CN210535978U - High-toughness control cable - Google Patents

Abstract

The utility model provides a high-toughness control cable, which comprises a cable body, wherein two ends of the cable body are detachably connected with a first connector and a second connector, and the first connector and the second connector are detachably connected between two adjacent cable bodies; the outer side of the cable body is provided with a rubber sleeve, and the outer side of the rubber sleeve is provided with a steel mesh reinforcing layer; and a plurality of second reinforcing structures are arranged between the first connector and the second connector and outside the steel mesh reinforcing layer. The utility model discloses at first make the more safety of overall structure through steel mesh back up coat and second reinforced structure combined action.

Description

High-toughness control cable

Technical Field

The utility model relates to the technical field of cables, mainly relate to a high tenacity control cable.

Background

The control cable is a polyvinyl chloride insulation and polyvinyl chloride sheath control cable suitable for industrial and mining enterprises, energy traffic departments, occasions for controlling and protecting lines with the alternating current rated voltage of below 450/750 volts, and the like.

In the conventional control cable, a rubber layer is arranged on the outer side of the cable, and the toughness of the rubber layer is enhanced by the rubber layer.

However, when the cable is pulled or is transported over a long distance, the outer surface of the cable is only depending on the rubber layer, and the cable may be broken when the pulling force is large, and the cable is broken to cause electric leakage, which is not safe.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high tenacity control cable is used for solving the cable that proposes in the background art when the pulling, perhaps when long distance conveying, its surface to singly rely on the rubber layer, probably breaks when receiving the pulling force great, and the cable fracture then can lead to the electric leakage to unsafe technical problem.

In order to achieve the above object, the utility model provides a following technical scheme: a high-toughness control cable comprises cable bodies, wherein two ends of each cable body are detachably connected with a first connector and a second connector, and the first connector and the second connector are detachably connected between every two adjacent cable bodies;

the outer side of the cable body is provided with a rubber sleeve, and the outer side of the rubber sleeve is provided with a steel mesh reinforcing layer;

and a plurality of second reinforcing structures are arranged between the first connector and the second connector and outside the steel mesh reinforcing layer.

Further, first connector inboard is equipped with first recess, the inboard one side of first recess is equipped with a plurality of electrode holes, the second connector includes first connector ring, first connector ring one side is equipped with the second recess, the connection electrode board can be dismantled to the second recess, electrode board one side is equipped with a plurality of electrode bars, and is a plurality of electrode bar sliding connection is a plurality of the electrode hole, just the connecting cable body can be dismantled to electrode board one side, just the electrode board extrusion is connected the second recess, again second recess inner wall is equipped with helical structure, the first clamp plate of helical structure screwed connection, first clamp plate extrusion is connected the electrode board.

Furthermore, first connecting plate, adjacent two first connecting plate bolt fixed connection all are equipped with first connecting plate on first connecting head with first connecting ring one side.

Furthermore, first connector with first connecting ring one side all is equipped with first spout, two equal sliding connection two first sealed cowls of first spout, two first sealed cowls both ends fixed connection.

Furthermore, first connector with second connector one side all is equipped with first bulge loop, all be equipped with the second spout on the first bulge loop, second reinforced structure includes two first stationary rings, two first stationary ring one side all is equipped with first lug, first lug sliding connection the second spout, just first stationary ring one side is equipped with the second lug, the connection can be dismantled to the second lug first connector or the second connector.

Furthermore, a first convex ball is arranged at the bottom of the first convex block, a first spherical groove is arranged in the second sliding groove, and the first convex ball is connected with the first spherical groove in an extrusion mode.

Furthermore, a plurality of third chutes are arranged on the outer side of the first reinforcing ring, first limiting columns are arranged in the third chutes, the first limiting columns are connected with first connecting pieces in a sliding mode, a first reinforcing plate is arranged between the first connecting pieces, and the first connecting pieces and the first limiting columns are fixed through limiting nuts.

Further, first gusset plate side is equipped with the fourth spout, the first sliding block of sliding connection in the fourth spout, first sliding block is type "L" type setting, and is equipped with first slide bar and second slide bar between the adjacent sliding block respectively, second slide bar sliding connection first slide bar, just be equipped with a plurality of first spacing holes on the second slide bar, sliding connection stopper on the first slide bar, the stopper is type "T" style of calligraphy setting, just stopper sliding connection first spacing hole, just the first spacing ring of rubber sleeve outside sliding connection, it is a plurality of the connection can be dismantled to first sliding block first spacing ring.

Further, the steel mesh reinforcing layer comprises a plurality of steel wires, and the steel wires are connected in a staggered mode.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses at first can dismantle the connection through first connector and second connector to be equipped with the steel mesh back up coat outside the rubber tube, thereby realize the tensile anti-bending's of rubber tube self performance.

And be equipped with second reinforced structure in its outside, utilize second reinforced structure to realize holistic secondary reinforcement and make whole structure more stable.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic perspective view of the present invention;

fig. 3 is a schematic structural view of a first connecting plate of the present invention;

fig. 4 is a schematic structural view of a second connector of the present invention;

fig. 5 is a schematic view of a second reinforcement structure of the present invention;

fig. 6 is a schematic diagram of a first reinforcing plate structure of the present invention.

In the figure: 1-a cable body, 2-a first connector, 21-a first groove, 22-an electrode hole, 23-a first connecting plate, 24-a first convex ring, 3-a second connector, 31-a first connecting ring, 32-a second groove, 33-an electrode plate, 34-an electrode rod, 35-a spiral structure, 36-a first pressing plate, 4-a rubber sleeve, a 5-a steel mesh reinforcing layer, 51-a steel wire, 6-a second reinforcing structure, 61-a first reinforcing ring, 611-a third sliding groove, 612-a first limiting column, 62-a first bump, 63-a second bump, 64-a first connector, 65-a first reinforcing plate, 651-a fourth sliding groove, 652-a first sliding block, 653-a first sliding rod, 654-a second sliding rod, 655-first limit hole, 656-limit block, 66-first limit ring.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully with reference to the accompanying drawings, in which several embodiments of the present invention are shown, but the present invention can be implemented in different forms, and is not limited to the embodiments described in the text, but rather, these embodiments are provided to make the disclosure of the present invention more thorough and comprehensive.

In an embodiment, referring to fig. 1 to 6, a high-toughness control cable includes a cable body 1, where two ends of the cable body 1 are detachably connected to a first connector 2 and a second connector 3, and the first connector 2 and the second connector 3 are detachably connected between two adjacent cable bodies 1;

the outer side of the cable body 1 is provided with a rubber sleeve 4, and the outer side of the rubber sleeve 4 is provided with a steel mesh reinforcing layer 5;

and a plurality of second reinforcing structures 6 are arranged between the first connector 2 and the second connector 3 and outside the steel mesh reinforcing layer 5.

In an embodiment, please refer to fig. 1-4, the first groove 21 is disposed on the inner side of the first connector 2, a plurality of electrode holes 22 are disposed on one side of the inner side of the first groove 21, the second connector 3 includes a first connection ring 31, a second groove 32 is disposed on one side of the first connection ring 31, a connection electrode plate 33 is detachable from the second groove 32, a plurality of electrode rods 34 are disposed on one side of the electrode plate 33, the electrode rods 34 are slidably connected to the electrode holes 22, the connection cable body 1 is detachable from one side of the electrode plate 33, the electrode plate 33 is connected to the second groove 32 in an extruding manner, a spiral structure 35 is disposed on the inner wall of the second groove 32, the spiral structure 35 is connected to a first pressing plate 36 in a spiral manner, and the first pressing plate 36 is connected to the electrode plate 33 in an extruding manner.

In an embodiment, referring to fig. 1 to 3, first connection plates 37 are disposed on one sides of the first connection joints 2 and the first connection rings 31, and two adjacent first connection plates 37 are fixedly connected by bolts.

In an embodiment, referring to fig. 1 to 3, a first sliding groove 38 is disposed on each of the first connecting head 2 and the first connecting ring 31, the two first sliding grooves 38 are slidably connected to the two first sealing covers 23, and two ends of the two first sealing covers 23 are fixedly connected.

In an embodiment, referring to fig. 5 to 6, a first convex ring 24 is disposed on each of the first connector 2 and the second connector 3, a second sliding groove 241 is disposed on each of the first convex rings 24, the second reinforcing structure 6 includes two first reinforcing rings 61, a first protrusion 62 is disposed on each of the two first reinforcing rings 61, the first protrusion 62 is slidably connected to the second sliding groove 241, a second protrusion 63 is disposed on each of the first reinforcing rings 61, and the second protrusion 63 is detachably connected to the first connector 2 or the second connector 3.

In an embodiment, referring to fig. 5 to 6, a first convex ball 621 is disposed at the bottom of the first protrusion 62, a first spherical groove 242 is disposed in the second sliding slot 241, and the first convex ball 621 is connected to the first spherical groove 242 in a pressing manner.

In an embodiment, referring to fig. 5 to 6, a plurality of third sliding grooves 611 are formed outside the first reinforcing ring 61, a first limiting column 612 is disposed inside the third sliding grooves 611, the first limiting column 612 is slidably connected to the first connecting member 64, a first reinforcing plate 65 is disposed between adjacent first connecting members 64, and the first connecting member 64 and the first limiting column 612 are fixed by a limiting nut.

In an embodiment, referring to fig. 5 to 6, a fourth sliding groove 651 is disposed on a side of the first reinforcing plate 65, the fourth sliding groove 651 is slidably connected to a first sliding block 652, the first sliding block 652 is disposed in an L-like shape, a first sliding rod 653 and a second sliding rod 654 are disposed between adjacent sliding blocks 652, the second sliding rod 654 is slidably connected to the first sliding rod 653, a plurality of first limiting holes 655 are disposed on the second sliding rod 654, a limiting block 656 is slidably connected to the first sliding rod 653, the limiting block 656 is disposed in a T-like shape, the limiting block 656 is slidably connected to the first limiting holes 655, the outer side of the rubber sleeve 4 is slidably connected to a first limiting ring 66, and the first sliding blocks 652 are detachably connected to the first limiting ring 66.

Referring to fig. 5 to 6, in an embodiment, the steel mesh-reinforced layer 5 includes a plurality of steel wires 51, and adjacent steel wires 51 are connected in a staggered manner.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents, and thus the embodiments of the invention are intended only as illustrative examples of the invention and no limitation of the invention is intended whatsoever to be construed by the embodiments of the invention.

Claims (9)

1. A high tenacity control cable comprising a cable body (1), characterized in that: the two ends of each cable body (1) are detachably connected with a first connector (2) and a second connector (3), and the first connector (2) and the second connector (3) are detachably connected between every two adjacent cable bodies (1);

the outer side of the cable body (1) is provided with a rubber sleeve (4), and the outer side of the rubber sleeve (4) is provided with a steel mesh reinforcing layer (5);

and a plurality of second reinforcing structures (6) are arranged between the first connector (2) and the second connector (3) and outside the steel mesh reinforcing layer (5).

2. A high tenacity control cable according to claim 1 wherein: a first groove (21) is arranged on the inner side of the first connector (2), a plurality of electrode holes (22) are arranged on one surface of the inner side of the first groove (21), the second connector (3) comprises a first connecting ring (31), one side of the first connecting ring (31) is provided with a second groove (32), the second groove (32) is detachably connected with an electrode plate (33), one side of the electrode plate (33) is provided with a plurality of electrode rods (34), the electrode rods (34) are connected with a plurality of electrode holes (22) in a sliding way, one side of the electrode plate (33) is detachably connected with the cable body (1), the electrode plate (33) is connected with the second groove (32) in an extruding way, the inner wall of the second groove (32) is provided with a spiral structure (35), the spiral structure (35) is in spiral connection with a first pressing plate (36), and the first pressing plate (36) is connected with the electrode plate (33) in an extrusion mode.

3. A high tenacity control cable according to claim 2 wherein: first connecting plate (37) are all equipped with on first connecting head (2) and first connecting ring (31) one side, adjacent two first connecting plate (37) bolt fixed connection.

4. A high tenacity control cable according to claim 3 wherein: first connector (2) with first connecting ring (31) one side all is equipped with first spout (38), two equal sliding connection two first sealed cowlings (23) of first spout (38), two first sealed cowlings (23) both ends fixed connection.

5. A high tenacity control cable according to claim 1 wherein: first connector (2) with second connector (3) one side all is equipped with first bulge loop (24), all be equipped with second spout (241) on first bulge loop (24), second reinforced structure (6) include two first reinforcement ring (61), two first reinforcement ring (61) one side all is equipped with first lug (62), first lug (62) sliding connection second spout (241), just first reinforcement ring (61) one side is equipped with second lug (63), connection can be dismantled in second lug (63) first connector (2) or second connector (3).

6. A high tenacity control cable according to claim 5 wherein: first protruding ball (621) is equipped with to first lug (62) bottom, be equipped with first spherical groove (242) in second spout (241), first protruding ball (621) extrusion connection first spherical groove (242).

7. A high tenacity control cable according to claim 5 wherein: a plurality of third sliding grooves (611) are formed in the outer side of the first reinforcing ring (61), first limiting columns (612) are arranged in the third sliding grooves (611), the first limiting columns (612) are connected with first connecting pieces (64) in a sliding mode, a first reinforcing plate (65) is arranged between every two adjacent first connecting pieces (64), and the first connecting pieces (64) and the first limiting columns (612) are fixed through limiting nuts.

8. A high tenacity control cable according to claim 7 wherein: a fourth sliding groove (651) is arranged on the side edge of the first reinforcing plate (65), a first sliding block (652) is connected in the fourth sliding groove (651) in a sliding manner, the first sliding block (652) is arranged in an L-shaped manner, a first sliding rod (653) and a second sliding rod (654) are respectively arranged between the adjacent sliding blocks (652), the second sliding rod (654) is connected with the first sliding rod (653) in a sliding way, a plurality of first limit holes (655) are arranged on the second sliding rod (654), a limit block (656) is connected on the first sliding rod (653) in a sliding way, the limit block (656) is arranged in a T-like shape, and the limiting block (656) is in sliding connection with the first limiting hole (655), the outer side of the rubber sleeve (4) is in sliding connection with the first limiting ring (66), and the first sliding blocks (652) are detachably connected with the first limiting ring (66).

9. A high tenacity control cable according to claim 1 wherein: the steel mesh reinforcing layer (5) comprises a plurality of steel wires (51), and the adjacent steel wires (51) are connected in a staggered mode.

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