CN112186987A

CN112186987A - Stator disassembling equipment for waste motor

Info

Publication number: CN112186987A
Application number: CN202011090544.3A
Authority: CN
Inventors: 刘亚康
Original assignee: Dongyang Wulun Electronic Technology Co ltd
Current assignee: Dongyang Wulun Electronic Technology Co ltd
Priority date: 2020-10-13
Filing date: 2020-10-13
Publication date: 2021-01-05

Abstract

The invention discloses a waste motor stator disassembling device which comprises a stabilizing bottom plate, wherein a supporting column and a supporting table are fixedly connected to the upper end surface of the stabilizing bottom plate, the supporting table is positioned on the left side of the supporting column, a compression cavity with an upward opening is arranged in the supporting table, the lower end of the compression cavity is positioned in the stabilizing bottom plate, a spiral gear ring is fixedly connected to the upper end of the supporting table, a bevel gear disc is rotatably connected to the outer circular surface of the supporting table, and a rack cutter is arranged in the bevel gear disc and slides left and right on the upper side of the spiral gear ring; according to the motor stator disassembling device, after the motor stator is clamped, the movable cutting knife is driven to slide by the rotating bevel gear disc and partition the enameled wire, then the enameled wire is separated from the motor stator by the sliding block, the motor stator is pushed away from the device after separation, and then the enameled wire is compressed by the compression sliding block, so that the integration of disassembling the waste motor stator is realized, the middle working process is reduced, and the working efficiency of disassembling the waste motor stator is improved.

Description

Stator disassembling equipment for waste motor

Technical Field

The invention relates to the related field of motors, in particular to stator disassembling equipment of a waste motor.

Background

The motor stator of the waste motor contains a large amount of enameled wires, which are metal resources capable of being recycled, the internal structure of the motor stator is complex, and multiple processes are needed to complete disassembly. The existing stator disassembly is mainly completed through manual operation of simple machinery, the process is complicated and needs a large amount of time, meanwhile, the stator contains lubricating oil, and if the operation is improper, danger is easy to occur, so that the factory for disassembling the existing stator still adopts relatively conservative manual disassembly, the efficiency is low, and a large amount of labor force is consumed.

The invention discloses a waste motor stator disassembling device which can solve the problems.

Disclosure of Invention

In order to solve the problems, the waste motor stator disassembling equipment is designed in the embodiment, and comprises a stabilizing bottom plate, wherein a supporting column and a supporting table are fixedly connected to the upper end surface of the stabilizing bottom plate, the supporting table is positioned on the left side of the supporting column, a compression cavity with an upward opening is arranged in the supporting table, the lower end of the compression cavity is positioned in the stabilizing bottom plate, a spiral toothed ring is fixedly connected to the upper end of the supporting table, a conical toothed disc is rotatably connected to the outer circular surface of the supporting table, a rack cutting knife is arranged in the conical toothed disc in a left-right sliding mode on the upper side of the spiral toothed ring, the lower end surface of the rack cutting knife is meshed with the upper end surface of the spiral toothed ring, a motor stator is placed on the upper end surface of the conical toothed disc, and an enameled wire is wound in the; the left end face of the supporting column is fixedly connected with a supporting plate, the supporting plate is positioned on the upper side of the supporting table, a sliding block is arranged in the supporting plate in a vertically sliding mode, a vertically through guide hole is formed in the sliding block, a sliding rack is arranged in the guide hole in a vertically penetrating and sliding mode, the lower end of the sliding rack is positioned on the lower side of the sliding block and fixedly connected with a connecting block, a left-right through gripper groove with a downward opening is formed in the lower end of the sliding block, two positioning rods are rotatably connected between the front inner wall and the rear inner wall of the gripper groove and are in bilateral symmetry with respect to the sliding rack, linkage gears are rotatably connected to the positioning rods and are meshed with the sliding rack, grippers are fixedly connected to the outer circular face of each linkage gear, and; a linkage cavity with a downward opening is arranged in the supporting column, the lower end of the linkage cavity is positioned in the stabilizing bottom plate, a compression slide block is arranged on the inner wall of the linkage cavity on the left side of one section in the stabilizing bottom plate in a sliding manner, the compression slide block can extend into the compression cavity, a gear cavity with a rightward opening is arranged in the compression slide block, a supporting shaft is rotatably connected between the upper inner wall and the lower inner wall of the gear cavity, a worm is rotatably connected to the right side of the compression slide block on the inner wall on the lower side of the linkage cavity, an elliptic gear and a fixed spring block are fixedly connected to the supporting shaft and the worm, the elliptic gear is positioned on the upper side of the fixed spring block, two elliptic gears are meshed, and the two fixed spring blocks are; the sliding rack upwards slides, and then drive linkage gear revolve, and then grasp the enameled wire through the tongs, the sliding rack stops sliding, later rotate the bevel gear disc, and then drive rack cutting knife opposite direction movement through the spiral ring gear, and then carry out the helical cutting with the lower extreme of enameled wire, the enameled wire lower extreme that cuts away falls into compression chamber downside, later drive the sliding block through linking up the piece and upwards slide, draw out remaining enameled wire in the motor stator, and then accomplished the separation between motor stator and the enameled wire, later drive the sliding block that compresses through the pivoted elliptical gear and slide, and then extrude the enameled wire in the compression chamber, the utilization ratio of compression chamber inner space has been increased.

Beneficially, a motor is fixedly connected to the inner wall of the upper side of the linkage cavity, a power output shaft is dynamically connected to the lower end face of the motor, a connecting bevel gear is fixedly connected to the power output shaft, a fixed shaft is rotatably connected to the inner wall of the front side of the linkage cavity, the rear end of the fixed shaft is fixedly connected with a fixed bevel gear, the fixed bevel gear is meshed with the connecting bevel gear, a connecting handle is rotatably connected to the rear end face of the fixed bevel gear, the rear end of the connecting handle is hinged to a swing rod, a long gear is connected to the motor through a spline at the lower side of the connecting bevel gear, a linkage plate is rotatably connected to the long gear, the lower end of the swing rod is hinged to the front end of the linkage plate, a matching gear is fixedly connected to the upper end of the; the starter motor, and then drive rectangular gear through power output shaft and rotate, drive fixed bevel gear through linking bevel gear simultaneously and rotate, and then drive and link up the handle and rotate, and then drive the linkage board through the pendulum rod and remove, and then drive rectangular gear and slide along power output shaft's direction, when rectangular gear and cooperation gear meshing, drive the worm through the cooperation gear and rotate.

Beneficially, a guide column is fixedly connected to the upper end face of the supporting plate, a vertically through receiving cavity is formed in the guide column, the sliding rack is located in the receiving cavity, a limiting ring is fixedly connected to an outer circular surface of one end of the sliding block in the receiving cavity, an outer circular surface of the limiting ring is abutted to an inner circular surface of the receiving cavity, a driven bevel gear is rotatably connected to the upper end of the guide column, the upper end of the sliding rack is in threaded connection with the driven bevel gear, a synchronizing shaft is rotatably connected to the inner wall of the upper side of the linkage cavity in a penetrating manner, the synchronizing shaft is located on the rear side of the motor, the upper end of the synchronizing shaft is located on the upper side of the supporting column and fixedly connected with a driving bevel gear, the driving bevel gear is meshed with the driven bevel gear, a linking gear is fixedly connected to the lower end; the strip gear drives the linking gear to rotate when being meshed with the linking gear, and then drives the synchronizing shaft to rotate, and then drives the driven bevel gear to rotate through the driving bevel gear, and then drives the sliding rack to slide upwards.

Beneficially, a fixed block is fixedly connected to the inner wall of the left side of the linkage cavity, the fixed block is provided with a spring cavity with a left opening, a push rod is slidably arranged in the spring cavity, the left end of the push rod is located on the left side of the support column and abuts against the outer circular surface of the motor stator, a push spring is fixedly connected between the right end face of the push rod and the inner wall of the right side of the spring cavity, a clamping groove with an upward opening is formed in the push rod, a sliding limiting rod is slidably arranged in the fixed block and above the push rod, the lower end of the sliding limiting rod can extend into the clamping groove, the upper end of the sliding limiting rod is located above the linkage plate and is slidably connected to the rear end of the linkage plate, and a linkage block is fixedly connected to the upper; the linkage plate slides upwards, and then drives the stop lever that slides rebound through the linkage piece, and then makes the lower extreme and the draw-in groove of the stop lever that slides break away from, and then pushes the push rod under the spring action that promotes the spring, and then promotes the motor stator.

Beneficially, a linkage shaft is rotatably connected to the inner wall of the left side of the linkage cavity, the linkage shaft is located on the lower side of the fixed block, the left end of the linkage shaft is located on the left side of the support column, a linkage bevel gear is fixedly connected to the left end of the linkage shaft, the linkage bevel gear is meshed with the bevel gear disc, a worm gear is fixedly connected to the left end of the linkage shaft, and the worm gear is meshed with the linkage block; the worm rotates, and then drives the linkage bevel gear through the universal driving shaft and rotates, and then drives the bevel gear disc and rotates, and then drives the rack cutting knife to slide and cut the enameled wire.

The invention has the beneficial effects that: according to the motor stator disassembling device, after the motor stator is clamped, the movable cutting knife is driven to slide by the rotating bevel gear disc and partition the enameled wire, then the enameled wire is separated from the motor stator by the sliding block, the motor stator is pushed away from the device after separation, and then the enameled wire is compressed by the compression sliding block, so that the integration of disassembling the waste motor stator is realized, the middle working process is reduced, and the working efficiency of disassembling the waste motor stator is improved.

Drawings

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

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic structural diagram of an overall stator disassembling device of a waste motor according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic diagram of B-B of FIG. 1;

FIG. 4 is a schematic diagram of the structure of C-C in FIG. 2;

fig. 5 is a schematic diagram of the structure of D-D in fig. 4.

Detailed Description

The invention will now be described in detail with reference to fig. 1 to 5, for the sake of convenience of description, the following orientations are now defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to stator disassembling equipment for waste motors, which comprises a stable bottom plate 11, wherein a supporting column 20 and a supporting table 48 are fixedly connected to the upper end surface of the stable bottom plate 11, the supporting table 48 is positioned on the left side of the supporting column 20, a compression cavity 12 with an upward opening is arranged in the supporting table 48, the lower end of the compression cavity 12 is positioned in the stable bottom plate 11, a spiral toothed ring 46 is fixedly connected to the upper end of the supporting table 48, a conical toothed disc 45 is rotatably connected to the outer circular surface of the supporting table 48, a rack cutter 44 is arranged in the conical toothed disc 45 and slides left and right on the upper side of the spiral toothed ring 46, the lower end surface of the rack cutter 44 is meshed with the upper end surface of the spiral toothed ring 46, a motor stator 49 is arranged on the upper end surface of the conical toothed disc 45, and an enameled wire 47 is wound in the; a supporting plate 63 is fixedly connected to the left end face of the supporting column 20, the supporting plate 63 is located on the upper side of the supporting table 48, a sliding block 39 is arranged in the supporting plate 63 in a vertically sliding manner, a guide hole 33 which is penetrated up and down is arranged in the sliding block 39, a sliding rack 34 is arranged in the guide hole 33 in a vertically penetrating and sliding manner, the lower end of the sliding rack 34 is positioned at the lower side of the sliding block 39 and fixedly connected with a connecting block 43, the lower end of the sliding block 39 is provided with a left-right through gripper groove 40 with a downward opening, two positioning rods 42 are rotatably connected between the front inner wall and the rear inner wall of the gripper groove 40, the positioning rod 42 is symmetrical left and right about the sliding rack 34, a linkage gear 41 is rotatably connected to the positioning rod 42, the linkage gear 41 is engaged with the sliding rack 34, a gripper 32 is fixedly connected to the outer circular surface of the linkage gear 41, and the gripper 32 is bilaterally symmetrical with respect to the sliding rack 34; a linkage cavity 16 with a downward opening is arranged in the supporting column 20, the lower end of the linkage cavity 16 is located in the stable bottom plate 11, a compression slider 13 is slidably arranged on the inner wall of the left side of one section of the linkage cavity 16 in the stable bottom plate 11, the compression slider 13 can extend into the compression cavity 12, a gear cavity 14 with a rightward opening is arranged in the compression slider 13, a supporting shaft 61 is rotatably connected between the upper inner wall and the lower inner wall of the gear cavity 14, a worm 58 is rotatably connected on the right side of the compression slider 13 on the inner wall of the lower side of the linkage cavity 16, an elliptic gear 15 and a fixed spring block 57 are fixedly connected to the supporting shaft 61 and the worm 58, the elliptic gear 15 is located on the upper side of the fixed spring block 57, the two elliptic gears 15 are meshed, and the two fixed spring blocks 57 are connected through a tension spring 62; sliding rack 34 upwards slides, and then drive linkage gear 41 and rotate, and then grasp enameled wire 47 through tongs 32, sliding rack 34 stops sliding, later rotate bevel gear disc 45, and then drive rack cutting knife 44 opposite displacement through spiral ring gear 46, and then carry out the spiral cutting with enameled wire 47's lower extreme, enameled wire 47 lower extreme that cuts away falls into compression chamber 12 downside, later drive sliding block 39 through linking piece 43 and upwards slide, draw out remaining enameled wire 47 in motor stator 49, and then accomplished the separation between motor stator 49 and the enameled wire 47, later drive compression sliding block 13 through pivoted oval gear 15 and slide, and then extrude enameled wire 47 in compression chamber 12, the utilization ratio of compression chamber 12 inner space has been increased.

Beneficially, a motor 50 is fixedly connected to the inner wall of the upper side of the linkage cavity 16, a power output shaft 60 is dynamically connected to the lower end surface of the motor 50, a connecting bevel gear 51 is fixedly connected on the power output shaft 60, a fixed shaft 54 is rotatably connected on the inner wall of the front side of the linkage cavity 16, a fixed bevel gear 52 is fixedly connected to the rear end of the fixed shaft 54, the fixed bevel gear 52 is engaged with the engaging bevel gear 51, the rear end surface of the fixed bevel gear 52 is rotatably connected with a connecting handle 53, the rear end of the connecting handle 53 is hinged with a swing rod 55, a long gear 59 is splined to the lower side of the engaging bevel gear 51 on the motor 50, the strip gear 59 is rotatably connected with a linkage plate 27, the lower end of the swing rod 55 is hinged with the front end of the linkage plate 27, a mating gear 56 is fixedly connected to the upper end of the worm 58, and the mating gear 56 can be meshed with the strip gear 59; the motor 50 is started, the strip gear 59 is driven to rotate through the power output shaft 60, meanwhile, the fixed bevel gear 52 is driven to rotate through the engaging bevel gear 51, the engaging handle 53 is driven to rotate, the linkage plate 27 is driven to move through the swing rod 55, the strip gear 59 is driven to slide along the direction of the power output shaft 60, and when the strip gear 59 is meshed with the matching gear 56, the worm 58 is driven to rotate through the matching gear 56.

Beneficially, a guide post 38 is fixedly connected to an upper end surface of the support plate 63, a vertically through receiving cavity 35 is arranged in the guide post 38, the sliding rack 34 is located in the receiving cavity 35, a limit ring 36 is fixedly connected to an outer circular surface of one end of the sliding block 39 in the receiving cavity 35, an outer circular surface of the limit ring 36 is abutted against an inner circular surface of the receiving cavity 35, a driven bevel gear 37 is rotatably connected to an upper end of the guide post 38, an upper end of the sliding rack 34 is in threaded connection with the driven bevel gear 37, a synchronizing shaft 30 is rotatably connected to an inner wall of an upper side of the linkage cavity 16 in a penetrating manner, the synchronizing shaft 30 is located at a rear side of the motor 50, an upper end of the synchronizing shaft 30 is located at an upper side of the support post 20 and is fixedly connected with a driving bevel gear 31, the driving bevel gear 31 is engaged with the driven bevel gear 37, and a lower end, the engaging gear 29 may be engaged with the strip gear 59; when the strip gear 59 is meshed with the engaging gear 29, the engaging gear 29 is driven to rotate, so that the synchronizing shaft 30 is driven to rotate, the driven bevel gear 37 is driven to rotate through the driving bevel gear 31, and the sliding rack 34 is driven to slide upwards.

Beneficially, a fixed block 22 is fixedly connected to an inner wall of the left side of the linkage cavity 16, the fixed block 22 is provided with a spring cavity 23 with a left opening, a push rod 21 is slidably arranged in the spring cavity 23, the left end of the push rod 21 is located at the left side of the support column 20 and abuts against an outer circular surface of the motor stator 49, a push spring 24 is fixedly connected between the right end surface of the push rod 21 and the inner wall of the right side of the spring cavity 23, a clamping groove 25 with an upward opening is arranged in the push rod 21, a sliding limiting rod 26 is slidably arranged on the upper side of the push rod 21 in the fixed block 22, the lower end of the sliding limiting rod 26 can extend into the clamping groove 25, the upper end of the sliding limiting rod 26 is located on the upper side of the linkage plate 27 and is slidably connected to the rear end of the linkage plate 27, and a linkage block 28; the linkage plate 27 slides upwards, and then drives the sliding limiting rod 26 to move upwards through the linkage block 28, so that the lower end of the sliding limiting rod 26 is separated from the clamping groove 25, and then the push rod 21 is pushed under the elastic action of the push spring 24, and further the motor stator 49 is pushed.

Beneficially, a linkage shaft 18 is rotatably connected to the inner wall of the left side of the linkage cavity 16, the linkage shaft 18 is located at the lower side of the fixed block 22, the left end of the linkage shaft 18 is located at the left side of the support column 20, a linkage bevel gear 17 is fixedly connected to the left end of the linkage shaft 18, the linkage bevel gear 17 is meshed with the bevel gear disc 45, a worm gear 19 is fixedly connected to the left end of the linkage shaft 18, and the worm gear 19 is meshed with the linkage block 28; the worm 58 rotates to drive the linkage bevel gear 17 to rotate through the linkage shaft 18, and further drive the bevel gear disk 45 to rotate, and further drive the rack cutter 44 to slide and cut the enameled wire 47.

The following describes in detail the use steps of the waste motor stator dismantling device with reference to fig. 1 to 5:

initially, the gripper 32 is in a horizontal state, the lower end of the enameled wire 47 extends into the compression cavity 12 and is located on the lower side of the rack cutter 44, the push rod 21 is abutted on the outer circular surface of the support platform 48, the lower end surface of the limit ring 36 is abutted on the inner wall of the lower side of the accommodating cavity 35, the rack cutter 44 is located at a limit position far away from the compression cavity 12, the lower end of the sliding limit rod 26 is located in the clamping groove 25, the upper end surface of the connecting block 43 is not in contact with the lower end surface of the sliding block 39, the short shafts of the two elliptic gears 15 are on the same straight line, the left end surface of the compression sliding block 13 is flush with the inner wall of the right side of the compression cavity 12, and the strip gear.

Starting the motor 50, driving the strip gear 59 to rotate through the power output shaft 60, driving the synchronizing shaft 30 to rotate through the connecting gear 29, driving the driven bevel gear 37 to rotate through the driving bevel gear 31, driving the sliding rack 34 to move upwards, driving the gripper 32 to rotate through the linkage gear 41, clamping the enameled wire 47, fixing the motor stator 49, and simultaneously abutting the upper end face of the connecting block 43 against the lower end face of the sliding block 39; the power output shaft 60 rotates and drives the engaging bevel gear 51 to rotate, and then drives the engaging handle 53 to rotate through the fixed bevel gear 52, and further drives the linkage plate 27 to move downwards through the swing rod 55, and further drives the strip gear 59 to move downwards, so that the strip gear 59 is disengaged from the engaging gear 29, and further the engaging gear 29 stops rotating, the strip gear 59 continues to move downwards, when the strip gear 59 moves to the engagement gear 56, the strip gear 56 is driven to rotate, and further the worm 58 drives the worm wheel 19 to rotate, and further the linkage bevel gear 17 is driven to rotate through the linkage shaft 18, and further drives the bevel gear disc 45 to rotate, the bevel gear disc 45 rotates and simultaneously drives the rack cutters 44 to rotate, and further under the driving of the helical gear ring 46, the two rack cutters 44 move towards the axis of the compression cavity 12, and further the lower ends of the enameled wires 47 are cut through the edges of the rack cutters 44, the lower end of the cut enameled wire 47 falls into the compression cavity 12; the worm 58 rotates and simultaneously drives the elliptic gears 15 to rotate, when the long axes of the two elliptic gears 15 are on the same straight line, the right elliptic gear 15 pushes the left elliptic gear 15 to move leftwards and stretch the tension spring 62, the support shaft 61 drives the compression slide block 13 to slide leftwards, and further extrudes the enameled wire 47 in the compression cavity 12, meanwhile, the two elliptic gears 15 used under the action of the tension spring 62 are always meshed and drive the compression slide block 13 to slide leftwards and rightwards in a reciprocating manner while the elliptic gears 15 rotate, so that the enameled wire 47 in the compression cavity 12 is repeatedly extruded, the space utilization rate in the compression cavity 12 is improved, and more enameled wires 47 can be accommodated; when the connecting handle 53 rotates to the lower limit position, the connecting handle starts to rotate upwards, so that the linkage plate 27 is driven to move upwards, the strip gear 59 is driven to slide upwards, and when the strip gear 59 is disengaged from the matching gear 56, the matching gear 56 stops rotating, so that the worm 58 stops rotating; when the strip gear 59 moves upwards to be meshed with the engaging gear 29 again, the engaging gear 29 is driven to rotate again, the sliding rack 34 is driven to move upwards again, the sliding block 39 is driven to move upwards through the engaging block 43, the enameled wire 47 is driven to move upwards through the handle 32, when the upper end face of the motor stator 49 abuts against the lower end face of the supporting plate 63, the motor stator 49 stops moving, the enameled wire 47 continues to move upwards, the enameled wire 47 is separated from the motor stator 49, and the motor stator 49 falls on the upper end face of the bevel-tooth disc 45; when the upper end of the linkage plate 27 contacts with the lower end face of the linkage block 28, the linkage block 28 is driven to move upwards together, and then the sliding limiting rod 26 is driven to move upwards, when the lower end of the sliding limiting rod 26 is separated from the clamping groove 25, the push rod 21 is pushed out leftwards under the action of the elastic force of the push spring 24, and then the motor stator 49 is pushed leftwards to the left side of the stable bottom plate 11, then the motor 50 is stopped and the motor 50 is reversed, and then the driven bevel gear 37 drives the sliding rack 34 to move downwards and enable the gripper 32 to be restored to the horizontal state, and meanwhile, the enameled wire 47 gripped by the gripper 32 falls into the compression cavity 12, and the motor 50 is stopped; the next motor stator 49 is then placed on the bevel disk 45 and the push rod 21 is restored to the initial state by the motor stator 49, thereby being ready for the next machining.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides an equipment is disassembled to stator of old and useless motor, includes the stabilising baseplate, its characterized in that: the upper end face of the stabilizing bottom plate is fixedly connected with a supporting column and a supporting table, the supporting table is located on the left side of the supporting column, a compression cavity with an upward opening is arranged in the supporting table, the lower end of the compression cavity is located in the stabilizing bottom plate, a spiral toothed ring is fixedly connected to the upper end of the supporting table, a bevel gear disc is rotatably connected to the outer circular face of the supporting table, a rack cutter is arranged in the bevel gear disc and slides left and right on the upper side of the spiral toothed ring, the lower end face of the rack cutter is meshed with the upper end face of the spiral toothed ring, a motor stator is placed on the upper end face of the bevel gear disc, and an enameled wire is wound in; the left end face of the supporting column is fixedly connected with a supporting plate, the supporting plate is positioned on the upper side of the supporting table, a sliding block is arranged in the supporting plate in a vertically sliding mode, a vertically through guide hole is formed in the sliding block, a sliding rack is arranged in the guide hole in a vertically penetrating and sliding mode, the lower end of the sliding rack is positioned on the lower side of the sliding block and fixedly connected with a connecting block, a left-right through gripper groove with a downward opening is formed in the lower end of the sliding block, two positioning rods are rotatably connected between the front inner wall and the rear inner wall of the gripper groove and are in bilateral symmetry with respect to the sliding rack, linkage gears are rotatably connected to the positioning rods and are meshed with the sliding rack, grippers are fixedly connected to the outer circular face of each linkage gear, and; be equipped with the decurrent linkage chamber of opening in the support column, the lower extreme in linkage chamber is located in the PMKD, the linkage chamber in one section left side inner wall in the PMKD slides and is equipped with the compression slider, the compression slider can stretch into the compression intracavity, be equipped with opening right gear chamber in the compression slider, it is connected with the back shaft to rotate between the inside wall about the gear chamber, on linkage chamber downside inner wall in the right side of compression slider rotates and is connected with the worm, the back shaft with equal rigid coupling has oval gear, rotation to be connected with the fixed spring piece on the worm, oval gear is located the upside and two of fixed spring piece oval gear engagement, two connect through tension spring between the fixed spring piece.

2. The stator disassembling equipment for waste motors according to claim 1, wherein: the utility model discloses a linkage chamber, including linkage chamber, fixed axis, fixed bevel gear, linking handle, linkage chamber.

3. The stator disassembling equipment for waste motors according to claim 1, wherein: the utility model discloses a motor, including backup pad, guide post, slip rack, sliding block, link chamber, synchronizing shaft, connecting gear, connecting.

4. The stator disassembling equipment for waste motors according to claim 1, wherein: the rigid coupling has the fixed block on the linkage chamber left side inner wall, the fixed block is equipped with the opening spring chamber to the left, the slip of spring intracavity is equipped with the push rod, the left end of push rod is located the left side of support column and contradict in on motor stator's the outer disc, the push rod right-hand member face with the promotion spring has been linked firmly between the spring chamber right side inner wall, be equipped with the ascending draw-in groove of opening in the push rod, the fixed block in the upside of push rod slides and is equipped with the slip gag lever post, the lower extreme of slip gag lever post can stretch into in the draw-in groove, the upper end of slip gag lever post is located the upside and the sliding connection of linkage plate in the rear end of linkage plate, the upper end rigid coupling of slip gag lever.

5. The stator disassembling equipment for waste motors according to claim 1, wherein: the linkage cavity comprises a support column, a linkage cavity, a linkage shaft, a bevel gear disc, a worm wheel, a linkage block, a linkage bevel gear, a bevel gear disc, a linkage shaft, a linkage bevel gear, a bevel gear disc.