CN215287787U - Automatic accuse line's motor-driven hank grinds - Google Patents

Abstract

The utility model discloses an automatic motor-driven hank of accuse line grinds, include: the device comprises a support, a grinding core, a driving mechanism, a wire outlet mechanism and a synchronous transmission mechanism; the grinding core is rotationally arranged on the support, the driving mechanism is arranged on the support, and the power output end of the driving mechanism is fixedly connected with the grinding core; the wire outlet mechanism comprises a first wire outlet control wheel and a second wire outlet control wheel which are oppositely and rotatably arranged on the support, the first wire outlet control wheel is provided with a first wire outlet control wheel groove, the second wire outlet control wheel is provided with a second wire outlet control wheel groove, and the first wire outlet control wheel groove and the second wire outlet control wheel groove are used for clamping a rope together; one end of the synchronous transmission mechanism is fixedly connected with the power output end of the driving mechanism, and the other end of the synchronous transmission mechanism is fixedly connected with the wire outlet mechanism so as to drive the first wire outlet control wheel and/or the second wire outlet control wheel to rotate. The technical problems that the investment of constructors is large, the labor intensity is large and potential safety hazards exist when the motor-driven winching machine with the automatic line control function is used are solved.

Description

Automatic accuse line's motor-driven hank grinds

Technical Field

The utility model relates to a technical field of power transmission and transformation circuit construction especially relates to an automatic motor-driven hank of accuse line grinds.

Background

The motorized winching machine capable of automatically controlling the wire is a general machine tool for hauling hoisting equipment of overhead transmission lines, power cable lines and communication lines, assembling towers, towing and paying off, tightening the wire and installing and constructing accessories.

The automatic wire control motor-driven winching machine is used for winding ropes with enough turns on a grinding core, tensioning the ropes through load and manpower to generate friction force between the ropes and the grinding core, and enabling the grinding core to rotate through mechanical transmission, so that the traction and releasing functions of the ropes are driven to meet the construction requirements.

In the prior art, a plurality of persons are generally required to pull the rope at the same time, so that the problems of more investment of constructors and higher labor intensity of the constructors can be caused; on the other hand, the problem of potential safety hazard caused by manually dragging the rope can occur.

SUMMERY OF THE UTILITY MODEL

Therefore, in order to solve the above problems, it is necessary to provide a motorized winch capable of automatically controlling a wire, so as to solve the technical problems of the prior art that the investment of constructors is large, the labor intensity is high, and potential safety hazards exist when the motorized winch capable of automatically controlling the wire is used.

To this end, in one embodiment there is provided a motorized winching with automatic wire control comprising: the device comprises a support, a grinding core, a driving mechanism, a wire outlet mechanism and a synchronous transmission mechanism;

the grinding core is rotatably arranged on the support, the driving mechanism is arranged on the support, and the power output end of the driving mechanism is fixedly connected with the grinding core; the wire outlet mechanism is positioned on one side of the grinding core and comprises a first wire outlet control wheel and a second wire outlet control wheel which are oppositely and rotatably arranged on the support, the first wire outlet control wheel is provided with a first wire outlet control wheel groove, the second wire outlet control wheel is provided with a second wire outlet control wheel groove, and the first wire outlet control wheel groove and the second wire outlet control wheel groove are used for clamping a rope together; one end of the synchronous transmission mechanism is fixedly connected with the power output end of the driving mechanism, and the other end of the synchronous transmission mechanism is fixedly connected with the wire outlet mechanism so as to drive the first wire outlet control wheel and/or the second wire outlet control wheel to rotate.

In some embodiments of the motorized winching device for automatically controlling the wire, the wire outlet mechanism further comprises a first support shaft and a second support shaft which are rotatably arranged on the support; the first wire outlet control wheel is fixedly connected with the first support shaft, and the second wire outlet control wheel is fixedly connected with the second support shaft; wherein, synchronous drive mechanism with first supporting shaft fixed connection.

In some embodiments of the motorized winching device for automatically controlling the wire, the wire outlet mechanism further comprises a first gear fixed to the first support shaft and a second gear fixed to the second support shaft, and the first gear is engaged with the second gear.

In some embodiments of the motorized winching device for automatically controlling wires, the synchronous transmission mechanism includes a first belt wheel, a second belt wheel and a transmission belt, the first belt wheel is fixedly connected with the power output end of the driving mechanism, the second belt wheel is fixedly connected with the first supporting shaft, one end of the transmission belt is sleeved on the first belt wheel, and the other end of the transmission belt is sleeved on the second belt wheel.

In some embodiments of the motorized winching device for automatically controlling the wire, the synchronous transmission mechanism includes a third gear, a fourth gear and a transmission chain, the third gear is fixedly connected with the power output end of the driving mechanism, the fourth gear is fixedly connected with the first supporting shaft, one end of the transmission chain is meshed with the third gear, and the other end of the transmission chain is meshed with the fourth gear.

In some embodiments of the motorized winching of the automatic wire control, the motorized winching of the automatic wire control further comprises a wire pressing safety mechanism arranged between the grinding core and the wire outlet mechanism;

the line pressing safety mechanism comprises a first line pressing block fixed on the support, a second line pressing block movably pressed on the first line pressing block, and a locking structure used for limiting and releasing the second line pressing block; the first wire pressing block is provided with a first wire pressing port, and the second wire pressing block is provided with a second wire pressing port used for forming a wire pressing hole together with the first wire pressing port; the locking structure has a locking state and an unlocking state, and in the locking state, the locking structure limits the movement of the second wire pressing block; and when the locking structure is in an unlocking state, the locking structure releases the second wire pressing block.

In some embodiments of the motorized winching of automatic wire control, one end of the second wire pressing block is rotatably connected with one end of the first wire pressing block; the locking structure is arranged between the other end of the second wire pressing block and the other end of the first wire pressing block.

In some embodiments of the motorized winching for automatically controlling the wire, the locking structure comprises a connecting shaft and a locking block, one end of the connecting shaft is rotatably connected with the first wire pressing block, the other end of the connecting shaft is provided with a threaded section, and the locking block is in threaded connection with the threaded section;

the second line ball piece is provided with a first avoidance opening used for avoiding the connecting shaft, the connecting shaft can rotate to the first avoidance opening so that the locking block is located on one side, far away from the first line ball piece, of the second line ball piece, and the locking block is used for abutting against the second line ball piece.

In some embodiments of the motorized winching machine with automatic wire control, the diameter of the wire pressing hole is gradually reduced in the direction of the wire outlet mechanism of the grinding core.

In some embodiments of the motorized winching device for automatically controlling the wire, the groove wall surface of the first wire control sheave groove is provided with an anti-slip structure, and/or the groove wall surface of the second wire control sheave groove is provided with an anti-slip structure.

Adopt the embodiment of the utility model provides a, following beneficial effect has:

in the utility model, a rope with enough turns is wound on the grinding core, one end of the rope is led out from the grinding core and connected with a load, and the other end of the rope is led out from the grinding core and clamped by a first outgoing line control wheel groove of the first outgoing line control wheel and a second outgoing line control wheel groove of the second outgoing line control wheel together; the driving mechanism drives the grinding core to start rotating, and at the moment, relative to the load, the grinding core starts to take up wires; relative to the wire outlet mechanism, the grinding core starts to be out of the wire; the first outgoing line control wheel and/or the second outgoing line control wheel of the outgoing line mechanism start to synchronously rotate along with the grinding core under the action of the synchronous transmission mechanism; the rope clamped between the first wire outlet control wheel groove and the second wire outlet control wheel groove continuously moves to be outlet under the synchronous rotation action of the first wire outlet control wheel, the second wire outlet control wheel and the grinding core. By the technical scheme, the technical problems that in the prior art, the investment of constructors is large, the labor intensity is high and potential safety hazards exist when the motorized winching machine for automatically controlling the wire is used are solved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Wherein:

fig. 1 is a schematic diagram illustrating an overall structure of a motorized winching machine with an automatic wire control according to the present invention;

FIG. 2 illustrates a partial schematic view of a motorized winching apparatus with automatic wire control according to the present invention;

FIG. 3 is a schematic diagram of the structure of the line clip safety mechanism;

fig. 4 is an exploded view of the wire pressing safety mechanism.

Description of the main element symbols:

100. automatic wire control motor-driven winching; 10. a support; 20. grinding the core; 30. a drive mechanism; 41. a first outgoing line control wheel; 411. the first outgoing line controls the wheel groove; 42. a second outgoing line control wheel; 421. the second outgoing line controls the wheel groove; 43. a first support shaft; 44. a second support shaft; 45. an elastic member; 46. a drive plate; 461. a connecting portion; 462. a drive section; 47. positioning the shaft; 48. positioning a plate; 51. a first pulley; 52. a second pulley; 53. a transmission belt; 60. a line pressing safety mechanism; 60a, a wire pressing hole; 61. a first wire pressing block; 611. a first wire pressing port; 612. hole turning; 613. a second avoidance port; 62. a second wire pressing block; 621. a second wire pressing port; 622. connecting blocks; 623. a first avoidance port; 63. a locking structure; 631. a connecting shaft; 632. a locking block; 64. a rotating shaft; 70. a shield.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. The 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.

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

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1-2, in an embodiment of the present invention, a motorized winching 100 for automatically controlling a wire is provided, and the motorized winching 100 for automatically controlling a wire includes a support 10, a grinding core 20, a driving mechanism 30, a wire outlet mechanism, and a synchronous transmission mechanism.

Wherein, the grinding core 20 is rotatably arranged on the support 10, the driving mechanism 30 is arranged on the support 10, and the power output end of the driving mechanism 30 is fixedly connected with the grinding core 20; the wire outlet mechanism is positioned at one side of the grinding core 20 and comprises a first wire outlet control wheel 41 and a second wire outlet control wheel 42 which are oppositely and rotatably arranged on the support 10, the first wire outlet control wheel 41 is provided with a first wire outlet control wheel groove 411, the second wire outlet control wheel 42 is provided with a second wire outlet control wheel groove 421, and the first wire outlet control wheel groove 411 and the second wire outlet control wheel groove 421 are used for clamping a rope together; one end of the synchronous transmission mechanism is fixedly connected with the grinding core 20, and the other end of the synchronous transmission mechanism is fixedly connected with the wire outlet mechanism so as to drive the first wire outlet control wheel 41 and/or the second wire outlet control wheel 42 to rotate.

In the utility model, a rope is wound on the grinding core 20, one end of the rope is led out from the grinding core 20 and connected with a load, and the other end of the rope is led out from the grinding core 20 and clamped by a first outgoing line control wheel groove 411 of the first outgoing line control wheel 41 and a second outgoing line control wheel groove 421 of the second outgoing line control wheel 42; the driving mechanism 30 drives the grinding core 20 to start rotating, and at the moment, relative to the load, the grinding core 20 starts to take up the wire; relative to the wire outlet mechanism, the grinding core 20 starts to be out of the wire; the first outgoing line control wheel 41 and/or the second outgoing line control wheel 42 of the outgoing line mechanism start to synchronously rotate along with the grinding core 20 under the action of the synchronous transmission mechanism; the rope clamped between the first outlet control wheel slot 411 and the second outlet control wheel slot 421 continuously moves to be outlet under the synchronous rotation action of the first outlet control wheel 41, the second outlet control wheel 42 and the grinding core 20. By the aid of the technical scheme, the technical problems that in the prior art, the investment of constructors is large, labor intensity is high and potential safety hazards exist when the motorized winch 100 for automatically controlling wires is used are solved.

In some specific implementations, the groove wall surface of the first outlet control wheel groove 411 is provided with an anti-slip structure to increase the friction between the first outlet control wheel 41 and the rope; and/or, a groove wall surface of the second outlet control wheel groove 421 is provided with an anti-slip structure to increase a frictional force between the second outlet control wheel 42 and the rope. The clamping force of the first and second wire controlling groove 411 and 421 to the rope is increased by adding a non-slip structure, wherein the non-slip structure can be configured as, but not limited to, an embossing or a friction pad.

In some embodiments, the first slot 411 and the second slot 421 are arcuate to provide a compliant grip on the cord.

In some embodiments, a bearing may be provided between the holder 10 and the grinding core 20 to reduce the friction between them and ensure smooth and stable rotation of the grinding core 20 relative to the holder 10.

When the driving mechanism 30 drives the grinding core 20 to rotate, the first outgoing line control wheel 41 can be driven to rotate through the synchronous transmission mechanism, and the second outgoing line control wheel 42 rotates along with the first outgoing line control wheel through the friction action of the rope; or, the second outgoing line control wheel 42 is driven to rotate through the synchronous transmission mechanism, and the first outgoing line control wheel 41 rotates along with the first outgoing line control wheel through the friction action of the rope; or, the first outgoing line control wheel 41 and the second outgoing line control wheel 42 are driven to rotate simultaneously through a synchronous transmission mechanism.

In one embodiment, the outlet mechanism further comprises a first support shaft 43 and a second support shaft 44 rotatably disposed on the support 10; the first outgoing control wheel 41 is fixedly connected with a first support shaft 43, and the second outgoing control wheel 42 is fixedly connected with a second support shaft 44; wherein the synchronous transmission mechanism is fixedly connected with the first support shaft 43. In the present embodiment, the synchronous transmission mechanism transmits the power of the driving mechanism 30 to the first outlet control wheel 41, so that the first outlet control wheel 41 rotates synchronously with the grinding core 20, and the second outlet control wheel 42 rotates synchronously with the first outlet control wheel 41 through the friction force between the rope and the second outlet control wheel 42.

In some embodiments, a bearing may be disposed between the support 10 and the first support shaft 43 to reduce friction between the two, so as to ensure that the first support shaft 43 can smoothly and stably rotate relative to the support 10.

In some embodiments, a bearing may be disposed between the second support shaft 44 and the grinding core 20 to reduce friction therebetween, so as to ensure smooth and stable rotation of the second support shaft 44 relative to the holder 10.

In one embodiment, the outlet mechanism further includes a first gear fixed to the first support shaft 43 and a second gear fixed to the second support shaft 44, and the first gear is engaged with the second gear. When the synchronous transmission mechanism drives the first outgoing line control wheel 41 to rotate through the first support shaft 43, the first gear fixed with the first support shaft 43 rotates along with the first support shaft, and the second support shaft 44 is further driven to rotate in the opposite direction relative to the first support shaft 43 through the meshing action of the first gear and the second gear, so that the second outgoing line control wheel 42 fixed on the second support shaft 44 rotates in the opposite direction relative to the first outgoing line control wheel 41; the first outgoing control wheel 41 and the second outgoing control wheel 42 which rotate in opposite directions jointly drive the rope to move, and outgoing driving force on the rope is improved.

In some specific embodiments, the synchronous transmission mechanism includes a first pulley 51, a second pulley 52 and a transmission belt 53, the first pulley 51 is fixedly connected to the power output end of the driving mechanism 30, the second pulley 52 is fixedly connected to the first supporting shaft 43, one end of the transmission belt 53 is sleeved on the first pulley 51, and the other end of the transmission belt 53 is sleeved on the second pulley 52. In the present embodiment, the driving mechanism 30 drives the first outlet control wheel 41 to rotate through the transmission action of the first pulley 51, the transmission belt 53 and the second pulley 52, so that the first outlet control wheel 41 rotates synchronously with the grinding core 20.

In other specific embodiments, the synchronous transmission mechanism includes a third gear fixedly connected to the power output end of the driving mechanism 30, a fourth gear fixedly connected to the first supporting shaft 43, and a transmission chain having one end engaged with the third gear and the other end engaged with the fourth gear. In the present embodiment, the driving mechanism 30 drives the first outlet control wheel 41 to rotate through the transmission action of the first gear, the transmission chain and the fourth gear, so that the first outlet control wheel 41 rotates synchronously with the grinding core 20.

If the radius of the grinding core 20 is R1, the radius of the first outgoing line control wheel 41 is R2, the radius of the first belt wheel 51/third gear is R3, and the radius of the second belt wheel 52/fourth gear is R4, then R1/R3 is R2/R4; to ensure that the grinding core 20 can continuously and stably output.

Referring to fig. 3 and 4, in one embodiment, the motorized grinder with automatic wire control 100 further includes a wire pressing safety mechanism 60 disposed between the grinding core 20 and the wire outlet mechanism; the line pressing safety mechanism 60 comprises a first line pressing block 61 fixed on the support 10, a second line pressing block 62 movably pressed on the first line pressing block 61, and a locking structure 63 for limiting and releasing the second line pressing block 62; the first wire pressing block 61 has a first wire pressing port 611, and the second wire pressing block 62 has a second wire pressing port 621 for forming a wire pressing hole 60a with the first wire pressing port 611; the locking structure 63 has a locking state and an unlocking state, and in the locking state, the locking structure 63 limits the movement of the second wire pressing block 62; in the unlocked state, the locking mechanism 63 releases the second crimping block 62.

In this embodiment, the line pressing safety mechanism 60 is located on one side of the grinding core 20 far away from the load, that is, the line pressing safety mechanism 60 and the line outgoing mechanism are located on the same side of the grinding core 20, and the line pressing safety mechanism 60 compresses the rope to limit the tension of the rope, so that the tension of the rope is increased together with the line outgoing mechanism, and the rope is prevented from being stressed and balanced at two ends under the load. When the automatic wire outgoing of the rope is realized through the rotation of the first wire outgoing control wheel 41 and the second wire outgoing control wheel 42, the locking structure 63 is switched from a locking state to an unlocking state, the second wire pressing block 62 can move relative to the first wire pressing block 61 to open the wire pressing hole 60a, and the rope is arranged in the first wire pressing opening 611 of the first wire pressing block 61 in a penetrating manner; when the first outgoing line control wheel 41 and the second outgoing line control wheel 42 stop rotating, that is, the rope stops outgoing, the unlocking state of the locking structure 63 is switched to the locking state, so that the second line pressing block 62 is fastened and pressed on the first line pressing block 61, at this time, the second line pressing port 621 of the second line pressing block 62 and the first line pressing port 611 of the first line pressing block 61 form a line pressing hole 60a, and the line pressing hole 60a presses the circumference of the rope for limitation, so as to ensure the pulling force on the rope.

It should be noted that the rope may be pressed by other power devices such as a manual cam pressing device or a hydraulic device.

In some specific embodiments, the diameter of the line pressing hole 60a is gradually reduced in the direction of the grinding core 20 towards the line outlet mechanism, so as to improve the pressing limit effect of the line pressing hole 60a on the rope.

In one embodiment, one end of the second press block 62 is rotatably connected to one end of the first press block 61; the locking structure 63 is provided between the other end of the second press block 62 and the other end of the first press block 61. That is, the rotation of the second wire pressing block 62 relative to the first wire pressing block 61 can be realized by switching the locking state of the locking structure 63 to the unlocking state.

In some specific implementations, one end of the first wire pressing block 61 has a rotation hole 612; the wire pressing safety mechanism 60 further includes a rotating shaft 64 rotatably disposed in the rotating hole 612, and the rotating shaft 64 is fixedly connected to one end of the second wire pressing block 62. Thereby achieving a rotational connection of the first and second wire holding blocks 61 and 62.

In addition, one end of the first wire pressing block 61 is opened with a second avoiding opening 613, the second wire pressing block 62 extends towards the second avoiding opening 613 to form a connecting block 622, and the connecting block 622 is accommodated in the second avoiding opening 613 and is fixedly connected with the rotating shaft 64.

In one embodiment, the locking structure 63 includes a connecting shaft 631 and a locking block 632, one end of the connecting shaft 631 is rotatably connected to the first wire pressing block 61, the other end of the connecting shaft 631 is provided with a threaded section, and the locking block 632 is threadedly connected to the threaded section; the second wire pressing block 62 is provided with a first avoiding opening 623 for avoiding the connecting shaft 631, the connecting shaft 631 can rotate into the first avoiding opening 623 so that the locking block 632 is located on one side of the second wire pressing block 62, which is far away from the first wire pressing block 61, and the locking block 632 is used for abutting against the second wire pressing block 62.

In this embodiment, when the connecting shaft 631 rotates into the first avoiding opening 623, the locking block 632 abuts against the first pressing block 61 by increasing the amount of the thread connection with the thread section, and at this time, the locking structure 63 is in a locking state, that is, the second pressing block 62 is tightly pressed on the first pressing block 61; when the locking block 632 reduces the connection amount of the thread with the thread section, the locking block 632 is spaced from the second thread pressing block 62, so that the connecting shaft 631 can rotate away from the first avoiding opening 623 to drive the locking block 632 to move away from the second thread pressing block 62; at this time, the locking structure 63 is in an unlocked state, i.e., the second press block 62 may be away from the first press block 61.

In an embodiment, the wire outgoing mechanism further includes an elastic member 45, a driving plate 46, a positioning shaft 47 and a positioning plate 48, the driving plate 46 is divided into a connecting portion 461 and a driving portion 462 along the wire outgoing direction, two elastic members 45 are provided, the two elastic members 45 are arranged at an interval, one end of each elastic member 45 is fixed on the support 10, the other end of each elastic member 45 is fixedly connected with the connecting portion 461, the second supporting shaft 44 is rotatably connected to the connecting portion 461, and the driving portion 462 is used for driving the connecting portion 461 to move up and down, so that the second wire pressing wheel is driven to move away from and close to the first wire pressing wheel relatively through the deformation capability and the restoring capability of the elastic members 45. The positioning shaft 47 is rotatably disposed on the support 10, one end of the positioning plate 48 is fixedly connected to the positioning shaft 47, and the other end of the positioning plate 48 is fixedly connected to the connecting portion 461 to limit the deformation direction of the elastic member 45.

In some embodiments, the driving mechanism 30 includes a mounting housing fixed on the support 10 and a driving motor accommodated in the mounting housing, and a power output end of the driving motor penetrates through the mounting housing and is fixedly connected with the grinding core 20.

In some embodiments, the motorized winching 100 for automatic wire control further comprises a guard 70 for the synchronous drive mechanism of the guard 70.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above examples are merely illustrative of several embodiments of the present invention, which are described in more detail and detail, but are not to be construed as limiting the scope of the claims. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The utility model provides an automatic motor-driven hank of accuse line grinds which characterized in that includes: the device comprises a support, a grinding core, a driving mechanism, a wire outlet mechanism and a synchronous transmission mechanism;

the grinding core is rotatably arranged on the support, the driving mechanism is arranged on the support, and the power output end of the driving mechanism is fixedly connected with the grinding core; the wire outlet mechanism is positioned on one side of the grinding core and comprises a first wire outlet control wheel and a second wire outlet control wheel which are oppositely and rotatably arranged on the support, the first wire outlet control wheel is provided with a first wire outlet control wheel groove, the second wire outlet control wheel is provided with a second wire outlet control wheel groove, and the first wire outlet control wheel groove and the second wire outlet control wheel groove are used for clamping a rope together; one end of the synchronous transmission mechanism is fixedly connected with the power output end of the driving mechanism, and the other end of the synchronous transmission mechanism is fixedly connected with the wire outlet mechanism so as to drive the first wire outlet control wheel and/or the second wire outlet control wheel to rotate.

2. The motorized winching device with automatic wire control according to claim 1, wherein the wire outlet mechanism further comprises a first support shaft and a second support shaft rotatably disposed on the support; the first wire outlet control wheel is fixedly connected with the first support shaft, and the second wire outlet control wheel is fixedly connected with the second support shaft; wherein, synchronous drive mechanism with first supporting shaft fixed connection.

3. The motorized winching of claim 2, wherein the pay-off mechanism further comprises a first gear affixed to the first support shaft and a second gear affixed to the second support shaft, the first gear being in mesh with the second gear.

4. The motorized winching device capable of automatically controlling wires according to claim 2, wherein the synchronous transmission mechanism comprises a first belt wheel, a second belt wheel and a transmission belt, the first belt wheel is fixedly connected with the power output end of the driving mechanism, the second belt wheel is fixedly connected with the first supporting shaft, one end of the transmission belt is sleeved on the first belt wheel, and the other end of the transmission belt is sleeved on the second belt wheel.

5. The motorized winching device capable of automatically controlling wires according to claim 2, wherein the synchronous transmission mechanism comprises a third gear, a fourth gear and a transmission chain, the third gear is fixedly connected with the power output end of the driving mechanism, the fourth gear is fixedly connected with the first supporting shaft, one end of the transmission chain is meshed with the third gear, and the other end of the transmission chain is meshed with the fourth gear.

6. The motorized winching of an automatic wire control system according to claim 1, further comprising a wire pressing safety mechanism disposed between the sharpening core and the wire outlet mechanism;

the line pressing safety mechanism comprises a first line pressing block fixed on the support, a second line pressing block movably pressed on the first line pressing block, and a locking structure used for limiting and releasing the second line pressing block; the first wire pressing block is provided with a first wire pressing port, and the second wire pressing block is provided with a second wire pressing port used for forming a wire pressing hole together with the first wire pressing port; the locking structure has a locking state and an unlocking state, and in the locking state, the locking structure limits the movement of the second wire pressing block; and when the locking structure is in an unlocking state, the locking structure releases the second wire pressing block.

7. The motorized winching of claim 6, wherein one end of said second wire pressing block is rotatably connected to one end of said first wire pressing block; the locking structure is arranged between the other end of the second wire pressing block and the other end of the first wire pressing block.

8. The motorized winching device capable of automatically controlling the line according to claim 6 or 7, wherein the locking structure comprises a connecting shaft and a locking block, one end of the connecting shaft is rotatably connected with the first line pressing block, the other end of the connecting shaft is provided with a threaded section, and the locking block is in threaded connection with the threaded section;

the second line ball piece is provided with a first avoidance opening used for avoiding the connecting shaft, the connecting shaft can rotate to the first avoidance opening so that the locking block is located on one side, far away from the first line ball piece, of the second line ball piece, and the locking block is used for abutting against the second line ball piece.

9. The motorized winching device capable of automatically controlling wires according to claim 6, wherein the diameter of the wire pressing hole is gradually reduced in a direction of the wire outlet mechanism of the grinding core.

10. The motorized grinder with automatic wire control according to claim 1, wherein the groove wall surface of the first wire control wheel groove is provided with an anti-slip structure, and/or the groove wall surface of the second wire control wheel groove is provided with an anti-slip structure.

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