BE1030240B1 - COLORED YARN WINDING DEVICE AND PRODUCTION METHOD THEREFOR - Google Patents

Abstract

The present invention discloses a colored yarn winding device and its production method, the colored yarn winding device comprises a housing, which is provided with an assembly table inside; a winding unit provided inside the housing, and comprises a transition roller, in which an input rail and an output rail are provided on either side of the transition roller, the input rail is movably connected to the output rail, the output rail is provided on its front side with a winding roller, the transition roller is inserted through a transmission shaft, one end of the shaft transmission is provided with a driving component, and the transition roller moves transversely reciprocating under the action of the driving component; an anti-loosening unit including transmission components and clamping components.

Description

DEVICE FOR WINDING COLORED YARNS AND ITS PROCESS FOR WINDING

PRODUCTION

TECHNICAL AREA

The present invention relates to the field of yarn production technology, particularly colored yarn winding, and its production method.

TECHNICAL BACKGROUND

Produced colored yarns need to be wound on yarn rolls to collect, for existing winding devices, the yarn entry position is fixed when in use, thus the yarn wound on the yarn roll is always in contact with the roller at the same position, which results in uneven winding on the wire roll, possibly causing the wires to become tangled, in addition, disconnecting the wire during winding will cause the wire to be released too quickly at the entry end and the wire wound on the wire roll, which causes the problems such as loosening of the wire wound on the wire roll and wire jamming of the mechanism at the entry end due to to wire bounce, such problems cannot be solved by existing winding devices.

DISCLOSURE OF THE INVENTION

The main purpose of the present invention is to provide a colored yarn winding device and its production method to solve the existing technical problems.

To achieve the above object, the present invention provides a device for winding colored threads, comprising:

A case, which is provided with a mounting table inside and an entrance hole on the surface;

A winding unit, which is provided inside the housing, and includes a transition roller, in which an input rail and an output rail are provided on either side of the transition roller, the rail input rail is movably connected to the output rail, the output rail is provided on its front side with a winding roller, the wire passes successively through the input rail, the transition roller and the output and is wound on the winding roller, the transition roller is inserted through a transmission shaft, the transmission shaft is movably arranged to pass through a support seat, one end of the transmission shaft is provided with a driving component, the transition roller moves transversely reciprocating under the action of the driving component;

An anti-loosening unit, which includes transmission components and clamping components, wherein the transmission components are provided at two ends of

V transmission shaft, the clamping components are arranged at the winding roller and at the input end, after the wire is disconnected, the transition roller returns to drive the transmission component to drive the clamping component to tighten the wires at the entry end and winding end.

In addition, the drive component includes a tilting tooth plate, the lower part of the tilting tooth plate has a fan-shaped plate structure with tooth grooves provided on an arc edge, and the upper part of the plate tilting tooth plate is movably connected to the transmission shaft, the surface of the transmission shaft is provided with a closed guide groove provided around the shaft body in the axial direction, and the tilting tooth plate rocks alternately during rotation of the transmission shaft;

A movable rack is provided below the tilting tooth plate and gear-connected thereto, a movable column is provided at one end of the movable rack, and the transmission shaft is through-connected to the mobile column via a bearing.

In addition, the input rail is rotatably arranged around an end remote from the transition roller as the center, and the lower part of the rotating end of the input rail is provided with a post, the post is connected to the output rail via a first connecting rod, the two ends of the first connecting rod are movably sheathed on the upright and on a boss provided at the lower part of one end of the output rail, the upright is connected to the movable column through a second connecting rod, and the input rail reciprocates along an arc path with the reciprocating transverse movement of the transition roller;

The two ends of the output rail are slidingly connected to a rectangular guide frame, and the output rail, driven by the input rail, moves transversely synchronously with the reciprocating transverse movement of the transition roller.

In addition, the transmission component includes a driving tooth roller connected to one end of the transmission shaft, the driving tooth roller side is provided with a driving tooth roller meshed therewith and having a shorter length to that thereof, the side of the driven tooth roller is provided with a locking tooth column coaxially connected therewith, the surface of the locking tooth column is provided with the arc locking grooves at a regular interval, and the upper part of the lock tooth column is provided with a lock plate connected in the clutch state thereto, the lock plate is fixed on a movable seat, the seat movable is provided with a locking component, and the locking component in the unlocked state drives the clamping component to clamp the wire on the winding roller.

In addition, the lock component comprises a first rod and a second rod, the first rod and the second rod are movably inserted at both ends of a sealing tube, the first rod is connected to the movable seat, the second rod is connected to a locking blade, when the movable seat moves upward under

As the lock tooth column drives back, the lock blade retracts and is separated from a spinning component to unlock.

In addition, the clamping component comprises a clamping plate provided on a winding roller, the two ends of the clamping plate are each provided with a first floating rod, the surface of the first floating rod is provided with a locking groove adapted to the locking blade, a cross plate is provided above the clamping plate, a first spring connects the cross plate to the clamping plate, after the locking blade is retracted and unlocked, the locking plate clamp moves downward under the action of the first spring to its initial position to tighten the wire on the winding roller.

In addition, rubber wedges are provided at both ends at the lower part of the clamp plate, and the rubber wedges press against the lower end of the clamp plate to reduce the downward movement speed of the clamp plate. clamp plate during the unlocking process.

In addition, the clamping component further comprises a threading seat provided at one end of the input rail, the inner side of the threading seat is provided with a movable clamping block, the upper part of the clamping block is provided with a second spring, and the other side of the clamp block is provided with a second floating rod, one end of the second floating rod is connected to the movable seat through the locking component, when the seat movable moves up under the driving of the locking tooth column returning, the clamping block moves down synchronously to clamp the wire at the inlet end.

A process for producing colored yarn winding, relating to the colored yarn winding device described above, and in particular comprising the following steps

S1: the wire to be wound passes through the input rail, the transition roller and the output rail, and finally is wound on the winding roller to drive the winding roller to execute winding; 82: During the wire winding process, the transition roller is driven to rotate continuously, the upper end of the tilting tooth plate slides along the guide groove on the surface of the transmission shaft, Since the guide groove is a closed groove provided around the shaft body along the axial direction of the surface of the transmission shaft, the tilting tooth plate swings reciprocally, thereby driving the movable rack connected in a manner gearing the same to move transversely reciprocally, and synchronously driving the movable column to move transversely, so that the transmission shaft drives the transition roller to move transversely reciprocally;

S3: the movable column drives, via the second connecting rod, the input rail to move alternately along an arc trajectory, and drives, via the first connecting rod, the output rail to move move transversely along the rectangular guide frame, so that the wires are wound evenly on the winding roller;

S4: After the wire is disconnected, the transition roller quickly returns, and drives the driving tooth roller and the driven tooth roller to rotate quickly synchronously, so that the blocking plate is separated from the blocking groove in arc to maintain a flapping separation state without contact with the locking tooth column, and the second rod pulls the locking blade rearward to separate it from the first floating rod and the second floating rod, under the The action of the first spring and the second spring, the clamp plate and the clamp block are ejected downward, so as to clamp the 5 wires on the winding roller and at the entry end, thus completing the anti-loosening operation.

The present invention has the following beneficial effects:

According to the present invention, by arranging the transition roller which rotates continuously during the wire winding process, the transmission shaft cooperates with the transmission component to drive the output rail to move transversely reciprocally, thereby which can wind the wires on the winding roller evenly, and avoid the problem of wire entanglement, and after the wire is disconnected, the transition roller quickly returns to unlock the clamp plate and the clamping block on both sides, so as to clamp the wires on the winding roller and at the entry end, avoiding the problem of loosening of the wound wire or wire jamming of the winding mechanism.

V input end due to wire disconnection, improving the ability to solve sudden problems of wire disconnection of the device, and facilitating subsequent maintenance and replacement.

DESCRIPTION OF FIGURES

[Fig. 1] is a view of the structure according to the present invention; [Fig. 2] is a view of the interior structure of the housing according to the present invention; [Fig. 3] is a view of the structure of the winding unit according to the present invention; [Fig. 4] is a view of the structure of the anti-loosening unit according to the present invention; [Fig. 5] is a structural view of the transmission component and the clamping component according to the present invention; [Fig. 6] is a view of the connection structure between the input rail and the output rail according to the present invention; and [Fig. 7] is a view of the structure of the locking component according to the present invention.

In the figures, the references are as follows: 100 - Housing; 101 - Assembly table; 200 - Entrance rail; 201 - Output rail; 202 - Second connecting rod; 203 - Winding roller; 204 - Transition roller; 205 - Transmission shaft; 2051 - Guide groove; 206 - Support seat; 207 - Tilting tooth plate; 208 -

Mobile rack; 209 - Mobile column; 210 - Rectangular guide frame; zi 92/6064

Amount ; 212 - First connecting rod; 300 - Driving toothed roller; 301 -Driven toothed roller; 302 - Column with blocking teeth; 303 - Blocking plate; 304 - Mobile seat; 305 - Locking component; 3051 - Sealing tube; 3052 - First stem; 3053 - Second rod; 3054 - Locking blade; 306 - First floating rod; 307 - Clamping plate; 308 -

First spring; 309 - Rubber wedge; 310 - Cross plate; 311 - Donning seat; 312 - Clamping block; 313 - Second spring; 314 - Second floating rod.

DETAILED STATEMENT OF MODE OF ACHIEVEMENT

The technical solutions of the exemplary embodiments of the present invention will be described clearly and completely by the following description with reference to the figures, in which said exemplary embodiments are only part of the exemplary embodiments instead of all exemplary embodiments. . It should be noted that the exemplary embodiments of the present application and the characteristics of the exemplary embodiments may be combined with each other unless otherwise indicated. Other exemplary embodiments based on the exemplary embodiments of the present invention and obtained by those skilled in the art without creative work must be included within the scope of the protection of the present invention.

It should be noted that, while the exemplary embodiments of the present invention relate to direction indication terms such as "upper", "lower", "left", "right", "front" and "rear", direction indication terms are only to explain a relative position relationship between components under a particular attitude (as shown in the figures) and movements, etc. if the specific attitude changes, the direction indication terms also change accordingly.

Furthermore, when the exemplary embodiments of the present invention relate to terms such as “first (first)” and “second (second)”, the terms “first (first)” and “second (second)” are illustrative, and should not be considered to indicate or imply a degree of relative importance or number of technical characteristics indicated. Thus, features with the words "first" or "second" can be taken to indicate or imply one or more features.

Furthermore, the meaning of "and/or" appearing in the description includes three parallel solutions, taking "A and/or B" as an example, including solution A, or solution B, or solutions A and B at the same time. time. Additionally, the term “a plurality” means two or more. In addition, the technical solutions of the different embodiments can be combined with each other, but must be based on the possibility of implementation by those skilled in the art in the field, when the combination of technical solutions seems contradictory or impossible to achieve. , it should be considered that the combination of such technical solutions does not exist, nor is it included within the framework of the protection claimed by the invention.

Referring to Figures 1 and 2, the present invention provides a device for winding colored threads, comprising:

A case 100, which is provided with a mounting table 101 inside and an entrance hole on the surface;

A winding unit, which is disposed inside the housing 100, and comprises a transition roller 204, in which an input rail 200 and an output rail 201 are provided on either side of the roller. transition 204, the input rail 200 is movably connected to the output rail 201, the output rail 201 is provided on its front side with a winding roller 203, the wire passes successively through the input rail 200, the transition roller 204 and the output rail 201 and is wound on the winding roller 203, the transition roller 204 is inserted through a transmission shaft 205, the transmission shaft 205 is arranged movably to pass through a support seat 206, one end of the transmission shaft 205 is provided with a drive component, the transition roller 204 moves transversely reciprocally under the action of the drive component training ;

An anti-loosening unit, which includes transmission components and clamping components, wherein the transmission components are provided at two ends of the transmission shaft 205, the clamping components are provided at the winding roller 203 and at the entry end, after the wire is disconnected, the transition roller 204 returns to drive the transmission component to control the clamping component to tighten the wires at the entry end and the winding.

By arranging the transition roller 204 which rotates continuously during the wire winding process, the transmission shaft 205 cooperates with the transmission component to drive the output rail 201 to move transversely reciprocally, thereby enabling to evenly wind the wires on the winding roller 203, and avoid the problem of wire entanglement, and once the wire is disconnected, the transition roller 204 quickly returns to unlock the clamping plate on the two sides, so as to tighten the wires on the winding roller 203 and at the entry end, thus avoiding the problems of loosening of the wound wire or blocking of wire from the mechanism to

V input end due to wire disconnection, improving the ability to solve sudden problems of wire disconnection of the device, and facilitating subsequent maintenance and replacement.

In an exemplary embodiment and referring to Figures 2 and 3, the drive component comprises a tilting tooth plate 207, the lower part of the tilting tooth plate 207 has a fan-shaped plate structure with tooth grooves provided on an arc edge, and the upper part of the tilting tooth plate 207 is movably connected to the transmission shaft 205, the surface of the transmission shaft 205 is provided with a closed guide groove 2051 provided around the shaft body in the axial direction, and the tilting tooth plate 207 swings alternately during the rotation of the transmission shaft 205;

A movable rack 208 is provided below the tilting tooth plate 207 and gearally connected thereto, a movable column 209 is provided at one end of the movable rack 208, and the transmission shaft 205 is connected in a through manner to the movable column 209 via a bearing.

During the wire winding process, the transition roller 204 is driven to rotate continuously, the upper end of the tilting tooth plate 207 slides along the guide groove 2051 on the surface of the transmission shaft 205, since the guide groove 2051 is a closed groove provided around the shaft body in the axial direction of the surface of the transmission shaft 205, the tilting tooth plate 207 swings alternately, thereby causing the movable rack 208 gearally connected thereto to move transversely reciprocally, and synchronously driving the movable column 209 to move transversely, so that the transmission shaft 205 drives the transition roller 204 to move transversely in an alternative manner, which makes it possible to wind the threads evenly on the winding roller 203, and to avoid the problem of entanglement of the threads.

In an exemplary embodiment and referring to Figures 3 and 6, the input rail 200 is rotatably arranged around a remote end of the transition roller 204 as the center, and the lower part of the rotating end of the rail input 200 is provided with an upright 211, the upright 211 is connected to the output rail 201 via a first connecting rod 212, the two ends of the first connecting rod 212 are movably sheathed on the upright 211 and on a bump provided at the lower part of one end of the output rail 201, the upright 211 is connected to the movable column 209 via a second connecting rod 202, and the input rail 200 moves from alternatively in an arcuate path with the alternating transverse movement of the transition roller 204;

Both ends of the output rail 201 are slidably connected to a rectangular guide frame 210, and the output rail 201, driven by the input rail 200, moves transversely synchronously with the reciprocating transverse movement of the roller transition 204.

When the transmission shaft 205 drives the tilting tooth plate 207 to control the movable rack 208 to move transversely, it synchronously drives the movable column 209 to move transversely, drives, through the second connecting rod 202 , one end of the input rail 200 to move, so that the input rail 200 moves alternately along an arc path, and drives, via the first connecting rod 212, the output rail 201 to move alternately in a straight path along the rectangular guide frame 210, so that the wires are wound evenly on the winding roller 203;

In an exemplary embodiment and referring to Figures 4 and 5, the transmission component comprises a driving tooth roller 300 connected to one end of the transmission shaft 205, the side of the driving tooth roller 300 is provided with a driven tooth roller 301 meshed therewith and having a length less than that of the latter, the side of the driven tooth roller 301 is provided with a locking tooth column 302 connected coaxially therewith, the surface of the locking tooth column 302 is provided with the arc locking grooves at a regular interval, and the upper part of the locking tooth column 302 is provided with a locking plate 303 connected in the state of clutch thereto, the locking plate 303 is fixed on a movable seat 304, the movable seat 304 is provided with a locking component 305, and the locking component 305 in the unlocking state drives the locking component tightening to tighten the wire on the winding roller 203.

The locking tooth column 302, driven by the driving tooth roller 300 and the driven tooth roller 301, rotates with the transmission shaft 205, during normal wire winding, the drive shaft 205 rotates continuously at a stable speed, in this case, the locking plate 303 successively comes into contact with the arcuate locking grooves provided at a compact interval on the surface of the locking tooth column 302 (it should be noted that the edge of the end of the locking plate 303 in contact with the arc locking grooves has an arc structure, thereby facilitating separation and limiting contact between the two), so that the locking component 305 is always in a locked state. After the wire is disconnected, the transmission shaft 205 returns quickly, so that the locking tooth column 302 is synchronously in a state of rotation at a high speed, in this case, the locking plate 303 is maintained to a flapping separation state without contact with the locking tooth column 302, so that the locking component 305 is locked and cooperates with the clamping component to tighten the wires, thereby avoiding problems of wire loosening or stuck wire bounced.

In an exemplary embodiment and referring to Figures 4, 5 and 7, the locking component 305 comprises a first rod 3052 and a second rod 3053, the first rod 3052 and the second rod 3053 are inserted movably at both ends of a sealing tube 3051, the first rod 3052 is connected to the movable seat 304, the second rod 3053 is connected to a locking blade 3054, when the movable seat 304 moves upward under the drive of the column to locking teeth 302 which returns, the locking blade 3054 retracts and is separated from a spinning component to unlock.

After the wire is disconnected, the blocking plate 303 is kept in a beating separation state without contact with the blocking tooth column 302, when the blocking plate 303 moves upward and is separated from the tooth column locking blade 302, it causes the first rod 3052 to move synchronously upwards, so that the second rod 3053 pulls the locking blade 3054 backwards and the end of the latter is separated from the locking component tightening to unlock and therefore apply a tightening effect on the wire, when the wire is in a normal winding state, the blocking plate 303 comes into continuous and regular contact with the column with blocking teeth 302, in this case, the locking blade 3054 moves transversely alternately along a short trajectory, the transverse movement interval is not insufficient to unlock the clamping component, which allows tightening of the disconnected wire, thus improving the reliability of the device without affect the normal operation of wire winding.

In an exemplary embodiment and referring to Figure 4, the clamping component comprises a clamping plate 307 arranged on a winding roller 203, the two ends of the clamping plate 307 are each provided with a first floating rod 306, the surface of the first floating rod 306 is provided with a locking groove suitable for the locking blade 3054, a cross plate 310 is provided above the clamping plate 307, a first spring 308 connects the cross plate 310 to the clamping plate 307, once the locking blade 3054 is retracted and unlocked, the clamping plate 307 moves downward under the action of the first spring 308 to its initial position to clamp the wire on the roller winding 203.

Once the wire is disconnected, the locking blade 3054 moves rearward and separates from the first floating rod 306 (it should be noted that the locking blade 3054 is provided on either side, thereby maintaining the first floating rod 306 is horizontal in the unlocked state), so that the first floating rod 306 moves downwards under the action of the first spring 308, and causes the clamping plate 307 to come into contact with the wire wound on the winding roller 203, thereby tightening the disconnected wire and avoiding the problem of loosening.

In an exemplary embodiment and referring to Figure 4, rubber wedges 309 are provided at both ends at the lower part of clamping plate 307, and the rubber wedges 309 rest against the lower end of the plate clamp 307 to reduce the downward movement speed of the clamp plate 307 during the unlocking process. The arrangement of the rubber wedges 309, when the wire is connected, during the process of continuous contact between the locking plate 303 and the locking tooth column 302, can reduce the downward movement speed of the locking plate. tightening 307 for a short time of separation of the locking blade 3054, thus avoiding the problem of false unlocking and ensuring stable operation of the device.

In an exemplary embodiment and referring to Figure 5, the clamping component further comprises a threading seat 311 disposed at one end of the entry rail 200, the interior side of the threading seat 311 is provided with a movable clamp block 312, the upper part of the clamp block 312 is provided with a second spring 313, and the other side of the clamp block 312 is provided with a second floating rod 314, one end of the second rod floating seat 314 is connected to the movable seat 304 through the locking component 305, when the movable seat 304 moves upward under the driving of the lock tooth column 302 which returns, the clamp block 312 moves synchronously downward to tighten the thread at the end of the inlet. Once the wire is disconnected, the locking blade 3054 moves rearward and separates from the second floating rod 314 (it should be noted that the locking blade 3054 is only provided on one side of the clamp block , which makes it possible to maintain the second floating rod 314 horizontal in the unlocked state), so that the second floating rod 314 moves downwards under the action of the second spring 313, and drives the clamping block 312 to come into contact with the wire at the entry end, thereby tightening the disconnected wire and avoiding the problem of loosening and avoiding the problem of wire jamming of the entry mechanism due to wire bouncing.

A process for producing colored yarn winding, relating to the colored yarn winding device described above, and comprising in particular the following steps:

S1: the wire to be wound passes through the input rail 200, the transition roller 204 and the output rail 201, and finally is wound on the winding roller 203 to drive the winding roller 203 to execute winding ;

S2: During the wire winding process, the transition roller 204 is driven to rotate continuously, the upper end of the tilting tooth plate 207 slides along the guide groove 2051 on the surface of the shaft transmission 205, since the guide groove 2051 is a closed groove provided around the shaft body in the axial direction of the surface of the transmission shaft 205, the tilting tooth plate 207 swings alternately, causing thus the movable rack 208 connected in a gear manner thereto to move transversely reciprocally, and synchronously driving the movable column 209 to move transversely, so that the transmission shaft 205 drives the roller of transition 204 to move transversely in an alternative manner;

S3: the movable column 209 drives, via the second connecting rod 202, the input rail 200 to move alternately along an arcuate trajectory, and drives, via the first connecting rod 212, the output rail 201 to move transversely along the rectangular guide frame 210, so that the wires are wound evenly on the winding roller 203;

S4: After the wire is disconnected, the transition roller 204 returns quickly, and drives the driving tooth roller 300 and the driven tooth roller 301 to rotate quickly synchronously, so that the blocking plate 303 is separated from the arc locking groove to maintain a flapping separation state without contact with the locking tooth column 302, and the second rod 3053 pulls the locking blade 3054 rearward to separate it from the first floating rod 306 and of the second floating rod 314, under the action of the first spring 308 and the second spring 313, the clamping plate 307 and the clamping block 312 are ejected downward, so as to clamp the wires on the winding roller 203 and at the entry end, thus completing the anti-loosening operation.

The examples of embodiments below are the preferred and non-limiting examples of embodiments, all modifications, alternative variations and improvements which respect the spirits and principles of the present invention must be included within the scope of the protection of the present invention.

Claims (9)

1. Device for winding colored wires, characterized in that it comprises: A housing (100), which is provided with an assembly table (101) inside and an entry hole on the surface; A winding unit, which is provided inside the housing (100), and includes a transition roller (204), in which an input rail (200) and an output rail (201) are provided to on either side of the transition roller (204), the input rail (200) is movably connected to the output rail (201), the output rail (201) is provided on its front side with a winding roller (203), the wire passes successively through the entry rail (200), the transition roller (204) and the exit rail (201) and is wound on the winding roller (203), the transition roller (204) is inserted through a transmission shaft (205), transmission shaft (205) is movably arranged to pass through a support seat (206), one end of the shaft transmission (205) is provided with a driving component, the transition roller (204) moves transversely reciprocating under the action of the driving component; An anti-loosening unit, which includes transmission components and clamping components, wherein the transmission components are provided at two ends of the transmission shaft (205), the clamping components are provided at the roller winding (203) and at the input end, after the wire is disconnected, the transition roller (204) returns to drive the transmission component to control the clamping component to tighten the wires at the end of entry and at the winding end. 2. Device for winding colored yarns according to claim 1, characterized in that the drive component comprises a tilting tooth plate (207), the lower part of the tilting tooth plate (207) has a structure of fan plate with tooth grooves provided on an arc edge, and the upper part of the tilting tooth plate (207) is movably connected to the transmission shaft (205), the surface of the transmission shaft transmission (205) is provided with a closed guide groove (2051) provided around the shaft body in the axial direction, and the tilting tooth plate (207) swings alternately during rotation of the transmission shaft (205); A movable rack (208) is provided below the tilting tooth plate (207) and gear-connected thereto, a movable column (209) is provided at one end of the movable rack (208) , and the transmission shaft (205) is through-connected to the movable column (209) through a bearing. 3. Device for winding colored yarns according to claim 2, characterized in that the input rail (200) is rotatably arranged around an end remote from the transition roller (204) as the center, and the lower part of the rotating end of the input rail (200) is provided with a post (211), the post (211) is connected to the output rail (201) via a first connecting rod (212 ), the two ends of the first connecting rod (212) are movably sheathed on the upright (211) and on a boss provided at the lower part of one end of the output rail (201), the upright (211) is connected to the movable column (209) via a second connecting rod (202), and the input rail (200) moves reciprocally along an arc path with the reciprocating transverse movement of the transition roller ( 204); Both ends of the output rail (201) are slidably connected to a rectangular guide frame (210), and the output rail (201), driven by the input rail (200), moves transversely in a manner synchronous with the reciprocating transverse movement of the transition roller (204). 4. Device for winding colored yarns according to claim 1, characterized in that the transmission component comprises a driving tooth roller (300) connected to one end of the transmission shaft (205), the roller side driving tooth roller (300) is provided with a driven tooth roller (301) meshed therewith and having a length less than that thereof, the side of the driven tooth roller (301) is provided with a locking tooth column (302) coaxially connected therewith, the surface of the locking tooth column (302) is provided with the arc locking grooves at a regular interval, and the upper part of the locking tooth column locking teeth (302) is provided with a locking plate (303) connected in the clutch state thereto, the locking plate (303) is fixed on a movable seat (304), the movable seat (304) is provided with a locking component (305), and the locking component (305) in the unlocked state causes the clamping component to clamp the wire on the winding roller (203). 5. Device for winding colored threads according to claim 4, characterized in that the locking component (305) comprises a first rod (3052) and a second rod (3053), the first rod (3052) and the second rod (3053) are movably inserted at both ends of a sealing tube (3051), the first rod (3052) is connected to the movable seat (304), the second rod (3053) is connected to a sealing blade lock (3054), when the movable seat (304) moves upward under the driving of the lock tooth column (302) which returns, the lock blade (3054) retracts and is separated from a component spinning to unlock. 6. Device for winding colored threads according to claim 5, characterized in that the clamping component comprises a clamping plate (307) arranged on a winding roller (203), the two ends of the clamping plate (307) are each provided with a first floating rod (306), the surface of the first floating rod (306) is provided with a locking groove matched to the locking blade (3054), a cross plate (310) is provided above the clamping plate (307), a first spring (308) connects the transverse plate (310) to the clamping plate (307), once the locking blade (3054) is retracted and unlocked, the clamping plate (307) moves downward under the action of the first spring (308) to its initial position to clamp the wire on the winding roller (203). 7. Device for winding colored threads according to claim 6, characterized in that rubber wedges (309) are provided at both ends at the lower part of the clamping plate (307), and the rubber wedges (309) ) press against the lower end of the clamp plate (307) to reduce the downward movement speed of the clamp plate (307) during the unlocking process. 8. Device for winding colored threads according to claim 6, characterized in that the clamping component further comprises a threading seat (311) disposed at one end of the entry rail (200), the inner side of the threading seat (311) is provided with a movable clamp block (312), the upper part of the clamp block (312) is provided with a second spring (313), and the other side of the threading block clamp (312) is provided with a second floating rod (314), one end of the second floating rod (314) is connected to the movable seat (304) via the locking component (305), when the movable seat (304) moves upward under the driving of the lock tooth column (302) which returns, the clamping block (312) moves synchronously downward to clamp the wire at the end of the 'entrance. 9. method of producing winding of colored threads, relating to the device for winding colored threads according to any one of claims 1 to 8, characterized in that the method comprises the following steps: S1: the thread to be wound passes through the input rail (200), the transition roller (204) and the output rail (201), and finally is wound on the winding roller (203) to drive the winding roller (203) to perform a winding; S2: During the wire winding process, the transition roller (204) is driven to rotate continuously, the upper end of the tilting tooth plate (207) slides along the guide groove (2051) on the surface of the transmission shaft (205), given that the guide groove (2051) is a closed groove provided around the shaft body in the axial direction of the surface of the transmission shaft (205), the tilting tooth plate (207) swings reciprocally, thereby driving the movable rack (208) gearingly connected thereto to move transversely reciprocally, and synchronously driving the movable column (209) moving transversely, so that the transmission shaft (205) drives the transition roller (204) to move transversely reciprocally; S3: the movable column (209) drives, via the second connecting rod (202), the input rail (200) to move alternately along an arc trajectory, and drives, via the first connecting rod (212), the output rail (201) to move transversely along the rectangular guide frame (210), so that the wires are evenly wound on the winding roller (203); S4: After the wire is disconnected, the transition roller (204) returns quickly, and drives the driving tooth roller (300) and the driven tooth roller (301) to rotate quickly synchronously, so that the driving plate lock (303) is separated from the arc lock groove to maintain a beating separation state without contact with the lock tooth column (302), and the second rod (3053) pulls the lock blade (3054) backwards to separate it from the first floating rod (306) and the second floating rod (314), under the action of the first spring (308) and the second spring (313), the clamping plate (307) and the clamp block (312) are ejected downward, so as to clamp the wires on the winding roller (203) and at the entry end, thus completing the anti-loosening operation.