CN111276906A - Safety wiring clamp for power supply laying - Google Patents

Abstract

The invention belongs to the field of wiring tools, in particular to a safe wiring clamp for power supply laying, which aims at solving the problems that the common wiring clamp is difficult to effectively fix large wires laid by urban power supply, the wiring of the wires is difficult to further extrude and fix the wiring head, and the wiring worker is difficult to work with time and labor after the wiring of the wires is finished in the prior art, and the invention provides the following scheme that the safe wiring clamp comprises a base, wherein the top of the base is fixedly connected with a workbench and a support column, the top of the support column is fixedly connected with a top plate, and the top of the workbench is slidably provided with two extrusion blocks. Time and labor are saved, and meanwhile, great convenience is brought to the work of a wiring worker.

Description

Safety wiring clamp for power supply laying

Technical Field

The invention relates to the technical field of wire laying tools, in particular to a safety wiring clamp for power supply laying.

Background

With the development of modern cities, power supply lines are laid in many places, so that electric power is supplied to thousands of households, the use of daily life or the processing of factory buildings and the working in office buildings are facilitated, and great convenience is brought to the life of people; the pliers are hand tools used for clamping and fixing a processing workpiece or twisting, bending and shearing a metal wire, and the jointing pliers are hand tools used for clamping a wire;

however, the common wire pliers are often difficult to effectively fix large wires laid in urban power supply, and after the wiring of the wires is completed, the wire pliers are difficult to further extrude and fix a connector lug, so that time and labor are wasted, and meanwhile, the work of a wiring worker is difficult to bring.

Disclosure of Invention

The invention aims to solve the problems that in the prior art, an ordinary wiring clamp is difficult to effectively fix large wires laid by urban power supply, and after wiring of the wires is completed, a connector lug is difficult to further extrude firmly, time and labor are wasted, and meanwhile, work of a wiring worker is difficult.

In order to achieve the purpose, the invention adopts the following technical scheme:

a safety jointing clamp for power supply laying comprises a base, wherein the top of the base is fixedly connected with a workbench and a support column, the top of the support column is fixedly connected with a top plate, the top of the workbench is provided with two extrusion blocks in a sliding manner, the top of the top plate is fixedly provided with a motor, the bottom of the top plate is fixedly connected with two fixing plates, the top plate is provided with a sliding hole, a first threaded rod is arranged in the sliding hole in a sliding manner, the top end of the first threaded rod extends to the outside of the top plate and is fixedly connected with a limiting block, the bottom end of the first threaded rod extends to the outside of the top plate and is fixedly connected with a stamping block, two sides of the stamping block are respectively arranged on the two fixing plates in a sliding manner, one side, close to each other, of the two fixing plates is provided with a first sliding groove, a first sliding block is arranged in, the two sliding rods are respectively installed in the two sliding holes in a sliding mode, and the first threaded rod and the two extrusion blocks are matched with the motor.

Preferably, the two sides of the punching block are fixedly connected with one ends of the fixing rods, the other ends of the two fixing rods are fixedly connected with one sides of the two first sliding blocks respectively, and the first sliding blocks can drive the fixing rods to move.

Preferably, the sliding hole is internally rotatably provided with a conical fluted disc, the conical fluted disc is provided with a first threaded hole, the first threaded rod is threadedly arranged in the first threaded hole, and the conical fluted disc can drive the first threaded rod to move downwards through the first threaded hole.

Preferably, a first gear cavity is formed in the top plate, one side, close to the sliding hole, of the first gear cavity is provided with a first rotating hole, a first rotating rod is installed in the first rotating hole in a rotating mode, one end of the first rotating rod extends into the first gear cavity and is fixedly connected with a first bevel gear, the other end of the first rotating rod extends into the sliding hole and is fixedly connected with a second bevel gear, the second bevel gear is meshed with the bevel gear disc, and the second bevel gear can drive the bevel gear disc to rotate.

Preferably, the output shaft of the motor is welded with a rotating shaft, one end of the rotating shaft extends into the first gear cavity and is fixedly connected with a third bevel gear, the third bevel gear is meshed with the first bevel gear, and the third bevel gear can drive the first bevel gear to rotate.

Preferably, the second rotating hole has been seted up on the support column, and the second rotary rod has been installed to the rotatory downthehole rotation of second, has seted up the transmission chamber on the base, the top of second rotary rod extend to first gear intracavity and with one side fixed connection of third bevel gear, the bottom of second rotary rod extend to the transmission intracavity and the first gear of fixedly connected with, first gear cooperatees with two extrusion pieces, third bevel gear can drive the second rotary rod and rotate.

Preferably, spring grooves have all been seted up to one side that two extrusion pieces are close to each other, and equal slidable mounting has the grip block in two spring grooves, and the one end of equal fixedly connected with spring on the inner wall of one side of two spring grooves, the other end of two springs respectively with one side fixed connection of two grip blocks, the spring can be with reaction force effect on the grip block.

Preferably, the second sliding groove is formed in the top of the workbench, a third sliding groove communicated with the second sliding groove is formed in the workbench, a second gear cavity is formed in the workbench, two sliding columns are slidably mounted in the second sliding groove, two second sliding blocks are slidably mounted in the third sliding groove, the tops of the two sliding columns are fixedly connected with the bottoms of the two extrusion blocks respectively, the bottoms of the two sliding columns are fixedly connected with the tops of the two second sliding blocks respectively, and the second sliding blocks drive the sliding columns to move.

Preferably, a second threaded rod is rotatably mounted in the third sliding groove, a second threaded hole and a third threaded hole are formed in the two second sliding blocks respectively, the second threaded rod is mounted in the second threaded hole and the third threaded hole in a threaded manner, one end of the second threaded rod extends into the second gear cavity and is fixedly connected with a fourth bevel gear, the fourth bevel gear is matched with the first gear, and the threads of the first threaded hole and the second threaded hole are opposite.

Preferably, slidable mounting has first rack and second rack on the bottom inner wall in transmission chamber, the both ends of the same connecting rod of one side fixedly connected with that first rack and second rack are close to each other, first gear meshes with first rack mutually, set up the third rotatory hole of putting through mutually with transmission chamber on the base, the third rotary rod is installed to third rotatory downthehole internal rotation, the bottom of third rotary rod extends to transmission intracavity and fixedly connected with second gear, second gear meshes with the second rack mutually, the top of third rotary rod extends to second gear intracavity and fixedly connected with fifth bevel gear, fifth bevel gear meshes with fourth bevel gear mutually, fifth bevel gear can drive fourth bevel gear and rotate.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the scheme, the second threaded rod is matched with the two second sliding blocks, and the clamping blocks are matched with the extrusion blocks through the springs, so that the second threaded rod can drive the two clamping blocks to further clamp and fix the electric wire;

2. according to the scheme, the first rotating rod is matched with the second bevel gear, and the bevel gear disc is matched with the first threaded rod through the first threaded hole, so that the first rotating rod can drive the first threaded rod to move;

3. according to the scheme, the first threaded rod is matched with the stamping block, and the first sliding block is matched with the first sliding rod, so that the first threaded rod can drive the stamping block to move downwards and the stamping block cannot rotate;

according to the invention, by arranging the stamping block, the clamping block, the first rack and the second rack, the clamping block can effectively fix large wires laid by urban power supply, and after the wiring of the wires is finished, the connector lug can be further firmly extruded, so that great convenience is brought to the work of wiring workers while time and labor are saved.

Drawings

FIG. 1 is a schematic perspective view of a safety wire connecting clamp for power supply laying according to the present invention;

FIG. 2 is a schematic cross-sectional view of a safety wire connecting clamp for power supply laying according to the present invention;

FIG. 3 is an enlarged schematic structural view of the safety wire connecting clamp for power supply laying in FIG. 1;

FIG. 4 is a schematic structural diagram of a safety wire connecting clamp for power supply laying, in which a first rack is connected with a second rack through a connecting rod;

fig. 5 is a schematic structural diagram of a bevel gear disk of a safety wire connecting clamp for power supply laying according to the present invention.

In the figure: 1 base, 2 work benches, 3 support columns, 4 top plates, 5 extrusion blocks, 6 motors, 7 fixing plates, 8 first threaded rods, 9 limiting blocks, 10 stamping blocks, 11 first sliding blocks, 12 sliding rods, 13 fixing rods, 14 bevel gear discs, 15 first rotating rods, 16 first bevel gears, 17 second bevel gears, 18 rotating shafts, 19 third bevel gears, 20 second rotating rods, 21 first gears, 22 springs, 23 sliding columns, 24 second sliding blocks, 25 second threaded rods, 26 fourth bevel gears, 27 first racks, 28 second racks, 29 connecting rods, 30 third rotating rods, 31 second gears, 32 fifth bevel gears and 33 clamping blocks.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example one

Referring to fig. 1-5, a safety jointing clamp for power supply laying comprises a base 1, a workbench 2 and a support pillar 3 are fixedly connected to the top of the base 1, a top plate 4 is fixedly connected to the top of the support pillar 3, two extrusion blocks 5 are slidably mounted on the top of the workbench 2, a motor 6 is fixedly mounted on the top of the top plate 4, two fixing plates 7 are fixedly connected to the bottom of the top plate 4, a sliding hole is formed in the top plate 4, a first threaded rod 8 is slidably mounted in the sliding hole, the top end of the first threaded rod 8 extends to the outside of the top plate 4 and is fixedly connected with a limiting block 9, the bottom end of the first threaded rod 8 extends to the outside of the top plate 4 and is fixedly connected with a stamping block 10, two sides of the stamping block 10 are respectively slidably mounted on the two fixing plates 7, a first sliding groove is formed in one side of the two fixing plates 7 close, and the two first sliding chutes are internally and fixedly connected with sliding rods 12, the two first sliding blocks 11 are respectively provided with a sliding hole, the two sliding rods 12 are respectively and slidably arranged in the two sliding holes, and the first threaded rod 8 and the two extrusion blocks 5 are matched with the motor 6.

In this embodiment, the equal fixedly connected with dead lever 13's in both sides one end of ram block 10, the other end of two dead levers 13 respectively with one side fixed connection of two first sliders 11, first slider 11 can drive dead lever 13 and remove.

In this embodiment, the taper-toothed disc 14 is rotatably installed in the sliding hole, a first threaded hole is formed in the taper-toothed disc 14, the first threaded rod 8 is threadedly installed in the first threaded hole, and the taper-toothed disc 14 can drive the first threaded rod 8 to move downwards through the first threaded hole.

In this embodiment, first gear chamber has been seted up on roof 4, same first rotatory hole has been seted up to one side that first gear chamber and sliding hole are close to each other, first rotary rod 15 is installed to first rotatory downthehole internal rotation, the one end of first rotary rod 15 extends to first gear intracavity and the first bevel gear of fixedly connected with 16, the other end of first rotary rod 15 extends to in the sliding hole and fixedly connected with second bevel gear 17, second bevel gear 17 meshes with bevel gear dish 14 mutually, second bevel gear 17 can drive bevel gear dish 14 and rotate.

In this embodiment, a rotating shaft 18 is welded on an output shaft of the motor 6, one end of the rotating shaft 18 extends into the first gear cavity and is fixedly connected with a third bevel gear 19, the third bevel gear 19 is meshed with the first bevel gear 16, and the third bevel gear 19 can drive the first bevel gear 16 to rotate.

In this embodiment, a second rotating hole has been seted up on the support column 3, a second rotating rod 20 is installed to the rotation in the second rotating hole, a transmission cavity has been seted up on the base 1, the top of second rotating rod 20 extends to first gear intracavity and with one side fixed connection of third bevel gear 19, the bottom of second rotating rod 20 extends to transmission intracavity and first gear 21 of fixedly connected with, first gear 21 cooperatees with two extrusion pieces 5, third bevel gear 19 can drive second rotating rod 20 and rotate.

In this embodiment, two extrusion piece 5 one sides that are close to each other have all seted up the spring groove, and equal slidable mounting has grip block 33 in two spring grooves, and equal fixedly connected with spring 22's one end on one side inner wall in two spring grooves, two spring 22's the other end respectively with one side fixed connection of two grip blocks 33, spring 22 can be with reaction effect on grip block 33.

In this embodiment, the second spout has been seted up at the top of workstation 2, set up the third spout that communicates with the second spout on the workstation 2, the second gear chamber has been seted up on the workstation 2, slidable mounting has two travelers 23 in the second spout, slidable mounting has two second sliders 24 in the third spout, the top of two travelers 23 respectively with the bottom fixed connection of two extrusion pieces 5, the bottom of two travelers 23 respectively with the top fixed connection of two second sliders 24, second slider 24 drives travelers 23 and removes.

In this embodiment, a second threaded rod 25 is rotatably mounted in the third sliding groove, a second threaded hole and a third threaded hole are respectively formed in the two second sliding blocks 24, the second threaded rod 25 is threadedly mounted in the second threaded hole and the third threaded hole, one end of the second threaded rod 25 extends into the second gear cavity and is fixedly connected with a fourth bevel gear 26, the fourth bevel gear 26 is matched with the first gear 21, and threads of the first threaded hole and the second threaded hole are opposite.

In this embodiment, slidable mounting has first rack 27 and second rack 28 on the bottom inner wall of transmission chamber, the both ends of one side fixedly connected with same connecting rod 29 that first rack 27 and second rack 28 are close to each other, first gear 21 meshes with first rack 27 mutually, the last third rotatory hole of putting through with the transmission chamber of offering of base 1, third rotary rod 30 is installed to the rotation in the third rotatory hole, the bottom of third rotary rod 30 extends to in the transmission chamber and fixedly connected with second gear 31, second gear 31 meshes with second rack 28 mutually, the top of third rotary rod 30 extends to in the second gear chamber and fixedly connected with fifth bevel gear 32, fifth bevel gear 32 meshes with fourth bevel gear 26 mutually, fifth bevel gear 32 can drive fourth bevel gear 26 and rotate.

Example two

Referring to fig. 1-5, a safety jointing clamp for power supply laying comprises a base 1, the top of the base 1 is fixedly connected with a workbench 2 and a support column 3 by welding, the top of the support column 3 is fixedly connected with a top plate 4 by welding, the top of the workbench 2 is slidably provided with two extrusion blocks 5, the top of the top plate 4 is fixedly provided with a motor 6 by bolts, the bottom of the top plate 4 is fixedly connected with two fixing plates 7 by welding, the top plate 4 is provided with a sliding hole, a first threaded rod 8 is slidably mounted in the sliding hole, the top end of the first threaded rod 8 extends to the outside of the top plate 4 and is fixedly connected with a limiting block 9 by welding, the bottom end of the first threaded rod 8 extends to the outside of the top plate 4 and is fixedly connected with a stamping block 10 by welding, two sides of the stamping block 10 are respectively slidably mounted on the two fixing plates 7, one side of, all slidable mounting has first slider 11 in two first spouts, and all is connected with slide bar 12 through welded fastening in two first spouts, has all seted up the slide opening on two first sliders 11, and two slide bars 12 are respectively slidable mounting in two slide openings, and first threaded rod 8 and two extrusion pieces 5 cooperate with motor 6.

In this embodiment, the both sides of ram block 10 are all through the one end of welded fastening connected with dead lever 13, and the other end of two dead levers 13 passes through welded fastening with one side of two first sliders 11 respectively to be connected, and first slider 11 can drive dead lever 13 and remove.

In this embodiment, the taper-toothed disc 14 is rotatably installed in the sliding hole, a first threaded hole is formed in the taper-toothed disc 14, the first threaded rod 8 is threadedly installed in the first threaded hole, and the taper-toothed disc 14 can drive the first threaded rod 8 to move downwards through the first threaded hole.

In this embodiment, first gear chamber has been seted up on roof 4, same first rotatory hole has been seted up to one side that first gear chamber and sliding hole are close to each other, first rotary rod 15 is installed to first rotatory downthehole internal rotation, the one end of first rotary rod 15 extends to first gear intracavity and is connected with first bevel gear 16 through welded fastening, the other end of first rotary rod 15 extends to in the sliding hole and is connected with second bevel gear 17 through welded fastening, second bevel gear 17 meshes with bevel gear disc 14 mutually, second bevel gear 17 can drive bevel gear disc 14 and rotate.

In this embodiment, a rotating shaft 18 is welded on an output shaft of the motor 6, one end of the rotating shaft 18 extends into the first gear cavity and is fixedly connected with a third bevel gear 19 by welding, the third bevel gear 19 is meshed with the first bevel gear 16, and the third bevel gear 19 can drive the first bevel gear 16 to rotate.

In this embodiment, a second rotating hole has been seted up on support column 3, second rotary rod 20 has been installed to the rotation in the second rotating hole, the transmission chamber has been seted up on base 1, the top of second rotary rod 20 extends to first gear intracavity and passes through welded fastening with one side of third bevel gear 19 to be connected, the bottom of second rotary rod 20 extends to the transmission intracavity and is connected with first gear 21 through welded fastening, first gear 21 cooperatees with two extrusion pieces 5, third bevel gear 19 can drive second rotary rod 20 and rotate.

In this embodiment, two extrusion piece 5 one sides that are close to each other have all seted up the spring groove, and equal slidable mounting has grip block 33 in two spring grooves, and all is connected with the one end of spring 22 through welded fastening on one side inner wall in two spring grooves, and the other end of two springs 22 is connected through welded fastening with one side of two grip blocks 33 respectively, and spring 22 can be with reaction force effect on grip block 33.

In this embodiment, the second spout has been seted up at the top of workstation 2, set up the third spout that communicates mutually with the second spout on the workstation 2, the second gear chamber has been seted up on the workstation 2, slidable mounting has two travelers 23 in the second spout, slidable mounting has two second sliders 24 in the third spout, welded fixed connection is passed through with the bottom of two extrusion blocks 5 respectively at the top of two travelers 23, welded fixed connection is passed through with the top of two second sliders 24 respectively in the bottom of two travelers 23, second slider 24 drives travelers 23 and removes.

In this embodiment, a second threaded rod 25 is rotatably mounted in the third sliding groove, a second threaded hole and a third threaded hole are respectively formed in the two second sliding blocks 24, the second threaded rod 25 is threadedly mounted in the second threaded hole and the third threaded hole, one end of the second threaded rod 25 extends into the second gear cavity and is fixedly connected with a fourth bevel gear 26 by welding, the fourth bevel gear 26 is matched with the first gear 21, and threads of the first threaded hole and the second threaded hole are opposite.

In this embodiment, a first rack 27 and a second rack 28 are slidably installed on the inner wall of the bottom of the transmission cavity, two ends of one side, close to each other, of the first rack 27 and the second rack 28 are connected with the same connecting rod 29 through welding and fixing, the first gear 21 is meshed with the first rack 27, a third rotating hole communicated with the transmission cavity is formed in the base 1, a third rotating rod 30 is rotatably installed in the third rotating hole, the bottom end of the third rotating rod 30 extends into the transmission cavity and is connected with a second gear 31 through welding and fixing, the second gear 31 is meshed with the second rack 28, the top end of the third rotating rod 30 extends into the second gear cavity and is connected with a fifth bevel gear 32 through welding and fixing, the fifth bevel gear 32 is meshed with the fourth bevel gear 26, and the fifth bevel gear 32 can drive the fourth bevel gear 26 to rotate.

In the invention, when in use, firstly, the electric wire to be connected is placed on the workbench 2, then the motor 6 is started, the motor 6 rotates forwards and drives the rotating shaft 18 to rotate through the output shaft, the rotating shaft 18 drives the third bevel gear 19 to rotate, the third bevel gear 19 drives the first bevel gear 16 to rotate and the second rotating shaft 20 to rotate respectively, the first bevel gear 16 drives the first rotating shaft 15 to rotate, the first rotating shaft 15 drives the second bevel gear 17 to rotate, the second bevel gear 17 drives the bevel gear disc 14 to rotate, the bevel gear disc 14 drives the first threaded rod 8 to displace downwards in the sliding hole through the first threaded hole without generating rotation, so that the first threaded rod 8 drives the stamping block 10 to move downwards, the stamping block 10 drives the fixing rod 13 to move, the fixing rod 13 drives the first sliding block 11 to move downwards on the sliding rod 12, and the first sliding block 11 limits the downward movement direction of the stamping block 10 from deviating, the second rotating rod 20 drives the first gear 21 to rotate, the first gear 21 drives the first rack 27 to move, the first rack 27 drives the connecting rod 29 to move, the connecting rod 29 drives the second rack 28 to move, the second rack 28 drives the second gear 31 to rotate by displacement, the second gear 31 drives the third rotating rod 30 to rotate, the third rotating rod 30 drives the fifth bevel gear 32 to rotate, the fifth bevel gear 32 drives the fourth bevel gear 26 to rotate, the fourth bevel gear 26 drives the second threaded rod 25 to rotate, the second threaded rod 25 drives the two second sliding blocks 24 to move through the second threaded hole and the third threaded hole, because the threads of the second threaded hole and the third threaded hole are just opposite, the two second sliding blocks 24 always move in opposite directions, at the moment, the two second sliding blocks 24 approach each other, the second sliding blocks 24 drive the sliding columns 23 to move, the sliding columns 23 drive the extrusion blocks 5 to move, extrusion piece 5 drives grip block 33 and removes, grip block 33 fixes the electric wire, simultaneously in fixed process, grip block 33 atress can slide in the spring inslot and make spring 22 deformation, the reaction force of spring 22 acts on grip block 33 and consolidates the electric wire, when need extrude the fastening to the interface after the wiring is accomplished, continue to make motor 6 corotation, motor 6 drives punching press piece 10 indirectly this moment and continues to move down, but first gear 21 can not drive first rack 27 again in the idle running of the one end of first rack 27 this moment and remove, though first rack 27 can produce and slightly rock, owing to there is the reaction force of spring 22, so can not become flexible by fixed electric wire, until the interface is extruded the fastening by punching press piece 10, then make motor 6 reversal, it can to take off the electric wire.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (10)

1. The utility model provides a power supply is laid and is used safe wiring pincers, including base (1), characterized in that, the top fixedly connected with workstation (2) and support column (3) of base (1), the top fixedly connected with roof (4) of support column (3), the top slidable mounting of workstation (2) has two extrusion piece (5), the top fixedly mounted of roof (4) has motor (6), and the bottom fixedly connected with two fixed plates (7) of roof (4), set up the sliding hole on roof (4), slidable mounting has first threaded rod (8) in the sliding hole, the top of first threaded rod (8) extends to the outside of roof (4) and fixedly connected with stopper (9), the bottom of first threaded rod (8) extends to the outside of roof (4) and fixedly connected with punching press piece (10), the both sides of punching press piece (10) slidable mounting respectively on two fixed plates (7), first chutes are formed in one sides, close to each other, of the two fixing plates (7), first sliding blocks (11) are arranged in the two first chutes in a sliding mode, sliding rods (12) are fixedly connected in the two first chutes, sliding holes are formed in the two first sliding blocks (11), the two sliding rods (12) are arranged in the two sliding holes in a sliding mode, and the first threaded rod (8) and the two extrusion blocks (5) are matched with the motor (6) respectively.

2. The safety jointing clamp for power supply laying according to claim 1, wherein one end of the fixing rod (13) is fixedly connected to both sides of the stamping block (10), and the other ends of the two fixing rods (13) are fixedly connected to one side of the two first sliding blocks (11), respectively.

3. The safety wire pliers for power supply laying according to claim 1, wherein a conical toothed disc (14) is rotatably mounted in the sliding hole, a first threaded hole is formed in the conical toothed disc (14), and the first threaded rod (8) is threadedly mounted in the first threaded hole.

4. The safety wire connecting pliers for power supply laying according to claim 1, wherein a first gear cavity is formed in the top plate (4), a first rotating hole is formed in one side, close to the sliding hole, of the first gear cavity, a first rotating rod (15) is rotatably mounted in the first rotating hole, one end of the first rotating rod (15) extends into the first gear cavity and is fixedly connected with a first bevel gear (16), the other end of the first rotating rod (15) extends into the sliding hole and is fixedly connected with a second bevel gear (17), and the second bevel gear (17) is meshed with a bevel gear disc (14).

5. A safety wire connecting clamp for power supply laying according to claim 1, characterized in that a rotating shaft (18) is welded on the output shaft of the motor (6), one end of the rotating shaft (18) extends into the first gear cavity and is fixedly connected with a third bevel gear (19), and the third bevel gear (19) is meshed with the first bevel gear (16).

6. The safety wire pliers for power supply laying according to claim 1, wherein a second rotating hole is formed in the supporting column (3), a second rotating rod (20) is rotatably mounted in the second rotating hole, a transmission cavity is formed in the base (1), the top end of the second rotating rod (20) extends into the first gear cavity and is fixedly connected with one side of a third bevel gear (19), the bottom end of the second rotating rod (20) extends into the transmission cavity and is fixedly connected with a first gear (21), and the first gear (21) is matched with the two extrusion blocks (5).

7. The safety jointing clamp for power supply laying according to claim 1, wherein spring grooves are formed in the sides, close to each other, of the two extrusion blocks (5), clamping blocks (33) are slidably mounted in the two spring grooves, one ends of springs (22) are fixedly connected to the inner walls of the two spring grooves on one side, and the other ends of the two springs (22) are fixedly connected to one sides of the two clamping blocks (33) respectively.

8. The safety jointing clamp for power supply laying according to claim 1, wherein a second sliding groove is formed in the top of the workbench (2), a third sliding groove communicated with the second sliding groove is formed in the workbench (2), a second gear cavity is formed in the workbench (2), two sliding columns (23) are slidably mounted in the second sliding groove, two second sliding blocks (24) are slidably mounted in the third sliding groove, the tops of the two sliding columns (23) are fixedly connected with the bottoms of the two extrusion blocks (5), and the bottoms of the two sliding columns (23) are fixedly connected with the tops of the two second sliding blocks (24).

9. The safety jointing clamp for power supply laying according to claim 8, wherein a second threaded rod (25) is rotatably mounted in the third sliding groove, the two second sliding blocks (24) are respectively provided with a second threaded hole and a third threaded hole, the second threaded rod (25) is threadedly mounted in the second threaded hole and the third threaded hole, one end of the second threaded rod (25) extends into the second gear cavity and is fixedly connected with a fourth bevel gear (26), and the fourth bevel gear (26) is matched with the first gear (21).

10. A safety wire holder for laying electricity according to claim 6, sliding installation has first rack (27) and second rack (28) in the bottom inner wall in transmission chamber, the both ends of one side fixedly connected with same connecting rod (29) that first rack (27) and second rack (28) are close to each other, first gear (21) mesh with first rack (27) mutually, set up the third rotatory hole of putting through mutually with the transmission chamber on base (1), third rotary rod (30) are installed to the rotatory rotation in the third rotatory hole, the bottom of third rotary rod (30) extends to the transmission intracavity and fixedly connected with second gear (31), second gear (31) mesh with second rack (28) mutually, the top of third rotary rod (30) extends to the second gear intracavity and fixedly connected with fifth bevel gear (32), fifth bevel gear (32) mesh with fourth bevel gear (26) mutually.

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