CN114275624B

CN114275624B - Quantitative winding device for wire production

Info

Publication number: CN114275624B
Application number: CN202210138485.5A
Authority: CN
Inventors: 邹凤娟; 李斌; 黄成保; 胡淑珍
Original assignee: Jiangxi Huaxin Electric Wire & Cable Co ltd
Current assignee: Jiangxi Huaxin Electric Wire & Cable Co ltd
Priority date: 2022-02-15
Filing date: 2022-02-15
Publication date: 2023-10-13
Anticipated expiration: 2042-02-15
Also published as: CN114275624A

Abstract

The invention relates to a winding device, in particular to a quantitative winding device for wire production. The invention aims to provide a quantitative winding device for wire production, which is convenient for people to take out the wound wire. The invention provides a quantitative winding device for wire production, which comprises a support shell, a double-shaft motor, a handle, a clamping assembly and the like, wherein the double-shaft motor is arranged in the middle of the inner bottom of the support shell, the handle is arranged in the middle of the front side of the support shell in a sliding manner, and the clamping assembly is arranged at the upper part of the inner side of the support shell. When the clamping block moves to the inner side, the take-up reel can be clamped, one end of the electric wire is wound on the take-up reel manually, the double-shaft motor is used as driving force to drive the take-up reel to rotate, winding work is completed, then the push plate is pushed backwards, the clamping block can be driven to move to the outer side to loosen the take-up reel, and people can conveniently take out the take-up reel with the electric wire wound.

Description

Quantitative winding device for wire production

Technical Field

The invention relates to a winding device, in particular to a quantitative winding device for wire production.

Background

When the wire leaves the factory, the wire needs to be wound and packed manually, but the manual operation is troublesome, so that the working efficiency is low.

Patent application CN215364215U, the publication day is 20211231, the utility model discloses an electric wire coiling mechanism, including translation pushing disc and pulley, can make a rolling section of thick bamboo horizontal direction free movement, can make the more even rolling of electric wire to a rolling section of thick bamboo, the helicla flute on first rotation post and second rotation post and the rotation post has been designed, residual surface and inside stress when can making the electric wire rolling eliminate production, make the electric wire can more inseparable combine to a rolling section of thick bamboo on, the tensile pole of base top has been designed, make the height of a rolling section of thick bamboo can freely be adjusted, more convenient carries out the rolling operation, the baffle of second carousel both sides has been designed, can effectively prevent the drop of drive belt. The above patent can automatically wind up the electric wire, but it is inconvenient to take down the electric wire after winding up.

In view of the above, there is a great need for a quantitative winding device for wire production, which is convenient for people to take out the wound wire, so as to solve the above problems.

Disclosure of Invention

In order to overcome the defect that the conventional wire winding device is generally inconvenient to take out the wound wire when in use, the invention aims to provide the quantitative winding device which is convenient for people to take out the wound wire for wire production.

The invention is realized by the following technical approaches:

the utility model provides a ration coiling mechanism of electric wire production, including supporting shell, clamp splice, biax motor, handle, clamping assembly, drive assembly and locking assembly, be equipped with biax motor in the middle of the interior bottom of supporting shell, the front side middle part of supporting shell is equipped with the handle in a sliding manner, the inboard upper portion of supporting shell is equipped with clamping assembly, the interval is equipped with the clamp splice that is used for pressing from both sides tight take-up reel on the clamping assembly, the interior bottom of supporting shell is equipped with and is used for driving take-up reel pivoted drive assembly, the lower part front side of supporting shell is equipped with and is used for carrying out spacing locking assembly to clamping assembly.

Further stated, the clamping assembly comprises a first push rod, a first spring, a first support rod, a movable block, a first guide rod, a second spring, a fixed block, a first shaft sleeve, a first sliding shaft, a third spring and a rotary table, wherein the first push rod is arranged on the rear side of the grip, the first push rod is connected with a support shell in a sliding mode, the first spring is symmetrically arranged between the rear side of the first push rod and the support shell, the middle parts of the left side and the right side of the inner wall of the support shell are all provided with the first support rod, the inner sides of the first support rod are all provided with two first guide rods in a sliding mode, the movable blocks are all arranged between the inner sides of the adjacent two first guide rods, the movable blocks are all in contact with the first push rod, the two ends of the second spring are all connected with the first support rod and the first guide rod respectively, the left side and the right side of the top in the support shell are all provided with the fixed block, the lower part of the fixed block is all rotationally provided with the first shaft sleeve, the inner sides of the first shaft sleeve are all slidingly provided with the first sliding shaft, the first sliding shaft is all connected with the upper parts of the adjacent movable blocks in a rotating mode, the first sliding shaft is all around the third spring is connected with the inner sides of the first shaft sleeve, the first inner sides of the first spring are all connected with the first rotary table respectively, and the inner sides of the first rotary table are all connected with the first sliding shaft respectively.

Further stated, the driving assembly comprises a first supporting block, a second sleeve, a second sliding shaft, a fourth spring, a rotary groove block, a first clamping rod, a first driving wheel and a first driving belt, wherein two first supporting blocks are respectively arranged on the left side and the right side of the inner bottom of the supporting shell, the second sleeve is respectively arranged on the upper parts of the two first supporting blocks on the inner side in a rotary mode, the output shafts on the left side and the right side of the double-shaft motor are respectively connected with the adjacent second sleeve, the second sliding shaft is respectively arranged on the outer side of the second sleeve in a sliding mode, the fourth spring is respectively arranged between the inner side of the second sliding shaft and the adjacent second sleeve, the rotary groove block is respectively arranged on the outer side of the second sliding shaft, the first clamping rod is respectively arranged on the upper parts of the two first supporting blocks on the outer sides of the second sliding shaft in a rotary groove block, and the first sleeve are respectively provided with the first driving wheels, and the first driving belt is respectively wound between the two first driving wheels which are respectively arranged on the outer side of the first clamping rod and the first shaft in a rotary mode.

Further stated, the locking assembly comprises a second guide rod, a sliding block, a fifth spring, a second clamping rod, a second push rod, a push plate and a sixth spring, wherein the second guide rods are symmetrically arranged on the left side and the right side of the lower portion of the supporting shell, the number of the second guide rods is four, the sliding blocks are arranged between the inner sides of two adjacent second guide rods in a sliding mode, the fifth spring is wound on each second guide rod, two ends of the fifth spring are respectively connected with the supporting shell and the sliding block, the second clamping rod is arranged at the top of each sliding block, the first push rod can move backwards to be in contact with the second clamping rod, the second push rod is slidably arranged in the middle of the front side of the lower portion of the supporting shell, the push plate is in contact with the sliding block, and the sixth spring is symmetrically arranged between the rear side of the second push rod and the supporting shell.

The automatic wire winding device is characterized by further comprising a stopping component for quantitatively winding wires, wherein the stopping component comprises a second supporting rod, a top rod, seventh springs and rollers, four second supporting rods are arranged at the middle of the bottom in a supporting shell at intervals, the second supporting rods are positioned on the outer side of the double-shaft motor, the top rods are arranged between the upper parts of the second supporting rods in a sliding mode, rotary groove blocks are in contact with the top rods, the seventh springs are arranged between the top rods and the second supporting rods, the number of the seventh springs is four, and the rollers are arranged in the middle of the upper parts of the top rods in a rotating mode.

Further, the winding reel comprises a placement component for supporting the winding reel, the placement component comprises a third supporting rod, a sliding frame, eighth springs, placement blocks, fourth supporting rods, third pushing rods and ninth springs, the third supporting rods are symmetrically arranged around the middle of the inner side of the supporting shell, the number of the third supporting rods is four, the sliding frames are respectively arranged between the upper parts of the two third supporting rods on the same lateral side in a sliding mode, the eighth springs are respectively arranged between the bottom of the sliding frame and the adjacent two third supporting rods, the placement blocks are respectively arranged on the left side and the right side of the sliding frames, the fourth supporting rods are respectively arranged on the left side and the right side of the bottom of the inner side of the supporting shell in a sliding mode, third pushing rods are respectively arranged on the upper parts of the adjacent two fourth supporting rods in a sliding mode and are respectively in contact with the two sliding frames, and the third pushing rods are respectively in contact with the adjacent movable blocks, and the ninth springs are respectively arranged between the inner side of the third pushing rods and the upper parts of the two fourth supporting rods on the same lateral side.

The wire guiding device comprises a wire guiding component, and is characterized by further comprising a toothed belt, a fifth supporting rod, a first gear, a second driving wheel, a second driving belt, a second supporting block, a groove drum, a supporting shell, supporting frames, the guiding blocks, sliding rods and second gears, wherein the toothed belt is arranged on the outer side of the first driving belt, the fifth supporting rod is symmetrically arranged on the rear side of the inner bottom of the supporting shell, two first rotating rods are rotatably arranged on the upper portion of the left fifth supporting rod, a second rotating rod is rotatably arranged on the upper portion of the right fifth supporting rod, the first gears are respectively arranged on the left side of the first rotating rod, the first gears are meshed with each other, the toothed belt on the left side can be meshed with the first gears on the front side when rotating, the second supporting block is symmetrically arranged on the upper portion of the rear side of the supporting shell, the second supporting block is rotatably arranged between the second supporting blocks, the second driving rods are respectively arranged on the left side and right side of the second supporting block, the number of the second driving wheels is four, the two adjacent second driving wheels are respectively wound around the second driving belt, the upper portion of the supporting shell is provided with the second supporting shell, the supporting shell is provided with the second supporting block is rotatably arranged on the right side of the supporting shell, the second supporting block is connected with the second supporting shell, and the sliding frame is arranged on the upper side of the second supporting shell, and the sliding frame is arranged on the rear side of the sliding frame.

Further, a round hole is formed in the upper portion of the guide block.

Compared with the prior art, the invention has the following advantages:

1. when the clamping block moves to the inner side, the take-up reel can be clamped, one end of the electric wire is wound on the take-up reel manually, the double-shaft motor is used as driving force to drive the take-up reel to rotate, winding work is completed, then the push plate is pushed backwards, the clamping block can be driven to move to the outer side to loosen the take-up reel, and people can conveniently take out the take-up reel with the electric wire wound.

2. Along with the electric wires on the take-up reel are more and more, the electric wires can extrude the idler wheels to move downwards, so that the rotary groove blocks move inwards to loosen the first clamping rods, and the take-up reel is not rotated any more, so that the purpose of quantitative winding can be achieved.

3. The placing block can support the take-up reel, and when the clamping block loosens the take-up reel, the take-up reel can be prevented from falling down into the support shell.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of another view of the present invention.

Fig. 3 is a schematic internal perspective view of the present invention.

Fig. 4 is a schematic internal perspective view of another view of the present invention.

Fig. 5 is a schematic view of the structure of the clamping assembly of the present invention.

Fig. 6 is a schematic structural view of the driving assembly of the present invention.

Fig. 7 is a schematic view of a part of the structure of the driving assembly of the present invention.

Fig. 8 is a schematic view of the structure of the locking assembly of the present invention.

Fig. 9 is a schematic view of a first partial structure of the locking assembly of the present invention.

Fig. 10 is a schematic view of a second partial structure of the locking assembly of the present invention.

FIG. 11 is a schematic view of a stop assembly according to the present invention.

Fig. 12 is a schematic structural view of the placement module of the present invention.

Fig. 13 is a schematic structural view of a guide assembly according to the present invention.

Fig. 14 is a schematic view of another view of the guide assembly of the present invention.

Fig. 15 is a schematic view of a first partial structure of the guide assembly of the present invention.

Fig. 16 is a schematic view of a second partial structure of the guide assembly of the present invention.

The reference symbols in the drawings: 1-support housing, 2-clamping block, 3-biaxial motor, 4-grip, 5-clamping assembly, 501-first push rod, 502-first spring, 503-first support rod, 504-movable block, 505-first guide rod, 506-second spring, 507-fixed block, 508-first sleeve, 509-first sliding shaft, 510-third spring, 511-turntable, 6-driving assembly, 601-first support block, 602-second sleeve, 603-second sliding shaft, 604-fourth spring, 605-rotating groove block, 606-first clamping rod, 607-first driving wheel, 608-first driving belt, 7-locking assembly, 701-second guide rod, 702-sliding block, 703-fifth spring, 704-second clamping rod, 705-second push rod, 706-push plate, 707-sixth spring, 8-stop component, 801-second support rod, 802-push rod, 803-seventh spring, 804-roller, 9-placement component, 901-third support rod, 902-slide frame, 903-eighth spring, 904-placement block, 905-fourth support rod, 906-third push rod, 907-ninth spring, 10-guide component, 1001-toothed belt, 1002-fifth support rod, 1003-first gear, 1004-second drive wheel, 1005-second drive belt, 1006-second support block, 1007-grooved drum, 1008-support shell, 1009-support frame, 1010-guide block, 1011-slide bar, 1012-second gear.

Detailed Description

The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which currently preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.

Example 1

The utility model provides a ration coiling mechanism of electric wire production, refer to fig. 1-10, including support shell 1, clamp splice 2, biax motor 3, handle 4, clamping assembly 5, actuating assembly 6 and locking assembly 7, the inboard upper portion of support shell 1 is equipped with clamping assembly 5, the interval welding has clamp splice 2 on the clamping assembly 5, can press from both sides the take-up reel when clamp splice 2 moves to the inboard, bolt has biax motor 3 in the middle of the interior bottom of support shell 1, the front side middle part slip of support shell 1 is equipped with handle 4, the interior bottom of support shell 1 is equipped with actuating assembly 6, the lower part front side of support shell 1 is equipped with locking assembly 7.

Referring to fig. 1-5, the clamping assembly 5 comprises a first push rod 501, a first spring 502, a first supporting rod 503, a movable block 504, a first guide rod 505, a second spring 506, a fixed block 507, a first shaft sleeve 508, a first sliding shaft 509, a third spring 510 and a rotary table 511, wherein the first push rod 501 is arranged at the rear side of the handle 4, the first push rod 501 is slidably connected with the supporting shell 1, the first spring 502 is symmetrically arranged between the rear side of the first push rod 501 and the supporting shell 1, the first supporting rod 503 is arranged in the middle of the left side and the right side of the inner wall of the supporting shell 1, the first supporting rod 503 is respectively provided with two first guide rods 505 in a sliding manner, the movable block 504 is respectively welded between the inner sides of the adjacent two first guide rods 505, the movable block 504 is respectively contacted with the first push rod 501, the two ends of the second spring 506 are respectively connected with the first support rod 503 and the first guide rod 505, the left side and the right side of the inner top of the supporting shell 1 are respectively welded with the fixed block 507, the lower part of the fixed block 507 is respectively provided with the first shaft sleeve 508, the first shaft sleeve 508 is respectively connected with the inner side of the first sliding shaft 509, the first sliding shaft 509 is respectively connected with the first sliding shaft 511, and the first sliding shaft is respectively connected with the inner side of the first sliding shaft 509.

Referring to fig. 4, fig. 6 and fig. 7, the driving assembly 6 includes a first supporting block 601, a second shaft sleeve 602, a second sliding shaft 603, a fourth spring 604, a rotary groove block 605, a first clamping rod 606, a first driving wheel 607 and a first driving belt 608, two first supporting blocks 601 are welded on the left side and the right side of the bottom in the supporting shell 1, the second shaft sleeve 602 is respectively and rotatably arranged on the upper portion of the two first supporting blocks 601 on the inner side, output shafts on the left side and the right side of the double-shaft motor 3 are respectively connected with the adjacent second shaft sleeve 602, the second sliding shaft 603 is respectively and slidably arranged on the outer side of the second shaft sleeve 602, the fourth spring 604 is respectively and rotatably arranged between the inner side of the second sliding shaft 603 and the adjacent second shaft sleeve 602, the rotary groove block 605 is respectively arranged on the outer side of the second sliding shaft 603, the first clamping rod 606 is respectively rotatably arranged on the upper portion of the two first supporting blocks 601 on the outer side, the first clamping rod 606 and the first driving wheel 607 is respectively and the first driving belt 607 is respectively rotatably arranged on the first driving wheels 607, the first driving belt 608 is respectively and the corresponding two driving wheels 607 on the upper and lower sides of the first clamping rod 606, the first driving shaft sleeve can rotate around the first driving shaft sleeve 3, and the first clamping rod 606 can rotate, and can drive the first winding drum 2.

Referring to fig. 1, 3, 8, 9 and 10, the locking assembly 7 includes a second guide bar 701, a sliding block 702, a fifth spring 703, a second clamping bar 704, a second push bar 705, a push plate 706 and a sixth spring 707, the second guide bar 701 is symmetrically welded on the front side of the lower portion of the support housing 1, the number of the second guide bars 701 is four, the sliding block 702 is slidably disposed between the inner sides of two adjacent second guide bars 701, the fifth spring 703 is wound on each second guide bar 701, two ends of the fifth spring 703 are respectively connected with the support housing 1 and the sliding block 702, the top of the sliding block 702 is provided with the second clamping bar 704, the first push bar 501 can move backwards and contact with the second clamping bar 704, the second clamping bar 704 can limit the first push bar 501, the middle portion of the lower portion of the support housing 1 is slidably provided with the second push bar 705, the second push bar 705 can move backwards and contact with the sliding block 702, the push plate 706 is slidably disposed in the middle of the bottom of the second push bar 705, the push plate 706 is slidably connected with the support housing 1, and the second push bar 705 is symmetrically disposed between the rear side of the second push bar 705 and the support housing 1.

When people need to use the device, firstly, a take-up reel is put between the clamping blocks 2, then the handle 4 is pushed backwards, the first push rod 501 is driven to move backwards, the first spring 502 is compressed, the first push rod 501 can extrude the movable block 504 to move inwards, the second spring 506 is compressed, the movable block 504 drives the first sliding shaft 509, the rotary disc 511 and the clamping block 2 to move inwards, the third spring 510 is compressed, when the first push rod 501 is contacted with the second clamping rod 704, the second clamping rod 704 is extruded to move outwards, the sliding block 702 is driven to move outwards, the fifth spring 703 is compressed, when the first push rod 501 passes over the second clamping rod 704, the fifth spring 703 is restored to drive the sliding block 702 and the second clamping rod 704 to move inwards to reset, so that the second clamping rod 704 clamps the first push rod 501, at the moment, the clamping block 2 can clamp the take-up reel, then one end of an electric wire is wound on the take-up reel manually, the biaxial motor 3 is started again, the output shaft of the double-shaft motor 3 drives the second sleeve 602 to rotate, thereby driving the second sliding shaft 603 and the rotary groove block 605 to rotate, the rotary groove block 605 drives the first clamping rod 606 to rotate, the first clamping rod 606 can drive the first sleeve 508 to rotate through the first transmission wheel 607 and the first transmission belt 608, thereby driving the first sliding shaft 509, the rotary disc 511 and the clamping block 2 to rotate, the clamping block 2 drives the take-up reel to rotate, thereby winding wires, at the moment, the wires need to be manually stirred aside to avoid being wound at the same place, after the take-up reel winds a certain amount of wires, the double-shaft motor 3 is closed, then the wires are cut off, the take-up reel is fixed by hands, then the push plate 706 is pushed backwards, the second push rod 705 is driven to move backwards, the sixth spring 707 is compressed, when the second push rod 705 contacts with the slide block 702, the second clamping rod 704 is driven to move outwards, the fifth spring 703 compresses to make the second clamping rod 704 release the first push rod 501, the first spring 502 returns to its original state, drives the first push rod 501 and the handle 4 to move forward for resetting, so that the first push rod 501 is separated from the movable block 504, the second spring 506 and the third spring 510 return to their original states, drives the movable block 504, the first sliding shaft 509, the turntable 511 and the clamping block 2 to move outward for resetting, so that the clamping block 2 releases the winding disc, then releases the push plate 706, the sixth spring 707 returns to its original state, drives the second push rod 705 and the push plate 706 to move forward for resetting, so that the second push rod 705 is separated from the slider 702, the fifth spring 703 returns to its original state, drives the slider 702 and the second clamping rod 704 to move inward for resetting, then the winding disc around which the wire is wound can wind the wire again by repeating the above operations.

Example 2

On the basis of embodiment 1, referring to fig. 1, 2, 3, 4 and 11, the device further comprises a stopping component 8, the stopping component 8 comprises a second supporting rod 801, a top rod 802, a seventh spring 803 and a roller 804, four second supporting rods 801 are welded in the middle of the inner bottom of the supporting shell 1 at intervals, the second supporting rods 801 are positioned on the outer side of the double-shaft motor 3, top rods 802 are slidably arranged between the upper parts of the second supporting rods 801, the rotary groove blocks 605 are contacted with the top rods 802, when the top rods 802 move downwards, the rotary groove blocks 605 can be extruded to move inwards to be separated from the first clamping rods 606, the winding drum stops rotating, the purpose of quantitative winding is achieved, seventh springs 803 are arranged between the top rods 802 and the second supporting rods 801, the number of the seventh springs 803 is four, and the rollers 804 are rotatably arranged in the middle of the upper parts of the top rods 802.

As more and more wires are wound on the winding disc, when the wires are in contact with the roller 804, the roller 804 is extruded to move downwards to drive the ejector rod 802 to move downwards, the seventh spring 803 is compressed, the ejector rod 802 extrudes the rotary groove block 605 to move inwards, the fourth spring 604 is compressed to enable the rotary groove block 605 to be separated from the first clamping rod 606, the winding disc stops rotating at the moment, then the winding disc wound with the wires is manually taken away, the purpose of quantitative winding can be achieved, when the wires are separated from the roller 804, the seventh spring 803 is restored to original shape to drive the ejector rod 802 and the roller 804 to move upwards to reset, the ejector rod 802 is separated from the rotary groove block 605, the fourth spring 604 is restored to original shape to drive the rotary groove block 605 to move outwards to reset, and the rotary groove block 605 is enabled to clamp the first clamping rod 606 again, if the rotary groove block 605 moves outwards to reset without clamping the first clamping rod 606, the fourth spring 604 cannot completely restore to original shape, and when the rotary groove block 605 rotates again, the rotary groove block 605 can be aligned with the first clamping rod 606 to enable the fourth spring 605 to restore to the original shape to the first clamping rod 606 to move outwards.

Referring to fig. 1, fig. 3, fig. 4 and fig. 12, still including placing the subassembly 9, place the subassembly 9 including third bracing piece 901, the carriage 902, eighth spring 903, place the piece 904, fourth bracing piece 905, third push rod 906 and ninth spring 907, the inboard middle part front and back symmetry welding of support housing 1 has third bracing piece 901, the quantity of third bracing piece 901 is four, all sliding type is equipped with carriage 902 between two third bracing piece 901 upper portions of horizontal homonymy, all be equipped with eighth spring 903 between carriage 902 bottom and two adjacent third bracing pieces 901, the left and right sides between the carriage 902 has all welded the piece 904 of placing, place the piece 904 and can support the take-up reel, avoid the take-up reel to drop down to support housing 1 inside, the left and right sides of support housing 1 inner bottom has all welded fourth bracing piece 905 front and back symmetry, all sliding type is equipped with third push rod 906 between two adjacent fourth bracing piece 905 upper portions, third push rod 906 all contacts with two carriage 902, all contacts with adjacent movable block 504, all is equipped with between the fourth push rod 906 and the fourth push rod 906 on the homonymy has between the fourth push rod 907.

When people need to use the device, the take-up reel can be placed between the tops of the placing blocks 904, so that the take-up reel is located between the clamping blocks 2, when the movable block 504 moves inwards, the clamping block 2 is driven to move inwards to clamp the take-up reel, meanwhile, the movable block 504 can extrude the third push rod 906 to move inwards, the ninth spring 907 compresses, the third push rod 906 extrudes the sliding frame 902 to move downwards, the eighth spring 903 compresses, the sliding frame 902 drives the placing blocks 904 to move downwards, the placing blocks 904 are separated from the take-up reel, the placing blocks 904 can be prevented from interfering with the rotation of the take-up reel, when the movable block 504 moves outwards to reset, the clamping block 2 is driven to move outwards to reset to loosen the take-up reel, meanwhile, the movable block 504 can loosen the third push rod 906, the ninth spring 907 returns to the original state, the third push rod 906 is driven to move outwards to reset, the third push rod 906 is separated from the sliding frame 902, the eighth spring 903 returns to the original state, the sliding frame 902 and the placing blocks 904 are driven to move upwards to reset, and the placing blocks 904 are enabled to contact with the bottom of the take-up reel again, and the take-up reel is prevented from falling down inside the supporting shell 1.

Referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 13, fig. 14, fig. 15 and fig. 16, the device further comprises a guide assembly 10, the guide assembly 10 comprises a toothed belt 1001, a fifth supporting rod 1002, a first gear 1003, a second driving wheel 1004, a second driving belt 1005, a second supporting block 1006, a groove drum 1007, a supporting frame 1009, a guide block 1010, a sliding rod 1011 and a second gear 1012, the toothed belt 1001 is arranged outside the first driving belt 608, the fifth supporting rod 1002 is symmetrically welded on the left and right sides of the inner bottom of the supporting shell 1, two first rotating rods are rotatably arranged on the upper part of the left side fifth supporting rod 1002, the second rotating rod is rotatably arranged on the upper part of the right side fifth supporting rod 1002, the first rotating rod is provided with a first gear 1003, the first gear 1003 is meshed with each other, the toothed belt 1001 on the left side is meshed with the first gear 1003, the second supporting block 1006 is symmetrically arranged on the left and right sides of the rear side of the supporting shell 1, a groove drum 1007 is rotatably arranged between the second supporting block 1006, the groove drum 1007 is rotatably arranged between the supporting shell 1006, the two adjacent supporting frames 1008 are rotatably arranged on the left and right side of the supporting shell 1008, the number of the second supporting shell is arranged on the guide block 1008 is arranged on the two side of the supporting shell, the number of the second supporting shell is arranged on the second supporting shell is 1010, the number of the second driving wheel 1010 is meshed with the second rotating rod 1010, and the guide block is rotatably arranged on the upper side, the number of the second driving wheel is meshed with the second driving wheel, and the second driving wheel is arranged.

When people need to wind the electric wire on the take-up reel, firstly one end of the electric wire passes through a round hole in the upper portion of the guide block 1010 and then winds the electric wire on the take-up reel, when the first transmission belt 608 rotates, the toothed belt 1001 is driven to rotate, when the toothed belt 1001 on the right side is meshed with the second gear 1012, the second gear 1012 is driven to rotate, thereby driving the second rotating rod to rotate, the second rotating rod can drive the grooved drum 1007 to rotate through the second transmission wheel 1004 on the right side and the second transmission belt 1005 on the right side, the grooved drum 1007 drives the sliding rod 1011 to move to the right, thereby driving the guide block 1010 to move to the right, when the toothed belt 1001 on the right side is separated from the second gear 1012, the grooved drum 1007 stops rotating, meanwhile, the toothed belt 1001 on the left side is meshed with the first gear 1003 on the front side, the first gear 1003 on the front side is driven to rotate, further the first gear 1003 on the rear side is driven to rotate, the first rotating rod on the left side is driven to rotate through the second transmission wheel 1004 on the left side and the second transmission belt 1005 on the left side, the grooved drum 1007 can be driven to rotate, and the guide block 1010 can be driven to move to the left and right, and the electric wire can be wound to the guide block 1010 can move to and reciprocate to the left and the wire can be wound to and the wire to and the right.

While the invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims

1. The quantitative winding device for the wire production comprises a supporting shell (1), a clamping block (2), a double-shaft motor (3) and a handle (4), wherein the double-shaft motor (3) is arranged in the middle of the inner bottom of the supporting shell (1), the handle (4) is arranged in the middle of the front side of the supporting shell (1) in a sliding mode, the clamping block (2) is used for clamping a wire collecting disc, the quantitative winding device is characterized by further comprising a clamping assembly (5), a driving assembly (6) and a locking assembly (7), the clamping assembly (5) is arranged at the upper part of the inner side of the supporting shell (1), the clamping block (2) is arranged on the clamping assembly (5) at intervals, the driving assembly (6) used for driving the wire collecting disc to rotate is arranged at the inner bottom of the supporting shell (1), and the locking assembly (7) used for limiting the clamping assembly (5) is arranged at the front side of the lower part of the supporting shell (1);

the clamping assembly (5) comprises a first push rod (501), a first spring (502), a first supporting rod (503), a movable block (504), a first guide rod (505), a second spring (506), a fixed block (507), a first shaft sleeve (508), a first sliding shaft (509), a third spring (510) and a rotary table (511), wherein the first push rod (501) is arranged at the rear side of a grip (4), the first push rod (501) is slidably connected with a supporting shell (1), the first spring (502) is symmetrically arranged between the rear side of the first push rod (501) and the supporting shell (1), the middle parts of the left side and the right side of the inner wall of the supporting shell (1) are respectively provided with the first supporting rod (503), the inner sides of the first supporting rod (503) are respectively provided with two first guide rods (505), the movable blocks (504) are respectively arranged between the inner sides of the adjacent two first guide rods (505), the movable blocks (504) are respectively contacted with the first push rod (501), the second springs (506) are respectively wound on the first guide rods (505), the two ends of the second springs (506) are respectively connected with the first guide rods (505), the two inner sides of the first guide rods (505) are respectively provided with the fixed parts (507) respectively, the inner sides of the first guide rods (507) are respectively provided with fixed parts, the inner parts of the first guide rods are respectively provided with the fixed parts, the inner parts of the first guide rods are respectively, a first sliding shaft (509) is arranged on the inner side of the first shaft sleeve (508) in a sliding manner, the first sliding shaft (509) is connected with the upper parts of the adjacent movable blocks (504) in a rotating manner, a third spring (510) is wound on the first sliding shaft (509), two ends of the third spring (510) are respectively connected with the first shaft sleeve (508) and the first sliding shaft (509), a rotary disc (511) is arranged at the inner end of the first sliding shaft (509), and the inner side of the rotary disc (511) is connected with the adjacent three clamping blocks (2);

the driving assembly (6) comprises a first supporting block (601), a second shaft sleeve (602), a second sliding shaft (603), a fourth spring (604), a rotary groove block (605), a first clamping rod (606), a first driving wheel (607) and a first driving belt (608), wherein two first supporting blocks (601) are respectively arranged on the left side and the right side of the inner bottom of the supporting shell (1), the second shaft sleeve (602) is respectively arranged on the upper parts of the two first supporting blocks (601) on the inner side in a rotating mode, output shafts on the left side and the right side of the double-shaft motor (3) are respectively connected with the adjacent second shaft sleeve (602), the second sliding shaft (603) is respectively arranged on the outer side of the second shaft sleeve (602) in a sliding mode, the fourth spring (604) is respectively arranged between the inner side of the second sliding shaft (603) and the adjacent second shaft sleeve (602), the rotary groove block (605) is respectively arranged on the outer side of the second sliding shaft (603), the first clamping rod (606) is respectively arranged on the upper parts of the two first supporting blocks (601) on the outer sides, the first clamping rod (606) is respectively clamped on the rotary groove block (605), and the first clamping rod (607) is respectively arranged on the upper parts of the first driving belt (607) and the first driving belt (608);

the wire winding device is characterized by further comprising a stopping assembly (8) for quantitatively winding wires, the stopping assembly (8) comprises a second supporting rod (801), a top rod (802), seventh springs (803) and rollers (804), four second supporting rods (801) are arranged in the middle of the inner bottom of the supporting shell (1), the second supporting rods (801) are located on the outer side of the double-shaft motor (3), the top rods (802) are slidably arranged between the upper parts of the second supporting rods (801), the rotary groove blocks (605) are in contact with the top rods (802), seventh springs (803) are arranged between the top rods (802) and the second supporting rods (801), the number of the seventh springs (803) is four, and the rollers (804) are rotatably arranged in the middle of the upper parts of the top rods (802).

2. The quantitative winding device for wire production according to claim 1, wherein the locking assembly (7) comprises a second guide rod (701), a sliding block (702), a fifth spring (703), a second clamping rod (704), a second push rod (705), a push plate (706) and a sixth spring (707), the second guide rods (701) are symmetrically arranged on the left side and the right side of the lower part of the supporting shell (1), the number of the second guide rods (701) is four, the sliding blocks (702) are slidably arranged between the inner sides of two adjacent second guide rods (701), the fifth springs (703) are wound on the second guide rods (701), two ends of each fifth spring (703) are respectively connected with the supporting shell (1) and the sliding blocks (702), the second clamping rods (704) are arranged at the top of each sliding block (702), the first push rod (501) can contact with the second clamping rods (704) in a backward movement mode, the second push rod (705) is slidably arranged in the middle of the front side of the lower part of the supporting shell (1), the second push rod (705) moves backward and contacts with the sliding blocks (702), the second push rod (705) is symmetrically arranged at the bottom of the second push plate (706) and the left side of the supporting shell (1) is slidably arranged between the second push rod (706) and the supporting shell (706).

3. A quantitative winding device for electric wire production according to claim 2, further comprising a placement component (9) for supporting the winding drum, wherein the placement component (9) comprises a third support rod (901), a sliding frame (902) and an eighth spring (903), place piece (904), fourth bracing piece (905), third push rod (906) and ninth spring (907), the inboard middle part front and back symmetry of support shell (1) is equipped with third bracing piece (901), the quantity of third bracing piece (901) is four, all slidingtype be equipped with carriage (902) between two third bracing piece (901) upper portions of horizontal homonymy, all be equipped with eighth spring (903) between carriage (902) bottom and two adjacent third bracing pieces (901), the left and right sides between carriage (902) all is equipped with places piece (904), the left and right sides of support shell (1) inner bottom all is equipped with fourth bracing piece (905) front and back symmetry, all slidingtype be equipped with third push rod (906) between two adjacent fourth bracing piece (905) upper portions, third push rod (906) all contact with two carriage (902), all contact with adjacent movable block (504) between three push rod (906) inboard and two fourth bracing piece (905) upper portions of homonymy.

4. The quantitative winding device for wire production according to claim 3, further comprising a guiding component (10) for guiding the wire, wherein the guiding component (10) comprises a toothed belt (1001), a fifth supporting rod (1002), a first gear (1003), a second driving wheel (1004), a second driving belt (1005), a second supporting block (1006), a grooved drum (1007), a supporting shell (1008), a supporting frame (1009), a guiding block (1010), a sliding rod (1011) and a second gear (1012), the toothed belt (1001) is arranged on the outer side of the first driving belt (608), the fifth supporting rod (1002) is symmetrically arranged on the rear side of the inner bottom of the supporting shell (1), two first rotating rods are rotatably arranged on the upper part of the fifth supporting rod (1002) on the left side, the second rotating rods are rotatably arranged on the upper part of the fifth supporting rod (1002) on the right side, the first rotating rods are respectively provided with the first gears (1003), the first gears (1003) are meshed with each other, the toothed belt (1001) on the left side can be meshed with the first gears (1003) on the front side when rotating, the supporting shell (1) is symmetrically arranged on the rear side of the left side, the second supporting block (1006) is symmetrically arranged on the right side, the second rotating rods (1006) are rotatably arranged on the left side of the left side, the number of the second driving wheels (1004) is four, a second driving belt (1005) is wound between every two adjacent second driving wheels (1004), a supporting shell (1008) is arranged on the upper portion of the rear side of the supporting shell (1), the supporting shell (1008) is located on the outer side of a second supporting block (1006), a supporting frame (1009) is arranged in the middle of the rear side of the inner bottom of the supporting shell (1008), a guide block (1010) is arranged on the supporting frame (1009) in a sliding mode, a sliding rod (1011) is arranged on the lower portion of the front side of the guide block (1010), the sliding rod (1011) is connected with a groove drum (1007) in a sliding mode, a second gear (1012) is arranged on the right side of the second rotating rod, and the toothed belt (1001) on the right side is meshed with the second gear (1012) when rotating.

5. A quantitative winding device for electric wire production according to claim 4, characterized in that the upper part of the guide block (1010) is provided with a round hole.