as described above, various modifications may be made to those skilled in the art without departing from the scope of the present invention. Therefore, the scope of the present invention is not limited to the above-described embodiments, and should be defined by not only the claims described below, but also the claims and equivalents.

10: ceiling 100: mounting anchor part
110: anchor body 120: screw joint
200: computerized bolt unit 210: main stick
220: flange nut 230: connecting rod
240: extension stick 250: stopper nut ball
300: vibration response unit 310: chain unit
320: upper connector 330: lower connector
340: easy fastener 350: link chain unit
360: body sphere 370: binding nut sphere
371: moving pressing unit 372: mounting piece
380: elastic spring 390: dustproof rubber
400: cable tray unit 410: tray member
420: tray displacement response unit 430: mounting unit
440: flexible copper portion 450: support hanger
500: elastic control unit 510: joint moving stick
520: mounting guide 530: connector control tool

Claims (5)

A mounting anchor part 100 installed at regular intervals on the ceiling 10 of a building, and a computerized bolt part 200 installed to extend in the direction of the mounting anchor part 100 from the cable tray unit 400 supporting the electric wire cable ), and the mounting anchor unit 100 and the computerized bolt unit 200 are installed to connect the vibration response unit 300 configured to respond to horizontal and vertical vibrations In a cable tray system comprising,
The vibration response unit 300 is a chain unit 310 that is fastenably installed on the mounting anchor unit 100 to respond to horizontal vibration, and the upper side is installed to be connected to the chain unit 310 . A body sphere 360 having a receiving space 362 formed therein, and a binding nut sphere 370 coupled to the upper side in the longitudinal direction of the computerized bolt part 200 extending inside the body sphere 360, and the An elastic spring 380 installed to surround the computerized bolt part 200 extending inside the body sphere 360 in a state located below the binding nut sphere 370, and the body sphere 360. It is installed on the inner lower side and is configured to include a vibration-proof rubber 390 for supporting the elastic spring 380 in a state in which a through hole 393 for penetrating the computerized bolt part 200 is formed,
The moving pressing unit 371 is connected to the moving pressing unit 371 installed to be seated on the upper side in the longitudinal direction of the elastic spring 380 in a state installed outside the lower side of the body sphere 360, and through a rotation operation, the moving pressing unit 371 is the Seismic-resistant cable tray system, characterized in that it further comprises an elastic control unit (500) for adjusting the elastic force by pressing the elastic spring (380).
According to claim 1,
The chain unit 310 is an upper connector 320 that is fastened to the mounting anchor part 100 by screwing, and a lower that is installed to be connected to the body part 360 via an easy fastener 340 . Seismic-resistant cable tray system, characterized in that it comprises a connector (330) and a link chain part (350) installed so that both sides are connected to the upper connector (320) and the lower connector (330).
3. The method of claim 2,
The cable tray unit 400 is a seismic-proof cable tray system, characterized in that a plurality of tray members 410 are installed to be interconnected via a tray displacement response unit 420 .
4. The method of claim 3,
The tray displacement response unit 420 is a mounting unit 430 mounted to the adjacent tray member 410, respectively, and both sides in the longitudinal direction are fixed to the mounting unit 430 to cope with the fluctuation of the tray member. Seismic-proof cable tray system, characterized in that it comprises a flexible copper portion 440 to allow.
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