CN221439977U - Automatic winding device for multi-strand core wire - Google Patents

Abstract

The utility model discloses an automatic winding device for multi-strand core wires, which comprises a bracket, a winding shaft and a driving mechanism, wherein a winding passing hole and a core wire passing hole which penetrate through the winding shaft are formed in the winding shaft along an axis, the core wire passing hole is formed in a central axis of the winding shaft, the winding passing hole is formed in the side part of the core wire passing hole, the winding shaft is connected with the bracket in a unidirectional rotation mode, the winding shaft rotates around the central axis of the winding shaft, the winding shaft is further connected with the bracket in a reciprocating sliding mode, the sliding direction of the winding shaft is parallel to the axis of the winding shaft, the driving mechanism is fixed on the bracket, and the driving mechanism drives the winding shaft to slide in a reciprocating mode and drive the winding shaft to slide in one direction and not rotate in the other direction. The automatic winding machine can realize automatic winding, reduce the number of operators, save physical strength, improve winding efficiency, save winding time and have remarkable effect especially under the condition of large workload.

Description

Automatic winding device for multi-strand core wire

Technical Field

The utility model relates to the technical field of cable processing, in particular to an automatic winding device for a multi-strand core wire.

Background

The railway signal cable is a multi-core cable, and each core wire consists of 7 strands of copper wires with the diameter of 0.52 mm. After each core wire is stripped, 7 strands of copper wire are wound together by using a copper wire with the diameter of 0.3 mm. The utility model patent with the application number 2013201318101 discloses a wire loop winding device of railway signal equipment, which is used for winding a wire loop spool, and after copper wires are filled, a wire outlet of a wire lead head, a wire loop regulator, a wire inlet and a wire loop winder outlet are led. And penetrating the part of the power wire, which is removed from the outer skin, of the power wire, which needs to be wound, into the wire winding device pipe, fixing the position, which needs to be wound, and rotating the winding handle. Winding the required length, taking out , bending, and fixing. The wire winding device has the advantages that the damage to hands caused by wire lifting winding can be reduced, the manual rotation is not reduced in the workload of manual operation of workers, and more force is needed to rotate the rotating frame and the wire winding device driven by the rotating frame.

Disclosure of utility model

Aiming at the defects of the prior art, the utility model innovatively provides the multi-strand core wire automatic winding device which can realize automatic winding, reduce the number of operators, save physical strength, improve the winding efficiency, save the winding time and have remarkable effect especially under the condition of large workload.

In order to achieve the technical aim, the utility model discloses an automatic winding device for a multi-strand core wire, which comprises a bracket, a winding shaft and a driving mechanism,

A winding wire passing hole and a core wire passing hole which penetrate through the winding shaft are arranged on the winding shaft along the axis, the core wire passing hole is positioned on the central axis of the winding shaft, the winding wire passing hole is positioned at the side part of the core wire passing hole,

The winding shaft is connected with the bracket in a unidirectional rotation way, the winding shaft rotates around the central axis of the winding shaft, the winding shaft is also connected with the bracket in a reciprocating sliding way, the sliding direction of the winding shaft is parallel to the axis of the winding shaft,

The driving mechanism is fixed on the bracket, and drives the winding shaft to slide back and forth and drive the winding shaft to slide along one direction and simultaneously rotate unidirectionally and not rotate when sliding along the other direction.

Further, the driving mechanism is a motor, an output shaft of the motor is coaxially and fixedly connected with a driving wheel, the driving wheel is respectively connected with a unidirectional driven wheel and a driven wheel in a transmission manner through a belt, the unidirectional driven wheel is coaxially fixed on the winding shaft, the driven wheel is provided with an internal thread, the driven wheel is coaxially and threadedly connected with a screw rod, the screw rod is fixedly connected with the support, the screw rod is parallel to the winding shaft, a connecting plate is fixedly connected with a machine body of the motor, and the driving wheel, the driven wheel and the unidirectional driven wheel are respectively and rotatably connected with the connecting plate.

The driving mechanism is a motor, a driving gear is coaxially and fixedly connected with an output shaft of the motor, the driving gear is respectively connected with a unidirectional driven gear and a driven gear in a transmission manner through a chain, the unidirectional driven gear is coaxially fixed on the winding shaft, the driven gear is provided with an internal thread, the driven gear is coaxially and fixedly connected with a screw rod, the screw rod is fixedly connected with the support, the screw rod is parallel to the winding shaft, a connecting plate is fixedly connected with a machine body of the motor, and the driving gear, the driven gear and the unidirectional driven gear are respectively connected with the connecting plate in a rotation manner.

Further, the device also comprises a guide shaft, wherein the guide shaft is fixedly connected with the support, the guide shaft is parallel to the winding shaft and the screw rod, a guide hole is formed in the connecting plate, and the guide hole is sleeved on the guide shaft.

Further, the number of the guide shafts is 2, and 2 guide shafts are arranged in parallel.

Further, the support comprises a first support plate, a second support plate and a third support plate connected with the first support plate and the second support plate, wherein the first support plate and the second support plate are arranged in parallel, the winding shaft is perpendicular to the first support plate and the second support plate and is arranged between the first support plate and the second support plate, and a wire passing hole is formed in the first support plate and the second support plate corresponding to the position of the wire passing hole and the position of the core wire passing hole.

Further, the support further comprises a core wire placing plate, the core wire placing plate is vertically fixed on the first supporting plate, the core wire placing plate is arranged on one side, away from the second supporting plate, of the first supporting plate, and a core wire clamping groove is formed in the core wire placing plate, corresponding to the wire passing hole.

Further, the support also comprises a fourth support plate and a protective cover, wherein the fourth support plate is parallel to the first support plate and the second support plate and is fixed on one side, far away from the first support plate, of the second support plate, and the protective cover is arranged above the first support plate, the second support plate, the third support plate and the fourth support plate.

Further, the wire inlet button, the wire outlet button and the speed regulating button are embedded in the support, and the wire inlet button, the wire outlet button and the speed regulating button are respectively and electrically connected with the driving mechanism.

The beneficial effects of the utility model are as follows:

The multi-strand core wire automatic winding device can realize automatic winding, reduce the number of operators, save physical strength, improve winding efficiency, save winding time and have remarkable effect especially under the condition of large workload.

Drawings

Fig. 1 is a perspective view of an automatic winding apparatus for a multi-strand wire according to an embodiment of the present utility model.

Fig. 2 is a schematic view showing the structure of the automatic winding apparatus for multi-strand wires according to the embodiment of the present utility model with a bracket removed.

Fig. 3 is a schematic view showing another view of the automatic winding apparatus for multi-strand wires according to the embodiment of the present utility model with a bracket removed.

Fig. 4 is an external view of the automatic winding apparatus for multi-strand wires according to the embodiment of the present utility model.

Fig. 5 is a perspective view of a stent according to an embodiment of the present utility model.

In the drawing the view of the figure,

1. A bracket; 11. a first support plate; 12. a second support plate; 13. a third support plate; 14. a fourth support plate; 15. a protective cover; 16. a core wire placement plate; 161. a core wire clamping groove; 17. a wire through hole; 2. a winding shaft; 21. the winding passes through the hole; 22. the core wire passes through the hole; 3. a driving mechanism; 4. a driving wheel; 5. a unidirectional driven wheel; 6. driven wheel; 7. a screw rod; 8. a connecting plate; 9. a guide shaft; 10. a wire inlet button; 20. a wire withdrawing button; 30. a speed adjusting knob; 40. a drive gear; 50. a unidirectional driven gear; 60. a driven gear.

Detailed Description

The automatic winding apparatus for multi-strand core wire provided by the present utility model will be explained and illustrated in detail with reference to the accompanying drawings.

The embodiment specifically discloses an automatic winding device for multi-strand core wires, as shown in fig. 1-5, including a support 1, a winding shaft 2 and a driving mechanism 3, the support 1 is used for fixedly supporting the winding shaft 2 and the driving mechanism 3, as shown in fig. 2 and 3, a winding wire passing hole 21 penetrating through the winding shaft 2 and a core wire passing hole 22 are arranged on the winding shaft 2 along the axis, the core wire passing hole 22 is located on the central axis of the winding shaft 2, the winding wire passing hole 21 is located on the side part of the core wire passing hole 22, the winding shaft 2 is connected with the support 1 in a unidirectional rotation manner, the winding shaft 2 rotates around the central axis of the winding shaft, the head end of the core wire penetrates into the core wire passing hole 22 of the winding shaft 2 from one end of the winding shaft 2 opposite to the core wire, and penetrates out of the winding shaft 2, the head end of the winding copper wire is lapped with the core wire, and when the winding shaft 2 rotates around the central axis of the winding shaft 1, the winding copper wire is wound onto the core wire. The winding shaft 2 is also connected with the support 1 in a reciprocating sliding manner, the sliding direction of the winding shaft 2 is parallel to the axis of the winding shaft 2, the driving mechanism 3 is fixed on the support 1, the driving mechanism 3 drives the winding shaft 2 to slide in a reciprocating manner and drive the winding shaft 2 to slide in one direction and simultaneously rotate unidirectionally, the winding shaft does not rotate when sliding in the other direction, the core wire and the winding copper wire are positioned on different sides, the winding shaft 2 slides to one side close to the core wire initially, and during winding, the winding shaft 2 slides to the other side while rotating, so that winding of the winding copper wire on the core wire is realized, and a wire loop with a certain density is formed.

Specifically, as shown in fig. 4 and 5, the bracket 1 includes a first support plate 11, a second support plate 12, and a third support plate 13 connecting the first support plate 11 and the second support plate 12, the first support plate 11 and the second support plate 12 are arranged in parallel, the third support plate 13 is fixed perpendicular to the first support plate 11 and the second support plate 12, both ends of the first support plate 11 and the second support plate 12 are fixed with the third support plate 13, the winding shaft 2 is perpendicular to the first support plate 11 and the second support plate 12 and is arranged between the first support plate 11 and the second support plate 12, the winding shaft 2 slides reciprocally between the first support plate 11 and the second support plate 12, and a wire passing hole 17 is formed in the first support plate 11 and the second support plate 12 at a position corresponding to the wire passing hole 21 and the core wire passing hole 22.

Optionally, the bracket 1 further includes a core wire placing plate 16, the core wire placing plate 16 is vertically fixed on the first supporting plate 11, the core wire placing plate 16 is disposed on one side, far away from the second supporting plate 12, of the first supporting plate 11, a core wire clamping groove 161 is formed in the core wire placing plate 16 corresponding to the wire passing hole 17, the core wire can be placed on the core wire placing plate 16 and clamped into the core wire clamping groove 161, the head end of the core wire passes through the wire passing hole 17 in the first supporting plate 11 to enter the core wire passing hole 22 of the winding shaft 2, the length of the core wire passing hole 22 is adjusted according to the position of the winding wire loop, and the head end of the core wire can pass out to the other end of the winding shaft 2 and also can pass out of the wire passing hole 17 in the second supporting plate 12. When winding the wire copper wire, the core wire is held in place at the core wire holding groove 161 of the core wire holding plate 16, and the wire copper wire is wound around the core wire.

Optionally, the bracket 1 further includes a fourth support plate 14 and a protection cover 15, the fourth support plate 14 is parallel to the first support plate 11 and the second support plate 12 and is fixed on a side of the second support plate 12 away from the first support plate 11, and the protection cover 15 is covered above the first support plate 11, the second support plate 12, the third support plate 13 and the fourth support plate 14. The fourth backup pad 14 is last be equipped with the coaxial wire through hole 17 of wire through hole 17 in first backup pad 11 and the second backup pad 12, the wire winding copper wire is placed in the one side that the fourth backup pad 14 kept away from the second backup pad 12, wire through hole 17 in the fourth backup pad 14 is passed in proper order to the head end of wire winding copper wire, wire through hole 17 in the second backup pad 12, wire winding through hole 21 on the winding axle 2, wire through hole 17 in the first backup pad 12 is worn out outside the support 1, the length of wire winding copper wire that support 1 supported has been increased in the setting of fourth backup pad 14, avoid wire winding copper wire knotting when the winding, protection cover 15 plays the guard action to actuating mechanism 3 and winding axle 2.

In this embodiment, the driving mechanism 3 is a motor, as shown in fig. 1-3, an output shaft of the motor is coaxially and fixedly connected with a driving wheel 4, the driving wheel 4 is respectively connected with a unidirectional driven wheel 5 and a driven wheel 6 (the belt is not shown in the figure) in a transmission manner through a belt, the unidirectional driven wheel 5 is coaxially fixed on the winding shaft 2, the driven wheel 6 is provided with internal threads, the driven wheel 6 is coaxially and threadedly connected with a screw rod 7, the screw rod 7 is fixedly connected with the bracket 1, the screw rod 7 is parallel to the winding shaft 2, two ends of the screw rod 7 are respectively and fixedly connected with a first supporting plate 11 and a second supporting plate 12, a connecting plate 8 is fixedly connected with a machine body of the motor, the connecting plate 8 is positioned between the first supporting plate 11 and the second supporting plate 12, and the driving wheel 4, the driven wheel 6 and the unidirectional driven wheel 5 are respectively and rotatably connected with the connecting plate 8. As shown in fig. 1, the connecting plate 8 is parallel to the first supporting plate 11 and the second supporting plate 12, holes for the lead screw 7 and the winding shaft 2 to pass through are formed in the connecting plate 8, the lead screw 7 and the winding shaft 2 pass through the connecting plate 8, the winding shaft 2, the unidirectional driven wheel 5, the driven wheel 6, the driving wheel 4 and the driving mechanism 3 are connected into a whole by the connecting plate 8, the body of the motor is fixed on one side of the connecting plate 8 far away from the driving wheel 4, the driven wheel 6 and the unidirectional driven wheel 5, and an output shaft of the motor passes through the connecting plate 8 and is coaxially connected with the driving wheel 4 on the other side of the connecting plate 8. The driving mechanism 3 drives the driving wheel 4 to rotate, the driving wheel 4 drives the unidirectional driven wheel 5 and the driven wheel 6 to rotate simultaneously through the transmission of a belt, the driven wheel 6 rotates around the screw rod 7 in a threaded manner, so that the connecting plate 8 is driven to linearly move, the connecting plate 8 carries the winding shaft 2 to linearly move, and meanwhile, the unidirectional driven wheel 5 slides along with the connecting plate 8 in one direction and simultaneously rotates to drive the winding shaft 2 to rotate, so that winding is realized.

In another embodiment, the driving mechanism 3 is a motor, an output shaft of the motor is fixedly connected with a driving gear 40 coaxially, the driving gear 40 is respectively connected with a unidirectional driven gear 50 and a driven gear 60 (a chain is not shown in the figure) in a transmission manner through a chain, the chain is respectively meshed with the driving gear 40, the unidirectional driven gear 50 and the driven gear 60, the unidirectional driven gear 50 is coaxially fixed on the winding shaft 2, the driven gear 60 is provided with internal threads, the driven gear 60 is coaxially connected with a screw rod 7, the screw rod 7 is fixedly connected with the bracket 1, the screw rod 7 is parallel to the winding shaft 2, two ends of the screw rod 7 are respectively fixedly connected with the first supporting plate 11 and the second supporting plate 12, a connecting plate 8 is fixedly connected with a machine body of the motor, the connecting plate 8 is positioned between the first supporting plate 11 and the second supporting plate 12, and the driving gear 40, the driven gear 60 and the unidirectional driven gear 50 are respectively rotationally connected with the connecting plate 8. As shown in fig. 1, the connecting plate 8 is parallel to the first supporting plate 11 and the second supporting plate 12, holes for the lead screw 7 and the winding shaft 2 to pass through are formed in the connecting plate 8, the lead screw 7 and the winding shaft 2 pass through the connecting plate 8, the winding shaft 2, the unidirectional driven gear 50, the driven gear 60, the driving gear 40 and the driving mechanism 3 are connected into a whole by the connecting plate 8, the body of the motor is fixed on one side of the connecting plate 8 far away from the driving gear 40, the driven gear 60 and the unidirectional driven gear 50, and an output shaft of the motor passes through the connecting plate 8 and is coaxially connected with the driving gear 40 on the other side of the connecting plate 8. The driving mechanism 3 drives the driving gear 40 to rotate, the driving gear 40 drives the unidirectional driven gear 50 and the driven gear 60 to rotate simultaneously through the transmission of a chain, the driven gear 60 rotates around the screw rod 7 in a threaded manner, so that the connecting plate 8 is driven to linearly move, the connecting plate 8 carries the winding shaft 2 to linearly move, and meanwhile, the unidirectional driven gear 50 rotates along with the connecting plate 8 in one direction to drive the winding shaft 2 to rotate simultaneously, so that winding is realized.

The driving wheel 4 and the driving gear 40 can be fixedly connected with the connecting plate 8 through a wheel frame, the wheel frame comprises two parallel wheel pressing plates, the two wheel pressing plates are fixed through a connecting shaft, the driving wheel or the driving gear is fixed between the two wheel pressing plates and is rotationally connected with the wheel pressing plates, an output shaft of the motor can penetrate through the two wheel pressing plates and is rotationally connected with the wheel pressing plates, and one wheel pressing plate is fixedly connected with the connecting plate 8.

In some embodiments, the automatic winding device for multi-strand core wires further comprises a guide shaft 9, the guide shaft 9 is fixedly connected with the support 1, the guide shaft 9 is parallel to the winding shaft 2 and the screw rod 7, guide holes are formed in the connecting plate 8 and sleeved on the guide shaft 9, two ends of the guide shaft 9 are fixedly connected with the first support plate 11 and the second support plate 12 respectively, the guide shaft 9 plays a role in guiding and supporting, and the connecting plate 8 drives the winding shaft 2, the motor and the like to slide along the guide shaft 9.

Preferably, the number of the guide shafts 9 is 2, 2 guide shafts 9 are arranged in parallel, a space is reserved between the 2 guide shafts 9, the supporting strength is improved, and the stability of the device is improved.

In some embodiments, as shown in fig. 5, the wire inlet button 10, the wire outlet button 20 and the speed regulating button 30 are embedded on the bracket 1, the wire inlet button 10, the wire outlet button 20 and the speed regulating button 30 are respectively electrically connected with the driving mechanism 3, the wire outlet button 20 can control the motor to rotate in one direction, such as forward rotation, so that the connecting plate 8 drives the motor and the winding shaft 2 to slide in a direction approaching to the first supporting plate 11, and the winding shaft 2 stops sliding when sliding to the vicinity of the first supporting plate 11 or contacting the first supporting plate 11, and the winding shaft 2 does not rotate in the process. The wire inlet button 10 controls the motor to rotate in the opposite direction, so that the connecting plate 8 is driven to drive the motor, the winding shaft 2 and the like to slide in the direction close to the second supporting plate 12, and the unidirectional driven wheel or the unidirectional driven gear drives the winding shaft to rotate while sliding, so that winding is performed, and rotary winding is realized while sliding. The speed adjusting knob 30 can control the rotation speed of the output shaft of the motor, further control the rotation speed and the sliding speed of the winding shaft 2, and control the density of the wire loops formed by winding the copper wire on the core wire.

The using method of the multi-strand core wire automatic winding device of the embodiment comprises the following steps:

Pulling the wire withdrawing button 20, driving the connecting plate 8 and the winding shaft 2, the motor and the like on the connecting plate 8 to slide towards the direction close to the first supporting plate 11 by the motor, and stopping sliding until the position close to the first supporting plate 11 or the end part of the winding shaft 2 contacts the first supporting plate 11, wherein the winding shaft 2 does not rotate in the process; the core wire is placed on the core wire placing plate 16 and clamped into the core wire clamping groove 161, the head end of the core wire passes through the wire passing hole 17 on the first supporting plate 11 and enters the core wire passing hole 22 on the winding shaft 2, the position of the head end of the core wire, which is penetrated out, is adjusted according to the position of a wire winding ring on the core wire, the wire passing hole 17 on the second supporting plate 12 and the wire passing hole 17 on the fourth supporting plate 14 can be penetrated out, or the head end of the core wire penetrates out of the wire passing hole 17 on the fourth supporting plate 14 for a certain distance, so that the core wire section needing to wind the wire ring is positioned between the first supporting plate and the second supporting plate, and the wire passing hole 17 of the second supporting plate 12 and the wire passing hole 17 of the fourth supporting plate 14 play a role of straightening down the core wire; penetrating a wire-wound copper wire from the wire passing hole 17 side of the fourth supporting plate 14, sequentially penetrating the wire passing hole 17 on the fourth supporting plate 14, the wire passing hole 17 on the second supporting plate 12 and the wire passing hole 21 on the winding shaft 2, penetrating out of the bracket 1 through the wire passing hole 17 on the first supporting plate 11, putting the head end of the wire-wound copper wire on a core wire on the core wire placing plate 16, and pressing or winding the head end of the wire-wound copper wire on the core wire; pulling the wire inlet knob 10, reversing the motor, sliding the connecting plate 8 and the winding shaft 2, the motor and the like on the connecting plate 8 towards the direction close to the second supporting plate 12, winding the copper wire to form a wire ring with a certain density on the core wire, and stopping winding when the end part of the winding shaft 2 slides to the vicinity of the second supporting plate 12 or contacts with the second supporting plate 12, or stopping winding at any time according to the length of the core wire section of the wire ring to be wound. Since the present application is aimed at winding the wound copper wire at a specified position on the core wire to form a wire loop, it is unnecessary to wind too many wound copper wires each time, i.e., the space between the first support plate 11 and the second support plate 12 is not excessively large, so that the actual winding requirement can be satisfied.

After winding is finished, the wire withdrawing button 20 can be pulled to enable the winding shaft 2 to slide towards the first supporting plate 11, the core wire section wound with the wire ring is pushed out of the support 1, then the core wire is manually pulled out of the support 1, the core wire wound with the wire ring is taken out, the winding copper wire is cut off, and winding is finished.

The speed adjusting knob 30 can be pulled to adjust the speed in the process of withdrawing and winding the wire, the sliding speed and the rotating speed of the winding shaft can be adjusted, the winding density of the wire loop is adjusted, and in order to ensure the uniform winding density each time, the speed is generally adjusted before the wire is wound.

The automatic winding device for the multi-strand core wires realizes the automation of winding, one worker can finish the winding operation, the labor is saved, the winding efficiency is high, and the working time is saved.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the description of the present specification, a description referring to the terms "present embodiment," "one embodiment," "some embodiments," "example," "specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any at least one embodiment or example. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

The above description is only of the preferred embodiments of the present utility model, and is not intended to limit the utility model, but any modifications, equivalents, and simple improvements made within the spirit of the present utility model should be included in the scope of the present utility model.

Claims (9)

1. An automatic winding device for a multi-strand core wire is characterized by comprising a bracket (1), a winding shaft (2) and a driving mechanism (3),

A winding wire passing hole (21) and a core wire passing hole (22) which penetrate through the winding shaft (2) are arranged on the winding shaft (2) along the axis, the core wire passing hole (22) is positioned on the central axis of the winding shaft (2), the winding wire passing hole (21) is positioned at the side part of the core wire passing hole (22),

The winding shaft (2) is connected with the bracket (1) in a unidirectional rotation way, the winding shaft (2) rotates around the central axis of the winding shaft, the winding shaft (2) is also connected with the bracket (1) in a reciprocating sliding way, the sliding direction of the winding shaft (2) is parallel to the axis of the winding shaft,

The driving mechanism (3) is fixed on the bracket (1), and the driving mechanism (3) drives the winding shaft (2) to slide reciprocally and drive the winding shaft (2) to slide in one direction while rotating unidirectionally and not rotating when sliding in the other direction.

2. The automatic multi-strand core wire winding device according to claim 1, wherein the driving mechanism (3) is a motor, an output shaft of the motor is coaxially and fixedly connected with a driving wheel (4), the driving wheel (4) is respectively connected with a unidirectional driven wheel (5) and a driven wheel (6) in a transmission manner through a belt, the unidirectional driven wheel (5) is coaxially fixed on the winding shaft (2), the driven wheel (6) is provided with an internal thread, the driven wheel (6) is coaxially and threadedly connected with a screw rod (7), the screw rod (7) is fixedly connected with the support (1), the screw rod (7) is parallel to the winding shaft (2), a connecting plate (8) is fixedly connected with a machine body of the motor, and the driving wheel (4), the driven wheel (6) and the unidirectional driven wheel (5) are respectively and rotatably connected with the connecting plate (8).

3. The automatic multi-strand core wire winding device according to claim 1, wherein the driving mechanism (3) is a motor, an output shaft of the motor is coaxially and fixedly connected with a driving gear (40), the driving gear (40) is respectively connected with a unidirectional driven gear (50) and a driven gear (60) in a transmission manner through a chain, the unidirectional driven gear (50) is coaxially fixed on the winding shaft (2), the driven gear (60) is provided with an internal thread, the driven gear (60) is coaxially and threadedly connected with a screw rod (7), the screw rod (7) is fixedly connected with the bracket (1), the screw rod (7) is parallel to the winding shaft (2), a connecting plate (8) is fixedly connected with a machine body of the motor, and the driving gear (40), the driven gear (60) and the unidirectional driven gear (50) are respectively and rotatably connected with the connecting plate (8).

4. The automatic multi-strand core wire winding device according to claim 2 or 3, further comprising a guide shaft (9), wherein the guide shaft (9) is fixedly connected with the bracket (1), the guide shaft (9) is parallel to the winding shaft (2) and the screw rod (7), a guide hole is formed in the connecting plate (8), and the guide hole is sleeved on the guide shaft (9).

5. The automatic winding device for a multi-strand core wire according to claim 4, wherein the number of the guide shafts (9) is 2, and 2 of the guide shafts (9) are arranged in parallel.

6. The multi-strand core wire automatic winding device according to claim 1, wherein the bracket (1) comprises a first supporting plate (11), a second supporting plate (12) and a third supporting plate (13) for connecting the first supporting plate (11) and the second supporting plate (12), the first supporting plate (11) and the second supporting plate (12) are arranged in parallel, the winding shaft (2) is perpendicular to the first supporting plate (11) and the second supporting plate (12) and is arranged between the first supporting plate (11) and the second supporting plate (12), and a wire passing hole (17) is formed in the position of the first supporting plate (11) and the second supporting plate (12) corresponding to the wire passing hole (21) and the core wire passing hole (22).

7. The automatic multi-strand core wire winding device according to claim 6, wherein the bracket (1) further comprises a core wire placing plate (16), the core wire placing plate (16) is vertically fixed on the first supporting plate (11), the core wire placing plate (16) is arranged on one side, far away from the second supporting plate (12), of the first supporting plate (11), and a core wire clamping groove (161) is formed in the core wire placing plate (16) corresponding to the wire passing hole (17).

8. The automatic multi-strand core wire winding device according to claim 6, wherein the bracket (1) further comprises a fourth supporting plate (14) and a protective cover (15), the fourth supporting plate (14) is parallel to the first supporting plate (11) and the second supporting plate (12) and is fixed on one side of the second supporting plate (12) away from the first supporting plate (11), and the protective cover (15) is covered above the first supporting plate (11), the second supporting plate (12), the third supporting plate (13) and the fourth supporting plate (14).

9. The automatic multi-strand core wire winding device according to claim 1, wherein the wire inlet button (10), the wire outlet button (20) and the speed adjusting button (30) are embedded on the bracket (1), and the wire inlet button (10), the wire outlet button (20) and the speed adjusting button (30) are respectively electrically connected with the driving mechanism (3).