CN117303128B - Wire winding device convenient for replacing stranded wire for manufacturing electric wire and cable - Google Patents

Abstract

The invention discloses a wire winding device convenient for replacing stranded wires for manufacturing wires and cables, which relates to the technical field of cable winding equipment and comprises a supporting mechanism, a shrinking mechanism and a translation mechanism, wherein when the wire winding device works, the shrinking mechanism drives a shrinking assembly to work through a second driving unit so as to drive a first bearing plate connected with the shrinking assembly to expand or shrink, and synchronously, the first bearing plate also drives a second bearing plate to expand or shrink, and the translation mechanism drives the bearing assembly and the second bearing plate to translate through a stretching unit so as to change the overall length of the second bearing plate and the first bearing plate.

Description

Wire winding device convenient for replacing stranded wire for manufacturing electric wire and cable

Technical Field

The invention relates to the technical field of wire and cable manufacturing, in particular to a wire winding device with stranded wires convenient to replace for wire and cable manufacturing.

Background

The cable is made of one or more mutually insulated conductors and an outer insulating protective layer, wires for transmitting power or information from one place to another are usually rope-like cables formed by twisting several or groups of wires (at least two wires per group), each group of wires are mutually insulated and are usually twisted around a center, the whole outer surface is covered with a highly insulating coating layer, the cable has the characteristics of inner power supply and outer insulation, and in the cable manufacturing process, the whole electric wires and cables are often required to be wound into bundles, and the processes are usually completed through electric wire and cable winding and unwinding devices and the like.

However, the existing wire and cable winding device is generally fixed in structure, so that the winding device can only perform winding work on a specific type or length of wire and cable, and has low applicability.

Disclosure of Invention

In view of the above, the main object of the present invention is to provide a take-up device for wire and cable manufacture, which is convenient for replacing stranded wires, and which is capable of solving the above-mentioned problems.

In order to achieve the above purpose, the present invention adopts the following technical scheme: wire and cable makes with take-up of conveniently changing stranded conductor includes:

the support mechanism comprises a support frame, a first driving unit arranged on one side of the support frame, a first rotating piece connected with the first driving unit and rotationally arranged on the support frame, and a second rotating piece which is arranged opposite to the first rotating piece and rotationally arranged on the support frame;

the contraction mechanism is arranged on the inner side of the first rotating piece and comprises a second driving unit fixedly connected with the first rotating piece, a contraction assembly arranged on one side of the second driving unit and connected with the second driving unit, and a plurality of first bearing plates connected with the contraction assembly and used for bearing wires and cables, wherein the plurality of first bearing plates are connected to the contraction assembly in a surrounding shape, and the size of the surrounding diameters of the plurality of first bearing plates can be synchronously changed when the contraction assembly works;

the translation mechanism comprises a telescopic unit which is arranged on one side of the second rotating piece and used for driving the second rotating piece to translate, and a bearing assembly which is arranged on the other side of the second rotating piece and used for supporting a plurality of second bearing plates, wherein the second bearing plates are correspondingly spliced with the first bearing plates in the length direction, the second bearing plates shrink/expand along with the shrinkage/expansion of the first bearing plates, and the telescopic unit drives the bearing assembly and the second bearing plates to translate along the length direction of the second bearing plates.

As a preferable scheme, the first rotating member comprises a first rotating roller rotatably arranged on the supporting frame and a plurality of first rotating rods arranged in an array along the circumferential direction of the first rotating roller;

and a placing groove for placing the second driving unit is formed in one side, close to the second driving unit, of the first rotating roller.

As a preferable scheme, the second rotating member comprises a second rotating roller rotatably arranged on the supporting frame and a plurality of second rotating rods arranged in an array along the circumferential direction of the second rotating roller;

the second rotating roller is provided with an annular groove which is used for being clamped with the output shaft of the telescopic unit at a position corresponding to the telescopic unit.

As a preferable scheme, the first rotating rods and the second rotating rods are arranged in one-to-one correspondence.

As a preferable scheme, the contraction component comprises a rotating disc connected with the second driving unit and internally provided with a plurality of arc grooves, a sliding rod arranged in the arc grooves in a sliding way, a first connecting rod fixedly connected with the sliding rod, and fixedly connected with the first bearing plate at the other end, and a fixed disc arranged at one side of the rotating disc;

the surface of the fixed disc is provided with a plurality of sliding grooves for placing the first connecting rods.

As a preferable scheme, the fixed disc is fixedly connected to the supporting frame through a fixed shaft, and the second rotating piece is sleeved on the outer side of the fixed shaft.

As a preferable scheme, the bearing assembly comprises a bearing disc which is arranged on the fixed shaft in a sliding manner and a second connecting rod which is arranged on the bearing disc in a sliding manner and is fixedly connected with the second bearing plate.

As a preferable scheme, a limiting groove for placing the second bearing plate is formed in the first bearing plate.

As a preferable scheme, a first chute matched with the first bearing plate is formed in the first rotating rod, and a second chute matched with the second bearing plate is formed in the second rotating rod.

Compared with the prior art, the invention has obvious advantages and beneficial effects, and particularly, the technical scheme mainly comprises the following steps;

this device is through setting up shrink mechanism and translation mechanism, at the during operation, shrink mechanism drives shrink subassembly work and then drives the first loading board that is connected with shrink subassembly through the second drive unit and expand or shrink, and simultaneously, first loading board also can drive the second loading board and expand or shrink, translation mechanism utilizes the flexible unit to drive the translation of loading subassembly and second loading board, thereby change the overall length of second loading board and first loading board, in this way, the operating personnel can adjust the overall length of first loading board and second loading board and by the external diameter size of the circular ring that multiunit first loading board, second loading board formed according to different grade type or different length electric wire and cable, in order to adapt to the receipts line of different length or different grade type electric wire and cable, the device convenient to use, simultaneously the suitability is strong.

In order to more clearly illustrate the structural features and efficacy of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and examples.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present invention;

FIG. 2 is a schematic view of the structure of the first rotary member of the present invention;

FIG. 3 is a schematic view of the structure of the retraction assembly of the present invention;

FIG. 4 is a schematic view of a partial structure of the present invention;

FIG. 5 is a schematic view of a second rotary member and the like according to the present invention;

fig. 6 is a cross-sectional view of the first carrier plate and the second carrier plate.

Reference numerals illustrate: 1. a support mechanism; 11. a support frame; 12. a first driving unit; 13. a first rotating member; 131. a first rotating roller; 1311. a placement groove; 132. a first rotating lever; 1321. a first chute; 14. a second rotating member; 141. a second rotating roller; 1411. an annular groove; 142. a second rotating lever; 1421. a second chute;

2. a retraction mechanism; 21. a second driving unit; 22. a retraction assembly; 221. a rotating disc; 2211. an arc-shaped groove; 222. a slide bar; 223. a first connecting rod; 224. a fixed plate; 2241. a sliding groove; 225. a fixed shaft; 23. a first bearing plate; 231. a limit groove;

3. a translation mechanism; 31. a telescoping unit; 32. a second bearing plate; 33. a carrier assembly; 331. a carrying tray; 332. and a second connecting rod.

Description of the embodiments

For the purpose of making the technical solution and advantages of the present invention more apparent, the present invention will be further described in detail below with reference to the accompanying drawings and examples of implementation. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Referring to fig. 1-2, an embodiment of the present invention provides a take-up device for manufacturing wires and cables, which is convenient for replacing stranded wires, and includes:

the support mechanism 1, the support mechanism 1 includes a support frame 11, a first driving unit 12 disposed at one side of the support frame 11, a first rotating member 13 connected with the first driving unit 12 and rotatably disposed on the support frame 11, and a second rotating member 14 disposed opposite to the first rotating member 13 and rotatably disposed on the support frame 11;

the contraction mechanism 2 is arranged on the inner side of the first rotating member 13, and comprises a second driving unit 21 fixedly connected with the first rotating member 13, a contraction assembly 22 arranged on one side of the second driving unit 21 and connected with the second driving unit 21, and a plurality of first bearing plates 23 connected with the contraction assembly 22 and used for bearing wires and cables, wherein the plurality of first bearing plates 23 are connected to the contraction assembly 22 in a surrounding shape, and the size of the surrounding diameters of the plurality of first bearing plates 23 can be synchronously changed when the contraction assembly 22 works;

the translation mechanism 3, the translation mechanism 3 includes a telescopic unit 31 disposed on one side of the second rotating member 14 and used for driving the second rotating member 14 to translate, and a bearing assembly 33 disposed on the other side of the second rotating member 14 and used for supporting a plurality of second bearing plates 32, where the plurality of second bearing plates 32 are spliced with the plurality of first bearing plates 23 correspondingly in the length direction, and the second bearing plates 32 shrink/expand along with the shrinkage/expansion of the first bearing plates 23, and the telescopic unit 31 drives the bearing assembly 33 and the second bearing plates 32 to translate along the length direction of the second bearing plates 32.

In this embodiment, by setting the shrinking mechanism 2 to cooperate with the translation mechanism 3 and the supporting mechanism 1, during operation, the shrinking mechanism 2 drives the shrinking assembly 22 to operate through the second driving unit 21 so as to drive the first carrying plate 23 connected with the shrinking assembly 22 to expand or shrink, and synchronously, the first carrying plate 23 also drives the second carrying plate 32 to expand or shrink, and the translation mechanism 3 utilizes the stretching unit 31 to drive the carrying assembly 33 and the second carrying plate 32 to translate, so that the overall length of the second carrying plate 32 and the first carrying plate 23 is changed to adapt to the wire winding operation of different lengths or different types of wires and cables.

Referring to fig. 2, the first rotating member 13 includes a first rotating roller 131 rotatably disposed on the supporting frame 11, and a plurality of first rotating rods 132 disposed in an array along a circumferential direction of the first rotating roller 131;

a placement groove 1311 for placing the second driving unit 21 is formed on one side of the first rotating roller 131 near the second driving unit 21.

In this embodiment, the first driving unit 12 drives the first rotating roller 131 and the plurality of first rotating rods 132 to rotate synchronously when in operation, and the first rotating roller 131 drives the second driving unit 21 disposed therein to rotate so as to drive the first bearing plate 23 to rotate.

Referring to fig. 1 to 5, the second rotating member 14 includes a second rotating roller 141 rotatably disposed on the supporting frame 11, and a plurality of second rotating rods 142 disposed in an array along a circumferential direction of the second rotating roller 141;

the second rotating roller 141 is provided with an annular groove 1411 at a position corresponding to the telescopic unit 31 for clamping the output shaft of the telescopic unit 31;

the first rotating rods 132 are disposed in one-to-one correspondence with the second rotating rods 142.

In this embodiment, when the first driving unit 12 drives the first rotating rod 132 to rotate, the first rotating rod 132 synchronously drives the second rotating rod 142 and the second rotating roller 141 to rotate through the first bearing plate 23 and the second bearing plate 32, so as to realize the normal operation of the wire winding device, meanwhile, the output shaft of the telescopic unit 31 is clamped in the annular groove 1411, when the second rotating roller 141 rotates, the output shaft of the telescopic unit 31 also rotates in the annular groove 1411, and when the telescopic unit 31 operates, the output shaft of the telescopic unit 31 drives the second rotating roller 141 to horizontally move along the axial direction thereof;

preferably, the telescopic unit 31 is an electric push rod.

Referring to fig. 1 to 3, the retraction assembly 22 includes a rotating disc 221 connected to the second driving unit 21 and having a plurality of arc grooves 2211 formed therein, a sliding rod 222 slidably disposed in the arc grooves 2211, a first connecting rod 223 fixedly connected to the sliding rod 222 and having the other end fixedly connected to the first carrying plate 23, and a fixing disc 224 disposed on one side of the rotating disc 221;

the surface of the fixed disk 224 is provided with a plurality of sliding grooves 2241 for placing the first connecting rod 223;

the fixed disk 224 is fixedly connected to the supporting frame 11 through a fixed shaft 225, and the second rotating member 14 is sleeved outside the fixed shaft 225.

In the present embodiment, the second driving unit 21 drives the rotating disc 221 to rotate when working, and since the fixed disc 224 is fixedly arranged, the sliding rod 222 arranged in the arc-shaped groove 2211 slides in the arc-shaped groove 2211 and drives the first connecting rod 223 to slide in the sliding groove 2241, and the first connecting rod 223 moves in the sliding groove 2241 and simultaneously drives the first carrying plate 23 to synchronously move, thereby achieving the effect of changing the position of the first carrying plate 23;

in order to ensure that the fixed disk 224 does not rotate, the fixed disk 224 is fixedly connected to the supporting frame 11 through a fixed shaft 225, and meanwhile, the second rotating member 14 is sleeved on the outer side of the fixed shaft 225 to ensure that the second rotating member 14 can move horizontally on the fixed shaft 225 along with the second bearing plate 32.

Referring to fig. 4 to 6, the bearing assembly 33 includes a bearing plate 331 slidably disposed on the fixed shaft 225, and a second connecting rod 332 slidably disposed on the bearing plate 331 and fixedly connected to the second bearing plate 32;

the first carrying plate 23 is provided with a limiting groove 231 for placing the second carrying plate 32 therein.

In this embodiment, the synchronous expansion or contraction of the first bearing plate 23 and the second bearing plate 32 is realized by arranging the bearing assembly 33 and matching with the contraction assembly 22, specifically, when the first bearing plate 23 moves, the first bearing plate 23 drives the second bearing plate 32 inside the first bearing plate to synchronously expand or contract, meanwhile, the second bearing plate 32 drives the second connecting rod 332 to slide on the bearing disc 331, so that the second bearing plate 32 is always inserted into the first bearing plate 23, and when the telescopic unit 31 works, the output shaft of the telescopic unit 31 drives the second rotating member 14, the second bearing plate 32, the second connecting rod 332 and the bearing disc 331 to synchronously move along the fixed shaft 225.

Referring to fig. 2 to 5, the first rotating rod 132 is provided with a first sliding groove 1321 matching with the first bearing plate 23, and the second rotating rod 142 is provided with a second sliding groove 1421 matching with the second bearing plate 32.

In this embodiment, in order to ensure the normal connection between the first rotating rod 132 and the first and second rotating rods 23, 142 and the second bearing plate 32, the first bearing plate 23 is slidably disposed on the first rotating rod 132, and the second bearing plate 32 is slidably disposed on the second rotating rod 142, and meanwhile, the first and second bearing plates 23, 32 will not be separated from the first and second rotating rods 132, 142, and the specific connection structure thereof is the prior art and will not be described herein.

Specifically, the operator first controls the second driving unit 21 to operate and drives the rotating disc 221 to rotate, because the fixed disc 224 is fixedly arranged, the sliding rod 222 arranged in the arc-shaped groove 2211 slides in the arc-shaped groove 2211 and drives the first connecting rod 223 to slide in the sliding groove 2241, the first connecting rod 223 moves in the sliding groove 2241 and simultaneously drives the first bearing plate 23 to synchronously move, the first bearing plate 23 drives the second bearing plate 32 in the first bearing plate to synchronously expand or retract, meanwhile, the second bearing plate 32 drives the second connecting rod 332 to slide on the bearing disc 331, when the telescopic unit 31 operates, the output shaft of the telescopic unit 31 drives the second rotating member 14, the second bearing plate 32, the second connecting rod 332 and the bearing disc 331 to synchronously move along the fixed shaft 225, and as the sizes of the first bearing plate 23 and the second bearing plate 32 are adjusted, one end of the wire cable can be connected to the first bearing plate 23 or the second bearing plate 32, and then the first driving unit 12 is controlled to operate and then drive the first rotating member 13 and the second rotating member 14 to synchronously rotate, so that the wire and the wire can be wound.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the invention, but any modifications, equivalents, improvements, etc. within the principles of the present invention should be included in the scope of the present invention.

Claims (5)

1. Wire and cable makes with taking-up device of conveniently changing stranded conductor, its characterized in that includes:

the support mechanism (1), the support mechanism (1) comprises a support frame (11), a first driving unit (12) arranged on one side of the support frame (11), a first rotating piece (13) which is connected with the first driving unit (12) and is rotatably arranged on the support frame (11), and a second rotating piece (14) which is opposite to the first rotating piece (13) and is rotatably arranged on the support frame (11);

the contraction mechanism (2) is arranged on the inner side of the first rotating piece (13), and comprises a second driving unit (21) fixedly connected with the first rotating piece (13), a contraction assembly (22) arranged on one side of the second driving unit (21) and connected with the second driving unit (21), and a plurality of first bearing plates (23) connected with the contraction assembly (22) and used for bearing wires and cables, wherein the plurality of first bearing plates (23) are connected to the contraction assembly (22) in a surrounding shape, and the size of the surrounding diameters of the plurality of first bearing plates (23) can be synchronously changed when the contraction assembly (22) works;

the translation mechanism (3), the translation mechanism (3) comprises a telescopic unit (31) which is arranged on one side of the second rotating piece (14) and is used for driving the second rotating piece (14) to translate, and a bearing assembly (33) which is arranged on the other side of the second rotating piece (14) and is used for supporting a plurality of second bearing plates (32), the second bearing plates (32) are correspondingly spliced with the first bearing plates (23) in the length direction, the second bearing plates (32) shrink and expand along with the shrinkage and expansion of the first bearing plates (23), and the telescopic unit (31) drives the bearing assembly (33) and the second bearing plates (32) to translate along the length direction of the second bearing plates (32);

specifically:

the shrinkage assembly (22) comprises a rotating disc (221) connected with the second driving unit (21) and internally provided with a plurality of arc grooves (2211), a sliding rod (222) arranged in the arc grooves (2211) in a sliding manner, a first connecting rod (223) fixedly connected with the sliding rod (222) and fixedly connected with the first bearing plate (23) at the other end, and a fixed disc (224) arranged on one side of the rotating disc (221); the surface of the fixed disc (224) is provided with a plurality of sliding grooves (2241) for placing the first connecting rod (223);

the fixed disc (224) is fixedly connected to the supporting frame (11) through a fixed shaft (225), and the second rotating piece (14) is sleeved on the outer side of the fixed shaft (225);

the bearing assembly (33) comprises a bearing disc (331) which is arranged on the fixed shaft (225) in a sliding manner, and a second connecting rod (332) which is arranged on the bearing disc (331) in a sliding manner and is fixedly connected with the second bearing plate (32);

a limiting groove (231) for placing the second bearing plate (32) is formed in the first bearing plate (23).

2. The wire-rewinding device for facilitating replacement of stranded wires for manufacturing electric wires and cables according to claim 1, wherein: the first rotating piece (13) comprises a first rotating roller (131) rotatably arranged on the supporting frame (11) and a plurality of first rotating rods (132) arranged in an array along the circumferential direction of the first rotating roller (131);

a placing groove (1311) for placing the second driving unit (21) is formed in one side, close to the second driving unit (21), of the first rotating roller (131).

3. The wire-rewinding device for facilitating replacement of stranded wires for manufacturing electric wires and cables according to claim 2, wherein: the second rotating piece (14) comprises a second rotating roller (141) rotatably arranged on the supporting frame (11) and a plurality of second rotating rods (142) arranged in an array along the circumferential direction of the second rotating roller (141); the second rotating roller (141) is provided with an annular groove (1411) which is used for being clamped with the output shaft of the telescopic unit (31) at a position corresponding to the telescopic unit (31).

4. The wire-rewinding device for facilitating replacement of stranded wires for electric wire and cable manufacturing according to claim 3, wherein: the first rotating rods (132) and the second rotating rods (142) are arranged in one-to-one correspondence.

5. The wire-rewinding device for manufacturing electric wires and cables with easy replacement of stranded wires according to any one of claims 3 to 4, characterized in that: the first rotating rod (132) is provided with a first sliding groove (1321) matched with the first bearing plate (23), and the second rotating rod (142) is provided with a second sliding groove (1421) matched with the second bearing plate (32).