CN111817212A

CN111817212A - Intelligent 5G network cable threading mechanism

Info

Publication number: CN111817212A
Application number: CN202010784121.5A
Authority: CN
Inventors: 梁金刚
Original assignee: Individual
Current assignee: Wang Yijiang
Priority date: 2020-08-06
Filing date: 2020-08-06
Publication date: 2020-10-23
Anticipated expiration: 2040-08-06
Also published as: CN111817212B

Abstract

An intelligent 5G network cable threading mechanism comprises a threading part and a cable feeding part; the machine is gripped by a user through the auxiliary side handle and the rear handle, the threading part and the wire feeding part are connected through a brake wire, the brake wire is divided into an inner layer and an outer layer, one fixed end of the outer wire is fixedly arranged on a groove for connecting the outer wire, and the inner wire penetrates through a steel wire threading hole and is wound on a shaft with a hole.

Description

Intelligent 5G network cable threading mechanism

Technical Field

The invention relates to the technical field of automatic threading machines, which can get through a blockage in a threading pipe.

Background

In the threading of some corridor network cables, a pulling cable needs to be placed in a threading pipeline in advance, the network cable is pulled through the pulling cable, but because no embedded cable or the embedded cable is broken when some pipelines are laid, the network cable cannot be passed through, and therefore a machine capable of penetrating through the network cable pipeline is needed to complete the network cable penetrating work.

Disclosure of Invention

Aiming at the above contents, the inventor invents a threading machine with a drill bit, which can get through the blockage in the threading pipe, and adopts the technical scheme that:

an intelligent 5G network cable threading mechanism comprises a threading part and a wire feeding part, wherein the wire feeding part comprises a winder, an auxiliary side handle, a wire feeding wheel, a shaft A, a gear B, a shaft for controlling winding of a steel wire, a reel, a gear C, a thin shaft, an electromagnet, a shaft sleeve, a disc gear, a semi-gear, a gear E, a gear F, a gear G, a gear H, a motor, a gear I, a shell, a rear handle, a motor switch, a mode selector switch, an inner wire and an outer wire; a rear handle is arranged behind the shell; the motor is fixedly arranged in the shell; the gear G and the gear H are fixedly arranged on a motor shaft of the motor; the shaft B is rotatably arranged in a shaft sleeve which is fixedly arranged in a circular hole of the shell; the half gear, the gear E, the gear F and the disc gear are all fixedly arranged on the shaft B, the half gear is arranged on the top, the gear E is arranged below the half gear, the gear F is arranged below the gear E, and the disc gear is arranged below the gear F; the electromagnet is fixedly arranged in the shaft sleeve, one end of the shaft B is provided with a spring, and the spring generates elasticity to enable the shaft B to move upwards; the shaft for controlling the wound steel wire is hollow, and the thin shaft is rotatably arranged in the shaft for controlling the wound steel wire; the winder is fixedly arranged on the outer side of the shaft for controlling the wound steel wire; the winding wheel is fixedly arranged on the thin shaft and is arranged in the middle of the winder; the gear I is fixedly arranged on the outer side of the shaft for controlling the steel wire winding and is positioned below the wire winder; the gear C is provided with a groove and is arranged at the lower ends of the shaft for controlling the steel wire winding and the thin shaft; the gear C is meshed with the disc gear; the upper side and the lower side of the disc gear are both provided with baffles, so that the gear C moves up and down along with the disc gear; two shafts A are rotatably arranged in the circular holes of the shell, a wire feeding wheel and a gear B are fixedly arranged on the shafts A, the wire feeding wheel is arranged above the gear B, the two gears B are meshed with each other, and the gear B is meshed with the gear C.

Furthermore, the threading part comprises a pulley, a telescopic pulley support, a drill bit, a threading hole, an outer line connecting groove, a steel wire threading hole, a spring, a gear A, a shaft with a hole, an electric drill shell, a telescopic pulley support arranged on the side surface of the electric drill shell, and a pulley rotatably arranged on the telescopic pulley support; a shaft with a hole is rotatably arranged in the shell of the electric drill, and a gear A key is arranged on the shaft with the hole; the spring is arranged on the shaft with the hole and plays a role of automatically winding up the wire, and the spring is arranged above the gear A; a gear A is arranged on the drill bit, the gear A is a bevel gear, and the two gears A are meshed with each other; a threading hole is arranged on the drill bit; the electric drill shell is provided with an outer line connecting groove and a steel wire threading hole.

Furthermore, the threading part and the wire feeding part are connected by a brake wire, the brake wire is divided into an inner layer and an outer layer, one fixed end of the outer wire is fixedly arranged on a groove of the outer wire, and the inner wire penetrates through a steel wire threading hole and is wound on a shaft with a hole; the brake cable is wound on the winder, the other end of the outer wire is fixed on the winder, the inner wire is longer than the outer wire, and the part which is grown out is wound on the reel.

Advantageous effects

1. The invention has simple operation, convenient control and convenient carrying, and can be used according to the situation by pressing the switch.

2. The invention uses a motor to control and transmit through the gear set, realizes the effects of large power and low power consumption, reduces the cost and greatly saves materials.

3. This product drill bit uses bevel gear group structural performance more stable, and threading speed is fast, and labour saving and time saving improves work efficiency.

Drawings

Fig. 1 and 2 are schematic diagrams of the overall structure of the present invention.

Fig. 3, 4, 5, 6 and 7 are schematic structural views of the threading part of the invention.

Fig. 8 and 9 are schematic structural views of the wire feeding portion of the present invention.

FIG. 10 is a schematic view of the second mode of wire feeding

FIG. 11 is a schematic view of a part of a structure

1-a winder; 2-auxiliary side handle; 3-a pulley; 4-a telescopic pulley support; 5-a drill bit; 6-threading hole; 7-link the outer line groove; 8-steel wire threading holes; 9-a clockwork spring; 10-gear a; 11-a shaft with a hole; 12-a wire feeding wheel; 13-axis a; 14-gear B; 15-axis B; 16-controlling the axis of the wound wire; 17-a reel; 18-gear C; 19-thin shaft; 20-an electromagnet; 21-shaft sleeve; 22-a disc gear; 23-half gear; 24-gear E; 25-gear F; 26-gear G; 27-gear H; 28-a motor; 29-gear I; 30-a housing; 31-rear handle; 32-motor switch; 33-mode selector switch; 34-an electric drill housing; 35-internal line; 36-outside line.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

The technical scheme of the invention is further specifically described by the following embodiments and the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, but rather should be construed as broadly as the present invention is capable of modification in various respects, all without departing from the spirit and scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "front", "back", "left", "right", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention are conventionally placed in use, and are only used for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

An intelligent 5G network cable threading mechanism comprises a threading part and a wire feeding part, wherein the wire feeding part comprises a wire winder 1, an auxiliary side handle 2, a wire feeding wheel 12, a shaft A13, a gear B14, a shaft B15, a shaft 16 for controlling wire winding, a reel 17, a gear C18, a thin shaft 19, an electromagnet 20, a shaft sleeve 21, a disc gear 22, a half gear 23, a gear E24, a gear F25, a gear G26, a gear H27, a motor 28, a gear I29, a shell 30, a rear handle 31, a motor switch 32, a mode switch 33, an inner wire 35 and an outer wire 36, and the auxiliary side handle 2 is fixedly installed on the side surface of the shell 30; a rear handle 31 is provided behind the housing 30, and a user grips the machine through the auxiliary side handle 2 and the rear handle 31; the motor 28 is fixedly mounted inside the housing 30; the gear G26 and the gear H27 are fixedly arranged on the shaft of the motor 28; the shaft B15 is rotatably arranged in the shaft sleeve 21, and the shaft sleeve 21 is fixedly arranged in a circular hole of the shell 30; half-gear 23, gear E24, gear F25, and disc gear 22 are all fixedly mounted on shaft B15 with half-gear 23 uppermost, gear E24 below half-gear 23, gear F25 below gear E24, and disc gear 22 below gear F25; the electromagnet 20 is fixedly arranged in the shaft sleeve 21, one end of the shaft B15 is provided with a spring, and the spring generates elastic force to enable the shaft B15 to move upwards; the shaft 16 for controlling the steel wire winding is hollow, and the thin shaft 19 is rotatably arranged in the shaft 16 for controlling the steel wire winding; the winder 1 is fixedly arranged outside a shaft 16 for controlling the winding of steel wires; the reel 17 is fixedly arranged on the thin shaft 19, and the reel 17 is arranged in the middle of the winder 1; the gear I29 is fixedly arranged outside the shaft 16 for controlling the wire winding and is positioned below the wire winder 1; the gear C18 is provided with a groove and is arranged at the lower ends of the shaft 16 for controlling the wire winding and the thin shaft 19; gear C18 intermeshes with the carousel gear 22; baffles are arranged on the upper side and the lower side of the disc gear 22, so that the gear C18 moves up and down along with the disc gear 22; two shafts A13 are rotatably arranged in a circular hole of the shell 30, a wire feeding wheel 12 and a gear B14 are fixedly arranged on the shaft A13, the wire feeding wheel 12 is arranged above the gear B14, the two gears B14 are meshed with each other, and the gear B14 is meshed with the gear C18.

The threading part comprises a pulley 3, a telescopic pulley support 4, a drill bit 5, a threading hole 6, an outer line connecting groove 7, a steel wire threading hole 8, a clockwork spring 9, a gear A10, a shaft 11 with a hole and an electric drill shell 34, wherein the telescopic pulley support 4 is arranged on the side surface of the electric drill shell 34, and the pulley 3 is rotatably arranged on the telescopic pulley support 4; the shaft 11 with the hole is rotatably arranged in the electric drill shell 34, and the gear A10 is arranged on the shaft 11 with the hole in a key mode; the clockwork spring 9 is arranged on the shaft 11 with the hole and plays a role of automatically winding up, and the clockwork spring 9 is arranged above the gear A10; a gear A10 is arranged on the drill bit 5, the gear A10 is a bevel gear, and the two gears A10 are meshed with each other; a threading hole 6 is arranged on the drill bit 5; an outer line connecting groove 7 and a steel wire threading hole 8 are arranged on the electric drill shell 34; specifically, the inside of the telescopic pulley bracket 4 is provided with a spring which enables the pulley 3 to move outwards, and the pulley 3 is in contact with the pipeline wall through the spring so as to facilitate threading.

In an optional implementation manner of the embodiment of the invention, except for the same parts as the previous embodiment, the threading part and the wire feeding part are connected by a brake wire, the brake wire is divided into an inner layer and an outer layer, one fixed end of the outer wire is fixedly arranged on a groove 7 for connecting the outer wire, and the inner wire passes through a steel wire threading hole 8 and is wound on a shaft 11 with a hole; the brake cable is wound on the bobbin 1, the other end of the outer cable is fixed on the bobbin 1, the inner cable is longer than the outer cable, and the extended part is wound on the winding wheel 17.

When the motor 28 works to drive the shaft of the motor 28, the gear G26 and the gear H27 which are fixedly arranged on the shaft of the motor 28 rotate along with the shaft of the motor 28, the gear F25 is meshed with the gear H27, the gear E24 is fixed on the shaft B15, the shaft B15 rotates to drive the half gear 23, the gear E24 and the disc gear 22 on the shaft to rotate together, the disc gear 22 is meshed with the gear C18, the groove of the gear C18 and the shaft 16 for controlling the wound steel wire are overlapped with the thin shaft 19 and then drive the shaft 16 for controlling the wound steel wire and the thin shaft 19 to rotate synchronously, the gear C drives the gear B14 and the shaft A13 to rotate together, the wire feeding wheels 12 rotate together, the two wire feeding wheels 12 generate thrust to synchronously feed the outer wire 36 and the inner wire 35 forwards, and the outer wire 36 is connected with the groove 7 for linking the; the whole threading part moves forwards under the action of thrust;

when the mode switch 33 is pressed to switch to the second mode, the electromagnet 20 generates suction to enable the shaft B15 to move downwards, the disc gear 22 fixedly installed on the shaft B15, the gear E24, the gear F25 and the half gear 23 move downwards along with the shaft B15, the half gear 23 is meshed with the gear I29, the gear C18 can move downwards together due to a chuck of the disc gear 22, the gear C18 and the thin shaft 19 are overlapped and completely separated from the shaft 16 for controlling the wound steel wire, due to the characteristic of the half gear 23, the gear I29 is stressed for a quarter of a turn, the inner wire 35 wound on the perforated shaft 11 can be pulled backwards to drive the perforated shaft 11 to rotate to drive the drill bit 5 to rotate, when the gear I29 is not stressed, the wound perforated shaft 11 of the spiral spring can automatically rotate to wind the inner wire 35 due to the reason of the winding, and the ratchet wheel on the perforated shaft 11 enables the perforated shaft 11 to rotate to not drive the gear A10 to rotate; realize the mediation of pipeline, when drill bit 5 came out from the other end mouth of pipe, through hanging the net twine on threading hole 6, through sending the partial line to retrieving the line threading part and withdrawing, and then pass the pipe with the net twine.

Claims

1. The utility model provides an intelligence 5G net twine threading mechanism which characterized in that: the wire feeding device comprises a threading part and a wire feeding part, wherein the wire feeding part comprises a wire winder (1), an auxiliary side handle (2), a wire feeding wheel (12), a shaft A (13), a gear B (14), a shaft B (15), a shaft (16) for controlling a wound steel wire, a wire winding wheel (17), a gear C (18), a thin shaft (19), an electromagnet (20), a shaft sleeve (21), a disc gear (22), a semi-gear (23), a gear E (24), a gear F (25), a gear G (26), a gear H (27), a motor (28), a gear I (29), a shell (30), a rear handle (31), a motor switch (32), a mode switch (33), an inner wire (35) and an outer wire (36), and the auxiliary side handle (2) is fixedly installed on the side surface of the shell (30); a rear handle (31) is arranged behind the shell (30); the motor (28) is fixedly arranged in the shell (30); the gear G (26) and the gear H (27) are fixedly arranged on a motor (28) shaft of the motor (28); the shaft B (15) is rotatably arranged in a shaft sleeve (21), and the shaft sleeve (21) is fixedly arranged in a circular hole of the shell (30); a half gear (23), a gear E (24), a gear F (25) and a disc gear (22) are all fixedly arranged on the shaft B (15), the half gear (23) is arranged on the top, the gear E (24) is arranged below the half gear (23), the gear F (25) is arranged below the gear E (24), and the disc gear (22) is arranged below the gear F (25); the electromagnet (20) is fixedly arranged in the shaft sleeve (21), one end of the shaft B (15) is provided with a spring, and the spring generates elastic force to enable the shaft B (15) to move upwards; the shaft (16) for controlling the wound steel wire is hollow, and the thin shaft (19) is rotatably arranged in the shaft (16) for controlling the wound steel wire; the winder (1) is fixedly arranged on the outer side of a shaft (16) for controlling a wound steel wire; the reel (17) is fixedly arranged on the thin shaft (19), and the reel (17) is arranged in the middle of the winder (1); the gear I (29) is fixedly arranged on the outer side of the shaft (16) for controlling the wire winding and is positioned below the wire winder (1); the gear C (18) is provided with a groove and is arranged at the lower ends of a shaft (16) for controlling a wound steel wire and a thin shaft (19); the gear C (18) is meshed with the disc gear (22); baffles are arranged on the upper side and the lower side of the disc gear (22) to enable the gear C (18) to move up and down along with the disc gear (22); two shafts A (13) are rotatably arranged in a circular hole of the shell (30), a wire feeding wheel (12) and a gear B (14) are fixedly arranged on the shafts A (13), the wire feeding wheel (12) is arranged above the gear B (14), the two gears B (14) are mutually meshed, and the gear B (14) is mutually meshed with the gear C (18).

2. The intelligent 5G network cable threading mechanism according to claim 1, wherein the threading part comprises a pulley (3), a telescopic pulley support (4), a drill bit (5), a threading hole (6), a linked outer cable groove (7), a steel wire threading hole (8), a spring (9), a gear A (10), a shaft (11) with a hole, an electric drill shell (34), the telescopic pulley support (4) is arranged on the side surface of the electric drill shell (34), and a pulley (3) is rotatably mounted on the telescopic pulley support (4); the shaft (11) with the hole is rotatably arranged in the electric drill shell (34), and the gear A (10) is arranged on the shaft (11) with the hole in a key way; the clockwork spring (9) is arranged on a shaft (11) with a hole and plays a role of automatically winding up, and the clockwork spring (9) is arranged above the gear A (10); a gear A (10) is arranged on the drill bit (5), the gear A (10) is a bevel gear, and the two gears A (10) are meshed with each other; a threading hole (6) is arranged on the drill bit (5); an outer line connecting groove (7) and a steel wire threading hole (8) are arranged on the electric drill shell (34).

3. The intelligent 5G network cable threading mechanism according to claim 1, wherein the threading part and the cable feeding part are connected by a brake cable, the brake cable is divided into an inner layer and an outer layer, one fixed end of the outer cable is fixedly arranged on a groove (7) for connecting the outer cable, and the inner cable passes through a steel cable threading hole (8) and is wound on a shaft (11) with a hole; the brake cable is wound on the winder (1), the other end of the outer cable is fixed on the winder (1), the inner cable is longer than the outer cable, and the part which is longer is wound on the winding wheel (17).