JP2000341837A - Cable cleat - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a cable from being dislocated when large current runs through an existing power cable by increasing the clamping force of the cable in relatively simple work. SOLUTION: A clamping stand 2 is fixed on a cable laying passage. A press cover 3 clamps a cable in a cable clamping groove in cooperation with the clamping stand 2. A jointing mechanism 4B joints the press cover 3 with the clamping stand to apply cable clamping force by resilience. A first spacer sheet 16 is put between the clamping stand 2 and the cable. A second spacer sheet 15 is put between the press cover 3 and the cable. The first spacer sheet 16 is constituted of chloroprene rubber and the second spacer sheet 15 is constituted of ethylene-propylene rubber.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cable cleat used for fixing a cable laid in a passage or the like.

[0002]

2. Description of the Related Art When laying a power cable in a tunnel, a cable cleat is used to fix the power cable in a predetermined place. The cable cleats are arranged at predetermined intervals in the sinus, and grip the cable to restrain the cable. Various types of cable cleats of this type have been developed and used (Japanese Utility Model Laid-Open No. 4-72).
No. 825, Japanese Utility Model Laid-Open No. 4-68428).

[0003]

The power cable generates heat due to the transmission current and thermally expands and contracts in the longitudinal and radial directions. This force extends to cable cleats. The cable cleat is designed to strongly restrain the power cable so that even if the cable cleat receives the expansion and contraction force of the cable, the power cable does not shift in the longitudinal direction. However,
In recent years, with an increase in power demand, it is not rare that an excessive current is supplied to an existing power cable beyond the current assumed at the time of design. The power cable itself is designed with a sufficient margin in terms of performance, and the short-time excessive current does not significantly affect the power cable.

[0004] However, when an excessive current flows through the power cable, the expansion and contraction and radial expansion of the power cable increase, and a larger force is applied to the cable cleat than ever. When this force exceeds the gripping force of the cable cleat,
Longitudinal shifts occur in the power cable, resulting in, for example, abnormal bending stresses or tensile forces in the curved portion of the cable. On the other hand, it is conceivable to increase the number of cable cleats in order to increase the binding force of the cable. However, the inside of the cave is generally narrow because various cables are laid, and there is a problem that it is not easy to increase the number of cleats by newly adding a cleat fixing base or the like.

Furthermore, if the gripping force of the cable by the cable cleat is increased unnecessarily in order to increase the restraining force, an excessive force may be applied to the cable jacket, and the cable jacket may be damaged. The present invention has been made focusing on the above points, and by selecting a spacer sheet for gripping an existing cleat cable,
An object of the present invention is to provide a cable cleat which increases the restraining force of a cable and has a stable gripping force even when the cable generates heat due to an excessive current.

[0006]

The cable cleat of the present invention employs the following construction. <Structure 1> A holding table fixed on a cable laying path and having a cable holding groove, a holding cover for holding the cable stored in the cable holding groove in cooperation with the holding table, and the holding cover A coupling mechanism that couples the gripping base to provide a cable gripping force by elasticity, a first spacer sheet sandwiched between the gripping base and the cable, and between the holding cover and the cable. A cable cleat, comprising: a second spacer sheet sandwiched between the first spacer sheet and the second spacer sheet, wherein the first spacer sheet is made of chloroprene rubber, and the second spacer sheet is made of ethylene propylene rubber.

<Structure 2> A holding table fixed on a cable laying path and having a cable holding groove, a holding cover for holding the cable stored in the cable holding groove in cooperation with the holding table, A connection mechanism for connecting the presser cover and the gripper to apply a cable gripping force by elasticity, a first spacer sheet sandwiched between the gripper and the cable, the presser cover and the cable, A second spacer sheet interposed between the first spacer sheet and the second spacer sheet, both of which are made of an elastic body, and one of the elastic bodies has a higher mechanical strength than the other. A cable cleat comprising:

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below using specific examples. 1A and 1B are diagrams for explaining a cable cleat of the present invention, in which FIG. 1A is a top view of the cable cleat, FIG. 1B is a partially cutaway cross-sectional view of the cable cleat viewed from the front, and FIG. Is a bottom view and (d) is a side view.

As shown in FIG. 1B, the cable cleat has a structure in which a cable (not shown) is gripped by a gripping base 2 and a pressing cover 3. The cable is
It is arranged on the holding groove 10 of the holding table 2. Both the holding table 2 and the pressing cover 3 are constituted by a half-pipe-shaped part for holding the cable and rib parts protruding on both sides. A mechanism for connecting the holding table 2 and the presser cover 3 is provided in the rib portions protruding on both sides.

This connecting mechanism is provided symmetrically as shown in the figure. In each connection mechanism, a spring 17 is disposed inside as shown in FIG.
The grip 2 and the presser cover 3 are connected by a bolt 7B and a lock nut 8B penetrating through the lock 7.

The spring 17 applies a cable gripping force to the gripping base 2 and the pressing cover 3 by its elasticity. The structure of the coupling mechanism itself is similarly employed in the conventional cable cleat described above.

As shown in FIG. 1C, a bolt hole 9 is provided in the leg 6 of the gripping base 2 and is fixed to a cleat fixing base 13 by a bolt 11 and a nut 12 shown in FIG. It is configured to: Cleat fixing base 13
Is fixed by being embedded in the wall of a cave.

Although a cable (not shown) is gripped by the holding table 2 and the holding cover 3 shown in FIG.
Is made of a hard metal such as an aluminum alloy. Therefore, the cable may be damaged if pressed directly onto the cable jacket. Therefore, spacer sheets 15 and 16 made of a rubber sheet or the like are sandwiched between the holding table 2 and the pressing cover 3 on the surfaces in contact with the cables.

According to the present invention, each spacer sheet is made of an elastic material, and one of the spacer sheets is made of an elastic material having a higher mechanical strength than the other. For example, in this example, chloroprene rubber is used for the first spacer sheet 16 and ethylene propylene rubber is used for the second spacer sheet 15. That is, the spacer sheet provided on the side of the holding cover 3 was made to be an elastic body having higher mechanical strength than the spacer sheet provided on the side of the holding table 2.

FIG. 2 shows an example of a test apparatus for performing a test for evaluating the binding force of the cable cleat according to the present invention.
(A) is a side view of a test apparatus, (b) is a front view of a test apparatus. As shown in FIG. 1A, this test apparatus has a structure in which a frame 22 is vertically mounted on a test table 21. The holding table 2 is fixed to the frame 22, and the test cable 1 is set to be held by the holding cover 3. This is set to exactly the same state as actually holding the cable 1 inside the sinus. Then, a test pressure is applied to the cable 1 vertically downward, that is, in the direction of the arrow in FIG. This pressure is selected in consideration of the force applied to the cable cleat by the thermal expansion and contraction of the cable 1. The illustration of the press arm 23 is omitted in FIG.

As shown in these figures, the cable 1 is cut to a predetermined length for testing. The cable 1 or the entire cable cleat is heated by a heater (not shown) to a required test temperature. This temperature is the temperature during normal use of the cable, and is left for a certain period of time. As a result of this test, even if chloroprene rubber was used for the first spacer sheet 16 and ethylene propylene rubber was used for the second spacer sheet 15 as in the above example, the displacement between the cable and the cable cleat was still small. Did not occur. That is, it was proved that the cable gripping force was equal to or higher than that of the conventional product.

FIG. 3 is an explanatory view showing a heat cycle test apparatus for cable cleats. Next, a test is performed to determine whether or not the cable cleats have predetermined characteristics in an environment during actual operation of the power cable. For this purpose, as shown in the figure, the cable 1 is fixed in the same state as the test apparatus of FIG. That is, the gripper 2 is fixed to the panel 24, and the test cable 1 is set so as to be gripped by the holding cover 3. Both ends of this cable are terminated and the terminals 25
And 27 are crimped. A power supply 26 is connected to the terminal 25,
The terminal 27 is connected to the ground side of the power supply 26. The power supply 26
As will be described later, the cable 1 is energized to generate heat. The cable 1 is suspended so that its axis is vertical, and a predetermined load is applied by a weight 28 in the direction of the arrow in the figure. The length of the cable 1 is 3 meters. The designed maximum gripping force of the cable cleat is 130 kg weight for a single-core cable with a conductor cross section of 2000 square millimeters and a conductor cross section of
The weight was 60 kg with a three-core cable of 00 square millimeters.

The cable cleat of the present invention described above was subjected to a verification test. In this test, the first spacer sheet 1 was tested using a test device as shown in FIG.
6 and the second spacer sheet 15 are both made of CR rubber, and the first spacer sheet 16 is made of EPDM rubber,
Was compared with the case where the spacer sheet 15 was CR rubber.
As a result, it was confirmed that no abnormal displacement occurred and that no harmful damage or deformation occurred in the cable core.

The CR rubber is chloroprene rubber and the EPDM rubber is ethylene propylene rubber, all of which are widely used for cable coating and cable accessories. In this example, the CR rubber has a hardness of 45 (JIS A
EDPM rubber with a hardness of 85
Was used. The physical properties of CR rubber are that its tensile strength is 50-250 kilograms per square centimeter,
The elongation was 100-1000%, the specific gravity was 1.15-1.25, and the maximum service temperature was about 130 ° C.

The physical properties of ethylene propylene rubber are as follows:
Tensile strength of 50-20 per square centimeter
0kg, elongation 100-800%, specific gravity 0.86-0.87,
The maximum service temperature was about 150 ° C.

A heat cycle test is performed by repeating a cycle in which the cable is energized for 8 hours and the energization is stopped for 4 hours using the above-described test apparatus. At this time, the cable generates heat due to the supplied current, and returns to the outside temperature when the supply of power is stopped. The test was carried out when the maximum temperature reached 105 ° C. was defined as the state of use when the overload current was applied, and when the maximum temperature reached 120 ° C., the state was defined when the fault current was applied. To change the maximum attainable temperature, the energizing current may be changed. The weight 2 is set so that the gripping force for gripping the cable by the cable cleat becomes the maximum gripping force in the design of the cable cleat described above.
Select a weight of 8. In this state, every time one heat cycle is completed, a change in the position of the cable from the reference position is measured to determine the slippage amount. At first, repeat the heat cycle with the maximum temperature of 105 ° C 50 times, then
A heat cycle having a maximum temperature of 120 ° C. was repeated three times. Thereafter, a heat cycle having a maximum temperature of 105 ° C. was repeated five times.

As a result of the test under the above conditions, when all the spacer sheets were made of CR rubber, when 10 heat cycles were completed at the maximum temperature of 105 ° C.,
The cable slipped over 50 mm. That is, under the condition that the maximum temperature is 105 ° C., the above-mentioned cable cleat does not have sufficient performance to restrain the cable. Therefore, this cable cleat cannot withstand use when an overload current is applied.

On the other hand, when the first spacer sheet was made of EPDM rubber and the second spacer sheet was made of CR rubber, the cable did not slip down by 10 mm or more even after repeating the heat cycle 50 times. .

Thereafter, a heat cycle having a maximum temperature of 120 ° C. was repeated three times. Even in such a state, the first spacer sheet is made of EPDM rubber,
When CR rubber is used as the second spacer sheet, no movement of the cable is observed, and a sufficient restraining force is obtained.

In order to obtain a sufficient restraining force at a high temperature, it is preferable that all the spacer sheets are made of an elastic material having high mechanical strength. However, if the spacer sheet is too hard, there is a possibility that a force that has a bad influence on the outer jacket of the cable may be given by a force for gripping the cable by the cable cleat. Therefore, in the present invention, one spacer sheet is made of an elastic body having high mechanical strength, and the other spacer sheet is made of an elastic body having low mechanical strength.

EPDM rubber has a somewhat hard property as a cushion at normal temperature or normal use temperature. On the other hand, CR
Rubber has sufficient elasticity at room temperature. Therefore, when the cable is gripped by the cable cleat of the present invention, the CR rubber serves as a cushion, absorbs the force applied to the cable, deforms, and protects the cable. On the other hand, when the temperature rises, C
The R rubber is softened and the mechanical strength is insufficient. Therefore, if all the spacer sheets are made of CR rubber, the gripping force is insufficient and the cable is displaced. On the other hand, when one spacer sheet is made of EPDM rubber as in the present invention, the EPDM rubber exhibits an appropriate elasticity at a high temperature and maintains the gripping force of the cable.

Further, the structure according to the present invention has the following effects. Conventionally, a spacer sheet made of CR rubber has been used for the cable cleats of the existing track, both on the holding table side and on the holding cover side. If both spacer sheets are to be replaced with a new material in order to increase the restraining force, the holding cover 3 is removed from the holding table 2, and the cable is lifted from the holding groove 10 of the holding table 2, and the holding table 2 The side spacer sheet must be replaced. However, when such a work is performed, heavy equipment for stopping power transmission or carrying a cable to lift the cable is required to perform a large-scale construction.

However, if only the work of replacing the spacer sheet on the side of the presser cover 3 with a new one having a higher mechanical strength as described above, the presser covers 3 of the cable spacers are removed one by one while the power transmission is continued. Remove it and replace the spacer sheet. Accordingly, the construction is greatly simplified.

The present invention is not limited to the above example. The shapes of the holding table and the holding cover are not limited to the above examples, and any shape may be used as long as the cable is held and held by using a spacer sheet. In the above example, the chloroprene rubber is used as the first spacer sheet sandwiched between the holding table and the cable. This is because replacement work of an existing one is considered. In the case of new construction, one of them may be made of chloroprene rubber and the other is made of ethylene propylene rubber. In any case, if one of the elastic members has high mechanical strength, the above object is achieved.

[0030]

As described above, the cable cleat according to the present invention can be comparatively made by selecting an optimal spacer sheet between the holding table and the cable and between the holding cover and the cable. With simple construction, the gripping force of the cable can be increased, and the displacement of the cable when an excessive current flows through the existing power cable can be prevented.

[Brief description of the drawings]

FIG. 1 is a view for explaining a cable cleat of the present invention, in which (a) is a top view of the cable cleat, (b) is a partially cutaway sectional view of the cable cleat as viewed from the front,
(C) is a bottom view and (d) is a side view.

FIG. 2 shows an example of a test apparatus for performing a test for evaluating the binding force of the cable cleat of the present invention, wherein (a) is a side view of the test apparatus and (b) is a front view of the test apparatus.

FIG. 3 is an explanatory diagram showing a heat cycle test device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Cable 2 Grasping base 3 Holding cover 4B Connecting mechanism 6 Leg 15 Second spacer sheet 16 First spacer sheet 17 Spring

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Toshiya Matsui 4-1 Egasakicho, Tsurumi-ku, Yokohama-shi, Kanagawa Prefecture Inside the Electric Power Research Laboratory, Tokyo Electric Power Company (72) Kumiko Kunii E, Tsurumi-ku, Yokohama-shi, Kanagawa Prefecture 4-1, Gasaki-cho, Tokyo Electric Power Company, Electric Power Research Laboratory (72) Inventor Osamu Tanda 2-1-1, Sakae Oda, Kawasaki-ku, Kawasaki-shi, Kanagawa Prefecture Showa Electric Wire & Cable Co., Ltd. F-term (reference) 3H023 AA04 AB07 AD26 AD38 5G369 AA10 AA13 BA05 CB01

Claims (2)

[Claims] 1. A holding table fixed on a cable laying path and having a cable holding groove, a pressing cover for holding a cable housed in the cable holding groove together with the holding table, and the pressing cover And a holding mechanism for connecting the holding table and the holding table to provide a cable holding force by elasticity; a first spacer sheet sandwiched between the holding table and the cable; and a connection between the holding cover and the cable. And a second spacer sheet sandwiched between the first and second spacer sheets, wherein the first spacer sheet is made of chloroprene rubber, and the second spacer sheet is made of ethylene propylene rubber. 2. A holding table fixed on a cable laying path and having a cable holding groove, a pressing cover for holding a cable housed in the cable holding groove together with the holding table, and the pressing cover. And a holding mechanism for connecting the holding table and the holding table to provide a cable holding force by elasticity; a first spacer sheet sandwiched between the holding table and the cable; and a connection between the holding cover and the cable. A first spacer sheet and the second spacer sheet are both formed of an elastic body, and one of the first spacer sheet and the second spacer sheet is formed of an elastic body having higher mechanical strength than the other. A cable cleat characterized in that: