CN113307107A

CN113307107A - Multi-strand signal wire winding equipment for communication

Info

Publication number: CN113307107A
Application number: CN202110576200.1A
Authority: CN
Inventors: 刘国军
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-08-27

Abstract

The invention relates to multi-strand signal wire winding equipment, in particular to multi-strand signal wire winding equipment for communication, which comprises a skin rotary linkage mechanism, a hot pressing mechanism and a single-side rotating mechanism, wherein the equipment can fix a signal wire core, can rotate the skin of a signal wire and enable the skin of the signal wire to accumulate certain torsion when the signal wire core is fixed, can act the torsion accumulated by the skin of the signal wire on the signal wire core, can rotate one end of the signal wire core, is connected with the hot pressing mechanism, and is connected with the single-side rotating mechanism.

Description

Multi-strand signal wire winding equipment for communication

Technical Field

The invention relates to a multi-strand signal wire winding device, in particular to a multi-strand signal wire winding device for communication.

Background

When the multi-strand signal wire is wound, under the action of the reaction force of torsion generated when the signal wire is wound, the wound signal is automatically unwound, but no better multi-strand signal wire winding equipment exists in the market, so the multi-strand signal wire winding equipment for communication is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing a multi-strand signal wire winding device for communication, wherein the device can fix a signal wire core, the device can rotate a signal wire skin and enable the signal wire skin to accumulate certain torsion when the signal wire core is fixed, the device can enable the torsion accumulated by the signal wire skin to act on the signal wire core, and the device can enable one end of the signal wire core to rotate.

In order to solve the technical problem, the invention relates to a multi-strand signal wire winding device, and particularly relates to a multi-strand signal wire winding device for communication.

The skin rotary linkage mechanism is connected with the hot pressing mechanism and the unilateral rotating mechanism.

As a further optimization of the technical scheme, the invention relates to a multistrand signal wire winding device for communication, wherein a skin rotation linkage mechanism comprises a power shaft, a friction wheel a, a conical friction wheel a, an inclined shaft, a conical friction wheel b, a friction belt, a connecting shaft a, a friction wheel a, a connecting shaft b, a connecting plate a, a friction plate, a connecting rod, a pressing block, a square sleeve, a sliding square column, a connecting plate b, a connecting shaft c, a pressing spring, a connecting shaft d, a device connecting box, a signal wire core and a signal wire skin, the power shaft is connected with the friction wheel a, the power shaft is connected with a bearing of the device connecting box, the friction wheel a is in friction connection with the conical friction wheel a, the friction wheel a is in friction connection with the friction wheel a, the conical friction wheel a is connected with the inclined shaft, the inclined shaft is connected with the conical friction wheel b, the inclined shaft is connected with a bearing of the device connecting box, and the conical friction wheel b is in friction connection with the friction belt, one end of a friction belt is connected with the power shaft in a sliding way, the other end of the friction belt is connected with a connecting shaft a in a sliding way, the friction belt is connected with a signal wire skin in a friction way, the connecting shaft a is connected with a bearing of an equipment connecting box, a friction wheel a is connected with a connecting shaft b, the connecting shaft b is connected with a bearing of a connecting plate a, the connecting shaft b is connected with a friction plate in a friction way, the connecting plate a is connected with the equipment connecting box, the friction plate is connected with a connecting rod, the friction plate is connected with the equipment connecting box in a sliding way, the connecting rod is connected with a square sleeve, a pressing block is pressed on the signal wire core, one end of the pressing block is connected with a sliding square column, the other end of the pressing block is connected with a connecting shaft c, the square sleeve is connected with the sliding square column, one end of the connecting plate b is connected with the connecting shaft c in a sliding way, a pressing spring is sleeved on the connecting shaft d and limited on the connecting plate b and the equipment connecting box, and the equipment connecting box is connected with the sliding square column, the equipment connecting box is connected with the connecting shaft c in a sliding mode, and the signal wire core is connected with the signal wire skin.

As a further optimization of the technical scheme, the invention relates to a multistrand signal wire winding device for communication, wherein a hot pressing mechanism comprises a belt I, a winding shaft, steel wires, a steel wire limiting plate, a lifting plate a, a lifting plate b, an electric heater, a lifting limiting plate a, a lifting limiting plate b, a connecting plate c, a pushing shaft, a pushing supporting block, a pushing spring and a connecting plate d, one end of the belt I is in friction connection with the winding shaft, the other end of the belt I is in friction connection with a power shaft, the winding shaft is connected with two steel wire limiting plates, the winding shaft is connected with a connecting plate d through a bearing, the two steel wires are wound on the winding shaft, one end of the two steel wires are connected with the steel wire limiting plate b, the lifting plate A is connected with the lifting plate b, the lifting plate A is in sliding connection with the lifting limiting plate a, the lifting plate A is in sliding connection with the lifting limiting plate b, the lifting plate A is connected with the connecting plate c, and the lifting plate b is connected with the electric heater, the lifting limiting plate a is connected with the equipment connecting box, the lifting limiting plate b is connected with the equipment connecting box, the connecting plate c is connected with the pushing shaft, the pushing shaft is connected with the pushing supporting block in a sliding mode, the pushing supporting block is connected with the equipment connecting box, the pushing spring sleeve is arranged on the pushing shaft and limited on the equipment connecting box and the connecting plate c, and the connecting plate d is connected with the equipment connecting box.

As a further optimization of the technical scheme, the invention relates to a multi-strand signal wire winding device for communication, wherein the single-side rotating mechanism comprises a linkage belt a, a transmission shaft a, a first friction wheel, a mounting plate a, a linkage belt b, a transmission shaft b, a second friction wheel, a special-shaped friction wheel rotating groove, a toggle column, a limiting plate a, a limiting spring, a limiting plate b, a sliding guide strip and an arc sliding strip, one end of the linkage belt a is in friction connection with the transmission shaft a, the other end of the linkage belt a is in friction connection with a power shaft, the transmission shaft a is connected with the first friction wheel, the transmission shaft a is in bearing connection with the mounting plate a, the transmission shaft a is in friction connection with the linkage belt b, the first friction wheel is in friction connection with the special-shaped friction wheel, the mounting plate a is connected with a device connecting box, the linkage belt b is in friction connection with the transmission shaft b, the transmission shaft b is connected with the second friction wheel, the transmission shaft b is in bearing connection with the device connecting box, the friction wheel II is in friction connection with the special-shaped friction wheel, the special-shaped friction wheel is in sliding connection with the special-shaped friction wheel rotating groove, the special-shaped friction wheel is in sliding connection with the limiting plate a, the special-shaped friction wheel is connected with the limiting plate b, the special-shaped friction wheel is in sliding connection with the arc sliding strip, the special-shaped friction wheel rotating groove is connected with the equipment connecting box, the stirring column is connected with the arc sliding strip, the limiting spring is limited in the limiting plate a and the limiting plate b, and the sliding guide strip is connected with the equipment connecting box.

In order to further optimize the technical scheme, the invention provides the multi-strand signal wire winding device for communication, wherein a large number of resistors are arranged in the electric heater, and a metal heat conducting plate on the surface can generate heat after the power is switched on.

The invention discloses a multi-strand signal wire winding device for communication, which has the beneficial effects that:

according to the multi-strand signal wire winding equipment for communication, the equipment can fix the signal wire core, the equipment can rotate the signal wire skin when the signal wire core is fixed and enable the signal wire skin to accumulate certain torsion, the equipment can enable the torsion accumulated by the signal wire skin to act on the signal wire core, and the equipment can enable one end of the signal wire core to rotate.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural view of a multi-strand signal wire winding apparatus for communication according to the present invention.

Fig. 2 is a first schematic structural diagram of a cover rotating linkage mechanism 1 of a multi-strand signal wire winding device for communication according to the present invention.

Fig. 3 is a schematic structural diagram of a cover rotating linkage mechanism 1 of a multi-strand signal wire winding device for communication according to the present invention.

Fig. 4 is a schematic structural diagram three of the covering rotary linkage mechanism 1 of the multi-strand signal wire winding device for communication according to the present invention.

Fig. 5 is a schematic structural diagram of a cover rotating linkage mechanism 1 of a multistrand signal wire winding device for communication according to the present invention.

Fig. 6 is a schematic structural diagram five of the covering rotary linkage mechanism 1 of the multistrand signal wire winding device for communication according to the present invention.

Fig. 7 is a sixth schematic structural view of the covering rotary linkage mechanism 1 of the multi-strand signal wire winding device for communication according to the present invention.

Fig. 8 is a schematic structural view of an apparatus connection box 1-20 of a multi-strand signal wire winding apparatus for communication according to the present invention.

Fig. 9 is a first schematic structural diagram of a heat pressing mechanism 2 of a multi-strand signal wire winding apparatus for communication according to the present invention.

Fig. 10 is a second schematic structural diagram of the thermocompression mechanism 2 of the multi-strand signal wire winding device for communication according to the present invention.

Fig. 11 is a third schematic structural diagram of the thermocompression mechanism 2 of the multi-strand signal wire winding device for communication according to the present invention.

Fig. 12 is a first schematic structural view of a single-side rotating mechanism 3 of a multi-strand signal wire winding apparatus for communication according to the present invention.

Fig. 13 is a second schematic structural view of a single-side rotating mechanism 3 of a multi-strand signal wire winding apparatus for communication according to the present invention.

Fig. 14 is a third schematic structural view of a single-side rotating mechanism 3 of a multi-strand signal wire winding apparatus for communication according to the present invention.

Fig. 15 is a fourth schematic structural view of the single-side rotating mechanism 3 of the multi-strand signal wire winding apparatus for communication according to the present invention.

In the figure: a skin rotation linkage mechanism 1; a power shaft 1-1; friction wheel a 1-2; a conical friction wheel a 1-3; an inclined axis 1-4; a conical friction wheel b 1-5; 1-6 of friction belt; connecting shaft a 1-7; friction wheel a 1-8; connecting shaft b 1-9; connecting plate a 1-10; 1-11 of friction plates; connecting rods 1-12; 1-13 of a compression block; 1-14 parts of square sleeve; 1-15 of a sliding square column; connecting plate b 1-16; connecting shafts c 1-17; pressing the springs 1-18; connecting shafts d 1-19; 1-20 parts of an equipment connecting box; 1-21 of signal wire core; signal line skins 1-22; a hot-press mechanism 2; 2-1 of a first belt; a winding shaft 2-2; 2-3 parts of steel wire; 2-4 steel wire limiting plates; lifting plate a 2-5; lifting plate b 2-6; 2-7 parts of an electric heater; the lifting limit plate a 2-8; a lifting limit plate b 2-9; connecting plate c 2-10; pushing the shaft 2-11; pushing the supporting block 2-12; pushing springs 2-13; connecting plate d 2-14; a single-side rotating mechanism 3; a link belt a 3-1; a transmission shaft a 3-2; 3-3 parts of a first friction wheel; mounting plate a 3-4; a link belt b 3-5; a transmission shaft b 3-6; 3-7 parts of a second friction wheel; 3-8 parts of a special-shaped friction wheel; 3-9 parts of a special-shaped friction wheel rotating groove; stirring the column for 3-10 times; the limiting plate a 3-11; 3-12 parts of a limiting spring; the limiting plate b 3-13; sliding guide bars 3-14; and 3-15 arc sliding bars.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the present invention relates to a multi-strand signal line winding device for communication, and more specifically to a multi-strand signal line winding device for communication, which includes a sampling mechanism 1, an anti-collision box mechanism 2, an adjusting mechanism 3, and a clamping mechanism 4, and the device can clamp an unmanned aerial vehicle, and can adjust the size of clamping the unmanned aerial vehicle, and the device can protect the unmanned aerial vehicle, and can stably stay on the water surface, and can sample, and the device can automatically release a sampled water sample.

Sampling mechanism 1 sets up in the inside of crashproof box mechanism 2, and adjustment mechanism 3 is located crashproof box mechanism 2's top, and clamping mechanism 4 is located adjustment mechanism 3's top.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, and the embodiment further describes the embodiment, and the embodiment includes a skin rotation linkage mechanism 1 including a power shaft 1-1, a friction wheel a1-2, a tapered friction wheel a1-3, an inclined shaft 1-4, a tapered friction wheel b1-5, a friction belt 1-6, a connecting shaft a1-7, a friction wheel a1-8, a connecting shaft b1-9, a connecting plate a1-10, a friction plate 1-11, a connecting rod 1-12, a pressing block 1-13, a square sleeve 1-14, a sliding square column 1-15, a connecting plate b1-16, a connecting shaft c1-17, a pressing spring 1-18, a connecting shaft d1-19, a connecting shaft b, The equipment connecting box comprises equipment connecting boxes 1-20, signal wire cores 1-21 and signal wire skins 1-22, wherein a power shaft 1-1 is connected with a friction wheel a1-2, the power shaft 1-1 is in bearing connection with the equipment connecting box 1-20, the friction wheel a1-2 is in friction connection with a conical friction wheel a1-3, the friction wheel a1-2 is in friction connection with a friction wheel a1-8, the conical friction wheel a1-3 is connected with an inclined shaft 1-4, the inclined shaft 1-4 is connected with a conical friction wheel b1-5, the inclined shaft 1-4 is in bearing connection with the equipment connecting box 1-20, the conical friction wheel b1-5 is in friction connection with friction belts 1-6, one end of each friction belt 1-6 is in sliding connection with the power shaft 1-1, the other end of each friction belt is in sliding connection with a connecting shaft a1-7, and each friction belt 1-6 is in friction connection with the signal wire skins 1-22, the connecting shaft a1-7 is connected with an equipment connecting box 1-20 through a bearing, the friction wheel a1-8 is connected with the connecting shaft b1-9, the connecting shaft b1-9 is connected with a connecting plate a1-10 through a bearing, the connecting shaft b1-9 is connected with a friction plate 1-11 through a friction connection, the connecting plate a1-10 is connected with an equipment connecting box 1-20, the friction plate 1-11 is connected with a connecting rod 1-12, the friction plate 1-11 is connected with an equipment connecting box 1-20 through a sliding connection, the connecting rod 1-12 is connected with a square sleeve 1-14, a compression block 1-13 is pressed on a signal wire core 1-21, one end of the compression block is connected with a sliding square column 1-15, the other end of the compression block is connected with a connecting shaft c1-17, the square sleeve 1-14 is connected with a sliding square column 1-15 through a sliding connection, one end of a connecting plate b1-16 is connected with the sliding square column 1-15, the other end of the connecting wire is connected with a connecting shaft c1-17, a connecting plate b1-16 is connected with a connecting shaft d1-19 in a sliding mode, a compression spring 1-18 is sleeved on the connecting shaft d1-19 and limited on the connecting plate b1-16 and an equipment connecting box 1-20, the equipment connecting box 1-20 is connected with a sliding square column 1-15 in a sliding mode, the equipment connecting box 1-20 is connected with a connecting shaft c1-17 in a sliding mode, and a signal wire core 1-21 is connected with a signal wire skin 1-22.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the embodiment further describes the embodiment, where the hot press mechanism 2 includes a belt one 2-1, a winding shaft 2-2, a steel wire 2-3, a steel wire limit plate 2-4, a lift plate a2-5, a lift plate b2-6, an electric heater 2-7, a lift limit plate a2-8, a lift limit plate b2-9, a connection plate c2-10, a pushing shaft 2-11, a pushing support block 2-12, a pushing spring 2-13, and a connection plate d2-14, one end of the belt one 2-1 is frictionally connected to the winding shaft 2-2, and the other end is frictionally connected to a power shaft 1-1, a winding shaft 2-2 is connected with two steel wire limit plates 2-4, the winding shaft 2-2 is connected with a connecting plate d2-14 through a bearing, two steel wires 2-3 are wound on the winding shaft 2-2, one end of each steel wire 2-2 is connected with the steel wire limit plate 2-4, the other end of each steel wire 2-2 is connected with a lifting plate a2-5, the lifting plate a2-5 is connected with a lifting plate b2-6, the lifting plate a2-5 is connected with a lifting limit plate a2-8 in a sliding manner, the lifting plate a2-5 is connected with a lifting limit plate b2-9 in a sliding manner, the lifting plate a2-5 is connected with a connecting plate c2-10, the lifting plate b2-6 is connected with an electric heater 2-7, the lifting limit plate a2-8 is connected with an equipment connecting box 1-20, the lifting limit plate b2-9 is connected with an equipment connecting box 1-20, the connecting plate c2-10 is connected with a pushing shaft 2-11, the pushing shaft 2-11 is connected with the pushing support block 2-12 in a sliding mode, the pushing support block 2-12 is connected with the equipment connecting box 1-20, the pushing spring 2-13 is sleeved on the pushing shaft 2-11 and limited on the equipment connecting box 1-20 and the connecting plate c2-10, and the connecting plate d2-14 is connected with the equipment connecting box 1-20.

The fourth concrete implementation mode:

the embodiment is described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, and fig. 15, and the embodiment further describes the embodiment, where the single-side rotating mechanism 3 includes a linkage belt a3-1, a transmission shaft a3-2, a friction wheel i 3-3, a mounting plate a3-4, a linkage belt b3-5, a transmission shaft b3-6, a friction wheel ii 3-7, a shaped friction wheel 3-8, a shaped friction wheel rotating groove 3-9, a toggle column 3-10, a limiting plate a3-11, a limiting spring 3-12, a limiting plate b3-13, a sliding guide strip 3-14, and an arc sliding strip 3-15, one end of the linkage belt a3-1 is frictionally connected to the transmission shaft a3-2, the other end of the transmission shaft is in friction connection with a power shaft 1-1, a transmission shaft a3-2 is connected with a friction wheel I3-3, a transmission shaft a3-2 is in bearing connection with an installation plate a3-4, a transmission shaft a3-2 is in friction connection with a linkage belt b3-5, a friction wheel I3-3 is in friction connection with a special-shaped friction wheel 3-8, an installation plate a3-4 is connected with an equipment connecting box 1-20, a linkage belt b3-5 is in friction connection with a transmission shaft b3-6, a transmission shaft b3-6 is connected with a friction wheel II 3-7, a transmission shaft b3-6 is in bearing connection with an equipment connecting box 1-20, a friction wheel II 3-7 is in friction connection with a special-8, a special-shaped friction wheel 3-8 is in sliding connection with a special-shaped friction wheel rotating groove 3-9, a special-shaped friction wheel 3-8 is in sliding connection with a limit plate a3-11, the special-shaped friction wheel 3-8 is connected with a limit plate b3-13, the special-shaped friction wheel 3-8 is connected with an arc sliding strip 3-15 in a sliding mode, a special-shaped friction wheel rotating groove 3-9 is connected with an equipment connecting box 1-20, a toggle column 3-10 is connected with the arc sliding strip 3-15, a limit spring 3-12 is limited on a limit plate a3-11 and a limit plate b3-13, and a sliding guide strip 3-14 is connected with an equipment connecting box 1-20.

The fifth concrete implementation mode:

the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 and 15, and the present embodiment will be described in more detail with reference to the following embodiments, in which the electric heaters 2 to 7 have a large number of resistors disposed therein and the metal heat-conducting plate on the surface can generate heat after the power is turned on.

The working principle of the device is as follows: the equipment can fix the signal wire core, the equipment can rotate a signal wire skin and enable the signal wire skin to accumulate certain torsion when the signal wire core is fixed, the power shaft 1-1 rotates to drive the friction wheel a1-2 to rotate, the friction wheel a1-2 rotates to drive the conical friction wheel a1-3 to rotate, the conical friction wheel a1-3 rotates to drive the conical friction wheel b1-5 to rotate through the inclined shaft 1-4, the conical friction wheel b1-5 rotates to drive the friction belt 1-6 to move, the friction belt 1-6 drives the signal wire skin 1-22 to rotate when moving, under the action of the shape characteristics of the conical friction wheel b1-5, the signal wire skin 1-22 at one end of the friction wheel a1-2 is driven to decelerate, the signal wire skin 1-22 at one end far away from the friction wheel a1-2 is driven to accelerate, the signal wire cores 1-21 are pressed by the pressing blocks 1-13, the pressing blocks 1-13 are pulled downwards under the action of the sliding square columns 1-15, the connecting plates b1-16, the connecting shafts c1-17, the pressing springs 1-18 and the connecting shafts d1-19, namely the signal wire cores 1-21 fix the signal wire skins 1-22 and are driven to rotate to accumulate torsion;

the equipment can apply the torsion accumulated by the signal wire skin on the signal wire core, when the power shaft 1-1 rotates, the belt I2-1 drives the winding shaft 2-2 to rotate, the winding shaft 2-2 rotates to drive the steel wire limit plate 2-4 to rotate, the steel wires 2-3 on the two winding shafts 2-2 are gradually unwound, at the moment, under the action of the pushing spring 2-13, the pushing shaft 2-11 presses the lifting plate a2-5 to move downwards through the connecting plate c2-10, the lifting plate a2-5 slides downwards under the limitation of the lifting limit plate a2-8 and the lifting limit plate b2-9, when the lifting plate a2-5 drives the lifting plate b2-6 to move downwards to be contacted with the signal wire skin 1-22, the electric heater 2-7 in the power supply is switched on to heat the signal wire skin 1-22, the signal wire skins 1-22 are locally adhered to the signal wire cores 1-21, namely most of torsion accumulated on the signal wire skins 1-22 acts on the signal wire cores 1-21;

the equipment can rotate one end of a signal wire core, when a power shaft 1-1 rotates reversely, a conical friction wheel a1-3 rotates to drive a friction wheel a1-8 to rotate, the friction wheel a1-8 rotates to drive a connecting shaft b1-9 to rotate, the connecting shaft b1-9 rotates to drive a friction plate 1-11 to move towards a connecting rod 1-12, the connecting rod 1-12 moves to drive two sliding square columns 1-15 to move through square sleeves 1-14, the sliding square columns 1-15 drive a connecting shaft c1-17 to move through compression blocks 1-13, the signal wire core 1-21 is also stirred to move when the compression blocks 1-13 move to be in contact with sliding guide strips 3-14, the signal wire core 1-21 slides to a long strip groove on a special-shaped friction wheel 3-8 under the guide of the sliding guide strips 3-14, at the moment, the power shaft 1-1 stops rotating, the toggle columns 3-10 are pulled, the toggle columns 3-10 drive the arc sliding strips 3-15 to move under the limitation of the circular grooves on the special-shaped friction wheels 3-8, when the other toggle column 3-10 is contacted with the limiting plate a3-11, the arc sliding strips 3-15 seal the long grooves on the special-shaped friction wheels 3-8, the arc sliding strips 3-15 and the special-shaped friction wheels 3-8 limit the relative positions of the toggle signal wire cores 1-21, the limiting plate a3-11 continuously presses the arc sliding strips 3-10 under the action of the limiting springs 3-12, the power shaft 1-1 continuously rotates, the power shaft 1-1 drives the transmission shaft a3-2 to rotate through the linkage belt a3-1, the transmission shaft a3-2 drives the friction wheel I3-3 to rotate, the transmission shaft a3-2 also drives the transmission shaft b3-6 to rotate through the linkage belt b3-5, the transmission shaft b3-6 rotates to drive the friction wheel II 3-7 to rotate, when the friction wheel I3-3 and the friction wheel II 3-7 rotate, the special-shaped friction wheel 3-8 is driven to rotate, one end of the signal wire core rotates when the special-shaped friction wheel 3-8 rotates, at the moment, the torsion accumulated on the signal wire core 1-21 and the signal wire skin 1-22 is released, so that the rotated signal wire core 1-21 and the signal wire skin 1-22 are not influenced by the torsion, namely, the signal wire core 1-21 and the signal wire skin 1-22 cannot generate the phenomenon of automatically releasing winding after being taken out of equipment.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a communication is with stranded signal line winding equipment, includes covering rotary linkage mechanism (1), hot pressing mechanism (2), unilateral rotary mechanism (3), its characterized in that: the skin rotary linkage mechanism (1) is connected with the hot pressing mechanism (2), and the skin rotary linkage mechanism (1) is connected with the unilateral rotating mechanism (3).

2. A multi-strand signal wire winding apparatus for telecommunications according to claim 1, wherein: the skin rotary linkage mechanism (1) comprises a power shaft (1-1), a friction wheel a (1-2), a conical friction wheel a (1-3), an inclined shaft (1-4), a conical friction wheel b (1-5), a friction belt (1-6), a connecting shaft a (1-7), a friction wheel a (1-8), a connecting shaft b (1-9), a connecting plate a (1-10), a friction plate (1-11), a connecting rod (1-12), a pressing block (1-13), a square sleeve (1-14), a sliding square column (1-15), a connecting plate b (1-16), a connecting shaft c (1-17), a pressing spring (1-18), a connecting shaft d (1-19), an equipment connecting box (1-20), a signal wire core (1-21), The signal line covering device comprises signal line covering skins (1-22), a power shaft (1-1) is connected with a friction wheel a (1-2), the power shaft (1-1) is in bearing connection with an equipment connection box (1-20), the friction wheel a (1-2) is in friction connection with a conical friction wheel a (1-3), the friction wheel a (1-2) is in friction connection with a friction wheel a (1-8), the conical friction wheel a (1-3) is connected with an inclined shaft (1-4), the inclined shaft (1-4) is connected with a conical friction wheel b (1-5), the inclined shaft (1-4) is in bearing connection with the equipment connection box (1-20), the conical friction wheel b (1-5) is in friction connection with a friction belt (1-6), one end of the friction belt (1-6) is in sliding connection with the power shaft (1-1), the other end is connected with a connecting shaft a (1-7) in a sliding way, a friction belt (1-6) is connected with a signal line skin (1-22) in a friction way, the connecting shaft a (1-7) is connected with an equipment connecting box (1-20) in a bearing way, a friction wheel a (1-8) is connected with a connecting shaft b (1-9), the connecting shaft b (1-9) is connected with a connecting plate a (1-10) in a bearing way, the connecting shaft b (1-9) is connected with a friction plate (1-11) in a friction way, the connecting plate a (1-10) is connected with the equipment connecting box (1-20), the friction plate (1-11) is connected with a connecting rod (1-12), the friction plate (1-11) is connected with the equipment connecting box (1-20) in a sliding way, the connecting rod (1-12) is connected with a square sleeve (1-14), the pressing block (1-13) is pressed on the signal wire core (1-21), one end of the pressing block is connected with the sliding square column (1-15), the other end of the pressing block is connected with the connecting shaft c (1-17), the square sleeve (1-14) is connected with the sliding square column (1-15) in a sliding manner, one end of the connecting plate b (1-16) is connected with the sliding square column (1-15), the other end of the connecting plate b (1-17) is connected with the connecting shaft c (1-17), the connecting plate b (1-16) is connected with the connecting shaft d (1-19) in a sliding manner, the pressing spring (1-18) is sleeved on the connecting shaft d (1-19) and limited on the connecting plate b (1-16) and the equipment connecting box (1-20), the equipment connecting box (1-20) is connected with the connecting shaft sliding square column (1-15) in a sliding manner, the equipment connecting box (1-20) is connected with the connecting shaft c (1-17) in a sliding manner, the signal wire cores (1-21) are connected with the signal wire skins (1-22).

3. A multi-strand signal wire winding apparatus for telecommunications according to claim 1, wherein: the hot pressing mechanism (2) comprises a belt I (2-1), a winding shaft (2-2), steel wires (2-3), steel wire limiting plates (2-4), lifting plates a (2-5), lifting plates b (2-6), electric heaters (2-7), lifting limiting plates a (2-8), lifting limiting plates b (2-9), connecting plates c (2-10), a pushing shaft (2-11), a pushing support block (2-12), a pushing spring (2-13) and a connecting plate d (2-14), one end of the belt I (2-1) is in friction connection with the winding shaft (2-2), the other end of the belt I (2-1) is in friction connection with the power shaft (1-1), the winding shaft (2-2) is connected with the two steel wire limiting plates (2-4), the winding shaft (2-2) is in bearing connection with the connecting plate d (2-14), two steel wires (2-3) are wound on the winding shaft (2-2), one end of each steel wire is connected with a steel wire limit plate (2-4), the other end of each steel wire is connected with a lifting plate a (2-5), the lifting plate a (2-5) is connected with a lifting plate b (2-6), the lifting plate a (2-5) is in sliding connection with a lifting limit plate a (2-8), the lifting plate a (2-5) is in sliding connection with a lifting limit plate b (2-9), the lifting plate a (2-5) is connected with a connecting plate c (2-10), the lifting plate b (2-6) is connected with an electric heater (2-7), the lifting limit plate a (2-8) is connected with an equipment connecting box (1-20), and the lifting limit plate b (2-9) is connected with the equipment connecting box (1-20), the connecting plate c (2-10) is connected with the pushing shaft (2-11), the pushing shaft (2-11) is connected with the pushing supporting block (2-12) in a sliding mode, the pushing supporting block (2-12) is connected with the equipment connecting box (1-20), the pushing spring (2-13) is sleeved on the pushing shaft (2-11) and limited on the equipment connecting box (1-20) and the connecting plate c (2-10), and the connecting plate d (2-14) is connected with the equipment connecting box (1-20).

4. A multi-strand signal wire winding apparatus for telecommunications according to claim 1, wherein: the single-side rotating mechanism (3) comprises a linkage belt a (3-1), a transmission shaft a (3-2), a friction wheel I (3-3), a mounting plate a (3-4), a linkage belt b (3-5), a transmission shaft b (3-6), a friction wheel II (3-7), a special-shaped friction wheel (3-8), a special-shaped friction wheel rotating groove (3-9), a toggle column (3-10), a limiting plate a (3-11), a limiting spring (3-12), a limiting plate b (3-13), a sliding guide strip (3-14) and an arc sliding strip (3-15), one end of the linkage belt a (3-1) is in friction connection with the transmission shaft a (3-2), the other end of the linkage belt a (3-1) is in friction connection with the power shaft (1-1), and the transmission shaft a (3-2) is connected with the friction wheel I (3-3), a transmission shaft a (3-2) is in bearing connection with a mounting plate a (3-4), the transmission shaft a (3-2) is in friction connection with a linkage belt b (3-5), a friction wheel I (3-3) is in friction connection with a special-shaped friction wheel (3-8), the mounting plate a (3-4) is connected with an equipment connecting box (1-20), the linkage belt b (3-5) is in friction connection with a transmission shaft b (3-6), the transmission shaft b (3-6) is connected with a friction wheel II (3-7), the transmission shaft b (3-6) is in bearing connection with the equipment connecting box (1-20), the friction wheel II (3-7) is in friction connection with the special-shaped friction wheel (3-8), the special-shaped friction wheel (3-8) is in sliding connection with a special-shaped friction wheel rotating groove (3-9), the special-shaped friction wheel (3-8) is connected with the limiting plate a (3-11) in a sliding mode, the special-shaped friction wheel (3-8) is connected with the limiting plate b (3-13), the special-shaped friction wheel (3-8) is connected with the arc sliding strip (3-15) in a sliding mode, the special-shaped friction wheel rotating groove (3-9) is connected with the equipment connecting box (1-20), the toggle column (3-10) is connected with the arc sliding strip (3-15), the limiting spring (3-12) is limited on the limiting plate a (3-11) and the limiting plate b (3-13), and the sliding guide strip (3-14) is connected with the equipment connecting box (1-20).

5. A multi-strand signal wire winding apparatus for telecommunications according to claim 1, wherein: the electric heaters (2-7) are internally provided with a large number of resistors, and the metal heat conducting plate on the surface can generate heat after the power is switched on.