KR102021357B1 - Cable supporting module and Construction method using the same - Google Patents

Abstract

According to an embodiment of the present invention, a cable support module is a device being fixed on a structure to support a cable and having an earthquake-resistant function, and comprises: a support unit to provide a space in which the cable is placed, and support the cable; and a fixed unit fixed on the structure and connected to the support unit to support the support unit. The support unit includes: a bottom unit on which the cable is placed; and a side wall unit extended from the bottom unit in a height direction to prevent a fall of the cable placed on the bottom unit. The fixed unit includes: a restriction unit fixed on the structure; a connection unit connected to the support unit; and an earthquake-resistant unit to realize an earthquake-resistant function. The earthquake-resistant unit includes: a link unit which is connected to the connection unit, and forms an accommodation space; and a rotating unit connected to the restriction unit, arranged in the accommodation space, and rotated in the accommodation space to realize an earthquake-resistant function. The cable support module further comprises an elastic unit arranged in the accommodation space to realize the earthquake-resistant function of the rotating unit in the height direction.

Description

Cable supporting module and construction method using the same

The present invention relates to a cable support module and a construction method using the same, and more particularly, to a cable support module fixed to a structure and having a seismic function, and a construction method using the same.

In general, large and small diameter cables are arranged along ceilings, floors, and walls in tunnels, factories, and marine structures to supply power and fluids.

Cables laid in this way shall not cause inconvenience to aesthetics or passers-by.

Therefore, a cable tray is used to support and fix the cable in a neat and tidy state.

The cable tray is a support made of a non-flammable or metallic material for supporting a cable. The cable tray includes a pair of side rails having a predetermined length and forming a left / right side, and a horizontal connecting member connecting the side rails to each other in the horizontal direction.

Here, when connecting the ends of the side rail and the horizontal connection member to each other directly fixed by welding or the like, coupling structures are used for convenience such as assembly and disassembly.

When an earthquake or impact occurs in a place where the cable tray is constructed, the cable tray support member is severely shaken from the ceiling RF to the top, bottom, left and right, and the cable tray may be separated from the horizontal member or damaged.

If the cable tray is not completely fixed to the cable tray support member due to the vibration as described above, there is a fear that the cable is cut or damaged to cause a very large damage electrically.

In order to solve this problem, a technique of implementing a seismic function using a wire such as a wire has been invented, but in order to apply the wire, a lot of additional parts such as fastening bolts are required, resulting in complicated assembly and construction difficulties. .

In addition, the connection device for a cable tray in which the seismic function of the Republic of Korea Patent Registration No. 10-1752402 (Jun. 30, 2017) is poor, implements the seismic function by forming the connector (233a, 233b) on both sides of the connecting table 231, In the point that the elastic coil 233 must always support the load of the cable, the elastic restoring force is reduced as time passes by the second elastic coil 233, and the connector formed on the upper side of the connecting table 231 by the enormous load in the event of an earthquake. There is a problem that 233a may be separated from the second elastic coil 233 and fall.

The present invention is to solve the above problems, the seismic function is implemented, the structure is simple, the operator can be easily installed and at the same time safe cable support module that does not drop the cable even during an earthquake and using the same To provide a construction method.

The problem to be solved by the present invention is not limited to the above-described problem, the objects that are not mentioned will be clearly understood by those skilled in the art from the present specification and the accompanying drawings. .

Cable support module according to an embodiment of the present invention is a device fixed to the structure to support the cable and having a seismic function, providing a space for the cable is seated and the support for supporting the cable; And a fixing part fixed to the structure and connected to the support part to support the support part, wherein the support part extends in a height direction from the bottom part on which the cable is seated and the bottom part and is seated on the bottom part. A side wall part for preventing a cable from falling, the fixing part includes a restraining part fixed to the structure, a connection part connected to the support part, and an earthquake-proof part for implementing the seismic function of the support part, and the seismic part is connected to the connection part. And a linking part forming a receiving space and a rotating part connected to the restraining part and disposed on the receiving space and rotating on the receiving space to implement a seismic function, and being disposed on the receiving space in the height direction. It may further include an elastic portion for implementing the seismic function of the rotating portion.

According to the cable support module according to an embodiment of the present invention, but the seismic function is implemented, the structure is simple, the operator can be easily installed and there is a safety advantage that the cable does not fall even during an earthquake.

The effects of the present invention are not limited to the above-described effects, and effects that are not mentioned will be clearly understood by those skilled in the art from the present specification and the accompanying drawings.

1 is a schematic perspective view of a cable support module according to an embodiment of the present invention.
2 is a schematic exploded perspective view of a cable support module according to an embodiment of the present invention.
3 to 5 is a schematic cross-sectional view for explaining the seismic function of the cable support module according to an embodiment of the present invention.
6 and 7 is a schematic cross-sectional view for explaining another embodiment of the seismic portion of the cable support module according to an embodiment of the present invention.
Figure 8 is a schematic cross-sectional view for explaining another embodiment of the seismic portion of the cable support module according to an embodiment of the present invention.
Figure 9 is a schematic cross-sectional view for explaining another embodiment of the seismic portion of the cable support module according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention may deteriorate other inventions or the present invention by adding, modifying, or deleting other elements within the scope of the same idea. Other embodiments that fall within the scope of the inventive concept may be readily proposed, but they will also be included within the scope of the inventive concept.

Cable support module according to an embodiment of the present invention is a device fixed to the structure to support the cable and having a seismic function, providing a space for the cable is seated and the support for supporting the cable; And a fixing part fixed to the structure and connected to the support part to support the support part, wherein the support part extends in a height direction from the bottom part on which the cable is seated and the bottom part and is seated on the bottom part. A side wall part for preventing a cable from falling, the fixing part includes a restraining part fixed to the structure, a connection part connected to the support part, and an earthquake-proof part for implementing the seismic function of the support part, and the seismic part is connected to the connection part. And a linking part forming a receiving space and a rotating part connected to the restraining part and disposed on the receiving space and rotating on the receiving space to implement a seismic function, and being disposed on the receiving space in the height direction. It may further include an elastic portion for implementing the seismic function of the rotating portion.

The elastic part may be disposed below the height direction of the rotating part.

The seismic part may further include a moving part that supports the elastic part and is moved in the height direction on the receiving space so that the elastic force applied to the rotating part is adjusted.

The moving part may be connected to the connection part and connected to the connection part to connect a connection between the connection part and the connection part.

In addition, the moving part may include a movement limiting part for limiting the positional movement in the width direction of the elastic portion disposed on the receiving space.

The apparatus may further include an upper elastic part disposed on the accommodation space to implement a seismic function of the rotating part in the height direction, and disposed above the height direction of the rotating part.

In addition, the linkage portion is provided with a linkage main body forming the receiving space, the width direction size of the receiving space in which the rotating portion is rotated size of the width direction of the rotating portion to increase the rotation range of the rotating portion on the receiving space Can be greater than

The linkage unit may further include a linkage limiter configured to limit a positional movement in the width direction of the upper elastic portion disposed on the accommodation space.

The rotating part may include a rotation limiting part for limiting the positional movement in the width direction of the elastic part disposed on the receiving space.

In addition, it is disposed on the accommodation space to implement the earthquake-resistant function of the rotating part in the height direction, and allows the rotary part to enter the accommodation space from the outside, but restricting the departure from the accommodation space to the outside It may further include an elastic portion.

The construction method for constructing a cable support module according to another embodiment of the present invention may be a method for constructing a cable support module in a structure using the cable support module.

Components having the same functions within the scope of the same idea shown in the drawings of each embodiment will be described using the same reference numerals.

1 is a schematic perspective view of a cable support module according to an embodiment of the present invention.

2 is a schematic exploded perspective view of a cable support module according to an embodiment of the present invention.

3 to 5 is a schematic cross-sectional view for explaining the seismic function of the cable support module according to an embodiment of the present invention.

6 and 7 are schematic cross-sectional views for explaining another embodiment of the seismic unit of the cable support module according to an embodiment of the present invention.

8 is a schematic cross-sectional view for explaining another embodiment of the seismic unit of the cable support module according to an embodiment of the present invention.

Figure 9 is a schematic cross-sectional view for explaining another embodiment of the seismic portion of the cable support module according to an embodiment of the present invention.

In the accompanying drawings, in order to more clearly express the technical idea of the present invention, parts that are not related to the technical idea of the present invention or can be easily derived from those skilled in the art will be simplified or omitted.

First, to define a term for a direction, in FIG. 5, the height direction may mean an up and down direction, and the width direction may mean a direction perpendicular to the height direction, that is, a left and right direction.

As shown in Figure 1 to 5, the cable support module 10 according to an embodiment of the present invention may be a structure that is fixed to the structure to support the cable (C).

The structure may be an architectural or civil engineering structure such as a building, a bridge, or the like, and may refer to any architectural or civil engineering structure in which the cable C is installed.

The cable support module 10 may be configured to support the cable C, but is not limited thereto. The cable support module 10 may be disposed on the structure as well as the cable C. It may be a configuration for supporting all objects that can be placed at a predetermined position of the structure.

The cable support module 10 may be fixed directly or indirectly to the ceiling, wall, and the like of the structure.

Here, the cable support module 10 provides a space in which the cable C is seated and is fixed to the support part 100 and the structure supporting the cable C and connected to the support part 100 so as to support the support part 100. It may include a fixing part 200 for supporting the (100).

In more detail, the support part 100 provides a space in which the cable C is seated to support the cable C so that the cable C can be positioned on the support part 100. Can be.

The fixing part 200 is directly or indirectly fixed to the structure, and is directly or indirectly connected to the support part 100 to receive the loads of the support part 100 and the cable C and transmit the same to the structure. It may be a configuration.

Therefore, the support part 100 and the cable C seated on the support part 100 may be supported by the fixing part 200 at a predetermined position of the structure and may not fall.

Here, for example, the support part 100 extends in the height direction from the bottom part 110 and the bottom part 110 in which the cable C is seated, and the cable seated on the bottom part 110 ( The side wall part 120 which prevents the fall of C) may be provided.

For example, the bottom portion 110 may be connected to and / or seated on the side wall portion 120.

For example, the bottom part 110 may be disposed to be spaced apart from each other along the side wall part 120.

The cable C may be seated or connected to the bottom part 110 to be supported by the bottom part 110.

The side wall part 120 may be configured to prevent the cable C seated on the bottom part 110 from being moved from the bottom part 110 by moving in the width direction by an external force.

For example, the side wall part 120 is disposed on the left and right sides of the support part 100, respectively, to limit the positional movement of the cable C seated on the support part 100 to drop the cable C. Can be prevented.

Here, as an example, the fixing part 200 is a seismic part (210) fixed to the structure, a connection part 220 connected to the support part 100 and an earthquake-resistant part for implementing the seismic function of the support part 100 ( 230 may be provided.

For example, the restraining part 210 is a component fixed to the structure, and may be directly or indirectly fixed to the ceiling, wall, or the like of the structure by an anchor or another fixing member.

For example, the restraining part 210 may be fixed to the ceiling of the structure and extend downward from the ceiling in the height direction.

In one example, the connection portion 220 is a configuration that is connected to the support portion 100, may be directly connected to the support portion 100, is connected to the coupling member (K) connected to the support portion 100 to the support portion ( The load of 100 may be indirectly transmitted.

For example, the connection between the connection part 220 and the support part 100 may be a concept including a direct / or indirect mechanism through which the connection part 220 may receive a load from the support part 100.

For example, the connection part 220 may be directly or indirectly connected to the support part 100 and extend in an upper direction of the height direction.

For example, the seismic unit 230 may be configured to limit the vibration of the structure is transmitted to the support unit 100 when an earthquake occurs.

That is, the seismic function of the support part 100 may mean a function of limiting the vibration generated in the structure to the support part 100 when an earthquake occurs.

Here, in one example, the seismic portion 230 is connected to the restraining portion 210 and the connecting portion 220, respectively, the load of the support portion 100 transferred from the support portion 100 to the connection portion 220 Received may be delivered to the restraining portion 210.

Here, as an example, the seismic unit 230 is connected to the connecting portion 220 and connected to the linking portion 233 and the restraining portion 210 to form the receiving space (S1) on the receiving space (S1) It is disposed on the receiving space (S1) may be provided with a rotating part 231 for implementing a seismic function.

For example, the rotating part 231 may be configured to rotate and / or move on the receiving space S1 of the linking part 233 by an external force generated by an earthquake or the like.

For example, as the rotary unit 231 is rotated on the linking unit 233, the seismic function of the cable support module 10 may be implemented.

For example, the rotating part 231 may have a spherical shape as a whole.

In one example, the rotating part 231 has a rotating main body portion 231a that is rotated on the receiving space S1 formed by the linking portion 233 and a rotating connecting portion 231b connected to the restraining portion 210. can do.

For example, the restraint part 210 may include a restraint connection part 211 connected to the rotation connection part 231b to correspond to the rotation connection part 231b.

For example, the rotary connector 231b and the restraint connector 211 may have a thread form corresponding to each other.

Therefore, the restraining part 210 and the rotating part 231 may be screwed together.

However, the connection between the restraining part 210 and the rotating part 231 is not limited only to screwing, but may be implemented as an interference fit, a locking engagement, or the like, and further, the restraining part 210 and the rotating part 231. May be integrally formed.

For example, the linking unit 233 may provide the accommodation space S1 in which the rotation unit 231 may be disposed.

The rotation part 231 may be rotated by an external force on the accommodation space (S1).

For example, the linking unit 233 may include a linking body unit 233a forming the accommodation space S1.

In addition, as an example, the linking body portion 233a is a through space in which the restricting portion 210 can pass so that the restricting portion 210 penetrates and extends upward from the accommodation space S1. (S2) can be further formed.

For example, the through space S2 may be formed to allow penetration of the constraining part 210 but prevent separation of the rotating part 231 disposed on the receiving space S1.

Here, for example, the cable support module 10 may further include an elastic portion 300 disposed on the accommodation space (S1) to implement the earthquake-resistant function of the rotating part 231 in the height direction. .

In one example, the elastic portion 300 may be a spring having a predetermined elastic force.

For example, the elastic part 300 may be disposed on the accommodation space (S1) to press the rotating part 231 in the height direction to provide an elastic force to the rotating part 231 in the height direction. .

Therefore, the elastic part 300 may implement a function of buffering the rocking of the rotating unit 231 rocking in the height direction.

For example, the elastic part 300 may be disposed below the height direction of the rotating part 231.

That is, the elastic part 300 may be disposed below the rotation part 231 on the accommodation space S1 to provide an elastic force to the rotation part 231 above the height direction.

Here, in one example, the seismic portion 230 supports the elastic portion 300, the height direction on the receiving space (S1) so that the elastic force applied to the rotating portion 231 by the elastic portion 300 is adjusted. It may be further provided with a moving unit 235 which is moved in position.

For example, the moving part 235 may support the elastic part 300 disposed on the accommodation space S1, and the height direction may be caused by an external force in a state disposed on the accommodation space S1. Moved to implement the function of adjusting the height direction position of the elastic portion 300 disposed on the accommodation space (S1).

Here, for example, the moving unit 235 may be connected to the connection unit 220 and connected to the connection unit 233 to connect the connection between the connection unit 220 and the connection unit 233.

To describe this in more detail, the moving part 235 is disposed on the accommodation space S1 and is connected to the moving body part 235b and the connecting part 220 and the moving fastening part ( 235d).

For example, the linking unit 233 may include a linking fastening unit 233c connected to the moving body unit 235b to correspond to the moving body unit 235b.

For example, the mobile body portion 235b and the linkage coupling portion 233c may be in the form of threads corresponding to each other.

Therefore, the moving part 235 and the linking part 233 may be screwed together.

As a result, the moving part 235 may be fastened to the linking part 233, and may be moved in the height direction by an external force even when fastened to the linking part 233.

However, the connection between the moving unit 235 and the linking unit 233 is not limited to screw coupling, but may be implemented by interference fit, engagement, or the like, and further, the moving unit 235 and the linking unit ( 233 may be integrally formed.

In addition, as an example, the connection part 220 may include a connection fastening part corresponding to the mobile fastening part 235d.

For example, the mobile fastening part 235d and the connection fastening part may have a thread form corresponding to each other.

Therefore, the moving part 235 and the connection part 220 may be screwed together.

However, the connection between the moving part 235 and the connection part 220 is not limited to screw coupling, but may be implemented by interference fit, locking engagement, or the like, and further, the moving part 235 and the connection part 220. May be integrally formed.

As shown in FIG. 4, for example, the moving part 235 may be disconnected from the linking part 233, and at this time, the elastic part 300 disposed on the accommodation space S1. ) And the rotating part 231 may be separated into the lower side of the linking part 233.

Accordingly, when the elastic part 300 and / or the rotating part 231 are damaged, the worker separates the moving part 235 from the linking part 233 and is disposed on the accommodation space S1. The elastic part 300 and / or the rotating part 231 may be easily replaced.

Here, as an example, the moving part 235 may further include a moving step part 235c forming a step with the moving body part 235b.

The moving step part 235c may be configured to define a limit in which the moving body part 235b moves in the height direction on the linking part 233.

For example, the moving step part 235c may have a larger outer diameter than the moving body part 235b, and further upwards when the moving body part 235b reaches a predetermined position in the height direction. It may be in contact with the linking unit 233 so as not to move.

For example, at least some of the moving steps 235c may be exposed to the outside without being covered by the linking unit 233.

Here, for example, the moving part 235 may further include a movement limiting part 235a for limiting the positional movement of the elastic part 300 disposed in the accommodation space S1 in the width direction. have.

For example, the movement limiting portion 235a may be disposed on the accommodation space S1 to limit the positional movement in the width direction with respect to the elastic portion 300 disposed on the accommodation space S1. have.

For example, the movement limiting portion 235a may protrude from the moving body portion 235b and may be in contact with the elastic portion 300, but is not limited thereto. If the configuration that can limit the movement in the width direction of the unit 300 may be variously modified.

As shown in FIG. 5, when the earthquake occurs, the cable support module 10 may implement a seismic function as the rotating part 231 is rotated on the linking part 233, and further, the elastic part 300. As a buffer of the swing in the height direction of the rotating unit 231 can be implemented in the height direction seismic function.

Hereinafter, another embodiment of the seismic unit 230 of the cable support module 10 according to an embodiment of the present invention will be described with reference to FIGS. 6 and 7.

The same function, shape, structure, and the like as the seismic unit 230 described above will be omitted for clarity of the invention.

For example, the cable support module 10 is disposed on the accommodation space (S1) to implement the seismic function of the rotating part 231 in the height direction, and is disposed above the height direction of the rotating part 231. It may further include an upper elastic portion 400.

For example, the upper elastic part 400 may be disposed in the accommodation space AS1 to be in contact with the upper side of the rotating part 231.

For example, the upper elastic part 400 may be configured to apply an elastic force to the rotating part 231 to the lower side in the height direction.

Therefore, when an earthquake occurs, the upper elastic part 400 may cooperate with the elastic part 300 to buffer the shaking of the rotation part 231 in the height direction.

In one example, the upper elastic portion 400 may be a spring shape.

For example, the upper elastic part 400 may surround at least a portion of the upper side of the rotating part 231, and the elastic part 300 may surround at least a part of the lower side of the rotating part 231.

As a result, the upper elastic part 400 and the elastic part 300 may not only implement the cushioning of the rotating part 231 in the height direction, but also the cushioning of the rotating part 231 in the width direction. .

Here, as an example, the width direction size of the accommodation space (AS1) to which the rotary unit 231 is rotated to increase the rotation range of the rotary unit 231 on the accommodation space (AS1) It may be larger than the width direction.

To explain this in more detail, as an example, the associated body part A233b may form the accommodation space AS1 larger than the cross section of the width direction of the rotation part 231, and the rotation part 231 may cause an earthquake. It may be disposed on the receiving space AS1 spaced apart from the linking body portion A233b rather than being in contact with the linking body portion A233b in a state where it is not.

For example, the upper elastic part 400 may apply an elastic force to the rotating part 231 downward in the height direction so that the upper side of the rotating part 231 does not contact the linking body part A233b. The rotating part 231 may not be in contact with the associated body part A233b in a state where an earthquake does not occur.

As a result, in the state of FIG. 6 in which the earthquake does not occur, when the state of FIG. 7 in which the earthquake occurs, the rotating unit 231 may increase the rotation range that can be rotated on the accommodation space AS1.

In this case, the upper elastic part 400 and the elastic part 300 not only implements the cushioning in the height direction with respect to the rotating part 231, but also cushions the rotating part 231 in the width direction. Can be implemented.

Here, as an example, the linking unit A233 may further include an linking limiting unit A233a for limiting the positional movement in the width direction of the upper elastic unit 400 disposed on the accommodation space AS1. Can be.

For example, the linkage limiting unit A233a may be formed to extend from the linkage body unit A233b onto the accommodation space AS1, and the upper elastic portion 400 disposed on the accommodation space AS1. You can limit the movement of the position.

In FIGS. 6 and 7, the linking limiting unit A233a is formed to protrude from the linking main unit A233b, but the present invention is not limited thereto. The linking limiting unit A233a may have the upper elasticity in view of those skilled in the art. If the configuration capable of limiting the position movement in the width direction with respect to the unit 400 can be variously modified.

Hereinafter, another embodiment of the seismic unit 230 of the cable support module 10 according to an embodiment of the present invention will be described with reference to FIG. 8.

The same function, shape, structure, and the like as the seismic unit 230 described above will be omitted for clarity of the invention.

In one example, the rotating portion A231 may be circular columnar rather than spherical in shape.

For example, the elastic part 300 may press the lower surface of the rotating part A231, and the upper elastic part 400 may press the upper surface of the rotating part A231.

Here, as an example, the rotating part A231 may include a rotation limiting part for limiting the positional movement of the elastic part 300 disposed in the accommodation space AS1 in the width direction.

For example, the rotation limiting part may be defined as an inner limiting part A231b that restrains the inner surface of the elastic part 300 and an outer limiting part A231c that restrains the outer surface of the elastic part 300.

Therefore, the elastic portion 300 may be limited in the position movement in the width direction by the rotation limiting portion.

Previously, the rotation limiting portion has been described as being defined as the inner limiting portion (A231b) and the outer limiting portion (A231c), but is not limited thereto, and the elastic portion disposed on the receiving space (AS1) ( As long as the position movement restriction in the width direction with respect to 300) can be implemented, various modifications can be made by those skilled in the art.

In addition, as an example, the rotation part A231 may further include a configuration for limiting the positional movement in the width direction with respect to the upper elastic part 400.

For example, the lower side of the upper elastic portion 400 may be inserted into a groove or a step formed by the rotating part A231 to limit the positional movement in the width direction.

In addition, as an example, the moving part 235 may be provided with a groove forming part 235e which forms a groove in cooperation with the movement limiting part 235a to restrict the elastic part 300 from being moved in the width direction. It may be further provided.

For example, the elastic part 300 may be inserted into a groove or a step formed by the movement limiting part 235a and the groove forming part 235e to limit the positional movement in the width direction.

Hereinafter, another embodiment of the seismic unit 230 of the cable support module 10 according to an embodiment of the present invention will be described with reference to FIG. 9.

The same function, shape, structure, and the like as the seismic unit 230 described above will be omitted for clarity of the invention.

For example, the cable support module 10 is disposed on the accommodation space (BS1) to implement the seismic function of the rotating part 231 in the height direction, the rotating part 231 from the outside of the receiving space ( Allowing entry into BS1, but may further include a limiting elastic portion 500 to limit the departure from the receiving space (BS1) to the outside.

For example, the linking part B233 may form a groove B233a in which the limiting elastic part 500 is disposed.

In the present embodiment, the linkage portion B233 may be a configuration related to the linkage portion described in Korean Patent Application No. 10-2018-0039059 (April 4, 2018. 04. Application), wherein the limiting elastic portion 500 is It may be a configuration related to the first elastic portion described in Republic of Korea Patent Application No. 10-2018-0039059 (application April 4, 2018), and therefore, Republic of Korea Patent Application No. 10-2018-0039059 (April 04, 2018) The contents of the (Application) can be included in all of the present specification.

That is, the limiting elastic part 500 not only realizes the cushioning of the rotating part 231 in the height direction but also allows the rotating part 231 to enter the receiving space BS1 from the outside, but the receiving space ( The departure to the outside from the BS1) may be configured to prevent.

The various embodiments described above are not limited to the described embodiments, and at least two or more of the embodiments may be combined with each other.

In addition, the construction method for constructing the cable support module 10 according to another embodiment of the present invention may be a method for constructing the cable support module 10 in the structure using the cable support module 10.

In the above description of the configuration and features of the present invention based on the embodiment according to the present invention, the present invention is not limited thereto, and various changes or modifications can be made within the spirit and scope of the present invention. It will be apparent to those skilled in the art that such changes or modifications fall within the scope of the appended claims.

100: support
200: fixed part
300: elastic part
400: upper elastic portion

Claims (11)

In the cable support module fixed to the structure to support the cable and having a seismic function,
A support for supporting the cable and providing a space in which the cable is seated; And
And a fixing part fixed to the structure and connected to the support part to support the support part.
The support portion,
A bottom portion on which the cable is seated and a side wall portion extending from the bottom portion in a height direction to prevent the cable from falling on the bottom portion;
The fixing portion,
And a seismic part fixed to the structure, a connection part connected to the support part, and an earthquake-proof part implementing the seismic function of the support part.
The seismic part,
A connection part connected to the connection part and forming an accommodation space and connected to the restriction part and disposed on the accommodation space and rotated on the accommodation space to implement a seismic function;
An elastic part disposed on the accommodation space to implement a seismic function of the rotating part in the height direction;
The elastic portion,
Disposed below the height direction of the rotating part,
The seismic part,
It further comprises a moving part supporting the elastic part, the elastic part is moved in the height direction with respect to the linking part on the receiving space so that the elastic force applied to the rotating part,
The connecting portion,
Positioned in the height direction relative to the moving unit,
Cable support module.
delete delete The method of claim 1,
The moving unit,
Is connected to the connecting portion and connected to the linking portion for linking the connection between the linking portion and the linking portion,
Cable support module.
The method of claim 4, wherein
The moving unit,
It includes a movement limiting unit for limiting the positional movement in the width direction of the elastic portion disposed on the accommodation space,
Cable support module.
The method of claim 1,
It is disposed on the receiving space to implement the earthquake-resistant function of the rotating part in the height direction, and further comprising an upper elastic portion disposed above the height direction of the rotating part;
Cable support module.
The method of claim 6,
The link portion,
It is provided with a linking body portion to form the receiving space,
The width direction size of the accommodation space in which the rotating unit is rotated,
Larger than the width direction of the rotating part to increase the rotation range of the rotating part on the receiving space;
Cable support module.
The method of claim 7, wherein
The link portion,
Further comprising a linkage limiting unit for limiting the positional movement in the width direction of the upper elastic portion disposed on the receiving space,
Cable support module.
The method of claim 7, wherein
The rotating part,
It includes a rotation limiting portion for limiting the positional movement in the width direction of the elastic portion disposed on the accommodation space,
Cable support module.
In the cable support module fixed to the structure to support the cable and having a seismic function,
A support for supporting the cable and providing a space in which the cable is seated; And
And a fixing part fixed to the structure and connected to the support part to support the support part.
The support portion,
A bottom portion on which the cable is seated and a side wall portion extending from the bottom portion in a height direction to prevent the cable from falling on the bottom portion;
The fixing portion,
And a seismic part fixed to the structure, a connection part connected to the support part, and an earthquake-proof part implementing the seismic function of the support part.
The seismic part,
A connection part connected to the connection part and forming an accommodation space and connected to the restriction part and disposed on the accommodation space and rotated on the accommodation space to implement a seismic function;
An elastic part disposed on the accommodation space to implement a seismic function of the rotating part in the height direction;
The elastic portion,
Disposed below the height direction of the rotating part,
A restrictive elastic part disposed on the accommodation space to implement the seismic function of the rotating part in the height direction, and allowing the rotation part to enter the accommodation space from the outside, but limiting the deviation from the accommodation space to the outside. More;
The limiting elastic portion,
Disposed above the height direction of the rotating part,
Cable support module.
A construction method for constructing a cable support module in a structure using the cable support module according to any one of claims 1, 4 to 10.

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