JP7248768B1 - Device for suppressing core displacement of cables - Google Patents

Abstract

A device for suppressing displacement between a core and a sheath of a cable is provided. SOLUTION: In a cable core deviation suppressing device A having a device B for constraining a cable 1 led out from a handhole or the like into a pipeline within the handhole or the like 2, the cable 1 is bent into a snake shape and the top portion thereof is bent. It is fixed by a spring-loaded cleat 7a, and the cable 1 at both ends of the snake-shaped straight portion is fixed by two spring-loaded cleats bc, respectively, and the top spring-loaded cleat 7a and two spring-loaded cleats 7b on both sides thereof are fixed. , 7c are vertically or horizontally reversed, and the spring-equipped cleats 7 are supported and fixed in a hand hole or the like. [Selection drawing] Fig. 1

Description

TECHNICAL FIELD The present invention relates to a device for suppressing displacement between a sheath and a conducting portion (core) caused by cable moving force inside manholes, handholes, U-shaped troughs, etc. of underground power transmission lines.

When laying the high voltage or special high voltage cable 1 used for the underground power transmission line in a manhole or a handhole, as shown in FIG. In order to absorb expansion and contraction of the cable 1 due to heat, the cable 1 is bent in a snake shape and provided with an offset portion 4. - 特許庁In addition, a large sliding force of the cable 1 is generated in a pipeline having a difference in height between the insides of the handhole 2, and the connecting portion 3 may be affected. In addition, when a vehicle travels on a road on an underground railroad track, there is a risk that the cable 1 will move due to the so-called wave riding phenomenon due to the vehicle traveling a number of times. In order to prevent movement of these cables 1, movement restraint measures are taken using restraining devices such as cable cleats.

Cleats that grip and fix the cable by applying pressure from the outside are often used as a measure to suppress this movement. If the tape is 0.2 MPa or less and the copper wire is 0.23 MPa or less, the cable may be damaged.

Conventionally, various structures have been developed in which the cleat prevents movement of cables such as manholes.

The one disclosed in Patent Document 1 is one of them, and is a cable restraining method for restraining a cable moving by a wave-riding phenomenon in a manhole on the side where this cable is pulled. After clamping the cable that is being pulled by the wave riding phenomenon, the frame 44 is supported against the pulling force acting on the cable. The amount of projection from the frame 44 of the plurality of rods 50 provided in the manhole is individually adjusted, and the frame 44 is supported on the inner wall of the manhole through these rods 50 .

Patent Document 2 is another example, and is a cable restraining device for restraining a cable 4 that is about to move due to a wave-riding phenomenon within a manhole 2, and has a clamp portion 41 that clamps the cable 4. a frame 50 for supporting the cleat 40; and a frame 50 for supporting the cleat 40; at least a pair of frame fixing portions 60 fixed to the frame 50; at least a pair of steel fixing portions 30 fixed to the pair of steel members; a pair of frame fixing portions 60; and a pair of steel fixing portions. 30 , and is provided with a connecting member 70 capable of adjusting the distance between the pair of frame fixing portions 60 and the pair of steel material fixing portions 30 .

Japanese Unexamined Patent Application Publication No. 2014-39402 Japanese Patent Application Laid-Open No. 2019-68502

However, although both of the above Patent Documents 1 and 2 have been developed for the purpose of suppressing the wave-riding phenomenon, these restraints are capable of adjusting the supporting posture of the cleat according to the inclination of the cable heading from inside the manhole or the like to the conduit opening. It is a device and does not directly increase the binding force of the cable.

In general, each cleat has a restraining force of 100 kgf. For example, seven cleats are required to stop a cable moving force of 700 kgf, and moreover, the cleats must be spaced apart. If so, 100% of the binding force for the installed number cannot be secured. That is, 1,300mm of cable straight is required for the installation of 7 cleats.

On the other hand, in recent years, the number of renewable energy projects has increased, and when laying the privately-owned lines (underground transmission lines) necessary for these projects, inexpensive and small handholes and troughs have been adopted to reduce costs. In some cases, there is no space to prevent the cable from moving due to sliding or wave riding, and sufficient offset may not be obtained. When arranging the above 7 cleats, it is necessary to extend the handhole and U-shaped trough.

In addition, as shown in FIGS. 15 and 16, the cable 1 used in the underground power transmission line has a core 1a structurally wound with a sheath 1b as an anticorrosion layer. The outer peripheral surface of the core 1a is covered with a copper tape or a copper wire, but the core 1a and the sheath 1b are integrated by adhesive force (frictional force) and are not physically fixed. . Therefore, when a tensile force (axial force) greater than the adhesive force is applied only to the core 1a or the sheath 1b, an event occurs in which the core 1a slips out (displaces) from the sheath 1b.

Also, if the existing cleat is tightened to increase the binding force, the cable 1 may be damaged. Integrating the core 1a and the sheath 1b with an adhesive or the like is impossible due to the structure of the cable.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a device for suppressing displacement between the core and the sheath of a cable in order to solve the above-described problems.

The invention according to claim 1 is a cable core misalignment having a device for restraining a cable led out into a pipeline from a handhole , a manhole, or a U-shaped trough in any one of the handhole, manhole, or U-shaped trough. In the restraint device, a cable is bent into a snake shape, the top of which is fixed by a cleat with springs, and the straight portions of the cable at both ends of the snake are fixed by two cleats with springs, respectively, and the cleats with springs at the top are fixed. The mounting directions of the two cleats with springs on both sides are reversed by 180 degrees, and the pedestal of the cleats with springs on the top is arranged on the concave side of the cable bent into a snake shape, and the two cleats on both sides are arranged. The spring-equipped cleat pedestal is arranged on the top side of the cable , and each of these spring-equipped cleats is supported and fixed in any of a handhole, a manhole, or a U-shaped trough to provide a device for suppressing core displacement of a cable.

In the invention according to claim 2, the device for restraining the cable in any one of a handhole, a manhole, or a U-shaped trough includes a spacer and a cleat with a spring that covers the outer circumference of the spacer, and covers the outer circumference of the cable. a stopper made of rubber or synthetic resin having a tubular outer periphery and having one end in contact with one end face of the spacer on the side end face of the cleat opposite to the conduit port is placed over the cable and fixed in close contact with the stopper; 2. The cable core deviation suppressing device according to claim 1, wherein one or a plurality of tightening bands for tightening the outer peripheral surface are provided on the outer peripheral surface of the cable.

Further, the invention of claim 3 is the device for suppressing core displacement of a cable according to claim 2, wherein an annular protruded edge is provided on the outer peripheral edge of the stopper that contacts the spacer.

According to the first aspect of the invention, even if the cable is thermally stretched in the cross-sectional direction, it is possible to prevent the core from shifting without damaging the copper tape or the copper wire. When the cable thermally expands and contracts in the cross-sectional direction, the gap between the cleat upper side and the pedestal side increases against the pressing force of the spring, which increases the width of the snake and increases the frictional force. It becomes a change in shape in which the force to stop the core becomes larger.

This method does not damage the cable's copper tape or copper wire shielding layer, and only applies force to the cleat's base side support material, ensuring sufficient strength to maintain the snake shape.

Further, according to the invention of claim 2, in addition to the effect of the invention of claim 1, the cable can be fixed by simply providing one cleat with a spring and a stopper having one end in contact with the cleat, which has been conventionally used, on the outer circumference of the cable. movement can be suppressed. In other words, the device of the present invention has a stopper attached to the outside of the cable to counteract the pulling force of the cable when it hits the cleat.

As a result, this cable movement suppressing device does not move even when subjected to a load (500 kgf or more) greater than that in the case where five conventional cleats with springs are fixed to the cable at intervals. Therefore, even if the device is small, it has a large deterrent force, so that the device as a whole is small and does not take up much space, so that it can be used in manholes, handholes, U-shaped troughs, and the like in small spaces.

Further, according to the third aspect of the present invention, since the outer peripheral edge of the stopper that contacts the cleat spacer is provided with an annular protruding edge, even if a tensile force is generated in the cable, the cleat spacer will not be affected. Since the entire end surface of the annular flange is in contact and the contact area is large, a stronger resistance is generated and movement of the tightening band in the direction of the cleat can be prevented, resulting in a high cable movement suppression effect.

1 is a schematic configuration side view of a device for suppressing core displacement of a cable according to Embodiment 1 of the present invention; FIG. FIG. 2 is an enlarged side view of a spring-equipped cleat of the device for suppressing core displacement of a cable according to Embodiment 1 of the present invention; FIG. 4 is a cross-sectional view of the device for suppressing core deviation for cables according to Embodiment 1 of the present invention, in the state of installation in the U-shaped groove. FIG. 4 is a schematic diagram showing an operating state of the device for suppressing core displacement of a cable according to Embodiment 1 of the present invention; It is a side view which shows the use condition of the cable displacement suppression apparatus used for the core displacement suppression apparatus of the cable of Embodiment 1 of this invention. FIG. 3 is a front view of a cleat with a spring of the cable movement suppressing device used in the cable core deviation suppressing device of Embodiment 1 of the present invention; FIG. 3 is a side view of a cleat with a spring of the cable movement suppressing device used in the cable core deviation suppressing device of Embodiment 1 of the present invention; FIG. 4 is a side view of a stopper of the cable movement suppressing device used in the cable core deviation suppressing device of Embodiment 1 of the present invention; FIG. 8 is a cross-sectional view taken along the line XX of FIG. 7 of the stopper of the cable movement suppressing device used in the cable core deviation suppressing device of Embodiment 1 of the present invention; FIG. 4 is a perspective view of a tightening band of a stopper of the cable movement suppressing device used in the cable core displacement suppressing device of Embodiment 1 of the present invention; FIG. 4 is a side view of a state in which a tightening band is attached to a stopper of the cable movement suppressing device used in the cable core deviation suppressing device of Embodiment 1 of the present invention; FIG. 7 is a side view showing a state of use of another example of the cable movement suppressing device used in the cable core deviation suppressing device of Embodiment 1 of the present invention. FIG. 2 is a side view showing a test state of the device for suppressing core displacement of a cable according to Embodiment 1 of the present invention; BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view of a hand hole used in a device for suppressing cable core displacement and a device for suppressing cable movement used therein according to Embodiment 1 of the present invention; BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a three-core cable used in a device for suppressing core displacement of a cable according to Embodiment 1 of the present invention; 1 is an enlarged cross-sectional view of a single-phase 1/4 of a cable used in the device for suppressing core displacement of a cable according to Embodiment 1 of the present invention; FIG.

(Embodiment example 1)
First, the cable movement suppressing device B used in the cable core deviation suppressing device A of Embodiment 1 of the present invention will be described with reference to FIGS. 5 to 11. FIG.

As shown in FIG. 5, this cable movement suppressing device B has a frame that supports the cable 1 at the conduit opening 5 in the U-shaped groove 21 provided in the underground power transmission line on the side wall of the conduit opening 5. 6, a stopper 8 is fixed to the outer periphery of the cable 1 beside the spring-equipped cleat 7, and the outer periphery of the stopper 8 is gripped by a tightening band 9.

The spring-equipped cleat 7 is an existing one, and as shown in FIGS. A downward recessed semi-curved upper frame 12 is provided, and bolts and nuts 13 are used to fasten and fix the lower frame 11 and the upper frame 12 at their respective ears.

Further, spring portions 14 are provided on the ear portions on both sides of the upper frame 12. In each spring portion 14, the bolts of the bolts and nuts 13 are extended, and springs 14a are provided on the outer periphery of the bolts. A spring 14a always urges the upper frame 12 against the lower frame 11 with a constant pressure.

In addition, a rubber cylindrical spacer 15 is provided in the circular portion formed on the inner periphery of the lower frame 11 and the upper frame 12, and a cable fitting hole 16 penetrating through both ends is provided inside the spacer 15. ing. The pedestal 10 is provided with bolts and nuts 10a on both sides thereof for attaching the cleat 7 with a spring to the base 6. As shown in FIG.

The stopper 8 is made of the same material as the spacer 15. As shown in FIGS. 8 and 9, the stopper 8 has substantially the same shape and size as the spacer 15. A projecting edge 17 is provided, and a cable fitting hole 18 penetrating through both ends is provided inside the stopper 8 .

In the first embodiment, the stopper 8 is made of the same material and has substantially the same size as the spacer 15. However, other materials may be used as long as they are in close contact with the cable 1. FIG. Further, the size (width) of the stopper 8 is 100 mm or more, and the flange or the entirety of the stopper 8 is required to have a thickness that prevents it from entering the cleat 7 with spring. In addition, when the stopper 8 is pressed against the cleat 7, the peeling of the stopper 8 from the cable 1 begins with the lifting of the adhesive surface. Further, it is necessary that the entire one end surface of the stopper 8 is in contact with the cleat 7 .

Furthermore, in Embodiment 1 above, the annular projecting edge 17 is provided on both outer peripheries of the stopper 8 , but the annular projecting edge 17 may be provided only on one end perimeter of the stopper 8 on the cleat 7 side.

The tightening band 9 is a narrow binding band, as shown in FIG. A plurality of tightening bands 9 are fixed to the outer periphery of the stopper 8 at such intervals that the adhesive surface does not float when a load is applied, and the outer periphery of the stopper 8 is tightened to compensate for the hardness of the stopper.

Alternatively, instead of this tightening band 9, as shown in FIG. 10, a single thick tightening band 19 is prepared, and both ends of the band are held together by fasteners 20 provided at one or both ends of the tightening band 19. fix the part. Then, as shown in FIG. 11, the outer circumference of the stopper 8 sandwiched between the annular protruding edges 17 at both ends of the stopper 8 is substantially covered with a tightening band 19 and fixed with a stopper 20 to tighten and fix the stopper 8 from above. , to compensate for the hardness of the stopper and prevent the adhesive surface from floating and peeling.

This cable movement suppressing device B is constructed as described above, and as shown in FIG. The attached clique 7 is fixed to the pedestal 6. Then, one end of the stopper 8 is brought into contact with one end of the spacer 15 on the side opposite to the conduit port 5 , and the stopper 8 is fixed to the outer circumference of the cable 1 . The stopper 8 is attached in close contact with the outer periphery of the cable 1 using an adhesive.

The outer periphery of the stopper 8 attached to the cable 1 is covered with the plurality of or singular tightening bands 9 or 19, and the outer periphery of the stopper 8 is tightened. This completes the installation of the cable movement restraining device B.

FIG. 12 shows a modification of the cable movement restraint device B. In this cable movement restraint device B, stoppers 8 are fixed to the cables 1 on both sides of the cleat 7 with a spring. A plurality of tightening bands 9 are attached to the outer periphery of each.

Thereby, the movement of the cable 1 can be prevented regardless of which direction the pulling force of the cable 1 is.

Next, a device A for suppressing core displacement of a cable according to the present invention will be described with reference to FIGS. 1 to 4. FIG.

As shown in FIG. 1 , the cable core deviation suppressing device A constrains the cable 1 in the U-shaped groove 21 with the cable movement suppressing device B, and the cable movement suppressing device B and the connecting portion 3 are separated from each other. The cable 1 is bent upward in a snake shape, the cable 1 at the top of the snake is gripped by the spring-equipped cleats 7a, and the straight cable 1 at both ends of the snake is held by the two spring-equipped cleats 7b, Each is gripped at 7c. The spring-equipped cleats 7a, 7b, and 7c all have the same structure.

As shown in FIGS. 2 and 3, the top spring-loaded cleat 7a is fixed by placing the pedestal 10 on a first channel support member 22 extending in the U-shaped groove 21, and securing the snake. The cleats 7b and 7c with springs at both ends of the cable 1 are fixed upside down by placing the pedestal 10 against the lower surfaces of the second and third channel support members 23 and 24 that extend into the U-shaped groove 21. It is. The first, second and third channel supports 22, 23 and 24 are supported on the inner walls of the U-shaped groove 21 via angle supports 25, respectively.

In this state, when a moving force in the pulling direction is applied to the cable 1 and the cable 1 thermally expands and contracts in the cross-sectional direction, the gap between the upper frame 12 and the lower frame 11 of each cleat 7 with springs becomes This increases the bending width of the snake of the cable 1, as shown by the dashed line in FIG. Become.

As a result of experiments, it was generally found that the movement (displacement) force of the core of the single-core cable or the three-core cable in manholes, handholes, etc. is 4.44 kN (453 kgf). Therefore, as shown in FIG. 13, this device for suppressing core displacement of a cable A was tested. In the test, at 9.8 kN (1,000 kgf), the corrosion protection layer (sheath 1b) began to wrinkle, but the core 1a did not move. When the pulling force was increased, the core 1a did not move, the cable itself started to move, and the hardware fixing the cleat with spring began to bend.

This binding force is more than double the above 4.44 kN, which is estimated to be the maximum force generated when the cable core moves, and is sufficient as a measure to prevent the anti-corrosion layer (sheath 1b) and core 1a from slipping. I was able to confirm that.

In Embodiment 1, the cable 1 is bent vertically (substantially vertically) to form a snake shape, but the cable 1 may be bent horizontally (substantially horizontally) to form a snake. Well, even in that case, the mounting positions of adjacent cleats with springs 7 are reversed. Further, the number of snake shapes is not limited to one, and a plurality of snake shapes may be arranged in the longitudinal direction of the cable 1 and the cable 1 may be restrained by the cleat 7 with springs as in the first embodiment.

Moreover, in the above embodiments 1 and 2, three-core cables have been described, but the cable movement restraining devices A and B can also be used for single-core cables and have the same effect.

Device for suppressing core deviation of A cable
B Cable Movement Suppressing Device 1 Cable 1a Core 1b Sheath 2 Hand Hole, etc. 3 Connection Portion 4 Offset Portion
5 pipe port 6 base 7 cleat with spring 8 stopper
9 tightening band 10 pedestal 10a bolt/nut 11 lower frame 12 upper frame 13 bolt/nut 14 spring portion 14a spring 15 spacer 16 cable fitting hole 17 annular flange 18 cable fitting hole 19 tightening band 20 stopper 21 U-shape groove 22 first channel support 23 second channel support 24 third channel support 25 angle support

Claims (3)

A device for suppressing core displacement of a cable having a device for constraining , in any one of the handhole, the manhole, and the U-shaped trough, the cable leading out into the pipeline from the handhole, the manhole, and the U-shaped trough ,
A cable is bent into a snake shape, the top of which is fixed with a spring-loaded cleat, the straight cables at both ends of the snake-shaped cable are fixed with two spring-loaded cleats, respectively, and the spring-loaded cleat at the top and two spring-loaded cleats on both sides are fixed. The two spring-loaded cleats on both sides of the spring-loaded cleats are arranged in such a way that the mounting direction of the two spring-loaded cleats is reversed by 180 degrees, and the pedestal of the top spring-loaded cleat is placed on the concave side of the cable bent into a snake shape. is disposed on the top side of the cable , and each of these cleats with springs is supported and fixed in any one of a handhole, a manhole, and a U-shaped trough . The device for restraining the cable in any of a handhole, a manhole, or a U-trough includes a spacer and a spring-loaded cleat that wraps around the spacer and the cleat opposite the conduit mouth. A stopper made of rubber or synthetic resin and having a tubular outer periphery and having one end abutted on one end face of the spacer on the side end face of the cable is covered and fixed in close contact with the cable, and the outer peripheral face is tightened to the outer peripheral face of the stopper. 2. The device for suppressing core displacement of a cable according to claim 1, wherein one or more tightening bands are provided. 3. The device for suppressing core displacement of a cable according to claim 2, wherein an annular protruding edge is provided on an outer peripheral edge of said stopper that contacts said spacer.

Images