CN116388493B - Electrostatic coating machine for motor manufacturing - Google Patents

Abstract

The invention relates to the technical field of electrostatic coating machines, in particular to an electrostatic coating machine for motor manufacturing, which comprises a positioning structure, a conveying structure, a stirring structure, a resisting structure, a moving structure, a clamping structure, a fixing structure, a rotating structure, a mounting structure, an electrostatic coating machine body and a screw rod.

Description

Electrostatic coating machine for motor manufacturing

Technical Field

The invention relates to the technical field of electrostatic coating machines, in particular to an electrostatic coating machine for motor manufacturing.

Background

The motor rotor can be coated with a layer of insulating paint through an electrostatic coating machine in the production process, a certain amount of insulating paint is filled in gaps between winding layers or grooves, so that the whole winding is insulated, after being integrated into a whole, a compact, smooth and complete continuous paint film is formed on the upper surface of a workpiece, and the heat resistance, the heat conductivity, the electromagnetic strength, the mechanical strength and the corrosion resistance of the whole insulating structure are improved.

However, before the electrostatic coating machine coats the motor rotor, the insert rod is firstly inserted into the motor rotor, then two ends of the insert rod are placed on two screw rods on the electrostatic coating machine, the motor rotor moves from one end of the coating machine to the other end of the coating machine along with the simultaneous rotation of the two screw rods, and coating is completed in the moving process.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides an electrostatic coating machine for motor manufacturing.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides an electrostatic coating machine for motor manufacturing, includes electrostatic coating machine body, be equipped with location structure on the electrostatic coating machine body, be equipped with conveying structure on the electrostatic coating machine body, be equipped with on the electrostatic coating machine body and keep out the structure, keep out to be equipped with on the structure and stir the structure, be equipped with the moving structure on the electrostatic coating machine body, be equipped with screens structure on the moving structure, be equipped with fixed knot structure on the moving structure, be equipped with rotating structure on the moving structure, be equipped with the screw rod on the electrostatic coating machine body, be equipped with mounting structure on the screw rod;

specifically, keep out the structure and include the backup pad, fixedly connected with backup pad on the static coating machine body, can dismantle through a plurality of bolts in the backup pad and be connected with the cover, sliding connection has two baffles in the backup pad, two guide bars of fixedly connected with on the cover, the one end threaded connection of guide bar has first dog, sliding connection has the baffle on the guide bar, the outside cover of guide bar is equipped with first spring, the one end of first spring is contradicted in first dog and the other end is contradicted in the cover, be equipped with first recess on the baffle.

Specifically, stir the structure and include electric putter, install electric putter on the cover of connection, electric putter's tip fixedly connected with spliced pole, it is connected with the adapter sleeve to rotate on the spliced pole, fixedly connected with support the pole on the adapter sleeve, fixedly connected with first guiding axle and fixedly connected with guide post in the backup pad, guide post sliding connection is in the spliced pole.

Specifically, the conveying structure comprises a supporting table, the supporting table is fixedly connected to the electrostatic coating machine body, a conveying groove is formed in the supporting table, the top surface of the supporting table is obliquely arranged, one end of the section of the screw rod is obliquely arranged, and the inclination of the top surface of the supporting table is smaller than that of the section of the end part of the screw rod.

Specifically, the mobile structure includes the pneumatic cylinder, install the pneumatic cylinder on the static coating machine body, the tip fixedly connected with ejector pad of pneumatic cylinder, ejector pad sliding connection is in first slider, be equipped with the spout on the static coating machine body, sliding fit between first slider and the spout.

Specifically, the screens structure includes the second slider, sliding connection has second slider and sliding connection to have the fixture block on the first slider, fixture block sliding connection is in the second slider, fixedly connected with second spring between second slider and the fixture block, be equipped with first draw-in groove and be equipped with the second draw-in groove on the static coating machine body, the block between one end of fixture block and the first draw-in groove, fixedly connected with second guiding axle on the second slider, be equipped with first guiding groove on the ejector pad, the one end of second guiding axle extends to the inside of first guiding groove and with sliding connection between the ejector pad.

Specifically, fixed knot constructs including the bull stick, rotate on the first slider and be connected with the bull stick, sliding connection has second dog and sliding connection to have the head rod on the bull stick, head rod fixedly connected with second dog, it has the third spring to contradict between second dog and the first slider, contradict between second dog and the ejector pad, sliding connection has two clamping bars on the bull stick, fixedly connected with rack on the clamping bar, two mesh between rack and the same gear, gear rotation is connected in the bull stick, one of them clamping bar fixed connection in the head rod.

Specifically, one end of the second stop block is in a conical structure, and the second stop block is perpendicular to the first connecting rod.

Specifically, the rotating structure comprises a second guide groove, the electrostatic coating machine body is provided with the second guide groove, a third sliding block is connected in the second guide groove in a sliding mode, a second connecting rod is connected to the third sliding block in a rotating mode, and the second connecting rod is connected to the rotating rod in a rotating mode.

Specifically, mounting structure includes the inserted bar, two a plurality of inserted bars have been placed between the screw rod, sliding connection has a plurality of butt plates on the inserted bar, sliding connection has two fourth sliders on the inserted bar, the one end of fourth slider is contradicted in a plurality of butt plates, it has the fourth spring to contradict between the other end of fourth slider and the inserted bar, be equipped with the second recess on the inserted bar.

Specifically, the location structure includes the locating plate, fixedly connected with two locating plates on the static coating machine body, be equipped with the constant head tank on the locating plate, be equipped with a plurality of openings on the constant head tank.

The beneficial effects of the invention are as follows:

(1) According to the electrostatic coating machine for manufacturing the motor, after the surface of the motor rotor is coated, the motor rotor moves to one end of the screw along with the rotation of the two screws, and because one end of the section of the screw is of a trapezoid structure, when the mounting structure moves at the end of the screw, the height of the motor rotor is reduced, so that the bottom end of the motor rotor is contacted with the conveying structure and separated from the screw, and because the outer side of the motor rotor is of a circular structure and the top end of the conveying structure is obliquely arranged, the motor rotor rolls on the conveying structure under the action of gravity, the motor rotor can be blocked by the blocking structure in the rolling process, a plurality of motor rotors and the conveying structure can be relatively static through the blocking of the blocking structure, and therefore the mounting structure can be conveniently removed from the motor rotor.

(2) According to the electrostatic coating machine for manufacturing the motor, after the withstanding structure withstands a plurality of motor rotors, the moving structure is started, and under the action of the clamping structure, the moving structure firstly drives the plurality of fixing structures to clamp the mounting structure, after the clamping is completed, the moving structure moves on the electrostatic coating machine body, so that the mounting structure is driven to deviate from the motor rotors to move, the mounting structure is separated from the motor rotors, after the mounting structure is separated from the motor rotors, the fixing structure is driven to rotate by a certain angle by the rotating structure, so that the plurality of mounting structures can be conveniently dropped into the storage device to be stored when the fixing structure is released from fixing the mounting structure, and when the fixing structure is rotated by a certain angle, the fixing structure can be automatically released from fixing the plurality of mounting structures, so that the plurality of mounting structures are dropped into the storage device to be stored, the automatic disassembly of the mounting structure and the motor rotors is realized, the manual disassembly is avoided, the time is shortened, and the efficiency is improved.

(3) According to the electrostatic coating machine for motor manufacturing, when the motor rotor is required to be coated, the mounting structure passes through the motor rotor at first, the mounting structure can be placed on the two screw rods along the positioning structure after the motor rotor is connected with the mounting structure, the mounting structure can be prevented from being placed askew when being placed through the positioning structure, the mounting structure is prevented from falling off the screw rods in the conveying process, the using stability is improved, and the placement direction is prevented from being wrong when the mounting structure is placed through the positioning structure, so that the subsequent mounting structure and the motor rotor are convenient to detach and separate.

Drawings

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

FIG. 1 is a schematic view of the overall structure of a preferred embodiment of an electrostatic coating machine for manufacturing an electric motor according to the present invention;

FIG. 2 is an enlarged schematic view of the portion A shown in FIG. 1;

FIG. 3 is an enlarged schematic view of the B-section structure shown in FIG. 1;

FIG. 4 is an enlarged schematic view of the structure of the portion C shown in FIG. 3;

FIG. 5 is an enlarged schematic view of the structure of the portion D shown in FIG. 1;

FIG. 6 is a schematic diagram of a connection structure between a connection cover and an electric push rod according to the present invention;

FIG. 7 is an enlarged schematic view of the E-section structure shown in FIG. 6;

fig. 8 is a schematic structural view of a connecting sleeve of the present invention;

FIG. 9 is a schematic view of a connection structure of a clamping bar and a rack of the present invention;

FIG. 10 is a schematic diagram of a connection structure between a first slider and a hydraulic cylinder according to the present invention;

fig. 11 is an enlarged schematic view of the F-section structure shown in fig. 10;

fig. 12 is a schematic diagram of a connection structure between a plunger and a retaining plate according to the present invention.

In the figure: 1. a positioning structure; 101. a positioning plate; 102. a positioning groove; 2. a conveying structure; 201. a support table; 202. a conveying trough; 3. a toggle structure; 301. an electric push rod; 302. a connecting column; 303. a guide post; 304. connecting sleeves; 305. a supporting rod; 306. a first guide shaft; 4. a resisting structure; 401. a support plate; 402. a connection cover; 403. a baffle; 404. a guide rod; 405. a first stopper; 406. a first spring; 407. a first groove; 5. a moving structure; 501. a hydraulic cylinder; 502. a first slider; 503. a pushing block; 6. a clamping structure; 601. a first guide groove; 602. a second guide shaft; 603. a second slider; 604. a clamping block; 605. a second spring; 606. a first clamping groove; 607. a second clamping groove; 7. a fixed structure; 701. a rotating rod; 702. a second stopper; 703. a third spring; 704. a first connecting rod; 705. a clamping rod; 706. a rack; 707. a gear; 8. a rotating structure; 801. a third slider; 802. a second guide groove; 803. a second connecting rod; 9. a mounting structure; 901. a rod; 902. a retaining plate; 903. a fourth slider; 904. a fourth spring; 905. a second groove; 10. an electrostatic coater body; 11. and (3) a screw.

Detailed Description

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

As shown in fig. 1-12, the electrostatic coater for manufacturing a motor according to the present invention comprises an electrostatic coater body 10, wherein a positioning structure 1 is arranged on the electrostatic coater body 10, a conveying structure 2 is arranged on the electrostatic coater body 10, a resisting structure 4 is arranged on the electrostatic coater body 10, a stirring structure 3 is arranged on the resisting structure 4, a moving structure 5 is arranged on the electrostatic coater body 10, a clamping structure 6 is arranged on the moving structure 5, a fixing structure 7 is arranged on the moving structure 5, a rotating structure 8 is arranged on the moving structure 5, a screw 11 is arranged on the electrostatic coater body 10, and a mounting structure 9 is arranged on the screw 11;

specifically, the blocking structure 4 comprises a supporting plate 401, the electrostatic coater body 10 is fixedly connected with the supporting plate 401, the supporting plate 401 is detachably connected with a connecting cover 402 through a plurality of bolts, the supporting plate 401 is slidably connected with two baffles 403, the connecting cover 402 is fixedly connected with two guide rods 404, one ends of the guide rods 404 are in threaded connection with a first stop block 405, the guide rods 404 are slidably connected with the baffles 403, a first spring 406 is sleeved outside the guide rods 404, one end of the first spring 406 is abutted against the first stop block 405 and the other end is abutted against the connecting cover 402, a first groove 407 is arranged on the baffles 403, the toggle structure 3 comprises an electric push rod 301, install electric putter 301 on the cover 402, electric putter 301's tip fixedly connected with spliced pole 302, rotationally be connected with adapter sleeve 304 on the spliced pole 302, fixedly connected with butt pole 305 on the adapter sleeve 304, fixedly connected with first guiding axle 306 and fixedly connected with guide post 303 on the backup pad 401, guide post 303 sliding connection is in spliced pole 302, conveying structure 2 includes brace table 201, fixedly connected with brace table 201 on the electrostatic coating machine body 10, be equipped with conveyer trough 202 on the brace table 201, the top surface of brace table 201 is the slope setting, the one end of screw rod 11 cross-section is the slope setting, the gradient of brace table 201 top surface is less than the gradient of screw rod 11 tip cross-section, namely: when the motor rotor is coated and then moves to the end parts of the screw rods 11 under the action of one baffle plate 403, the end parts of the motor rotors 201 are enabled to move to the end parts of the screw rods 11 under the action of gravity, so that the motor rotors are enabled to be positioned on the supporting table under the action of gravity, the motor rotors 201 are enabled to be stopped by one baffle plate 403 in the rolling process, the motor rotors are enabled to be positioned on the supporting table at rest, the follow-up inserting rods 901 are enabled to be conveniently taken out, when a part of inserting rods 901 are taken off from the motor stators, the electric push rods 301 extend to drive the other baffle plate 403 to move towards the motor rotors, the first springs 406 extend, the guide rods 404 play a guiding role on the baffle plate 403 in the moving process of the baffle plate 403, when the other baffle plate 403 moves to be abutted against the first baffle plate 405, the end parts of the motor rotors are just abutted against one motor rotors 304, the electric push rods 301 extend, the end parts of the electric push rods 403 are abutted against one baffle plate 403, the other baffle plate 403 are separated from the end parts of the other baffle plate 403, the electric push rods are abutted against one baffle plate 304, the other baffle plate 403 rotate, the one baffle plate is abutted against the other baffle plate 304 is retracted, the other baffle plate 301 is retracted, the one baffle plate 304 is retracted, the electric push rods 304 is retracted, and the other baffle rods are retracted, the end parts of the other baffle plates 403 are separated from the motor rotors, and the motor rotors are retracted, and the end parts of the motor rotors are separated from the first baffle plate 403, and move, and the motor rotors are separated from the motor rotors, and move, and are in the motor rotors, and are in the process, and are in a direction, and are contacted. So that one of the baffles 403 does not resist the motor rotor from which the inserted bar 901 has been removed, so that a plurality of motor rotors from which the inserted bar 901 has been removed continue to roll along the conveying groove 202 and finally fall into the collecting device for collection, thereby facilitating collection of the coated motor rotor, and then the electric push rod 301 can be made to repeat the above actions to make one of the baffles 403 collide with the motor rotor from which the inserted bar 901 has not been removed, and make the other baffle 403 not collide with the motor rotor, thereby facilitating separation between the following motor rotor and the inserted bar 901.

Specifically, the moving structure 5 includes a hydraulic cylinder 501, the electrostatic coater body 10 is mounted with the hydraulic cylinder 501, the end of the hydraulic cylinder 501 is fixedly connected with a push block 503, the push block 503 is slidably connected with a first slider 502, the electrostatic coater body 10 is provided with a chute 504, the first slider 502 is slidably matched with the chute 504, the clamping structure 6 includes a second slider 603, the first slider 502 is slidably connected with a second slider 603 and is slidably connected with a clamping block 604, the clamping block 604 is slidably connected with a second slider 603, a second spring 605 is fixedly connected between the second slider 603 and the clamping block 604, the electrostatic coater body 10 is provided with a first clamping groove 606 and is provided with a second clamping groove 607, one end of the push block 604 is engaged with the first clamping groove 606, the second slider 603 is fixedly connected with a second guide shaft 602, one end of the second guide shaft 602 extends to the inside the first guide groove 601 and is slidably connected with the push block 603, the second slider is slidably connected with a clamping block 604, the second slider 604 is slidably connected with a second clamping block 702, the second clamping block 701 is rotatably connected with a second clamping block 706, a second rack-and is rotatably connected with a second clamping block 704, a second rack-and is rotatably connected with a second clamping block 706, a second rack-and a rack-shaped clamp structure 706 is fixedly connected with the second clamping block 702, and is rotatably connected with a rack-shaped structure 706, and is fixedly connected with a rack-shaped structure. The second block 702 is perpendicular to the first connecting rod 704, the rotating structure 8 includes a second guiding groove 802, the electrostatic coater body 10 is provided with the second guiding groove 802, a third sliding block 801 is slidably connected in the second guiding groove 802, a second connecting rod 803 is rotatably connected to the third sliding block 801, and the second connecting rod 803 is rotatably connected to the rotating rod 701, namely: when the inserting rod 901 needs to be removed from the electronic rotor, the hydraulic cylinder 501 is started and the hydraulic cylinder 501 is extended, because the clamping block 604 is clamped with the electrostatic coating machine body 10, the first sliding block 502 cannot slide under the thrust of the hydraulic cylinder 501, the hydraulic cylinder 501 is extended to drive the pushing block 503 to slide in the first sliding block 502, the pushing block 503 can abut against the second stop block 702 to move in the sliding process of the first sliding block 502, the second stop block 702 drives one of the clamping rods 705 to move through the first connecting rod 704, one of the clamping rods 705 drives one of the racks 706 to move, one of the racks 706 drives the gear 707 to move, the gear 707 rotates to drive the other rack 706 to move, so that the two clamping rods 705 simultaneously move towards the second groove 905 on the inserting rod 901, the second guide shaft 602 is also driven through the first guide groove 601 in the moving process of the pushing block 503, the second guide shaft 602 drives the second slide block 603 to move, the second slide block 603 drives the clamping block 604 to move away from the first clamping groove 606 through the second spring 605, when the two clamping rods 705 are positioned in the second groove 905 and clamp the inserting rods 901, the end parts of the clamping blocks 604 are separated from the first clamping groove 606, and at the moment, the axle center of the second stop block 702 and the axle center of the rotating rod 701 are on the same straight line, so that the position of the second stop block 702 is not changed when the rotating rod 701 rotates, then the hydraulic cylinder 501 stretches to drive the first slide block 502 to slide in the sliding groove 504, the first slide block 502 moves to drive the third slide block 801 to slide in the second guide groove 802 through the second connecting rod 803, and simultaneously, the two clamping rods 705 clamp the inserting rods 901 to move away from the motor rotor, thereby separating the inserting rods 901 from the electronic rotors, when the third sliding block 801 moves to the turning position of the second guide groove 802 after the inserting rod 901 and the motor rotor are separated, at this time, along with the movement of the third sliding block 801 in the second guide groove 802, the rotating rod 701 rotates on the first sliding block 502, so that a plurality of inserting rods 901 turn to a storage device, after the rotating rod 701 rotates by a certain angle, the first sliding block 502 continues to move, the rotating rod 701 can not rotate, when the end part of the clamping block 604 moves to the second clamping groove 607, the hydraulic cylinder 501 stops stretching and shrinking, at the moment, the end part of the clamping block 604 can enter the inside of the second clamping groove 607, the second spring 605 shrinks to drive the second stop block 702 to move, the second stop block 702 moves to drive one clamping rod 705 to move, at the moment, the two clamping rods 705 are mutually far away, so that the clamping of the inserting rods 901 can fall into the storage device under the action of gravity to be collected, thereby realizing the automatic separation of the inserting rods 901 and the motor rotor, the manual disassembly time is avoided, the efficiency is improved, the electrostatic coating machine 10 in the body of the first sliding block 502 is reset, and the reset machine 605 is prevented from moving towards the second sliding block 502 under the action of the first sliding block 603, and the reset spring 605 is prevented from shrinking due to the reset of the first sliding block 502.

Specifically, the mounting structure 9 includes the inserted bar 901, two a plurality of inserted bars 901 have been placed between the screw rod 11, sliding connection has a plurality of butt plates 902 on the inserted bar 901, sliding connection has two fourth sliders 903 on the inserted bar 901, the one end of fourth sliders 903 is contradicted in a plurality of butt plates 902, contradict between the other end of fourth sliders 903 and the inserted bar 901 has fourth spring 904, be equipped with the second recess 905 on the inserted bar 901, location structure 1 includes locating plate 101, fixedly connected with two locating plates 101 on the electrostatic coating machine body 10, be equipped with constant head tank 102 on the locating plate 101, be equipped with a plurality of openings on the constant head tank 102, namely: can insert the inserted bar 901 when needs carry out the coating to motor rotor in the motor rotor, can contradict a plurality of butt plates 902 motion at the in-process that the inserted bar 901 inserted motor rotor, butt plate 902 can contradict the motion of fourth slider 903, two fourth springs 904 shrink, stop inserting the inserted bar 901 when contradicting between the arch in motor rotor's one side and inserted bar 901 middle part, realize the grafting between inserted bar 901 and the electron rotor this moment, can contradict between a plurality of butt plates 902 and the motor rotor's the inboard under the effect of two fourth springs 904 elasticity, thereby effectually avoid taking place to rotate between inserted bar 901 and the motor rotor, stability is improved, can place the both ends of inserted bar 901 respectively in two relative openings on constant head tank 102 after the installation of inserted bar 901 and motor rotor is accomplished, and place the inserted bar 901 along constant head tank 102 on two screw rods 11, thereby can prevent under the effect of constant head tank 102 that the inserted bar 901 from placing crooked condition from taking place, avoided inserted bar 901 to drop from screw rod 11 in the in-process of carrying, and consequently, and the stability has been improved, and the diameter of two opposite opening of two large and small diameter of inserted bar 901 can be guaranteed to be placed between two different diameters of motor 901 and the opposite end of motor rotor 11, thereby can be placed consistently after the two large and small diameter of the motor 901 is guaranteed.

When the electric paint coating machine is used, the inserted rod 901 can be inserted into the motor rotor when the motor rotor is required to be coated, a plurality of abutting plates 902 can be abutted against to move in the process of inserting the inserted rod 901 into the motor rotor, the abutting plates 902 can be abutted against a fourth sliding block 903 to move, two fourth springs 904 are contracted, the inserted rod 901 is stopped when one side of the motor rotor is abutted against a bulge in the middle of the inserted rod 901, the inserted rod 901 and the electronic rotor are inserted at the moment, the abutting of the inserted rod 901 and the inner side of the motor rotor is realized under the action of elastic force of the two fourth springs 904, so that the rotation of the inserted rod 901 and the motor rotor is effectively avoided, the stability is improved, two ends of the inserted rod 901 can be respectively placed into two opposite openings on a positioning groove 102 after the inserted rod 901 and the motor rotor are installed, the inserted rod 901 is placed on two screws 11 along the positioning groove 102, the situation that the inserted rod 901 is askew is prevented under the action of the positioning groove 102 is avoided, the inserted rod 901 is prevented from falling from the screw 11 in the conveying process, the stability is improved, the two opposite to the two opposite openings of the two opposite sides of the motor rotor 901 can be placed at the two opposite sides of the positioning groove 102, and the two opposite sides of the motor rotor 1 can be placed under the two opposite to the two opposite sides, and the diameter of the two opposite sides of the motor rotor 1 can be conveniently placed into the two opposite opening sides to the two opposite sides to the position opening 1 to the position end 1 to be coated with the diameter 1;

when the motor rotor is coated and then moves to the end parts of the screw rods 11 under the action of the two screw rods 11, the height of the inserted link 901 is reduced in the rolling process of the screw rods 11 due to the trapezoid structure of the cross section of the end parts of the screw rods 11, so that the bottom end of the motor rotor is contacted with the supporting table 201, the top end of the supporting table 201 is obliquely arranged, the outer side of the electronic rotor is in a circular structure, the motor rotor rolls on the supporting table 201 under the action of gravity, the motor rotor 201 is resisted by one baffle 403 in the rolling process, so that a plurality of motor rotors are still positioned on the supporting table, then the hydraulic cylinder 501 is started to extend the hydraulic cylinder 501, the first sliding block 502 does not slide under the thrust of the hydraulic cylinder 501 at this time due to the clamping between the clamping block 604 and the electrostatic coating machine body 10, the extension of the hydraulic cylinder 501 drives the pushing block 503 to slide inside the first sliding block 502, the pushing block 503 will abut against the second stop block 702 to move during the sliding process of the first sliding block 502, the second stop block 702 drives one of the clamping bars 705 to move through the first connecting rod 704, one of the clamping bars 705 drives one of the racks 706 to move, one of the racks 706 drives the gear 707 to move, the gear 707 rotates to drive the other rack 706 to move, so that the two clamping bars 705 simultaneously move towards the second groove 905 on the inserting bar 901, during the moving process of the pushing block 503, the second guiding shaft 602 is driven by the first guiding groove 601 to move, the second sliding block 603 is driven by the second guiding shaft 602 to move, the second sliding block 603 drives the clamping block 604 to move away from the first clamping groove 606 through the second spring 605, when the two clamping bars 705 are positioned in the second groove 905 and clamp the inserting bar 901, the end part of the clamping block 604 is separated from the first clamping groove 606, the axial center of the second stop block 702 and the axial center of the rotating rod 701 are on the same straight line, so that the position of the second stop block 702 is not changed when the rotating rod 701 rotates, then the hydraulic cylinder 501 stretches to drive the first slide block 502 to slide in the sliding groove 504, the first slide block 502 moves to drive the third slide block 801 to slide in the second guide groove 802 through the second connecting rod 803, meanwhile, the two clamping rods 705 clamp the plurality of inserting rods 901 to move away from the motor rotor, thereby separating the plurality of inserting rods 901 from the plurality of electronic rotors, the third slide block 801 moves to the turning position of the second guide groove 802 after the inserting rods 901 are separated from the motor rotor, at the moment, the rotating rod 701 moves in the second guide groove 802 along with the movement of the third slide block 801 in the first slide block 502, so that the plurality of inserting rods 901 turn to the storage device, when the rotating rod 701 rotates by a certain angle, the first sliding block 502 continues to move the rotating rod 701, the rotating rod 701 will not rotate, when the end part of the clamping block 604 moves to the second clamping groove 607, the hydraulic cylinder 501 stops extending and shrinking, at the moment, the end part of the clamping block 604 enters the second clamping groove 607, the second spring 605 shrinks to drive the second stop block 702 to move, the second stop block 702 moves to drive one clamping rod 705 to move, at the moment, the two clamping rods 705 are mutually separated, so that the clamping rods 705 release the clamping of a plurality of inserting rods 901, the inserting rods 901 fall into a collecting device under the action of gravity to collect, thereby realizing the automatic separation of the inserting rods 901 and a motor rotor, avoiding the need of manual disassembly, shortening the time, improving the efficiency, moving the clamping block 604 towards the second sliding block 603 under the interference of the electrostatic coating machine body 10 in the resetting process of the first sliding block 502, shrinking the second spring 605, therefore, the first slide block 502 is prevented from being reset in a five-way due to the blocking of the clamping block 604, the resetting of the first slide block 502 is facilitated, when a part of the inserted rod 901 is taken off from the motor stator, the electric push rod 301 is started to extend to drive the other baffle 403 to move towards the motor rotor, the first spring 406 is extended, the guide rod 404 plays a guiding role on the baffle 403 in the moving process of the baffle 403, when the other baffle 403 moves to abut against the first baffle 405, the end part of the other baffle 403 just abuts against one motor rotor, at the moment, the electric push rod 301 continues to extend, the end part of the abutting rod 305 is separated from the other baffle 403, the guide post 303 abuts against the connecting sleeve 304 to rotate, when the connecting sleeve 304 rotates ninety degrees, the electric push rod 301 is contracted, at the moment, the guide post 303 abuts against the connecting sleeve 304 again to rotate ninety degrees, thus, when the connecting sleeve 304 is separated from the guide post 303, the connecting sleeve 304 can rotate 180 degrees, so that when the electric push rod 301 is contracted, the supporting rod 305 can collide with one baffle 403 and is clamped into the first groove 407 on one baffle 403, at the moment, the electric push rod 301 is contracted to drive one baffle 403 to move away from the motor rotor, so that one baffle 403 does not bear the motor rotor of the removed inserting rod 901, a plurality of motor rotors of the removed inserting rod 901 continue to roll along the conveying groove 202 and finally fall into the collecting device to be collected, the collection of the coated motor rotors is facilitated, then the electric push rod 301 can repeat the actions to collide between one baffle 403 and the motor rotor of the un-removed inserting rod 901 and not collide between the other baffle 403 and the motor rotor, thereby facilitating the separation between the subsequent motor rotor and the plunger 901.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (1)

1. The utility model provides an electrostatic coating machine for motor manufacturing, its characterized in that, including electrostatic coating machine body (10), be equipped with location structure (1) on electrostatic coating machine body (10), be equipped with conveying structure (2) on electrostatic coating machine body (10), be equipped with on electrostatic coating machine body (10) and keep out structure (4), be equipped with on keeping out structure (4) and stir structure (3), be equipped with on electrostatic coating machine body (10) and remove structure (5), be equipped with screens structure (6) on removing structure (5), be equipped with fixed knot structure (7) on removing structure (5), be equipped with rotating structure (8) on removing structure (5), be equipped with screw rod (11) on electrostatic coating machine body (10), be equipped with mounting structure (9) on screw rod (11);

the resisting structure (4) comprises a supporting plate (401), the supporting plate (401) is fixedly connected to the electrostatic coating machine body (10), a connecting cover (402) is detachably connected to the supporting plate (401) through a plurality of bolts, two baffles (403) are connected to the supporting plate (401) in a sliding mode, two guide rods (404) are fixedly connected to the connecting cover (402), one ends of the guide rods (404) are connected with first check blocks (405) in a threaded mode, the baffle (403) are connected to the guide rods (404) in a sliding mode, first springs (406) are sleeved outside the guide rods (404), one ends of the first springs (406) are abutted to the first check blocks (405) and the other ends of the first springs are abutted to the connecting cover (402), and first grooves (407) are formed in the baffle (403);

the stirring structure (3) comprises an electric push rod (301), the electric push rod (301) is mounted on a connecting cover (402), a connecting column (302) is fixedly connected to the end portion of the electric push rod (301), a connecting sleeve (304) is rotatably connected to the connecting column (302), a supporting rod (305) is fixedly connected to the connecting sleeve (304), a first guide shaft (306) is fixedly connected to a supporting plate (401), a guide column (303) is fixedly connected to the supporting plate, and the guide column (303) is slidably connected to the connecting column (302);

the conveying structure (2) comprises a supporting table (201), the supporting table (201) is fixedly connected to the electrostatic coating machine body (10), a conveying groove (202) is formed in the supporting table (201), the top surface of the supporting table (201) is obliquely arranged, one end of the section of the screw (11) is obliquely arranged, and the inclination of the top surface of the supporting table (201) is smaller than that of the section of the end part of the screw (11);

the movable structure (5) comprises a hydraulic cylinder (501), the hydraulic cylinder (501) is arranged on the electrostatic coater body (10), a push block (503) is fixedly connected to the end part of the hydraulic cylinder (501), the push block (503) is slidably connected to a first sliding block (502), a sliding groove (504) is formed in the electrostatic coater body (10), and the first sliding block (502) is slidably matched with the sliding groove (504);

the clamping structure (6) comprises a second sliding block (603), the first sliding block (502) is connected with the second sliding block (603) in a sliding manner and is connected with a clamping block (604) in a sliding manner, the clamping block (604) is connected with the second sliding block (603) in a sliding manner, a second spring (605) is fixedly connected between the second sliding block (603) and the clamping block (604), a first clamping groove (606) and a second clamping groove (607) are formed in the electrostatic coating machine body (10), one end of the clamping block (604) is clamped with the first clamping groove (606), a second guide shaft (602) is fixedly connected to the second sliding block (603), a first guide groove (601) is formed in the pushing block (503), and one end of the second guide shaft (602) extends to the inside of the first guide groove (601) and is connected with the pushing block (503) in a sliding manner.

The fixed structure (7) comprises a rotating rod (701), the rotating rod (701) is rotationally connected to the first sliding block (502), a second stop block (702) is slidingly connected to the rotating rod (701) and is slidingly connected with a first connecting rod (704), the first connecting rod (704) is fixedly connected to the second stop block (702), a third spring (703) is abutted between the second stop block (702) and the first sliding block (502), two clamping rods (705) are slidingly connected to the rotating rod (701), racks (706) are fixedly connected to the clamping rods (705), the two racks (706) are meshed with the same gear (707), the gear (707) is rotationally connected to the rotating rod (701), and one clamping rod (705) is fixedly connected to the first connecting rod (704); one end of the second stop block (702) is in a conical structure, and the second stop block (702) is perpendicular to the first connecting rod (704);

the rotating structure (8) comprises a second guide groove (802), the electrostatic coating machine body (10) is provided with the second guide groove (802), a third sliding block (801) is connected inside the second guide groove (802) in a sliding mode, a second connecting rod (803) is connected to the third sliding block (801) in a rotating mode, and the second connecting rod (803) is connected to the rotating rod (701) in a rotating mode; the mounting structure (9) comprises a plug rod (901), a plurality of plug rods (901) are arranged between two screw rods (11), a plurality of retaining plates (902) are connected to the plug rod (901) in a sliding mode, two fourth sliding blocks (903) are connected to the plug rod (901) in a sliding mode, one ends of the fourth sliding blocks (903) are abutted to the retaining plates (902), a fourth spring (904) is abutted between the other ends of the fourth sliding blocks (903) and the plug rod (901), and a second groove (905) is formed in the plug rod (901);

the positioning structure (1) comprises positioning plates (101), two positioning plates (101) are fixedly connected to the electrostatic coating machine body (10), positioning grooves (102) are formed in the positioning plates (101), and a plurality of openings are formed in the positioning grooves (102).