CN117856554B - Coil winding forming equipment for variable frequency motor stator production - Google Patents

Abstract

The invention relates to the technical field of motor production and manufacturing, and discloses coil winding forming equipment for variable frequency motor stator production, which comprises a total mounting plate and a stator mounting plate, wherein the stator mounting plate is rotationally connected to the upper end of the total mounting plate, a fixed clamping groove is formed in the stator mounting plate along the radial direction of the stator mounting plate, a stator clamping assembly is arranged at the upper end of the stator mounting plate, a winding device is further arranged on the total mounting plate, a synchronous mounting groove is formed in the middle position of the stator mounting plate, and a synchronous mechanism is arranged in the synchronous mounting groove, so that coils can be wound on an inner stator or an outer stator and simultaneously stators with different sizes can be fixed.

Description

Coil winding forming equipment for variable frequency motor stator production

Technical Field

The invention relates to the field of motor production and manufacturing, in particular to coil winding forming equipment for variable frequency motor stator production.

Background

In the production and manufacture of the motor, the conventional motor generally uses permanent magnets as the stator, and along with the development of motor technology, the permanent magnets are found to have better power generation efficiency and higher controllability as the rotor, and in the production of the motor, the stator carrying a large number of annular enameled wires is divided into an inner stator and an outer stator.

The enameled wire in the inner stator is wound on the outer side of the sleeve group formed by the silicon steel sheets, the enameled wire in the outer stator is wound on the inner side of the sleeve group formed by the silicon steel sheets, the traditional coil winding equipment for motor stator production can only wind the inner stator or the outer stator singly, and meanwhile, the traditional coil winding arrangement can only fix the inner stator or the outer stator with the same size, so that the coil winding equipment has no good applicability.

Therefore, it is necessary to provide a coil winding forming device for stator production of variable frequency motor to solve the above technical problems.

Disclosure of Invention

The invention provides coil winding forming equipment for variable frequency motor stator production, which can not only wind coils on an inner stator or an outer stator, but also fix stators with different sizes.

The invention provides coil winding forming equipment for variable frequency motor stator production, which comprises a total plate;

The stator fixing plate is rotationally connected to the upper end of the assembly plate, a plurality of fixing clamping grooves are formed in the stator fixing plate along the radial direction of the stator fixing plate, and the fixing clamping grooves are uniformly distributed along the circumferential direction of the stator fixing plate;

The fixed screw rod is rotationally connected with the stator fixing plate and is erected in the middle of the fixed clamping groove, the fixed screw rod penetrates through the stator fixing plate to be fixedly connected with a rotary button, and the fixed clamping groove is slidably connected with a fixed sliding block;

The stator clamping assembly is arranged at the upper end of the stator fixing plate and fixed by bolts through a plurality of fixing sliding blocks, and the winding device is further arranged on the assembly plate.

Preferably, the middle position of the stator fixing plate is provided with a synchronous setting groove, a synchronous mechanism is arranged in the synchronous setting groove, the synchronous mechanism comprises a bevel gear A and a bevel gear B, the bevel gear A is rotationally connected to the middle position of the synchronous setting groove, the edge of the upper end of the bevel gear A is meshed with the bevel gear B, and a plurality of bevel gears are circumferentially distributed and in threaded connection with the fixing screw.

Preferably, the stator clamping assembly comprises a stator clamping cylinder, the stator clamping cylinder is fixedly connected with the fixed sliding block through a bolt, the middle position of the stator clamping cylinder is hollow with an open upper end, an annular supporting plate is fixedly connected above the inner bottom end of the stator clamping cylinder, and first clamping mechanisms are arranged on the left side and the right side of the inner wall of the stator clamping cylinder.

Preferably, the first clamping mechanism comprises an arc-surface clamping plate, a pressing plate a, a tightening plate a and a tightening screw a, wherein an arc-surface placing groove a is formed in the inner side of the stator clamping cylinder, a tightening groove a is formed in the corresponding arc-surface placing groove a, the arc-surface clamping plate is placed in the arc-surface placing groove a, one end, far away from the central shaft of the stator clamping cylinder, of the arc-surface clamping plate is fixedly connected with the pressing plate a, the pressing plate a is in sliding connection with the tightening groove a along the radial direction of the stator clamping cylinder, the tightening plate a is in contact with the pressing plate a, the surfaces in contact with each other are in sliding connection with each other, the surfaces in contact with each other are inclined, and the tightening screw a is connected to the stator clamping cylinder in threaded connection with the tightening plate a in a vertical reverse rotation mode.

Preferably, the inner side of the cambered surface clamping plate is provided with a rubber layer.

Preferably, the stator clamping assembly comprises a stator fixed column, the stator fixed column pass through the bolt with fixed slider fixed connection, the left and right sides of stator fixed column is provided with second clamping mechanism, second clamping mechanism includes cambered surface top tight board, pressure strip b, top tight board b and top tight screw rod b, cambered surface standing groove b has been seted up to the left and right sides of stator fixed column, top tight groove b has been seted up to stator fixed column correspondence cambered surface standing groove b, the cambered surface top tight board has been put in the cambered surface standing groove b, one side fixedly connected with pressure strip b that the cambered surface top tight board is close to the stator fixed column center pin, the terminal surface sliding connection that pressure strip b is close to the stator fixed column center pin has top tight board b, just pressure strip b with top tight board b contact's one side is the slope, the stator fixed column is corresponding top tight groove b rotates and is connected with top tight screw rod b, just top tight screw rod b with top tight board b threaded connection.

Preferably, the outer side of the cambered surface jacking plate is provided with a rubber layer.

Preferably, the assembly plate is provided with winding device on the right side that is located the stator fixed plate, winding device includes longitudinal movement board, lateral movement board, vertical movement board, steering column and wire winding pole, the assembly plate is located the position on the right side of stator fixed plate and is followed fore-and-aft direction sliding connection and has longitudinal movement board, sliding connection has lateral movement board about the upper end of longitudinal movement board, lateral movement board is followed vertical direction sliding connection and is had vertical movement board, rotate on the vertical movement board and be connected with the steering column, the lower extreme fixedly connected with wire winding pole of the horizontal segment of steering column, the left and right sides of the lower extreme of wire winding pole is fixedly connected with wire winding gyro wheel and wire winding head respectively.

Preferably, the winding rod is divided into a fixed rod and a rotating rod, the fixed rod is fixedly connected with the lower end of the horizontal section of the steering rod, the rotating rod is rotatably connected with the lower end of the fixed rod, a locking mechanism is arranged between the fixed rod and the rotating rod and comprises a locking rod and a locking spring, two locking grooves with 180-degree intervals are formed in the outer side of the fixed rod along the vertical direction, a positioning groove is formed in the rotating rod corresponding to the locking groove, the locking rod is connected with the positioning groove in a sliding mode, the locking rod is fixedly connected with the bottom end of the positioning groove, and the locking rod is inserted into the locking groove.

The invention has the beneficial effects that:

(1) The fixed screw rod is rotated to enable the fixed sliding block to slide in the fixed clamping groove until the fixed sliding block is contacted with the fixed bolt of the stator clamping assembly, the stator clamping assembly is fixed with the fixed sliding block through the bolt, after the stator clamping assembly is fixed, the coil is wound on the stator through the winding device, in the process of rotating the fixed screw rod, all the fixed screw rods are simultaneously rotated through the mutual linkage of the bevel gear A and the bevel gear B, and therefore the position of the fixed sliding block is synchronously adjusted, and therefore the stator can be clamped by the stator clamping assembly according to the type and the size of the stator.

(2) Through setting the inboard of cambered surface grip block and the outside of with cambered surface top tight board as the rubber layer, can increase the steadiness when the centre gripping stator.

(3) The winding rod is divided into the fixed rod and the rotating rod, so that the rotating rod can rotate 180 degrees, deflection in the direction of a winding head is realized, and the winding rod is suitable for winding enameled wires of an outer stator and an inner stator.

Drawings

The invention will be further described with reference to the drawings and examples.

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

FIG. 2 is an enlarged schematic view of the structure A in FIG. 1 according to the present invention;

FIG. 3 is an enlarged schematic view of the structure of FIG. 1B according to the present invention;

FIG. 4 is a schematic illustration of a cut-away configuration of a stator clamping cylinder in accordance with the present invention;

FIG. 5 is a schematic view showing the internal structure of a stator mounting plate according to the present invention;

Fig. 6 is a schematic sectional view of a stator fixing post according to the present invention.

In the figure: 1. a total plate; 2. a stator fixing plate; 21. a fixed clamping groove; 22. a fixed screw; 23. a rotary knob; 24. a fixed slide block; 25. a synchronous placement groove; 3. a stator clamping assembly; 31. a stator clamping cylinder; 311. a support plate; 312. a cambered surface placing groove a; 313. a groove a is tightly propped; 32. a first clamping mechanism; 321. a cambered surface clamping plate; 322. a compacting plate a; 323. a pressing plate a; 324. tightly pushing the screw a; 33. a stator fixing column; 331. a cambered surface placing groove b; 332. a tightening groove b; 34. a second clamping mechanism; 341. the cambered surface is tightly propped against the plate; 342. a compacting plate b; 343. a pressing plate b; 344. tightly pushing the screw b; 4. a winding device; 41. a longitudinally moving plate; 42. a lateral moving plate; 43. a vertical moving plate; 44. a steering lever; 45. a winding rod; 451. a fixed rod; 4511. a locking groove; 452. a rotating lever; 4521. a positioning groove; 453. a locking mechanism; 4531. a lock lever; 4532. a lock direction spring; 46. a winding roller; 47. a wire winding head; 5. a synchronizing mechanism; 51. bevel gears A; 52. bevel gear B.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1 and 5, the invention provides a coil winding forming device for the production of a variable frequency motor stator, which comprises a total plate 1;

The stator fixing plate 2 is rotationally connected to the upper end of the assembly plate 1, the stator fixing plate 2 is provided with fixed clamping grooves 21 along the radial direction of the stator fixing plate 2, and a plurality of fixed clamping grooves 21 are uniformly distributed along the circumferential direction of the stator fixing plate 2;

the fixed screw rod 22 is rotatably connected with the stator fixed plate 2 and is erected in the middle of the fixed clamping groove 21, the fixed screw rod 22 penetrates through the stator fixed plate 2 to be fixedly connected with a rotary button 23, and the fixed clamping groove 21 is slidably connected with a fixed sliding block 24;

The stator clamping assembly 3, the stator clamping assembly 3 is arranged at the upper end of the stator fixing plate 2, the stator clamping assembly 3 is fixed by bolts through a plurality of fixing sliding blocks 24, and the winding device 4 is further arranged on the assembly plate 1.

As shown in fig. 5, a synchronous positioning groove 25 is formed in the middle position of the stator fixing plate 2, a synchronous mechanism 5 is arranged in the synchronous positioning groove 25, the synchronous mechanism 5 comprises a bevel gear a51 and a bevel gear B52, the bevel gear a51 is rotationally connected to the middle position of the synchronous positioning groove 25, the bevel gear B52 is meshed with the edge of the upper end of the bevel gear a51, and a plurality of bevel gears B52 are circumferentially distributed and in threaded connection with the fixing screw 22.

It should be noted that, fix the stator through stator clamping assembly 3 to fix stator clamping assembly 3 through fixed slider 24 and bolt, in this process, make fixed slider 24 slide in fixed clamping groove 21 through rotating fixed screw 22, until fixed slider 24 contacts with the fixed bolt department of stator clamping assembly 3, and fix stator clamping assembly 3 and fixed slider 24 together through the bolt, after accomplishing the fixed to stator clamping assembly 3, coil winding is carried out on the stator through winding device 4, in the in-process of rotating fixed bolt, realize the simultaneous rotation of all fixed screws 22 through the mutual linkage of bevel gear A51 and bevel gear B52, thereby synchronous adjustment fixed slider 24's position.

As shown in fig. 4, the stator clamping assembly 3 includes a stator clamping cylinder 31, the stator clamping cylinder 31 is fixedly connected with a fixed sliding block 24 through a bolt, the middle position of the stator clamping cylinder 31 is hollow with an open upper end, an annular supporting plate 311 is fixedly connected above the inner bottom end of the stator clamping cylinder 31, and first clamping mechanisms 32 are arranged on the left and right sides of the inner wall of the stator clamping cylinder 31.

When the stator to be wound is an outer stator, the stator is placed in a position in the middle of the stator clamping cylinder 31, and the stator is placed in an overhead state by the supporting plate 311, so that the winding device 4 is convenient to wind the stator, and the stator is fixed by the first clamping mechanism 32.

As shown in fig. 4, the first clamping mechanism 32 includes an arc-surface clamping plate 321, a pressing plate a322, a tightening plate a323 and a tightening screw a324, an arc-surface placing groove a312 is formed in the inner side of the stator clamping cylinder 31, a tightening groove a313 is formed in the corresponding arc-surface placing groove a312, the arc-surface clamping plate 321 is placed in the arc-surface placing groove a312, one end, far away from the central axis of the stator clamping cylinder 31, of the arc-surface clamping plate 321 is fixedly connected with the pressing plate a322, the pressing plate a322 and the tightening groove a313 are in sliding connection along the radial direction of the stator clamping cylinder 31, the tightening plate a323 and the pressing plate a322 are in contact with each other, the surfaces in contact with each other are in sliding connection, the surfaces in contact with each other are in an inclined shape, the tightening screw a324 is connected to the stator clamping cylinder 31 in a vertical reverse rotation mode, and the inner side of the arc-surface clamping plate 321 is a layer of rubber.

It should be noted that, when the outer stator is fixed by the first clamping mechanism 32, the tightening screw a324 is rotated, the tightening screw a324 drives the tightening plate a323 to move along the vertical direction, the tightening plate a323 drives the pressing plate a322 to move toward the central axis direction of the stator clamping cylinder 31 and finally fix the stator by the cambered surface clamping plate 321, and the inner side of the cambered surface clamping plate 321 is a rubber layer which can increase the friction between the rubber layer and the stator, so that the outer stator is fixed more firmly.

As shown in fig. 6, the stator clamping assembly 3 includes a stator fixing column 33, the stator fixing column 33 is fixedly connected with the fixing slider 24 through a bolt, the left and right sides of the stator fixing column 33 are provided with a second clamping mechanism 34, the second clamping mechanism 34 includes a cambered surface tightening plate 341, a pressing plate b342, a tightening plate b343 and a tightening screw b344, cambered surface placing grooves b331 are formed in the left and right sides of the stator fixing column 33, a tightening groove b332 is formed in the stator fixing column 33 corresponding to the cambered surface placing grooves b331, a cambered surface tightening plate 341 is placed in the cambered surface placing grooves b331, one side of the cambered surface tightening plate 341 close to the central axis of the stator fixing column 33 is fixedly connected with a pressing plate b342, the end face of the pressing plate b342 close to the central axis of the stator fixing column 33 is slidably connected with a tightening plate b343, one side of the pressing plate b342 and the tightening plate b343 in contact with each other is inclined, the stator fixing column 33 is rotatably connected with a tightening screw b344 corresponding to the tightening groove b332, the tightening screw b344 is in threaded connection with the tightening plate b, and the outer side of the cambered surface tightening plate 341 is a rubber layer.

It should be noted that, when the stator to be processed is an inner stator, the stator is sleeved on the outer side of the stator fixing column, the tightening screw b344 is rotated, the tightening screw b344 drives the tightening plate b343 to move along the vertical direction, the tightening plate b343 drives the compressing plate b342 to approach the outer side of the stator fixing plate 2, and finally the cambered surface tightening plate 341 is tightened on the inner wall of the inner stator, so that the inner stator is fixed, and a layer of rubber layer is wrapped on the outer side of the cambered surface tightening plate 341 to effectively promote the friction force between the cambered surface tightening plate 341 and the stator.

As shown in fig. 1,2 and 3, the assembly plate 1 is provided with a winding device 4 on the right side of the stator fixing plate 2, the winding device 4 comprises a longitudinal moving plate 41, a transverse moving plate 42, a vertical moving plate 43, a steering rod 44 and a winding rod 45, the assembly plate 1 is slidably connected with the longitudinal moving plate 41 in the front-rear direction at the right side of the stator fixing plate 2, the upper end of the longitudinal moving plate 41 is slidably connected with the transverse moving plate 42 in the left-right direction, the transverse moving plate 42 is slidably connected with the vertical moving plate 43 in the vertical direction, the steering rod 44 is rotatably connected on the vertical moving plate 43, the lower end of the horizontal section of the steering rod 44 is fixedly connected with the winding rod 45, and the left side and the right side of the lower end of the winding rod 45 are fixedly connected with a winding roller 46 and a winding head 47 respectively.

It should be noted that, in the process of processing the stator by the winding device 4, the linear driving device such as an air cylinder is installed on the assembly plate 1, the longitudinal moving plate 41 and the transverse moving plate 42 to drive the longitudinal moving plate 41 to move along the front-back direction, so that the transverse moving plate 42 moves along the left-right direction, the vertical moving plate 43 moves along the vertical direction, thereby driving the winding rod 45 to perform winding action, and driving the steering rod 44 to rotate by an external power supply so as to facilitate winding and cutting of the enameled wire, the enameled wire is oriented by the winding roller 46, and through holes corresponding to the winding roller 46 are commonly formed in the lower end of the winding rod 45 and the winding head 47, so that the enameled wire can pass through conveniently.

As shown in fig. 1 and 2, the winding rod 45 is divided into a fixed rod 451 and a rotating rod 452, the fixed rod 451 is fixedly connected to the lower end of the horizontal section of the steering rod 44, the rotating rod 452 is rotatably connected to the lower end of the fixed rod 451, a locking mechanism 453 is arranged between the fixed rod 451 and the rotating rod 452, the locking mechanism 453 comprises a locking rod 4531 and a locking spring 4532, two locking grooves 4511 with 180-degree intervals are formed in the outer side of the fixed rod 451 along the vertical direction, a positioning groove 4521 is formed in the rotating rod 452 corresponding to the locking grooves 4511, a locking rod 4531 is slidably connected in the positioning groove 4521, a locking spring 4532 is fixedly connected to the bottom ends of the locking rod 4531 and the positioning groove 4521, and the locking rod 4531 is inserted into the locking grooves 4511.

It should be noted that, in the process of winding the stator, in order to be suitable for the winding arrangement of the inner stator and the outer stator, the locking lever 4531 and the locking slot 4511 are separated from each other by pulling the locking lever 4531, then the rotating lever 452 is rotated until the rotating lever is rotated by 180 degrees, the locking lever 4531 is released, and under the elastic force of the locking spring 4532, the locking lever 4531 is reinserted into the locking slot 4511, so that the direction of the rotating lever 452 is fixed, and thus, the deflection of the winding head 47 is realized, thereby being suitable for winding the enameled wire of the outer stator and the inner stator.

The working principle of the invention is that the stator is fixed by the stator clamping assembly 3 and the stator clamping assembly 3 is fixed by the fixing sliding block 24 and the bolt, in the process, the fixing sliding block 24 slides in the fixing clamping groove 21 by rotating the fixing screw 22 until the fixing sliding block 24 contacts with the fixing bolt of the stator clamping assembly 3 and the stator clamping assembly 3 is fixed with the fixing sliding block 24 by the bolt, after the stator clamping assembly 3 is fixed, the coil winding is carried out on the stator by the winding device 4, in the process of rotating the fixing bolt, the simultaneous rotation of all the fixing screw 22 is realized by the mutual linkage of the bevel gear A51 and the bevel gear B52, so that the position of the fixing sliding block 24 is synchronously adjusted, when the stator needing coil winding is an outer stator, the stator is placed in the middle of the stator clamping cylinder 31, the stator is placed in an overhead state through the supporting plate 311, thereby facilitating the winding device 4 to wind the stator, the stator is fixed through the first clamping mechanism 32, when the outer stator is fixed through the first clamping mechanism 32, the jacking screw a324 is rotated, the jacking screw a324 drives the jacking plate a323 to move along the vertical direction, the jacking plate a323 drives the compacting plate a322 to move towards the central axis direction of the stator clamping cylinder 31 and finally fix the stator through the cambered surface clamping plate 321, the friction force between the cambered surface clamping plate 321 and the stator can be increased through the rubber layer on the inner side of the cambered surface clamping plate 321, so that the outer stator is more stable to fix, when the stator to be processed is the inner stator, the stator is sleeved on the outer side of the stator fixing column, the jacking screw B344 is rotated, the jacking screw B344 drives the jacking plate B343 to move along the vertical direction, the pressing plate b343 drives the pressing plate b342 to approach the outer side of the stator fixing plate 2, and finally the cambered surface pressing plate 341 is pressed against the inner wall of the stator to fix the inner stator, a rubber layer wraps the outer side of the cambered surface pressing plate 341, friction force between the cambered surface pressing plate 341 and the stator can be effectively improved, in the process of processing the stator through the winding device 4, the linear driving devices such as cylinders are respectively arranged on the assembly plate 1, the longitudinal moving plate 41 and the transverse moving plate 42 to drive the longitudinal moving plate 41 to move in the front-back direction, the transverse moving plate 42 to move in the left-right direction, the vertical moving plate 43 is driven to move in the vertical direction, the winding rod 45 is driven to perform winding, the steering rod 44 is driven to rotate through an external power supply to facilitate winding and cutting of the enameled wire, through holes corresponding to the winding rollers 46 are jointly formed in the lower end of the winding rod 45 and the winding head 47, and the passage of the enameled wire is facilitated.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the foregoing examples, and that the foregoing description and description are merely illustrative of the principles of this invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. Coil winding forming equipment for variable frequency motor stator production, including always installing board (1), its characterized in that: further comprises:

The stator fixing plate (2), the stator fixing plate (2) is rotationally connected to the upper end of the assembly plate (1), the stator fixing plate (2) is provided with fixed clamping grooves (21) along the radial direction of the stator fixing plate (2), and the fixed clamping grooves (21) are uniformly distributed along the circumferential direction of the stator fixing plate (2);

The fixed screw (22) is rotationally connected with the stator fixing plate (2) and is erected in the middle of the fixed clamping groove (21), the fixed screw (22) penetrates through the stator fixing plate (2) to be fixedly connected with a rotary button (23), and the fixed clamping groove (21) is slidably connected with a fixed sliding block (24);

The stator clamping assembly (3), the stator clamping assembly (3) is arranged at the upper end of the stator fixing plate (2), the stator clamping assembly (3) is fixed by bolts through a plurality of fixing sliding blocks (24), and the assembly plate (1) is further provided with a winding device (4);

The stator clamping assembly (3) comprises a stator clamping cylinder (31), the stator clamping cylinder (31) is fixedly connected with the fixed sliding block (24) through a bolt, the middle position of the stator clamping cylinder (31) is hollow with an open upper end, an annular supporting plate (311) is fixedly connected above the inner bottom end of the stator clamping cylinder (31), and first clamping mechanisms (32) are arranged on the left side and the right side of the inner wall of the stator clamping cylinder (31);

the first clamping mechanism (32) comprises an arc-surface clamping plate (321), a compression plate a (322), a tightening plate a (323) and a tightening screw a (324), wherein an arc-surface placing groove a (312) is formed in the inner side of the stator clamping cylinder (31), a tightening groove a (313) is formed in the corresponding arc-surface placing groove a (312), the arc-surface clamping plate (321) is placed in the arc-surface placing groove a (312), one end, far away from the central shaft of the stator clamping cylinder (31), of the arc-surface clamping plate (321) is fixedly connected with the compression plate a (322), the compression plate a (322) and the tightening groove a (313) are in sliding connection along the radial direction of the stator clamping cylinder (31), the tightening plate a (323) and the compression plate a (322) are in sliding connection, the surfaces in contact with each other are inclined, the stator clamping cylinder (31) are connected with the tightening screw a (324) in a threaded connection with the tightening plate a (323) along the vertical reverse rotation direction;

Stator clamping assembly (3) are including stator fixed column (33), stator fixed column (33) pass through the bolt with fixed slider (24) fixed connection, the left and right sides of stator fixed column (33) is provided with second clamping mechanism (34), second clamping mechanism (34) are including cambered surface tight jacking plate (341), clamp strip b (342), tight jacking plate b (343) and tight jacking screw b (344), cambered surface standing groove b (331) have been seted up to the left and right sides of stator fixed column (33), tight jacking groove b (332) have been seted up to stator fixed column (33) corresponding cambered surface standing groove b (331), cambered surface tight jacking plate (341) have been placed in cambered surface standing groove b (331), one side fixedly connected with clamp strip b (342) that cambered surface tight jacking plate (341) is close to stator fixed column (33) center pin, terminal surface sliding connection that clamp strip b (342) is close to stator fixed column (33) center pin has tight jacking plate b (342), just clamp strip b (342) and tight jacking screw (343) are connected with tight jacking screw b (343) in the slope of stator fixed column (33).

2. The coil winding forming apparatus according to claim 1, wherein: the stator fixing plate is characterized in that a synchronous placement groove (25) is formed in the middle position of the stator fixing plate (2), a synchronous mechanism (5) is arranged in the synchronous placement groove (25), the synchronous mechanism (5) comprises a bevel gear A (51) and a bevel gear B (52), the bevel gear A (51) is rotationally connected to the middle position of the synchronous placement groove (25), the bevel gear B (52) is meshed with the edge of the upper end of the bevel gear A (51), and a plurality of bevel gears B (52) are circumferentially distributed and are in threaded connection with the fixing screw (22).

3. The coil winding forming apparatus according to claim 2, wherein: the inner side of the cambered surface clamping plate (321) is provided with a rubber layer.

4. The coil winding forming apparatus according to claim 1, wherein: the outer side of the cambered surface jacking plate (341) is provided with a rubber layer.

5. The coil wire-winding forming apparatus as set forth in claim 4, wherein: the utility model provides a wire winding device, including stator fixed plate (2), stator fixed plate (2) are located in the right side, wire winding device (4) are including longitudinal movement board (41), lateral movement board (42), vertical movement board (43), steering column (44) and wire winding pole (45), longitudinal movement board (41) are located in the position of stator fixed plate (2) right side along fore-and-aft direction sliding connection, lateral movement board (42) are connected with along controlling sliding connection in the upper end of longitudinal movement board (41), vertical movement board (42) are connected with vertical movement board (43) along vertical direction sliding connection, rotate on vertical movement board (43) and be connected with steering column (44), the lower extreme fixedly connected with wire winding pole (45) of the horizontal segment of steering column (44), the left and right sides of wire winding pole (45) lower extreme is fixedly connected with wire winding gyro wheel (46) and wire winding head (47) respectively.

6. The coil wire-winding forming apparatus as set forth in claim 5, wherein: winding pole (45) divide into dead lever (451) and dwang (452), dead lever (451) fixed connection is in the lower extreme of the horizontal segment of steering column (44), the lower extreme rotation of dead lever (451) is connected with dwang (452), dead lever (451) with be provided with between dwang (452) lock to mechanism (453), lock to mechanism (453) including lock to pole (4531) and lock to spring (4532), two lock to groove (4511) of 180 degrees intervals are seted up in the outside of dead lever (451) along vertical direction, detent (4521) have been seted up to corresponding lock to groove (4511) to dwang (452), sliding connection has lock to pole (4531) in detent (4521), lock to pole (4531) with bottom fixedly connected with lock to spring (4532) of detent (4521), lock to pole (4531) inserts lock to groove (4511).