CN219379253U - Stator winding tin coating structure - Google Patents

Abstract

The utility model relates to the field of motor processing, in particular to a stator winding tin coating structure. According to the utility model, the clamping jaw cylinder drives the two clamping blocks to clamp the stator coil on the feeding station, the material taking mechanism drives the stator coil on the material taking clamp to move to the soldering flux dipping component to be dipped with the soldering flux, and then the stator coil dipped with the soldering flux is conveyed to the tin ironing mechanism to be subjected to tin ironing operation, so that automatic tin feeding of the stator is completed, the production efficiency is effectively improved, the labor input is reduced, and the production cost is reduced; meanwhile, smoke and splash generated by tin stamping are effectively avoided, the tin stamping machine is safer for operators, and the tin stamping length and the tin stamping quality of the tin stamping mechanism are high in consistency.

Description

Stator winding tin coating structure

Technical Field

The utility model relates to the field of motor processing, in particular to a stator winding tin coating structure.

Background

An electric motor is widely used in various fields as a device capable of converting electric energy into driving torque. The stator is an important component of the motor and mainly comprises an iron core, a wire frame and a winding. In the existing stator tin dipping process, soldering flux is required to be dipped firstly and then tin dipping is required, an operator holds the stator in a traditional soldering flux manner, the stator terminal faces downwards, soldering flux is dipped firstly and then tin dipping is carried out, the soldering flux dipping is manually controlled, the level of the stator cannot be guaranteed, the soldering flux dipping is uneven, the height of the soldering flux dipping cannot be consistent, the subsequent tin dipping operation of a product is affected, meanwhile, splashing is easily caused when tin is dipped, and the operator is easy to scald.

Disclosure of Invention

The technical problem to be solved by the utility model is to provide the stator winding tin-plating structure which is used for completing automatic stator tin-plating, improves the production efficiency, and has the advantages of tin-plating length and high tin-plating quality consistency.

In order to solve the technical problems, the technical scheme adopted by the utility model for solving the technical problems is as follows:

a stator winding tin coating structure comprising:

the feeding mechanism is provided with a feeding jig for loading the stator coils, and the feeding mechanism conveys the stator coils on the feeding jig to a feeding station:

the feeding device comprises a feeding mechanism, a feeding mechanism and a feeding mechanism, wherein a feeding gripper for gripping a stator coil is arranged on the feeding mechanism, the feeding gripper comprises a clamping jaw cylinder, two clamping blocks are arranged on two clamping arms of the clamping jaw cylinder, and the clamping jaw cylinder is used for driving the two clamping blocks to clamp the stator coil on a feeding station;

the soldering flux dipping mechanism is arranged on one side of the feeding mechanism and comprises a lifting component and a soldering flux dipping component which are arranged on the base, the lifting component is in driving connection with the soldering flux dipping component, and the lifting component drives the soldering flux dipping component to reciprocate up and down;

the tin-plating mechanism is arranged on one side of the soldering flux-dipping mechanism, the soldering flux-dipping mechanism is arranged between the feeding mechanism and the tin-plating mechanism, and the material taking mechanism is used for driving the material taking gripper to grasp the stator coil on the feeding station onto the soldering flux-dipping component for soldering flux-dipping, and then conveying the stator coil after soldering flux-dipping to the tin-plating mechanism for tin-plating operation.

In one embodiment of the utility model, the feeding mechanism comprises a feeding frame, a moving part is arranged on the feeding frame and is in driving connection with a feeding plate, a positioning block matched with the stator coil is arranged on the feeding plate, and the moving part drives the stator coil on the feeding plate to move to a feeding station.

In one embodiment of the utility model, the feeding mechanism comprises a detection component, the detection component comprises a first support and a second support, the first support is arranged at the feeding station, a first sensor for detecting the condition of a stator coil at the feeding station is arranged on the first support, the second support is arranged at the feeding end of the feeding mechanism, and a second sensor for detecting the condition of a low-cost sub-coil at the feeding end is arranged on the second support.

In one embodiment of the utility model, the lifting component comprises a lifting cylinder, the lifting cylinder is arranged on the bottom surface of the base, the lifting cylinder is in driving connection with a lifting frame, a lifting guide rod is arranged on the lifting frame, and the lifting guide rod penetrates through the base to be connected with the soldering flux component.

In one embodiment of the utility model, the soldering flux wetting component comprises a mounting frame and a box body loaded with soldering flux, wherein connecting rods are arranged on two sides of the mounting frame and are in driving connection with the lifting component, the box body is arranged on the base, a slot matched with the mounting frame is formed in the box body, a cup body used for loading soldering flux is arranged on the mounting frame, and the lifting component drives the cup body on the mounting frame to enter the box body from the slot to be filled with soldering flux so as to carry out soldering flux wetting operation on the stator coil.

In one embodiment of the utility model, the tin ironing mechanism comprises a tin ironing machine, a tin ironing cylinder is arranged on the tin ironing machine, and the material taking mechanism drives the stator coil with the soldering flux to move to the tin ironing cylinder to perform tin ironing operation.

In one embodiment of the utility model, the clamping blocks are provided with clamping grooves which are in arc structures, mounting grooves are formed in two ends of the clamping grooves, and clamping blocks which are in contact with the side edges of the stator coil are arranged on the mounting grooves.

In one embodiment of the utility model, the clamping blocks are provided with a supporting frame, the supporting frame is provided with a positioning plate, the positioning plate is provided with a positioning opening, and the two clamping blocks clamp the stator coil and simultaneously enable the wiring end of the stator coil to leak out of a processing channel formed by the two positioning openings.

In one embodiment of the utility model, the feeding mechanism further comprises a feeding frame and a positioning frame, wherein the feeding frame is provided with a belt conveying line, the positioning frame is arranged on the belt conveying line, the positioning frame is provided with a guide groove, the guide groove is opposite to the belt conveying line, and the belt conveying line conveys the stator coil to the discharging end of the feeding mechanism along the guide groove.

In one embodiment of the utility model, the width of the guide groove is larger than or equal to the diameter of the stator coil, the locating rack is provided with a locating groove matched with the shape of the stator coil, the locating groove is communicated with the guide groove, and the locating groove is positioned at the discharge end of the belt conveying line.

The utility model has the beneficial effects that:

according to the utility model, the clamping jaw cylinder drives the two clamping blocks to clamp the stator coil on the feeding station, the material taking mechanism drives the stator coil on the material taking clamp to move to the soldering flux dipping component to be dipped with the soldering flux, and then the stator coil dipped with the soldering flux is conveyed to the tin ironing mechanism to be subjected to tin ironing operation, so that automatic tin feeding of the stator is completed, the production efficiency is effectively improved, the labor input is reduced, and the production cost is reduced; meanwhile, smoke and splash generated by tin stamping are effectively avoided, the tin stamping machine is safer for operators, and the tin stamping length and the tin stamping quality of the tin stamping mechanism are high in consistency.

Drawings

Fig. 1 is a schematic diagram of a stator winding tin coating structure according to the present utility model.

Fig. 2 is a schematic diagram of a feeding mechanism of the present utility model.

Fig. 3 is a schematic view of a flux dipping mechanism of the present utility model.

Fig. 4 is a schematic view of a pick-up gripper of the present utility model.

Fig. 5 is a schematic view of a tin stamping mechanism of the present utility model.

The reference numerals in the figures illustrate: 1. a feeding mechanism; 11. a feeding frame; 12. a moving member; 13. a loading plate; 14. a positioning block; 15. a first bracket; 16. a first sensor; 17. a second bracket; 18. a second sensor; 2. a soldering flux dipping mechanism; 21. a base; 22. a lifting cylinder; 23. a lifting frame; 24. lifting guide rods; 25. a case; 26. slotting; 27. a mounting frame; 28. a cup body; 29. a connecting rod; 3. a tin ironing mechanism; 31. a tin ironing machine; 32. a tin stamping cylinder; 4. a material taking mechanism; 5. a material taking gripper; 51. a clamping jaw cylinder; 52. clamping blocks; 53. a clamping groove; 54. a clamping block; 55. a positioning plate; 56. positioning the opening; 57. a processing channel; 6. a blanking mechanism; 61. a blanking frame; 62. a belt conveyor line; 63. a positioning frame; 64. a guide groove; 65. a positioning groove; 7. a stator coil.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings and specific examples, which are not intended to be limiting, so that those skilled in the art will better understand the utility model and practice it.

Referring to fig. 1, a stator winding tin coating structure includes:

the feeding mechanism 1 is provided with a feeding jig for loading the stator coil 7, and the feeding mechanism 1 conveys the stator coil 7 on the feeding jig to a feeding station:

the feeding mechanism 4 is provided with a feeding gripper 5 for gripping the stator coil 7, the feeding gripper 5 comprises a clamping jaw air cylinder 51, two clamping blocks 52 are arranged on two clamping arms of the clamping jaw air cylinder 51, and the clamping jaw air cylinder 51 is used for driving the two clamping blocks 52 to clamp the stator coil 7 on the feeding station;

the soldering flux dipping mechanism 2 is arranged on one side of the feeding mechanism 1, the soldering flux dipping mechanism 2 comprises a lifting component and a soldering flux dipping component which are arranged on the base 21, the lifting component is in driving connection with the soldering flux dipping component, and the lifting component drives the soldering flux dipping component to reciprocate up and down;

the tin plating mechanism 31 is arranged on one side of the soldering flux dipping mechanism 2, the soldering flux dipping mechanism 2 is arranged between the feeding mechanism 1 and the tin plating mechanism 31, the material taking mechanism 4 is used for driving the material taking gripper 5 to grab the stator coil 7 on the feeding station onto the soldering flux dipping component for soldering flux dipping, and then the stator coil 7 after soldering flux dipping is conveyed onto the tin plating mechanism 31 for tin plating operation.

According to the utility model, the clamping jaw air cylinder 51 drives the two clamping blocks 52 to clamp the stator coil 7 on the feeding station, the material taking mechanism 4 drives the stator coil 7 on the material taking grip 5 to move to a soldering flux component to be dipped with soldering flux, and then the stator coil 7 dipped with soldering flux is conveyed to the tin ironing mechanism 31 to be subjected to tin ironing operation, so that automatic tin feeding of a stator is completed, the production efficiency is effectively improved, the labor input is reduced, and the production cost is reduced; meanwhile, smoke and splash generated by tin stamping are effectively avoided, the tin stamping machine is safer for operators, and the tin stamping length and the tin stamping quality of the tin stamping mechanism 31 are high in consistency.

Specifically, the material taking mechanism 4 may be a multi-axis mechanical arm, the material taking gripper 5 is disposed at the mounting end of the multi-axis mechanical arm, the multi-axis mechanical arm drives the material taking gripper 5 to move in space, so as to drive the stator coil 7 thereon to move or rotate, and the like, to complete the soldering flux coating of the terminal of the stator coil 7 and the tin ironing treatment on the terminal, the multi-axis mechanical arm can properly adjust the heights of the stators according to different specifications, thereby meeting the tin dipping of the stators with different sizes, and the application range is wide.

In one embodiment of the present utility model, the feeding mechanism 1 includes a feeding frame 11, a moving part 12 is disposed on the feeding frame 11, the moving part 12 is in driving connection with a feeding plate 13, a positioning block 14 matched with the stator coil 7 is disposed on the feeding plate 13, and the moving part 12 drives the stator coil 7 on the feeding plate 13 to move to a feeding station.

Specifically, the moving component 12 may be any one of an air cylinder, an oil cylinder, an electric cylinder, and a linear module, and is used for driving the stator coil 7 on the feeding plate 13 to perform rapid conveying, so that conveying efficiency is high.

The stator coil 7 is placed on the feeding plate 13, the positioning coil is rapidly positioned through the positioning block 14, the moving part 12 drives the stator coil 7 on the feeding plate 13 to move to the feeding station, the transmission efficiency is high, the running cost is reduced, and the device is safe and reliable.

In one embodiment of the present utility model, the feeding mechanism 1 includes a detecting component, where the detecting component includes a first bracket 15 and a second bracket 17, the first bracket 15 is disposed at the feeding station, a first sensor 16 for detecting the condition of the stator coil 7 at the feeding station is disposed on the first bracket 15, the second bracket 17 is disposed at the feeding end of the feeding mechanism 1, and a second sensor 18 for detecting the condition of the stator coil 7 at the feeding end is disposed on the second bracket 17.

Specifically, the second sensor 18 on the second bracket 17 detects the condition of the stator coil 7 at the feeding end, and after the moving component 12 moves to the feeding station position on the stator coil 7 on the feeding plate 13, the first sensor 16 on the first bracket 15 detects the condition of the stator coil 7 at the feeding station position, so that the feeding accuracy of the stator coil 7 is ensured, the waste is avoided, and the processing quality is improved.

In one embodiment of the present utility model, the lifting component includes a lifting cylinder 22, the lifting cylinder 22 is disposed on the bottom surface of the base 21, the lifting cylinder 22 is in driving connection with a lifting frame 23, a lifting guide rod 24 is disposed on the lifting frame 23, and the lifting guide rod 24 penetrates through the base 21 to be connected with the soldering flux component.

Specifically, the lifting cylinder 22 drives the mounting frame 27 connected with the lifting guide rod 24 to move downwards, so that after the mounting frame 27 enters the box body 25 from the slot 26 to fill the soldering flux in the cup body 28, the soldering flux can be discharged from the box body 25 and kept at a stable position of the cup body 28, the height of the stator dipped with the soldering flux can be properly adjusted according to the requirements, the soldering flux dipping of the stators with different sizes is met, and the applicability of the soldering flux dipping mechanism 2 is improved.

In one embodiment of the present utility model, the soldering flux dipping component includes a mounting frame 27 and a box 25 for loading soldering flux, connecting rods 29 are disposed on two sides of the mounting frame 27, the connecting rods 29 are in driving connection with the lifting component, the box 25 is disposed on the base 21, a slot 26 matched with the mounting frame 27 is disposed on the box 25, a cup 28 for loading soldering flux is disposed on the mounting frame 27, and the lifting component drives the cup 28 on the mounting frame 27 to enter the box 25 from the slot 26 to be filled with soldering flux for performing soldering flux dipping operation on the stator coil 7.

Specifically, the lifting part drives the cup 28 on the mounting frame 27 to enter the box 25 from the slot 26 to be filled with soldering flux so as to carry out soldering flux dipping operation on the stator coil 7, so that the soldering flux dipped by the wiring terminal is uniform in height, the tin dipping is firmer, the situation of desoldering is not easy to occur, and the qualification rate of the tin dipping is improved.

In one embodiment of the present utility model, the tin-ironing mechanism 31 includes a tin-ironing machine 31, a tin-ironing cylinder 32 is disposed on the tin-ironing machine 31, and the material-taking mechanism 4 drives the stator coil 7 with the soldering flux to move onto the tin-ironing cylinder 32 for tin-ironing operation.

Specifically, the multiaxis arm drives the stator coil 7 that the coating is favorable to the scaling powder and removes to scalding tin mechanism 31 department, the arm drives the stator coil 7 that gets on the tongs 5 and removes, rotate to scalding tin barrel 32 top, scalding tin barrel 32 on the tin machine 31 carries out scalding tin to the stator wiring end and handles, adopt current jet-type soldering machine to carry out quick scalding tin operation to the wiring end of stator coil 7, the automatic tin that scalds of tin machine 31 can guarantee that the wiring end lacquer skin is effectively got rid of, can not cause other positions of wiring end to remove lacquer and scald tin, the higher advantage of security.

In one embodiment of the present utility model, the clamping block 52 is provided with a clamping groove 53, the clamping groove 53 has an arc structure, two ends of the clamping groove 53 are provided with mounting grooves, and the mounting grooves are provided with clamping blocks 54 contacting with the side edges of the stator coil 7.

Specifically, the clamping blocks 54 can be made of rubber materials, the clamping blocks 54 which are in contact with the side edges of the stator coils 7 are arranged on the mounting grooves, the stator coils 7 with different sizes can be conveniently and rapidly clamped, the application range is wide, meanwhile, the clamping blocks 54 can be conveniently replaced, and the production cost is reduced.

In one embodiment of the present utility model, the clamping blocks 52 are provided with a supporting frame, the supporting frame is provided with a positioning plate 55, the positioning plate 55 is provided with a positioning opening 56, and the two clamping blocks 52 clamp the stator coil 7 and simultaneously enable the terminals of the stator coil 7 to leak out of the processing channels 57 formed by the two positioning openings 56.

The wiring end of the stator coil 7 leaks out from a processing channel 57 formed by the two positioning openings 56, specifically, the tin-ironing cylinder 32 enters from the processing channel 57 formed by the two positioning openings 56, and the tin-ironing cylinder 32 on the tin-ironing machine 31 carries out tin-ironing treatment on the wiring end of the stator; the cup 28 enters from the processing channel 57 formed by the two positioning openings 56, meanwhile, the wiring end of the stator coil 7 is immersed into the soldering flux in the cup 28, the processing channel 57 can be matched with the cup 28 or the tin-ironing cylinder 32 for use, the width of the processing channel 57 is slightly larger than the diameter of the cup 28 or the tin-ironing cylinder 32, and the position of the wiring end is rapidly positioned and guided, so that the wiring end of the stator coil 7 enters into the cup 28 or the tin-ironing cylinder 32, and the processing stability is ensured.

In one embodiment of the present utility model, the feeding mechanism 6 further includes a feeding frame 61 and a positioning frame 63, the feeding frame 61 is provided with a belt conveying line 62, the positioning frame 63 is disposed on the belt conveying line 62, the positioning frame 63 is provided with a guide groove 64, the guide groove 64 is disposed opposite to the belt conveying line 62, and the belt conveying line 62 conveys the stator coil 7 to a discharge end of the feeding mechanism 6 along the guide groove 64.

Specifically, the belt conveyor line 62 conveys the stator coil 7 to the discharge end of the discharging mechanism 6 along the guide groove 64, so that the conveying efficiency is high, the running cost is reduced, and the safety and reliability are realized.

In one embodiment of the present utility model, the width of the guiding groove 64 is greater than or equal to the diameter of the stator coil 7, the positioning frame 63 is provided with a positioning groove 65 matching the shape of the stator coil 7, the positioning groove 65 is communicated with the guiding groove 64, and the positioning groove 65 is located at the discharge end of the belt conveying line 62.

Specifically, the width of guide slot 64 is slightly greater than the diameter of stator coil 7 for stator coil 7 is under the blocking effect of guide slot 64, guarantees the accuracy of direction of transmission, constant head tank 65 with guide slot 64 is linked together, constant head tank 65 is located the discharge end of belt transfer chain 62, and constant head tank 65 carries out position location to stator coil 7 position, guarantees that stator coil 7 unloading position is accurate.

The using process comprises the following steps:

the stator coil 7 is placed on the feeding plate 13, the positioning coil is rapidly positioned through the positioning block 14, the second sensor 18 on the second bracket 17 detects the condition of the stator coil 7 at the feeding end, and after the stator coil 7 on the feeding plate 13 of the moving part 12 moves to the feeding station, the first sensor 16 on the first bracket 15 detects the condition of the stator coil 7 at the feeding station;

the multi-axis mechanical arm drives the material taking gripper 5 to move to a coming station, the clamping jaw air cylinder 51 drives the two clamping blocks 52 to clamp the positioning coil, meanwhile, the wiring end of the stator coil 7 leaks out of the processing channel 57 formed by the two positioning openings 56, and the multi-axis mechanical arm drives the stator coil 7 on the material taking gripper 5 to move to the position above the cup 28 loaded with soldering flux;

the lifting cylinder 22 drives the mounting frame 27 connected with the lifting guide rod 24 to move downwards, so that the mounting frame 27 enters the box body 25 from the slot 26, the cup body 28 is filled with soldering flux, the mounting frame comes out of the box body 25 and keeps the position of the cup body 28 stable, the mechanical arm drives the stator coil 7 on the material taking grip 5 to move and rotate to the position above the cup body 28 loaded with the soldering flux, the cup body 28 enters from the processing channel 57 formed by the two positioning openings 56, and meanwhile, the wiring ends of the stator coil 7 are immersed into the soldering flux in the cup body 28;

the multi-axis mechanical arm drives the stator coil 7 coated with the soldering flux to move to the tin ironing mechanism 31, the mechanical arm drives the stator coil 7 on the material taking gripper 5 to move and rotate to the position above the tin ironing cylinder 32, the tin ironing cylinder 32 enters from a processing channel 57 formed by two positioning openings 56, and after tin ironing is carried out on the stator wiring end by the tin ironing cylinder 32 on the tin ironing machine 31;

the multi-axis mechanical arm drives the stator coil 7 for removing the tin stamping treatment of the wiring end to be placed on the belt conveying line 62, the belt conveying line 62 conveys the stator coil 7 to the discharge end of the discharging mechanism 6 along the guide groove 64, and the positioning groove 65 positions the stator coil 7.

The above-described embodiments are merely preferred embodiments for fully explaining the present utility model, and the scope of the present utility model is not limited thereto. Equivalent substitutions and modifications will occur to those skilled in the art based on the present utility model, and are intended to be within the scope of the present utility model. The protection scope of the utility model is subject to the claims.

Claims (10)

1. A stator winding tin coating structure, comprising:

the feeding mechanism is provided with a feeding jig for loading the stator coils, and the feeding mechanism conveys the stator coils on the feeding jig to a feeding station:

the feeding device comprises a feeding mechanism, a feeding mechanism and a feeding mechanism, wherein a feeding gripper for gripping a stator coil is arranged on the feeding mechanism, the feeding gripper comprises a clamping jaw cylinder, two clamping blocks are arranged on two clamping arms of the clamping jaw cylinder, and the clamping jaw cylinder is used for driving the two clamping blocks to clamp the stator coil on a feeding station;

the soldering flux dipping mechanism is arranged on one side of the feeding mechanism and comprises a lifting component and a soldering flux dipping component which are arranged on the base, the lifting component is in driving connection with the soldering flux dipping component, and the lifting component drives the soldering flux dipping component to reciprocate up and down;

the tin-plating mechanism is arranged on one side of the soldering flux-dipping mechanism, the soldering flux-dipping mechanism is arranged between the feeding mechanism and the tin-plating mechanism, and the material taking mechanism is used for driving the material taking gripper to grasp the stator coil on the feeding station onto the soldering flux-dipping component for soldering flux-dipping, and then conveying the stator coil after soldering flux-dipping to the tin-plating mechanism for tin-plating operation.

2. The stator winding tin coating structure of claim 1, wherein the feeding mechanism comprises a feeding frame, a moving part is arranged on the feeding frame and is in driving connection with a feeding plate, a positioning block matched with the stator coil is arranged on the feeding plate, and the moving part drives the stator coil on the feeding plate to move to a feeding station.

3. The stator winding tin coating structure of claim 1, wherein the feeding mechanism comprises a detection component, the detection component comprises a first support and a second support, the first support is arranged at the feeding station, a first sensor for detecting the condition of the stator coil at the feeding station is arranged on the first support, the second support is arranged at the feeding end of the feeding mechanism, and a second sensor for detecting the condition of the low-frequency sub-coil at the feeding end is arranged on the second support.

4. The stator winding tin coating structure of claim 1, wherein the lifting component comprises a lifting cylinder, the lifting cylinder is arranged on the bottom surface of the base, the lifting cylinder is in driving connection with a lifting frame, a lifting guide rod is arranged on the lifting frame, and the lifting guide rod penetrates through the base to be connected with the soldering flux component.

5. The tin coating structure of claim 1, wherein the soldering flux wetting component comprises a mounting frame and a box body loaded with soldering flux, connecting rods are arranged on two sides of the mounting frame, the connecting rods are in driving connection with the lifting component, the box body is arranged on the base, a groove matched with the mounting frame is formed in the box body, a cup body used for loading soldering flux is arranged on the mounting frame, and the lifting component drives the cup body on the mounting frame to fill soldering flux into the box body from the groove so as to carry out soldering flux wetting operation on the stator coil.

6. The stator winding tinning structure according to claim 1, wherein the tin ironing mechanism comprises a tin ironing machine, a tin ironing cylinder is arranged on the tin ironing machine, and the material taking mechanism drives a stator coil with soldering flux to move onto the tin ironing cylinder to conduct tin ironing operation.

7. The stator winding tin coating structure of claim 1, wherein the clamping blocks are provided with clamping grooves, the clamping grooves are of arc-shaped structures, mounting grooves are formed in two ends of the clamping grooves, and clamping blocks which are in contact with the side edges of the stator coil are arranged on the mounting grooves.

8. The stator winding tin coating structure of claim 1, wherein the clamping blocks are provided with supporting frames, the supporting frames are provided with positioning plates, the positioning plates are provided with positioning openings, and the two clamping blocks clamp the stator coils and enable the terminals of the stator coils to leak out of the processing channels formed by the two positioning openings.

9. The stator winding tin feeding structure of claim 1, further comprising a blanking mechanism, wherein the blanking mechanism comprises a blanking frame and a positioning frame, a belt conveying line is arranged on the blanking frame, the positioning frame is arranged on the belt conveying line, a guide groove is arranged on the positioning frame, the guide groove is arranged opposite to the belt conveying line, and the belt conveying line conveys the stator coil to a discharging end of the blanking mechanism along the guide groove.

10. The stator winding tin coating structure of claim 9, wherein the width of the guide groove is greater than or equal to the diameter of the stator coil, a positioning groove matched with the shape of the stator coil is arranged on the positioning frame, the positioning groove is communicated with the guide groove, and the positioning groove is positioned at the discharge end of the belt conveying line.