CN222773944U - Stator lamination detection device - Google Patents

Abstract

The utility model discloses a stator lamination detection device which comprises a detection workbench and a fixing table, wherein the fixing table is fixed in the middle of the top of the detection workbench, a synchronous clamping mechanism is arranged on the detection workbench and surrounds the fixing table, the upper end of the detection workbench is rotatably connected with a rotating base, lifting guide rods are uniformly distributed on the rotating base along the circumferential direction, a partition plate is arranged on the inner wall of the lifting guide rod, a multidirectional detection mechanism is arranged on the lifting guide rod, the synchronous clamping mechanism comprises a guide groove, a distance adjusting screw rod, a distance adjusting sliding block, a fixing plate, a speed reducing motor and a bevel gear, and the multidirectional detection mechanism comprises a lifting sliding block, a cylinder, a linear motor sliding rail, a linear motor sliding table, a ceramic detection contact I and a ceramic detection contact II. The utility model belongs to the technical field of stator lamination detection, and particularly relates to a stator lamination detection device.

Description

Stator lamination detection device

Technical Field

The utility model belongs to the technical field of stator lamination detection, and particularly relates to a stator lamination detection device.

Background

The stator is a major part of the motor and usually comprises a set of coils which generate a magnetic field when the motor is in operation, and the lamination is constructed by stacking a plurality of thin iron sheets, so that eddy current loss can be reduced, the efficiency of the motor can be improved, and the stator lamination needs to be detected in the production process to improve the quality of products.

An existing stator lamination detection device is disclosed in application number CN202221809658.3, and can realize synchronous movement of a plurality of moving blocks through an adjusting component, so that the stator lamination is conveniently detected by a horizontal detection component on the moving block, the position of the plurality of stator laminations is conveniently detected, whether the edges of the plurality of stator laminations are neat is conveniently detected, the height of the stator laminations is conveniently adjusted through the vertical detection component, and whether the plurality of stator laminations are horizontal or not is conveniently detected, so that the stator lamination detection device is convenient to use.

However, in practical use, the stator lamination detection device in the prior art is fixed in structure, and the position capable of being detected cannot be changed, so that the detection result is single, the accuracy is low, the detection range is small due to the fixed structure, and the stator lamination detection device cannot realize fixed detection of stator laminations with different sizes.

Disclosure of utility model

Aiming at the situation, in order to overcome the defects of the prior art, the utility model provides the stator lamination detection device, which effectively solves the problems that the existing stator lamination detection device is fixed in structure and the detection position cannot be changed, so that the detection result has lower accuracy, and simultaneously solves the problems that the stator lamination cannot be comprehensively and multiply detected and the detection range is small.

The technical scheme includes that the stator lamination detection device comprises a detection workbench and a fixing table, wherein the fixing table is fixed in the middle of the top of the detection workbench, a synchronous clamping mechanism is arranged on the detection workbench and surrounds the fixing table, the upper end of the detection workbench is rotatably connected with a rotating base, lifting guide rods are uniformly distributed on the rotating base along the circumferential direction, a partition plate is arranged on the inner wall of the lifting guide rod, and a multidirectional detection mechanism is arranged on the lifting guide rod.

As this scheme improvement, synchronous clamping mechanism includes guide way, roll adjustment screw rod, roll adjustment slider, fixed plate, gear motor and bevel gear, the guide way is along circumferencial direction equipartition on detecting the workstation, the roll adjustment screw rod rotates to be connected in the guide way, roll adjustment slider sliding connection is on the guide way and threaded connection is on the roll adjustment screw rod, the fixed plate passes through the bolt fastening on the roll adjustment slider, gear motor locates detecting the bottom of workstation, gear motor's output shaft is located on the roll adjustment screw rod and is located on the bevel gear, bevel gear on the roll adjustment screw rod and the epaxial bevel gear engagement of gear motor output.

As this scheme improvement, multidirectional detection mechanism includes lift slider, cylinder, linear electric motor slide rail, linear electric motor slip table, ceramic detection contact one and ceramic detection contact two, lift slider sliding connection is on the lift guide arm, the cylinder is located on the lift slider lateral wall, linear electric motor slide rail sliding connection is on the lift guide arm and is located the top of baffle, linear electric motor slip table sliding connection is on the linear electric motor slide rail, ceramic detection contact one is fixed in the lower extreme of linear electric motor slip table, ceramic detection contact two locates the output of cylinder.

As this scheme improvement, the output of cylinder is fixed with the range finding baffle, the upper end of baffle is equipped with laser range finding sensor one, be equipped with laser range finding sensor two on the lift slider lateral wall, and laser range finding sensor two locates the top of cylinder.

As this scheme improvement, the upper end of lift guide arm is equipped with the electricity push rod, and the output of electricity push rod runs through the top and the linear electric motor sliding connection of lift guide arm, the bottom in the lift guide arm is equipped with the lift motor, the output of lift motor is connected with the lift screw, and the other end rotation of lift screw is connected in the bottom of baffle, lift slider threaded connection is on the lift screw.

As this scheme improvement, be equipped with outer ring gear on rotating the lateral wall of base, the last rotation of detection workstation is connected with drive gear, and drive gear meshes in outer ring gear, detection workstation's bottom is equipped with driving motor, and driving motor's output shaft runs through detection workstation and drive gear connection.

As this scheme improvement, rotation base and fixed station are coaxial setting, lift guide arm is perpendicular setting with detection workstation, linear electric motor slide rail is parallel arrangement with detection workstation, range finding baffle is same horizontal plane setting in laser range finding sensor two.

The beneficial effects obtained by the utility model by adopting the structure are as follows:

1. Adopt multidirectional detection mechanism, can realize detecting stator lamination vertical and horizontal size, and the cooperation rotates the base, can realize the adjustment of multidirectional detection mechanism position, conveniently change the detection position, improved the variety and the accuracy of testing result

2. Be equipped with synchronous clamping mechanism, through interval adjustable fixed plate, can realize the fixed to not equidimension stator lamination, cooperation telescopic multidirectional detection mechanism can increase detection device's application scope, has improved the practicality that detects.

Drawings

Fig. 1 is a schematic diagram of an overall structure of a stator lamination detection device according to a first view angle;

FIG. 2 is an enlarged schematic view of a portion A of FIG. 1;

Fig. 3 is a schematic diagram of an overall structure of a second view angle of a stator lamination detection device according to the present utility model;

Fig. 4 is a cross-sectional view of a stator lamination detection apparatus according to the present utility model.

The device comprises a detection workbench, a fixed table, a synchronous clamping mechanism, a rotary base, a lifting guide rod, a baffle plate, a multi-direction detection mechanism, a guide groove, a distance adjusting slide block, a fixed plate, a speed reducing motor, a bevel gear, a 13 lifting slide block, a 14 cylinder, a 15 linear motor slide rail, a 16 linear motor slide table, a 17 ceramic detection contact I, a 18 ceramic detection contact II, a 19 ranging baffle plate, a 20 laser ranging sensor I, a 21 laser ranging sensor II, a 22, an electric push rod, a 23 lifting motor, a 24 lifting screw rod, a 25, an outer gear ring, a 26, a driving gear, a 27, a driving motor, a 28 and a distance adjusting screw rod.

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and all other embodiments obtained by those skilled in the art without making any inventive effort based on the embodiments of the present utility model are within the scope of protection of the present utility model.

As shown in fig. 1, fig. 2, fig. 3 and fig. 4, the stator lamination detection device provided by the utility model comprises a detection workbench 1 and a fixing table 2, wherein the fixing table 2 is fixed in the middle of the top of the detection workbench 1, the detection workbench 1 is provided with a synchronous clamping mechanism 3, the synchronous clamping mechanism 3 is arranged around the fixing table 2, the upper end of the detection workbench 1 is rotationally connected with a rotating base 4, lifting guide rods 5 are uniformly distributed on the rotating base 4 along the circumferential direction, a partition plate 6 is arranged on the inner wall of the lifting guide rods 5, and a multidirectional detection mechanism 7 is arranged on the lifting guide rods 5.

In order to realize the clamping fixation of stator lamination of different sizes, synchronous clamping mechanism 3 includes guide way 8, pitch adjusting screw 28, pitch adjusting slider 9, fixed plate 10, gear motor 11 and bevel gear 12, guide way 8 is along circumference direction equipartition on detection workstation 1, pitch adjusting screw 28 rotates to be connected in guide way 8, pitch adjusting slider 9 sliding connection is on guide way 8 and threaded connection is on pitch adjusting screw 28, fixed plate 10 passes through the bolt fastening on the pitch adjusting slider 9, gear motor 11 locates the bottom of detection workstation 1, bevel gear 12 locates on gear motor 11's the output shaft and locates on the pitch adjusting screw 28, bevel gear 12 on the pitch adjusting screw 28 meshes with bevel gear 12 on gear motor 11 output shaft.

In order to achieve the aims of detecting multiple positions of stator laminations and improving accuracy of detection results, the multidirectional detection mechanism 7 comprises a lifting slide block 13, an air cylinder 14, a linear motor sliding rail 15, a linear motor sliding table 16, a first ceramic detection contact 17 and a second ceramic detection contact 18, wherein the lifting slide block 13 is slidably connected to a lifting guide rod 5, the air cylinder 14 is arranged on the side wall of the lifting slide block 13, the linear motor sliding rail 15 is slidably connected to the lifting guide rod 5 and is arranged above a partition plate 6, the linear motor sliding table 16 is slidably connected to the linear motor sliding rail 15, the first ceramic detection contact 17 is fixed to the lower end of the linear motor sliding table 16, the second ceramic detection contact 18 is arranged at the output end of the air cylinder 14, a ranging baffle 19 is fixed at the output end of the air cylinder 14, a first laser ranging sensor 20 is arranged at the upper end of the partition plate 6, a second laser ranging sensor 21 is arranged on the side wall of the lifting slide block 13, and the second laser ranging sensor 21 is arranged above the air cylinder 14.

In order to enrich the data detected by the stator lamination, the upper end of the lifting guide rod 5 is provided with an electric push rod 22, the output end of the electric push rod 22 penetrates through the top of the lifting guide rod 5 and is connected with the linear motor sliding rail 15, the bottom in the lifting guide rod 5 is provided with a lifting motor 23, the output end of the lifting motor 23 is connected with a lifting screw 24, the other end of the lifting screw 24 is rotationally connected to the bottom of the partition plate 6, and the lifting slide block 13 is in threaded connection with the lifting screw 24.

In order to change the detection position fast, be equipped with outer ring gear 25 on the lateral wall of rotating base 4, be connected with drive gear 26 on the detection workstation 1 rotation, and drive gear 26 meshes in outer ring gear 25, and the bottom of detection workstation 1 is equipped with driving motor 27, and driving motor 27's output shaft runs through detection workstation 1 and is connected with drive gear 26.

As shown in fig. 1 and 4, the rotating base 4 and the fixed table 2 are coaxially arranged, the lifting guide rod 5 and the detection workbench 1 are vertically arranged, the linear motor sliding rail 15 and the detection workbench 1 are parallel, and the ranging baffle 19 is arranged on the same horizontal plane as the second laser ranging sensor 21.

When the device is specifically used, stator laminations are inserted onto the fixed table 2, the gear motor 11 is opened to drive the bevel gear 12 to rotate, under the action of the bevel gear 12, each group of distance-adjusting screw rods 28 synchronously rotate, the distance-adjusting slide blocks 9 which are in threaded connection with the distance-adjusting screw rods 28 slide towards one side of the fixed table 2 along the guide grooves 8 until the outer wall of the stator laminations is clamped by the fixed plate 10, the air cylinders 14 extend until the ceramic detection contact two 18 contacts with the side wall of the stator laminations, the distance between the ceramic detection contact two 18 and the side wall of the stator laminations is measured by the laser distance-measuring sensor two 21, the linear motor slide rail 15 is pushed by the electric push rod 22 to move downwards until the ceramic detection contact one 17 contacts with the upper end of the stator laminations, the distance between the linear motor slide rail 15 is measured by the laser distance-measuring sensor one 20, when the height of the horizontal measurement needs to be adjusted, the lifting motor 23 only needs to be opened to drive the lifting screw rods 24 to rotate, the height of the lifting slide blocks 13 on the lifting screw rods 24 can be adjusted along the direction of the lifting guide rods 5, the height of the ceramic detection contact two 18 can be adjusted, when the horizontal measurement position needs to be adjusted, the linear motor 16 is only needs to be made to be in contact with the ceramic detection contact two sides of the stator laminations, the upper end of the gear 26 is required to be driven to rotate, and the gear 26 is required to be in a rotary position needs to be changed, and the position of the rotary device can be meshed with the stator lamination can be driven to be driven, and the position needs to be detected, and the position of the gear device is required to be driven to be in a rotary device to be in a rotary position to be and a rotary device is required to be and a rotary device.

The utility model and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (7)

1. The stator lamination detection device comprises a detection workbench (1) and a fixing table (2), wherein the fixing table (2) is fixed in the middle of the top of the detection workbench (1), and is characterized in that a synchronous clamping mechanism (3) is arranged on the detection workbench (1), the synchronous clamping mechanism (3) is arranged around the fixing table (2), the upper end of the detection workbench (1) is rotationally connected with a rotation base (4), lifting guide rods (5) are uniformly distributed on the rotation base (4) along the circumferential direction, a partition plate (6) is arranged on the inner wall of the lifting guide rods (5), and a multidirectional detection mechanism (7) is arranged on the lifting guide rods (5).

2. The stator lamination detection device according to claim 1, wherein the synchronous clamping mechanism (3) comprises a guide groove (8), a distance adjusting screw rod (28), a distance adjusting slide block (9), a fixing plate (10), a gear motor (11) and bevel gears (12), the guide groove (8) is uniformly distributed on the detection workbench (1) along the circumferential direction, the distance adjusting screw rod (28) is rotationally connected in the guide groove (8), the distance adjusting slide block (9) is slidingly connected on the guide groove (8) and is in threaded connection on the distance adjusting screw rod (28), the fixing plate (10) is fixed on the distance adjusting slide block (9) through bolts, the gear motor (11) is arranged at the bottom of the detection workbench (1), the bevel gears (12) are arranged on an output shaft of the gear motor (11) and on the distance adjusting screw rod (28), and the bevel gears (12) on the distance adjusting screw rod (28) are meshed with the bevel gears (12) on an output shaft of the gear motor (11).

3. The stator lamination detection device according to claim 2, wherein the multidirectional detection mechanism (7) comprises a lifting slide block (13), an air cylinder (14), a linear motor sliding rail (15), a linear motor sliding table (16), a first ceramic detection contact (17) and a second ceramic detection contact (18), the lifting slide block (13) is slidably connected to the lifting guide rod (5), the air cylinder (14) is arranged on the side wall of the lifting slide block (13), the linear motor sliding rail (15) is slidably connected to the lifting guide rod (5) and is arranged above the partition plate (6), the linear motor sliding table (16) is slidably connected to the linear motor sliding rail (15), the first ceramic detection contact (17) is fixed at the lower end of the linear motor sliding table (16), and the second ceramic detection contact (18) is arranged at the output end of the air cylinder (14).

4. The stator lamination detection device according to claim 3, wherein a ranging baffle plate (19) is fixed at the output end of the air cylinder (14), a first laser ranging sensor (20) is arranged at the upper end of the partition plate (6), a second laser ranging sensor (21) is arranged on the side wall of the lifting sliding block (13), and the second laser ranging sensor (21) is arranged above the air cylinder (14).

5. The stator lamination detection device according to claim 4, wherein an electric push rod (22) is arranged at the upper end of the lifting guide rod (5), the output end of the electric push rod (22) penetrates through the top of the lifting guide rod (5) and is connected with the linear motor sliding rail (15), a lifting motor (23) is arranged at the bottom in the lifting guide rod (5), the output end of the lifting motor (23) is connected with a lifting screw (24), the other end of the lifting screw (24) is rotatably connected to the bottom of the partition plate (6), and the lifting slider (13) is in threaded connection with the lifting screw (24).

6. The stator lamination detection device according to claim 5, wherein an outer gear ring (25) is arranged on the side wall of the rotating base (4), a driving gear (26) is rotatably connected to the detection workbench (1), the driving gear (26) is meshed with the outer gear ring (25), a driving motor (27) is arranged at the bottom of the detection workbench (1), and an output shaft of the driving motor (27) penetrates through the detection workbench (1) and is connected with the driving gear (26).

7. The stator lamination detection device according to claim 6, wherein the rotating base (4) and the fixed table (2) are coaxially arranged, the lifting guide rod (5) and the detection workbench (1) are vertically arranged, the linear motor sliding rail (15) and the detection workbench (1) are parallelly arranged, and the ranging baffle (19) is arranged on the same horizontal plane of the laser ranging sensor II (21).