CN222234623U - A stator winding shaping device for bidirectional processing - Google Patents

Abstract

The utility model discloses a stator winding shaping device for bidirectional processing, which belongs to the technical field of motor stator shaping devices, including an equipment frame, including an equipment frame, a downward pressure driving component is installed on the equipment frame, and also includes a shaping component, the shaping component has two groups, upper and lower, and is respectively installed on the downward pressure driving component and the equipment frame; and also includes a motor stator, the motor stator is arranged on the two groups of shaping components, the shaping component includes a driving component, an inner shaping component and an outer shaping component, the driving components of the two groups of shaping components are respectively installed on the equipment frame and the downward pressure driving component, the inner shaping component and the outer shaping component are both connected to the driving component, the inner shaping component is connected to the outer shaping component, and the motor stator is arranged on the two groups of outer shaping components. Through the above method, the utility model realizes the synchronous shaping of the inner and outer sides of the coils at the upper and lower ends of the stator.

Description

Stator winding shaping device for bidirectional processing

Technical Field

The utility model relates to the technical field of motor stator shaping devices, in particular to a stator winding shaping device for bidirectional processing.

Background

In many prior arts, CN205753875U discloses a stator coil shaping device, which comprises a base, a horizontally arranged stator coil shaping lower die fixed on the base, a horizontally arranged stator coil shaping upper die arranged right above the stator coil shaping lower die, a horizontally arranged lifting plate with the bottom surface fixed with the top surface of the stator coil shaping upper die, and a hydraulic device capable of driving the lifting plate to vertically press down so as to enable the stator coil shaping upper die and the stator coil shaping lower die to be closed, wherein the stator coil shaping lower die is provided with a top opening and a lower die cavity for placing a stator coil, and a vertically arranged lower convex column for closing the opening of the lower die cavity is arranged at the bottom surface of the stator coil shaping upper die, so that the shaping of the stator coil is realized.

But this patent fails to simultaneously shape the windings on the inside and outside of the upper and lower ends of the stator.

Based on the above, the present utility model designs a stator winding shaping device with bidirectional processing to solve the above problems.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model provides a stator winding shaping device with bidirectional processing.

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

The stator winding shaping device for bidirectional processing comprises an equipment frame, a shaping assembly, a motor stator, a motor driving mechanism and a motor driving mechanism, wherein the equipment frame is provided with a pressing driving assembly, the shaping assembly is provided with an upper group and a lower group and is respectively arranged on the pressing driving assembly and the equipment frame;

The shaping assembly comprises a driving assembly, an inner shaping assembly and an outer shaping assembly, wherein the driving assemblies of the two groups of shaping assemblies are respectively arranged on the equipment frame and the pushing driving assembly, the inner shaping assembly and the outer shaping assembly are connected with the driving assemblies, the inner shaping assembly is connected with the outer shaping assembly, and the motor stator is arranged on the two groups of outer shaping assemblies.

Still further, push down actuating assembly includes motor, belt pulley assembly, thread bush, threaded rod, connecting plate, connecting rod, mounting panel and slide bar, motor fixed mounting is on equipment frame, is connected through belt pulley assembly transmission between the output of motor and the thread bush, thread bush and threaded rod threaded connection, threaded rod and connecting plate fixed connection, connecting plate and through connecting rod and mounting panel fixed connection, mounting panel and slide bar sliding connection, slide bar fixed mounting is on equipment frame.

Still further, the drive assembly includes first flange board, first traveller, spring and conical head post, two first flange boards are connected in equipment frame and mounting panel respectively, first traveller fixed mounting is on first flange board, the spring housing is on first traveller, and the both ends of spring are connected with first flange board, interior plastic subassembly respectively, conical head post fixed mounting is on first flange board, first traveller is connected with outer plastic subassembly, conical head post is connected with interior plastic subassembly.

Still further, interior plastic subassembly includes second flange board and rises core anchor clamps, the upper end fixed connection of second flange board and spring, first slide hole, the second slide hole of seting up on the second flange board cooperate first traveller, cone head post sliding connection respectively and use, rise core anchor clamps fixed mounting on the second flange board, rise core anchor clamps cooperation cone head post contact connection and use, the second flange board is connected with outer plastic subassembly.

Still further, outer plastic subassembly includes flange ring, first spout, second spout, first slider, second slider, ejector pad, embraces piece and third flange board.

Still further, flange ring fixed mounting is on the second flange board, a plurality of first spouts, second spout have been seted up on the flange ring, a plurality of first sliders, second slider of sliding connection respectively have a plurality of first sliders, second slider, a plurality of first sliders, second slider respectively fixedly connected with push block and embracing the piece, push block and embracing piece laminating sliding connection, third flange board fixed mounting is on the flange ring, the chute has been seted up on the push block, the inclined plane that cooperation push block chute laminating sliding connection used has been seted up to the upper end of first slide column, push block and second flange board sliding connection, all be connected through reset spring between push block, the embracing piece and the flange ring.

Furthermore, the two third flange plates are provided with fixing grooves.

Further, the motor stator is arranged between the two fixed grooves.

The utility model has the following technical effects:

When the motor stator is used, the motor stator is placed on the outer shaping assembly of the shaping assembly at the lower end, the shaping assembly at the upper end is driven to be pressed down by the pressing driving assembly, when the outer shaping assembly of the shaping assembly at the upper end is contacted with the motor stator, the pressing driving assembly continues to be pressed down, the driving assembly at the upper end is driven to be pressed down, the driving assembly at the upper end is contacted with the inner shaping assembly and the outer shaping assembly, the inner shaping assembly and the outer shaping assembly are enabled to shape the inner coil and the outer coil at the upper end of the motor stator, and meanwhile, the driving assembly at the lower end is contacted with the inner shaping assembly and the outer shaping assembly, so that the inner shaping assembly and the outer shaping assembly are enabled to shape the inner coil and the outer coil at the lower end of the motor stator, and bidirectional shaping of the motor stator is achieved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model 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 evident that the drawings in the following description are only some embodiments of the present utility model and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a perspective view of a bi-directional processed stator winding shaping apparatus according to the present utility model;

FIG. 2 is an elevation view of a bi-directionally processed stator winding shaping apparatus in accordance with the present utility model;

FIG. 3 is a second perspective view of a bi-directional processed stator winding shaping apparatus according to the present utility model;

FIG. 4 is an exploded view of the shaping assembly of the present utility model;

Fig. 5 is a cross-sectional view of a shaping assembly of the present utility model.

Reference numerals in the drawings represent respectively:

1. Device frame 2, lower drive assembly 21, motor 22, pulley assembly 23, threaded sleeve 24, threaded rod 25, connecting plate 26, connecting rod 27, mounting plate 28, slide bar 3, swage assembly 31, drive assembly 311, first flange plate 312, first slide post 313, spring 314, tapered head post 32, inner swage assembly 321, second flange plate 322, core expanding fixture 33, outer swage assembly 331, flange ring 332, first runner 333, second runner 334, first runner 335, second runner 336, push block 337, clasping block 338, third flange plate 339, fixed slot 4, motor stator.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model is further described below with reference to examples.

Reference to "left", "right", "front", "rear", "upper", "lower" in the following description is oriented in the viewing direction of the front view.

Example 1

Referring to fig. 1-5 of the specification, the device comprises a device frame 1, a shaping assembly, a motor stator and a motor driving mechanism, wherein the device frame is provided with a pressing driving assembly, the shaping assembly is provided with an upper group and a lower group and is respectively arranged on the pressing driving assembly and the device frame;

The shaping assembly comprises a driving assembly, an inner shaping assembly and an outer shaping assembly, wherein the driving assemblies of the two groups of shaping assemblies are respectively arranged on the equipment frame and the pushing driving assembly, the inner shaping assembly and the outer shaping assembly are connected with the driving assemblies, the inner shaping assembly is connected with the outer shaping assembly, and the motor stator is arranged on the two groups of outer shaping assemblies.

The motor stator 4 is placed on the outer shaping assembly 33 of the shaping assembly 3 at the lower end, the shaping assembly 3 at the upper end is driven to be pressed downwards by the pressing driving assembly 2, when the outer shaping assembly 33 of the shaping assembly 3 at the upper end is contacted with the motor stator 4, the pressing driving assembly 2 is continuously pressed downwards, the driving assembly 31 at the upper end is driven to be pressed downwards, the driving assembly 31 at the upper end is contacted with the inner shaping assembly 32 and the outer shaping assembly 33, the inner shaping assembly 32 and the outer shaping assembly 33 are enabled to shape the inner and outer coils at the upper end of the motor stator 4, and meanwhile, the driving assembly 31 at the lower end is contacted with the inner shaping assembly 32 and the outer shaping assembly 33, so that the inner shaping assembly 32 and the outer shaping assembly 33 are enabled to shape the inner and outer coils at the lower end of the motor stator 4, and accordingly bidirectional shaping of the motor stator 4 is achieved.

The pushing-down driving assembly 2 comprises a motor 21, a belt pulley assembly 22, a thread bush 23, a threaded rod 24, a connecting plate 25, a connecting rod 26, a mounting plate 27 and a sliding rod 28, wherein the motor 21 is fixedly arranged on the equipment frame 1, an output end of the motor 21 is in transmission connection with the thread bush 23 through the belt pulley assembly 22, the thread bush 23 is in threaded connection with the threaded rod 24, the threaded rod 24 is fixedly connected with the connecting plate 25, the connecting plate 25 is fixedly connected with the mounting plate 27 through the connecting rod 26, the mounting plate 27 is in sliding connection with the sliding rod 28, and the sliding rod 28 is fixedly arranged on the equipment frame 1.

When the utility model is used, the motor 21 drives the thread sleeve 23 to rotate through the belt pulley assembly 22 by starting the motor 21, the thread sleeve 23 drives the threaded rod 24 to move, the threaded rod 24 drives the connecting plate 25 and the connecting rod 26 to move downwards, the connecting plate 25 and the connecting rod 26 drive the mounting plate 27 to slide on the slide rod 28, and the slide rod 28 drives the shaping assembly 3 thereon to press downwards.

The driving assembly 31 comprises a first flange plate 311, a first sliding column 312, a spring 313 and a conical head column 314, wherein the two first flange plates 311 are respectively connected with the equipment frame 1 and the mounting plate 27, the first sliding column 312 is fixedly arranged on the first flange plate 311, the spring 313 is sleeved on the first sliding column 312, two ends of the spring 313 are respectively connected with the first flange plate 311 and the inner shaping assembly 32, the conical head column 314 is fixedly arranged on the first flange plate 311, the first sliding column 312 is connected with the outer shaping assembly 33, and the conical head column 314 is connected with the inner shaping assembly 32.

The inner shaping assembly 32 comprises a second flange plate 321 and an expanding core clamp 322, the second flange plate 321 is fixedly connected with the upper end of the spring 313, a first sliding hole and a second sliding hole formed in the second flange plate 321 are respectively matched with the first sliding column 312 and the conical head column 314 in a sliding connection mode, the expanding core clamp 322 is fixedly arranged on the second flange plate 321, the expanding core clamp 322 is matched with the conical head column 314 in a contact connection mode, and the second flange plate 321 is connected with the outer shaping assembly 33.

The outer shaping assembly 33 includes a flange ring 331, a first runner 332, a second runner 333, a first slider 334, a second slider 335, a push block 336, a cradle block 337, and a third flange plate 338;

The flange ring 331 is fixedly mounted on the second flange plate 321, a plurality of first sliding grooves 332 and second sliding grooves 333 are formed in the flange ring 331, a plurality of first sliding blocks 334 and second sliding blocks 335 are respectively and slidably connected with the plurality of first sliding blocks 332 and the plurality of second sliding blocks 335, a plurality of pushing blocks 336 and holding blocks 337 are respectively and fixedly connected with the plurality of first sliding blocks 334 and the plurality of second sliding blocks 335, the pushing blocks 336 are in fit sliding connection with the holding blocks 337, the third flange plate 338 is fixedly mounted on the flange ring 331, inclined grooves are formed in the pushing blocks 336, inclined planes matched with the inclined grooves of the pushing blocks 336 in fit sliding connection are formed in the upper end of the first sliding column 312, the pushing blocks 336 are in sliding connection with the second flange plate 321, and the pushing blocks 336 and the holding blocks 337 are connected with the flange ring 331 through reset springs.

The two third flange plates 338 are provided with fixing grooves 339;

the motor stator 4 is disposed between the two fixing grooves 339.

When the motor stator shaping device is used, the inclined plane of the first sliding column 312 of the driving assembly 31 of the shaping assembly 3 at the upper end is in fit sliding connection with the inclined groove on the push block 336, the first sliding column 312 pushes the push block 336 to slide, the push block 336 drives the holding blocks 337 to slide, so that the plurality of groups of holding blocks 337 extrude and shape the outer side of the upper end of the motor stator 4, meanwhile, the conical head column 314 at the upper end is in fit sliding connection with the expanding core clamp 322, the conical head column 314 drives the movable end of the expanding core clamp 322 to expand and shape the inner side of the upper end of the motor stator 4, and the shaping principle of the shaping assembly 3 at the lower end is the same as above, so that the inner side and outer side of the winding at the upper end and the lower end of the motor stator 4 are synchronously shaped.

The foregoing embodiments are merely for illustrating the technical solution of the present utility model, but not for limiting the same, and although the present utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art that modifications may be made to the technical solution described in the foregoing embodiments or equivalents may be substituted for parts of the technical features thereof, and such modifications or substitutions may be made without departing from the spirit and scope of the technical solution of the embodiments of the present utility model.

Claims (8)

1. The stator winding shaping device for bidirectional processing comprises an equipment frame (1) and is characterized in that a pressing driving assembly (2) is arranged on the equipment frame (1), the shaping assembly (3) is further arranged on the equipment frame (1), and the shaping assembly (3) is provided with an upper group and a lower group and is respectively arranged on the pressing driving assembly (2) and the equipment frame (1);

The shaping assembly (3) comprises a driving assembly (31), an inner shaping assembly (32) and an outer shaping assembly (33), the driving assemblies (31) of the two groups of shaping assemblies (3) are respectively arranged on the equipment frame (1) and the pushing driving assembly (2), the inner shaping assembly (32) and the outer shaping assembly (33) are both connected with the driving assembly (31), the inner shaping assembly (32) is connected with the outer shaping assembly (33), and the motor stator (4) is arranged on the two groups of outer shaping assemblies (33).

2. The bidirectional processed stator winding shaping device according to claim 1, wherein the push-down driving assembly (2) comprises a motor (21), a belt pulley assembly (22), a thread bush (23), a threaded rod (24), a connecting plate (25), a connecting rod (26), a mounting plate (27) and a sliding rod (28), the motor (21) is fixedly mounted on the equipment frame (1), an output end of the motor (21) is in transmission connection with the thread bush (23) through the belt pulley assembly (22), the thread bush (23) is in threaded connection with the threaded rod (24), the threaded rod (24) is fixedly connected with the connecting plate (25), the connecting plate (25) is fixedly connected with the mounting plate (27) through the connecting rod (26), the mounting plate (27) is in sliding connection with the sliding rod (28), and the sliding rod (28) is fixedly mounted on the equipment frame (1).

3. The bidirectional processed stator winding shaping device according to claim 2, wherein the driving assembly (31) comprises a first flange plate (311), a first sliding column (312), a spring (313) and a conical head column (314), the two first flange plates (311) are respectively connected with the equipment frame (1) and the mounting plate (27), the first sliding column (312) is fixedly mounted on the first flange plate (311), the spring (313) is sleeved on the first sliding column (312), two ends of the spring (313) are respectively connected with the first flange plate (311) and the inner shaping assembly (32), the conical head column (314) is fixedly mounted on the first flange plate (311), the first sliding column (312) is connected with the outer shaping assembly (33), and the conical head column (314) is connected with the inner shaping assembly (32).

4. A stator winding shaping apparatus according to claim 3, wherein the inner shaping assembly (32) comprises a second flange plate (321) and an expanding core clamp (322), the second flange plate (321) is fixedly connected with the upper end of the spring (313), a first sliding hole and a second sliding hole formed in the second flange plate (321) are respectively matched with the first sliding column (312) and the conical head column (314) in a sliding connection manner, the expanding core clamp (322) is fixedly installed on the second flange plate (321), the expanding core clamp (322) is matched with the conical head column (314) in a contact connection manner, and the second flange plate (321) is connected with the outer shaping assembly (33).

5. The bi-directional processed stator winding shaping apparatus of claim 4 wherein said outer shaping assembly (33) comprises a flange ring (331), a first runner (332), a second runner (333), a first slider (334), a second slider (335), a push block (336), a cradle block (337), and a third flange plate (338).

6. The bidirectional processed stator winding shaping device of claim 5, wherein the flange ring (331) is fixedly mounted on the second flange plate (321), a plurality of first sliding grooves (332) and second sliding grooves (333) are formed in the flange ring (331), a plurality of first sliding blocks (334) and second sliding blocks (335) are respectively and slidably connected with the plurality of first sliding blocks (334) and the plurality of second sliding blocks (335), a plurality of pushing blocks (336) and holding blocks (337) are respectively and fixedly connected with the plurality of first sliding blocks (334) and the plurality of second sliding blocks (335), the pushing blocks (336) are in joint sliding connection with the holding blocks (337), the third flange plate (338) is fixedly mounted on the flange ring (331), inclined grooves are formed in the pushing blocks (336), inclined surfaces matched with the inclined grooves of the pushing blocks (336) in joint sliding connection are formed in the upper end of the first sliding columns (312), the pushing blocks (336) are in sliding connection with the second flange plate (321), and the pushing blocks (336) and the holding blocks (337) are connected with the flange ring (331) through the reset springs.

7. The two-way processed stator winding shaping apparatus of claim 6 wherein said two third flange plates (338) are each provided with a securing slot (339).

8. The bi-directional processed stator winding shaping apparatus of claim 7 wherein said motor stator (4) is disposed between two fixed slots (339).