CN117019746B - Automatic cleaning device for motor rotor - Google Patents

Abstract

The invention discloses an automatic cleaning device for a motor rotor, and relates to the technical field of rotor cleaning. The cleaning device comprises a shell component, wherein a gap moving component, a driving component, a transmission component and an agitating component are arranged on the shell component, a drying component is arranged on the gap moving component, the gap moving component comprises a moving rod, and the moving rod is rotationally connected to a circulating belt; the ratchet wheel is matched with the pawl on the middle swivel to control the stirring plate to rotate unidirectionally, so that the cleaning liquid in the upper shell is driven to circularly flow, the flow speed of the cleaning liquid is limited, and larger spray of the cleaning liquid is avoided; the cleaned rotor is dried by heating air through the heating coil, so that the residue of cleaning liquid is avoided.

Description

Automatic cleaning device for motor rotor

Technical Field

The invention relates to the technical field of rotor cleaning, in particular to an automatic motor rotor cleaning device.

Background

In modern industrial production, motors are widely used in various equipment and mechanical systems for rotation and driving work. However, since the motor is operated for a long time, contaminants such as dust, dirt, grease and the like are easily accumulated on the outer surface thereof, and these contaminants affect the performance and efficiency of the motor, and may even cause malfunction and damage of the motor.

The Chinese patent publication No. CN106623013B discloses a motor rotor cleaning device, which comprises a bearing frame, a lifting hydraulic cylinder vertically arranged on the bearing frame and a cross beam with one end arranged at the top of the lifting hydraulic cylinder, wherein a cleaning brush is arranged at the other end of the cross beam.

The above patent has the following problems for cleaning the rotor: the brush is incomplete in cleaning the rotor, and fine parts are not easy to clean; the cleaning liquid remains and cannot be removed; the cleaning efficiency is low. There is a need for a device that can efficiently clean the rotor and remove the cleaning fluid.

Disclosure of Invention

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a motor rotor self-cleaning device, including the shell subassembly, be provided with clearance removal subassembly on the shell subassembly, drive assembly and stirring subassembly, be provided with the stoving subassembly on the clearance removal subassembly, the shell subassembly includes upper shell, fixedly connected with upper bracket and lower shell on the upper shell, fixedly mounted has the motor on the upper bracket, the clearance removes the subassembly and includes the carriage release lever, the carriage release lever rotates to be connected on the circulation belt, frictional connection has the drive shaft on the circulation belt, fixedly connected with driving disk in the drive shaft, be provided with three hole on the driving disk, the both ends of drive shaft pass through connecting block fixedly connected with small support, sliding connection has the first end of transverse connection pole on the first end of small support, fixedly connected with bracing piece on the second end of transverse connection pole, the second end sliding connection of spacing sliding shaft is on the second end of small support, still fixedly connected with transverse guide ring on the small support.

Preferably, the gap moving assembly further comprises an upper guide ring, the upper guide ring is fixedly connected to the transverse guide ring, the moving rod is further fixedly connected with a first end of a torsion spring, a second end of the torsion spring is fixedly connected to the circulating belt, the transverse guide ring is further movably connected with a first end of a magnetic plate, and a second end of the magnetic plate is rotatably connected to the upper shell.

Preferably, the driving assembly comprises a gear, the gear is rotationally connected to a gear frame, the gear frame is fixedly connected to a base, the base is fixedly connected to an upper bracket, the two ends of the gear are fixedly connected with the first ends of small connecting rods, the second ends of the small connecting rods are rotationally connected with the first ends of long connecting rods, the second ends of the long connecting rods are rotationally connected with the first ends of connecting pieces, the second ends of the connecting pieces are slidably connected to a sliding shaft, and the sliding shaft is fixedly connected to an upper shell.

Preferably, the driving assembly further comprises a transverse connecting piece, a shaft is arranged at the first end of the transverse connecting piece and is rotationally connected to the long connecting rod close to the drying assembly, a sliding groove is arranged at the second end of the transverse connecting piece and is slidingly connected to a convex shaft on the long connecting rod far away from the drying assembly, a rotating ring is rotationally connected to the transverse connecting piece, a rotating plate is fixedly connected to the rotating ring, a first end of a middle rotating block is rotationally connected to the rotating plate, a second end of the middle rotating block is rotationally connected to the first end of the driving plate, and a sliding groove is arranged at the second end of the driving plate.

Preferably, the stirring assembly comprises a transmission plate, a first end of the transmission plate is slidably connected to a sliding groove on a second end of the driving plate, a rotary table is fixedly connected to the second end of the transmission plate, a first end of a transmission shaft is fixedly connected to the rotary table, a second end of the transmission shaft is fixedly connected to a ratchet wheel, the ratchet wheel is rotatably connected to the stirring plate, a first end of a middle swivel is fixedly connected to the stirring plate, a pawl is arranged on the middle swivel, and a second end of the middle swivel is rotatably connected to the rotary table.

Preferably, the transmission assembly comprises a front telescopic rod, the first end of the front telescopic rod is fixedly connected to a connecting piece far away from the drying assembly, the first end of a telescopic spring is fixedly connected to the first end of the front telescopic rod, the second end of the front telescopic rod is slidably connected to the first end of a rear telescopic rod, the second end of the telescopic spring is fixedly connected to the first end of the telescopic spring, the second end of the rear telescopic rod is rotatably connected with the first end of a middle connecting rod, the second end of the rear telescopic rod is rotatably connected with the first end of a sliding rod, the second end of the sliding rod is slidably connected to a bottom plate, a limiting block is fixedly connected to the bottom plate, the bottom plate is fixedly connected to an upper shell, the rear telescopic rod is slidably connected to a telescopic carriage, and the telescopic carriage is fixedly connected to the upper shell.

Preferably, the transmission assembly further comprises a transmission block, a baffle is arranged on the transmission block, a first end of the connection plate is fixedly connected to the transmission block, a threaded ring is fixedly connected to a second end of the connection plate, threads are arranged on the threaded ring, the threaded ring is further slidably connected to the first end of the casing, the second end of the casing is fixedly connected to the sliding rod, a threaded shaft is fixedly connected to the sliding rod, and the threaded shaft is in threaded connection with the threaded ring.

Preferably, the drying assembly comprises a drying driving shaft, the drying driving shaft is fixedly connected to the threaded rod, a pinion is fixedly connected to the drying driving shaft, a fan is fixedly connected to the pinion, the drying driving shaft is rotatably connected to the guide shell, a transmission toothed chain is slidably connected to the guide shell, the transmission toothed chain is meshed with the pinions, a heating coil is fixedly connected to the guide shell, and an air inlet pipe is fixedly connected to the guide shell.

The invention provides an automatic cleaning device for a motor rotor, which has the following beneficial effects: (1) The invention is provided with the movable rod, the rotor is pushed to move on the transverse guide ring by driving the circular movement of the movable rod, so that the rotor is immersed in the cleaning liquid, and the plurality of rotors are prevented from being contacted with each other by the blocking of the movable rod, thereby influencing the cleaning effect; (2) The stirring plate is arranged, and the ratchet wheel is matched with the pawl on the middle swivel to control the stirring plate to rotate unidirectionally, so that the cleaning liquid in the upper shell is driven to circularly flow, the flowing speed of the cleaning liquid is limited, and larger spray of the cleaning liquid is avoided; (3) The invention is provided with the heating coil, and the cleaned rotor is dried by heating air through the heating coil, so that the residue of cleaning liquid is avoided.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a top view of the present invention;

FIG. 4 is a side view of the present invention;

FIG. 5 is a schematic view of the construction of the traverse guide ring of the present invention;

FIG. 6 is an enlarged view of a partial structure at A in FIG. 5;

FIG. 7 is a schematic view of the endless belt of the present invention;

FIG. 8 is an enlarged view of a part of the structure at B in FIG. 7;

FIG. 9 is a schematic view of a sliding axle according to the present invention;

FIG. 10 is an enlarged view of a part of the structure at C in FIG. 9;

FIG. 11 is a schematic view of the structure of the guide housing of the present invention;

FIG. 12 is an enlarged view of a part of the structure at D in FIG. 11;

FIG. 13 is an enlarged view of a part of the structure at E in FIG. 11;

fig. 14 is a schematic structural view of a threaded shaft according to the present invention.

In the figure: 1-a housing assembly; 2-gap movement assembly; 3-a drive assembly; 4-a drying component; 5-a transmission assembly; 6-an agitation assembly; 101-an electric motor; 102-upper support; 103-upper shell; 104-a lower shell; 201-upper guide ring; 202-transverse guide ring; 203-a magnetic plate; 204-moving the rod; 205-endless belt; 206-driving shaft; 207-drive disk; 208-supporting rods; 209-torsion spring; 210-small stent; 211-a transverse connection rod; 212-limiting a sliding shaft; 301-gear; 302—small connecting rod; 303-carrier; 304-long connecting rod; 305-a connector; 306-a sliding shaft; 307-cross connectors; 308-rotating a ring; 309-rotating plate; 310-an intermediate rotating block; 311-base; 312-threaded rod; 313-drive plate; 401-drying a driving shaft; 402-pinion; 403-a fan; 404-heating coils; 405-a drive toothed chain; 406-a guide housing; 407-an air inlet pipe; 501-front telescopic rod; 502-a telescopic spring; 503-a rear telescopic rod; 504-telescoping carriage; 505—intermediate links; 506-sliding bar; 507-floor; 508-a casing; 509-a threaded shaft; 510-a threaded ring; 511-a connection plate; 512-a transmission block; 513-limiting blocks; 601-a drive plate; 602-a turntable; 603-a drive shaft; 604-ratchet; 605-an intermediate swivel; 606-agitating the plate; 607-arc slide block.

Detailed Description

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

Referring to fig. 1 to 11, the present invention provides a technical solution: the utility model provides a motor rotor self-cleaning device, including shell subassembly 1, be provided with clearance removal subassembly 2 on the shell subassembly 1, drive assembly 3, drive assembly 5 and stirring subassembly 6, be provided with stoving subassembly 4 on the clearance removal subassembly 2, shell subassembly 1 includes upper housing 103, fixedly connected with upper bracket 102 and lower housing 104 on the upper housing 103, fixedly mounted has motor 101 on upper bracket 102, clearance removal subassembly 2 includes movable rod 204, movable rod 204 rotates to be connected on endless belt 205, frictional connection has drive shaft 206 on the endless belt 205, fixedly connected with driving disk 207 on the drive shaft 206, be provided with three hole on the driving disk 207, the both ends of drive shaft 206 are through connecting block fixedly connected with small support 210, fixedly connected with cross connecting rod 211's first end on the first end of small support 210, fixedly connected with bracing piece 208 on the second end of cross connecting rod 211, the second end sliding connection of spacing slide 212 is on the second end of small support 210 on the cross connecting rod 211, still fixedly connected with cross guide ring 202 on the small support 210.

As shown in fig. 8, a spring is provided on the limit slide shaft 212, and a first end of the spring is fixedly connected to the transverse connection rod 211, and a second end of the spring is fixedly connected to a second end of the small bracket 210. Through the setting of movable rod 204, guarantee every rotor's clearance, avoid the rotor to collide etc. each other when wasing, influence the washing to can also adjust the specification of movable rod 204 according to the rotor of different specifications.

Openings are formed at two ends of the bottom plate of the upper shell 103, and a cavity is formed in the lower shell 104, so that the upper shell 103 and the lower shell 104 together form a water flow path, namely, mixed liquid of water and a cleaning machine flows from the position of the transmission assembly 5 to the direction of the drying assembly 4, then enters the lower shell 104, moves to the direction of the transmission assembly 5 and then enters the upper shell 103, and then reciprocates.

The gap moving assembly 2 further comprises an upper guide ring 201, the upper guide ring 201 is fixedly connected to the transverse guide ring 202, a first end of a torsion spring 209 is fixedly connected to the moving rod 204, a second end of the torsion spring 209 is fixedly connected to the circulating belt 205, a first end of a magnetic plate 203 is magnetically connected to the transverse guide ring 202, and a second end of the magnetic plate 203 is rotatably connected to the upper shell 103.

As shown in fig. 6, 7 and 8, an opening is provided on the transverse guide ring 202 toward one end of the upper guide ring 201, a first end of the moving rod 204 slides on the opening, a blocking post is provided on a second end of the moving rod 204, a guide wheel is further provided on a second end of the small bracket 210, the guide wheel slides on the endless belt 205, and a plurality of magnetic plates 203 are provided to jointly support and fix the transverse guide ring 202.

The circulating belt 205 is provided with a plurality of groups of moving rods 204, the first end of the moving rod 204 positioned above slides on the opening of the transverse guide ring 202, the blocking column at the second end of the moving rod 204 is propped against the supporting rod 208, the first end of the moving rod 204 positioned below is propped against one side of the transverse guide ring 202 far away from the opening, the second end of the moving rod 204 is propped against the supporting rod 208, because the torsion spring 209 on the moving rod 204 always has a counterclockwise rotating force, the moving rod 204 positioned above is not limited by the external force, namely the transverse guide ring 202, so that the second end of the moving rod 204 positioned above is always propped against the supporting rod 208, and the moving rod 204 positioned below is limited by the transverse guide ring 202, when the moving rod 204 moves along the circulating belt 205 and enters the inside of the transverse guide ring 202 from the outside of the transverse guide ring 202, the first end of the moving rod 204 is driven to rotate counterclockwise through the limitation of the transverse guide ring 202, the blocking column at the second end of the moving rod 204 is propped against the supporting rod 208, and then the two connecting rods 212 are driven to slide on the two sides of the supporting rods 212 respectively, which are driven by the sliding shafts 212 to slide upwards, and the limiting shafts 212 are respectively positioned on the two sides of the sliding shafts 212.

Can be according to the specification size of abluent motor rotor before the use, change the specification of movable rod 204, avoid because the internal diameter of rotor is too big, lead to when wasing, rivers drive the rotor and rock, the rotor is direct to cross the first end of movable rod 204 to unable restriction rotor's position.

In use, as shown in fig. 6, the motor rotor is placed on the upper guide ring 201, the rotor falls on the transverse guide ring 202, the driving shaft 206 is driven to rotate by driving the driving disc 207 to drive the circulating belt 205 to move, so that the moving rod 204 on the circulating belt 205 pushes the rotor to move on the transverse guide ring 202, when the rotor contacts the magnetic plate 203, the rotor is pushed by the moving rod 204, and then the rotor pushes the first end of the magnetic plate 203, so that the magnetic plate 203 rotates around the second end of the magnetic plate 203, and the first end of the magnetic plate 203 is separated from the transverse guide ring 202, and then the moving rod 204 pushes to rotate away from the magnetic plate 203.

The driving assembly 3 comprises a gear 301, the gear 301 is rotationally connected to a gear rack 303, the gear rack 303 is fixedly connected to a base 311, the base 311 is fixedly connected to the upper bracket 102, both ends of the gear 301 are fixedly connected with first ends of small connecting rods 302, second ends of the small connecting rods 302 are rotationally connected with first ends of long connecting rods 304, second ends of the long connecting rods 304 are rotationally connected with first ends of connecting pieces 305, second ends of the connecting pieces 305 are slidably connected to sliding shafts 306, and the sliding shafts 306 are fixedly connected to the upper-layer shell 103.

The driving assembly 3 further comprises a cross connecting member 307, a shaft is arranged at a first end of the cross connecting member 307 and is rotatably connected to the long connecting rod 304 close to the drying assembly 4, a sliding groove is arranged at a second end of the cross connecting member 307 and is slidably connected to a convex shaft on the long connecting rod 304 far away from the drying assembly 4, a rotating ring 308 is rotatably connected to the cross connecting member 307, a rotating plate 309 is fixedly connected to the rotating ring 308, a first end of a middle rotating block 310 is rotatably connected to the rotating plate 309, a second end of the middle rotating block 310 is rotatably connected to a first end of a driving plate 313, and a sliding groove is arranged at a second end of the driving plate 313.

As shown in fig. 9 and 11, the gear 301 is symmetrically provided with a small connecting rod 302, a long connecting rod 304, a cross connecting member 307, a driving plate 313, an agitating unit 6 and other parts on both sides. In use, the motor 101 drives the gear 301 to rotate, the gear 301 drives the small connecting rod 302 to rotate, the second end of the small connecting rod 302 drives the first end of the long connecting rod 304, the second end of the small connecting rod 302 pulls the connecting piece 305 to slide on the sliding shaft 306, the second end of the long connecting rod 304 close to the drying assembly 4 also drives the transverse connecting piece 307 to move, the second end of the transverse connecting piece 307 slides on the convex shaft on the long connecting rod 304 far away from the drying assembly 4, and the first end of the transverse connecting piece 307 drives the first end of the driving plate 313 to move through the cooperation of the rotating ring 308, the rotating plate 309 and the middle rotating block 310, so that the second end of the driving plate 313 slides on the driving plate 601 and drives the driving plate 601 to rotate, and thus the driving plate 601 is driven to reciprocate.

The stirring assembly 6 comprises a transmission plate 601, a first end of the transmission plate 601 is slidably connected to a sliding groove on a second end of the driving plate 313, a rotary table 602 is fixedly connected to a second end of the transmission plate 601, a first end of a transmission shaft 603 is fixedly connected to the rotary table 602, a second end of the transmission shaft 603 is fixedly connected to a ratchet wheel 604, the ratchet wheel 604 is rotatably connected to a stirring plate 606, a first end of an intermediate rotary ring 605 is fixedly connected to the stirring plate 606, a pawl is arranged on the intermediate rotary ring 605, and a second end of the intermediate rotary ring 605 is rotatably connected to the rotary table 602.

As shown in fig. 11 and 12, two arc-shaped sliding blocks 607 are fixedly connected to the stirring plate 606, the arc-shaped sliding blocks 607 are slidably connected to sliding grooves on the upper shell 103, and a plurality of groups of stirring assemblies 6 are arranged. When the rotary type water washing machine is used, the driving plate 601 is driven to rotate through the driving plate 313, when the driving plate 601 rotates clockwise, the driving plate 601 drives the ratchet wheel 604 to rotate clockwise through the rotary plate 602 and the transmission shaft 603, the ratchet wheel 604 is matched with the pawl on the middle rotary ring 605, the middle rotary ring 605 is driven to rotate clockwise, the stirring plate 606 is driven to rotate clockwise, and accordingly water flow in the transmission shaft 603 is driven to move through the stirring plate 606, and then the rotor is washed through water flow. The arc-shaped sliding blocks 607 on the stirring plate 606 limit the stirring plate 606, so that the stirring plate 606 is prevented from being separated because the flow speed of the water flow in the upper shell 103 is too fast.

Through the cooperation of ratchet 604 and pawl on the intermediate swivel 605 for the stirring board 606 can be driven to clockwise rotation when driving the carousel 602 to clockwise rotation to drive the drive plate 313, and when carousel 602 anticlockwise rotates, stirring board 606 does not follow carousel 602 rotation, can restrict the velocity of flow of rivers from this, and avoid the spray that produces when rivers stir too big, influence the life of part etc..

The transmission assembly 5 comprises a front telescopic rod 501, a first end of the front telescopic rod 501 is fixedly connected to a connecting piece 305 far away from the drying assembly 4, a first end of a telescopic spring 502 is fixedly connected to the first end of the front telescopic rod 501, a second end of the front telescopic rod 501 is slidably connected to a first end of a rear telescopic rod 503, a second end of the telescopic spring 502 is fixedly connected to a first end of a telescopic spring 502, a first end of a middle connecting rod 505 is rotatably connected to the second end of the rear telescopic rod 503, a first end of a sliding rod 506 is rotatably connected to the second end of the rear telescopic rod 503, a second end of the sliding rod 506 is slidably connected to a bottom plate 507, a limiting block 513 is fixedly connected to the bottom plate 507, the bottom plate 507 is fixedly connected to the upper shell 103, the rear telescopic rod 503 is slidably connected to a telescopic carriage 504, and the telescopic carriage 504 is fixedly connected to the upper shell 103.

The transmission assembly 5 further comprises a transmission block 512, a baffle is arranged on the transmission block 512, a first end of a connecting plate 511 is fixedly connected to the transmission block 512, a threaded ring 510 is fixedly connected to a second end of the connecting plate 511, threads are arranged on the threaded ring 510, the threaded ring 510 is further slidably connected to the first end of the casing 508, a second end of the casing 508 is fixedly connected to the sliding rod 506, a threaded shaft 509 is fixedly connected to the sliding rod 506, and the threaded shaft 509 is in threaded connection with the threaded ring 510.

As shown in fig. 12 and 13, when the long link 304 pushes the connection member 305 to move on the sliding shaft 306, the connection member 305 pushes the first end of the front telescopic rod 501 to move, so that the first end of the front telescopic rod 501 pushes the first end of the telescopic spring 502, the second end of the telescopic spring 502 pushes the first end of the rear telescopic rod 503 through the elastic force of the telescopic spring 502, and thus the telescopic spring 502 slides on the telescopic carriage 504, and the second end of the rear telescopic rod 503 drives the first end of the middle link 505, and the second end of the middle link 505 pulls the sliding rod 506, so that the sliding rod 506 slides on the bottom plate 507. The sliding rod 506 pushes the threaded ring 510, the connecting plate 511 and the transmission block 512 to move through the threaded grooves on the threaded shaft 509, so that the transmission block 512 is close to the driving disc 207, three protruding shafts corresponding to holes on the driving disc 207 are arranged on the transmission block 512, when the transmission block 512 contacts the driving disc 207, the situation that the protruding shafts are not aligned with the holes may occur, and when the sliding rod 506 continues to move, the transmission block 512 cannot continue to move, so that the threaded ring 510 is driven to rotate through the threaded engagement of the threaded shaft 509 and the threaded ring 510, the transmission block 512 is driven to rotate through the connecting plate 511, the three protruding shafts on the transmission block 512 are aligned with the three holes on the driving disc 207, and the protruding shafts on the transmission block 512 are inserted into the holes on the driving disc 207, so that the driving disc 207 is driven to rotate through the transmission block 512, and the circulating belt 205 and the moving rod 204 are driven to move, so that the rotor is driven to move.

When the connecting piece 305 moves in the opposite direction, the driving threaded shaft 509 drives the transmission block 512 to reset, and when the transmission block 512 contacts the limiting block 513, the threaded shaft 509 and the threaded ring 510 are matched by threads to drive the threaded ring 510 to rotate, so that the threaded ring 510 and one end, close to the sliding rod 506, of the threaded shaft 509 move towards the direction close to the transmission block 512 and rotate on the threaded shaft 509 in a spiral manner, and the threaded ring 510 returns to the initial position shown in fig. 14, so that the protruding shaft on the transmission block 512 can be ensured to be inserted into the hole of the driving disc 207 every time the sliding rod 506 moves.

The drying assembly 4 comprises a drying driving shaft 401, the drying driving shaft 401 is fixedly connected to the threaded rod 312, a pinion 402 is fixedly connected to the drying driving shaft 401, a fan 403 is fixedly connected to the pinion 402, the drying driving shaft 401 is rotatably connected to a guide shell 406, a plurality of parts such as the drying driving shaft 401 and the pinion 402 are arranged on the guide shell 406, a transmission toothed chain 405 is slidably connected to the guide shell 406, the transmission toothed chain 405 is meshed with the plurality of pinions 402, a heating coil 404 is fixedly connected to the guide shell 406, and an air inlet pipe 407 is fixedly connected to the guide shell 406.

As shown in fig. 10, after the rotor is cleaned, the rotor is separated from the cleaning solution and moved to the position of the drying assembly 4 by pushing the moving rod 204, the threaded rod 312 is driven to rotate by the gear 301, the threaded rod 312 drives the pinion 402 to rotate again, the pinion 402 drives the other pinions 402 to rotate by the transmission toothed chain 405, the pinion 402 drives the fan 403 to rotate, the air sucked from the air inlet pipe 407 is heated by the heating coil 404, the hot air is blown by the wind force generated by the rotation of the fan 403, and the rotor is dried by guiding the guiding shell 406, so that the residue of the cleaning solution is avoided, and the rotor is cleaned.

Claims (3)

1. The utility model provides a motor rotor self-cleaning device, includes shell subassembly (1), its characterized in that: the utility model discloses a device for drying the waste water, a motor (101) is fixedly installed on an upper shell (103), an upper bracket (102) and a lower shell (104) are fixedly connected on the upper shell (103), a motor (101) is fixedly installed on the upper bracket (102), the gap movement assembly (2) comprises a moving rod (204), the moving rod (204) is rotationally connected on a circulating belt (205), a driving shaft (206) is in friction connection on the circulating belt (205), a driving disc (207) is fixedly connected on the driving shaft (206), three holes are formed in the driving disc (207), two ends of the driving shaft (206) are fixedly connected with small brackets (210) through connecting blocks, a first end of a transverse connecting rod (211) is connected on a first end of the small bracket (210) in a sliding manner, a supporting rod (208) is fixedly connected on a second end of the transverse connecting rod (211), a first end of a limiting sliding shaft (212) is also fixedly connected on the transverse connecting rod (211), a second end of the sliding shaft (212) is connected on a second end of the small bracket (210), the small bracket (210) is also fixedly connected with a transverse guide ring (202);

the driving assembly (3) comprises a gear (301), the gear (301) is rotationally connected to a gear frame (303), the gear frame (303) is fixedly connected to a base (311), the base (311) is fixedly connected to an upper bracket (102), the two ends of the gear (301) are fixedly connected with the first ends of small connecting rods (302), the second ends of the small connecting rods (302) are rotationally connected with the first ends of long connecting rods (304), the second ends of the long connecting rods (304) are rotationally connected with the first ends of connecting pieces (305), the second ends of the connecting pieces (305) are slidably connected to sliding shafts (306), and the sliding shafts (306) are fixedly connected to an upper-layer shell (103);

the driving assembly (3) further comprises a transverse connecting piece (307), a shaft is arranged at the first end of the transverse connecting piece (307), the shaft is rotatably connected to the long connecting rod (304) close to the drying assembly (4), a sliding groove is arranged at the second end of the transverse connecting piece (307), the sliding groove is slidably connected to a convex shaft on the long connecting rod (304) far away from the drying assembly (4), a rotating ring (308) is rotatably connected to the transverse connecting piece (307), a rotating plate (309) is fixedly connected to the rotating ring (308), a first end of a middle rotating block (310) is rotatably connected to the rotating plate (309), a second end of the middle rotating block (310) is rotatably connected to the first end of the driving plate (313), and a sliding groove is arranged at the second end of the driving plate (313);

the stirring assembly (6) comprises a transmission plate (601), wherein a first end of the transmission plate (601) is slidably connected to a sliding groove on a second end of the driving plate (313), a rotary table (602) is fixedly connected to a second end of the transmission plate (601), a first end of a transmission shaft (603) is fixedly connected to the rotary table (602), a second end of the transmission shaft (603) is fixedly connected to a ratchet wheel (604), the ratchet wheel (604) is rotatably connected to a stirring plate (606), a first end of an intermediate rotary ring (605) is fixedly connected to the stirring plate (606), a pawl is arranged on the intermediate rotary ring (605), and a second end of the intermediate rotary ring (605) is rotatably connected to the rotary table (602);

the transmission assembly (5) comprises a front telescopic rod (501), wherein the first end of the front telescopic rod (501) is fixedly connected to a connecting piece (305) far away from the drying assembly (4), the first end of the front telescopic rod (501) is fixedly connected with the first end of a telescopic spring (502), the second end of the front telescopic rod (501) is slidably connected to the first end of a rear telescopic rod (503), the second end of the telescopic spring (502) is fixedly connected to the first end of the telescopic spring (502), the second end of the rear telescopic rod (503) is rotatably connected with the first end of a middle connecting rod (505), the second end of the rear telescopic rod (503) is rotatably connected with the first end of a sliding rod (506), the second end of the sliding rod (506) is slidably connected to a bottom plate (507), the bottom plate (507) is fixedly connected with a limiting block (513), the bottom plate (507) is fixedly connected to an upper shell (103), the rear telescopic rod (503) is slidably connected to a telescopic carriage (504), and the telescopic carriage (504) is fixedly connected to the upper shell (103).

The transmission assembly (5) further comprises a transmission block (512), a baffle is arranged on the transmission block (512), a first end of a connecting plate (511) is fixedly connected to the transmission block (512), a threaded ring (510) is fixedly connected to a second end of the connecting plate (511), threads are arranged on the threaded ring (510), the threaded ring (510) is further connected to the first end of the casing (508) in a sliding mode, the second end of the casing (508) is fixedly connected to the sliding rod (506), a threaded shaft (509) is fixedly connected to the sliding rod (506), and the threaded shaft (509) is in threaded connection with the threaded ring (510).

2. An automatic motor rotor cleaning device according to claim 1, wherein: the clearance moving assembly (2) further comprises an upper guide ring (201), the upper guide ring (201) is fixedly connected to the transverse guide ring (202), the moving rod (204) is fixedly connected with a first end of a torsion spring (209), a second end of the torsion spring (209) is fixedly connected to the circulating belt (205), the transverse guide ring (202) is further movably connected with a first end of a magnetic plate (203), and a second end of the magnetic plate (203) is rotatably connected to the upper shell (103).

3. An automatic motor rotor cleaning device according to claim 1, wherein: drying component (4) are including stoving drive shaft (401), stoving drive shaft (401) fixed connection is on threaded rod (312), fixedly connected with pinion (402) on stoving drive shaft (401), fixedly connected with fan (403) on pinion (402), stoving drive shaft (401) rotate and connect on direction shell (406), sliding connection has transmission toothed chain (405) on direction shell (406), transmission toothed chain (405) and a plurality of pinion (402) meshing, still fixedly connected with heating coil (404) on direction shell (406), fixedly connected with air-supply line (407) on direction shell (406).