CN112846710A - Little motor housing bearing press-fitting device - Google Patents

Abstract

The application relates to a micromotor shell bearing press mounting device, which comprises a frame, a bearing top pressing mechanism, a conveying belt, a conveying slide way, the conveying belt is communicated with the conveying slide way in an end-to-end mode, a material pushing mechanism and a limiting mechanism are sequentially arranged on the conveying slide way, the bearing top pressing mechanism is arranged at a position, close to the limiting mechanism, of the conveying slide way, the material pushing mechanism comprises a material pushing slide rail, a sliding block sliding on the material pushing slide rail and a telescopic device pushing the sliding block to move on the material pushing slide rail, a strip-shaped sliding groove is formed in one side, close to the material pushing slide rail, of the conveying slide way, a sliding hole facing the conveying slide way is formed in one end, close to the bearing top pressing mechanism, of the sliding block, a push rod stretching into the conveying slide way through the sliding groove is arranged in the sliding hole, one end, far away from the bearing top pressing mechanism, of the sliding block The effect of the work is good.

Description

Little motor housing bearing press-fitting device

Technical Field

The application relates to the field of micro-motor machining equipment, in particular to a bearing press-mounting device for a micro-motor shell.

Background

The end part of the shell of the micromotor needs to be inserted with the rotor shaft, the bearing needs to be pressed in the mounting groove at the end part of the shell in order to reduce the friction between the rotor shaft and the shell in the working process of the rotor shaft, and the micromotor shell needs to be put into the bearing pressing mechanism one by one to be pressed in order to ensure the accurate pressing of the bearing due to the small size of the micromotor shell.

In view of the related art in the above, the inventors consider that the current micromotor case transfer while maintaining accurate pressing efficiency is too low.

Disclosure of Invention

In order to promote the transport efficiency of micromotor casing, this application provides a micromotor casing pressure equipment device.

The application provides a little motor case bearing pressure equipment device adopts following technical scheme:

a micro-motor shell bearing press-mounting device comprises a rack, a bearing press mechanism, a conveying belt and a conveying slide way, wherein the conveying belt and the conveying slide way are arranged on the rack, the conveying belt is communicated with the head and the tail of the conveying slide way, a material pushing mechanism and a limiting mechanism are sequentially arranged on the conveying slide way, the bearing press mechanism is arranged at the position, close to the limiting mechanism, of the conveying slide way, the material pushing mechanism comprises a material pushing slide rail, a slide block and a telescopic device, the material pushing slide rail is the same as the length direction of the conveying slide way, the slide block slides on the material pushing slide rail, the telescopic device pushes the slide block to move on the material pushing slide rail, a strip-shaped slide groove is formed in one side, close to the material pushing slide rail, of the slide block, a slide hole facing the conveying slide way is formed in one end, far away from the bearing press, the connecting plate is hinged with the push rod close to the edge of the push rod.

By adopting the technical scheme, the micromotor shell is conveyed into the conveying slide way through the conveying belt, the movable micromotor shell is limited at the position of the bearing jacking mechanism by the limiting action of the limiting mechanism, the bearing is jacked and inverted in the micromotor shell to realize fixation through the jacking action of the bearing jacking mechanism, after the jacking process is finished, the expansion piece extends out to push the connecting plate to rotate by taking the position connected with the slide block as the center, the rotating connecting plate drives the push rod to slide towards the conveying slide way, so that the push rod extends into the space between the two micromotor shells in the conveying slide way, when the push rod cannot be pushed continuously, the expansion piece continues to extend outwards, so that the slide block is pushed to move along the material pushing slide way, the push rod also moves along the material pushing slide way, the movable push rod pushes the micromotor shells to move towards the limiting mechanism, so that the pressed micromotor shells are pushed out of the limiting mechanism, and the micromotor shells which are, thereby promote the transport and the pressure equipment efficiency of micromotor shell.

Optionally, the push rod is provided with a lock rod penetrating through the slider, and the connecting plate is close to a clamping groove at the edge of the push rod for the lock rod to be clamped in.

Through adopting above-mentioned technical scheme, at the in-process of connecting plate upset, the lateral wall of draw-in groove can promote the locking lever to carry the slide to remove, and the locking lever produces the displacement in the draw-in groove, avoids producing the phenomenon of jamming.

Optionally, the locking rod is screwed on the push rod.

Through adopting above-mentioned technical scheme, make things convenient for locking lever installation to change.

Optionally, a pushing arc surface is arranged on one side, close to the bearing jacking mechanism, of one end, extending into the conveying slide way, of the push rod.

By adopting the technical scheme, the area of the end part of the push rod is effectively reduced by the arrangement of the pushing cambered surface, the push rod can be conveniently inserted between the micromotor shells in the conveying slide way, the pushing cambered surface can be conveniently attached to the outer wall of the micromotor shell, and the stability during pushing is improved.

Optionally, both ends of the pushing slide rail are provided with positioning blocks for the sliding block to abut against.

Through adopting above-mentioned technical scheme, the effectual slip interval of restriction slider of locating piece, and avoid the slider roll-off to push away the material slide rail.

Optionally, the positioning blocks are all in threaded connection with positioning adjusting rods facing the sliding blocks.

Through adopting above-mentioned technical scheme, through the effectual slip interval that changes the slider of pilot lever to be convenient for adapt to the not equidimension micromotor shell.

Optionally, stop gear includes mount, stopper, spacing elastic component, the mount is fixed in the transport slide side, stopper sliding connection is on the mount, stopper one end runs through and stretches into in the transport slide, spacing elastic component promotes the stopper and removes to transport the slide, be equipped with the screens subassembly in the mount, the length that screens subassembly restriction stopper stretched into transport slide is less than half of transport slide width.

Through adopting above-mentioned technical scheme, the stopper stretches into in the conveying slide, thereby the micromotor shell that removes can block on the stopper and realized effectual fixed, when pushing away the material when pushing away material mechanism, the stopper produces the slip along micromotor shell outer wall to overcome in the elasticity withdrawal mount of spacing elastic component, make micromotor shell continue to move.

Optionally, the screens subassembly is including setting up the screens groove on the mount to and at the gliding screens pole in the screens inslot, screens pole threaded connection is on the stopper.

Through adopting above-mentioned technical scheme, through the slip restriction of screens pole in the screens inslot, avoid the stopper excessively to stretch into in the transportation slide.

Optionally, one end of the limiting block extending into the conveying slide way, which is close to one side of the pushing mechanism, is provided with a limiting arc surface.

Through adopting above-mentioned technical scheme, spacing cambered surface can effectually be contradicted with little motor case outer wall, and the stopper of being convenient for at the in-process that little motor case removed contracts.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the micromotor shells are quickly and accurately pushed to the bearing jacking mechanism one by one through the material pushing mechanism to be processed;

2. the pushing mechanism is convenient to adjust and is used for adapting to the micro motor shells of different models.

Drawings

Fig. 1 is a structural view of the present embodiment.

Fig. 2 is a mounting state diagram of the pushing mechanism and the limiting mechanism in the present embodiment.

Fig. 3 is a diagram illustrating the state of the push rod abutting against the micro-motor case in this embodiment.

Fig. 4 is a pushing state diagram of the pushing mechanism of the present embodiment.

Description of reference numerals: 1. a frame; 11. a conveyor belt; 12. a conveying chute; 121. a chute; 2. a bearing jacking mechanism; 3. a material pushing mechanism; 31. a material pushing slide rail; 32. a slider; 321. a slide hole; 33. a retractor; 34. a push rod; 35. a connecting plate; 36. a lock lever; 37. a card slot; 38. a material pushing cambered surface; 39. positioning blocks; 391. positioning an adjusting rod; 4. a limiting mechanism; 41. a fixed mount; 42. a limiting block; 43. a limiting elastic part; 44. limiting the arc surface; 5. a position clamping rod; 51. a clamping groove; 6. a micro motor housing; 61. and a bearing.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

As shown in fig. 1, the micro-motor comprises a micro-motor shell 6, a motor rotor and a rear end cover, wherein the stator is a magnetized magnetic shoe and is fixed on the inner wall of the micro-motor shell 6, the rear end is fixed at the tail part of the micro-motor shell 6, the motor rotor is arranged in the micro-motor shell 6, one end of a rotor shaft is arranged at the front end part of the micro-motor shell 6, the other end of the rotor shaft is arranged at the rear end cover, and in order to reduce the friction between the rotor shaft and the shell in the working process, a bearing jacking mechanism 2 is required to press a bearing 61 in a mounting groove at the front end part of the.

The embodiment of the application discloses a bearing press-mounting device of a micromotor shell, and relates to fig. 1 and 2, which comprises a rack 1, a bearing press-mounting mechanism 2, a conveying belt 11 and a conveying slide way 12 which are arranged on the rack 1, wherein the conveying belt 11 is communicated with the conveying slide way 12 end to end, a material pushing mechanism 3 and a limiting mechanism 4 are sequentially arranged on the conveying slide way 12, the bearing press-mounting mechanism 2 is arranged at the position of the conveying slide way 12 close to the limiting mechanism 4, the micromotor shell 6 for mounting a bearing 61 is continuously conveyed to the conveying slide way 12 through the conveying belt 11, the distance between the conveying slide ways 12 is the same as the diameter of the micromotor shell 6, so that the micromotor shells 6 sequentially enter the conveying slide way 12 one by one, the micromotor shells 6 slide towards the bearing press-mounting mechanism 2 under the thrust action of continuous inward conveying of the conveying belt 11, and after the micromotor shell 6 moves to, the micro motor shells 6 are controlled to move towards the bearing jacking mechanism 2 one by one through the material pushing mechanism 3, the micro motor shells 6 are controlled by the material pushing mechanism 3 to move to the limiting mechanism 4, the limiting mechanism 4 effectively limits the working positions of the micro motor shells 6 at the bearing jacking mechanism 2, the bearing jacking mechanism 2 comprises a lifter positioned below the conveying slide way 12 and a contact device positioned above the conveying slide way 12, the bearings 61 are placed on the lifter, the lifter lifts the bearings 61 to enter the mounting grooves in the micro motor shells 6 through the abdicating holes in the conveying slide way 12, the lifter is lifted continuously to drive the micro motor shells 6 to move upwards for a small distance to contact the contact device, the lifter is lifted continuously to enable the bearings 61 to be pressed into the mounting grooves completely, so that the jacking work of the bearings 61 is realized, after the jacking of the bearings 61 is finished, the lifter descends completely to enable the micro motor shells 6 to return to the conveying slide way 12, at this time, the limiting mechanism 4 is opened, and the micro motor shell 6 continues to move along the conveying slide way 12, so that the subsequent micro motor shell 6 can continue to be conveyed and the bearing 61 is pressed and assembled.

Referring to fig. 2 and 3, wherein the material pushing mechanism 3 includes a material pushing slide rail 31 having the same length direction as the conveying slide rail 12, a slide block 32 sliding on the material pushing slide rail 31, and an expansion piece 33 pushing the slide block 32 to move on the material pushing slide rail 31, the expansion piece 33 is an air cylinder, one side of the conveying slide rail 12 close to the material pushing slide rail 31 is provided with a strip-shaped slide groove 121, one end of the slide block 32 close to the bearing press mechanism 2 is provided with a slide hole 321 facing the conveying slide rail 12, the slide hole 321 is slidably provided with a push rod 34 extending into the conveying slide rail 12 through the slide groove 121, one side of one end of the push rod 34 extending into the conveying slide rail 12 close to the bearing press mechanism 2 is provided with a material pushing arc 38, one end of the slide block 32 far from the bearing press mechanism 2 is hinged with a connecting plate 35, one end of the expansion piece 33 is hinged with the other end of, the lock rod 36 slides in the limit sliding chute 121, the connecting plate 35 is close to the clamping groove 37 at the edge of the push rod 34 for the lock rod 36 to be clamped in, so that the expansion piece 33 extends out to push the connecting plate 35 to rotate by taking the position connected with the slide block 32 as the center, at the moment, the lock rod 36 is not fixed and is in a movable state, most of the push force conversion connecting plate 35 rotates to push the lock rod 36 to slide in the limit sliding chute 121 and cannot overcome the static friction force of the slide block 32, so that the slide block 32 cannot slide on the push material sliding rail 31, the rotating connecting plate 35 drives the lock rod 36 to move towards the conveying slide way 12, the push rod 34 is also driven to slide towards the conveying slide way 12, the moving distance of the lock rod 36 is limited due to the arrangement of the limit sliding chute 121, the push rod 34 is prevented from excessively extending into the conveying slide way 12, the push rod 34, the push rod 34 extends into the conveying slide way 12 and then is inserted between the two micro motor shells 6, the area of the end part of the push rod 34 is reduced due to the arrangement of the push-pushing cambered surface 38 on the push rod 34, so that the push rod 34 can better extend into the space between the two micro motor shells 6, and the push-pushing cambered surface 38 can be effectively attached to the outer wall of the micro motor shell 6, so that the micro motor shell 6 can be pushed more stably subsequently.

Referring to fig. 2 and 4, when the lock rod 36 is clamped on the limiting chute 121 and cannot continue the slide way, the push rod 34 cannot continue to extend into the conveying slide way 12, the expansion piece 33 continues to extend outward, the thrust of the expansion piece 33 directly acts on the slide block 32 through the lock rod 36, so that all the thrust directly acts on the slide block 32, the slide block 32 is pushed to move towards the bearing jacking mechanism 2 on the material pushing slide way 31, the push rod 34 is made to move towards the bearing jacking mechanism 2 in the conveying slide way 12, the micro motor shell 6 is pushed to move towards the bearing jacking mechanism 2, the micro motor shells 6 are mutually pushed, the pressed micro motor shell 6 is also made to push out the limiting mechanism 4, the non-pressed micro motor shell 6 enters the limiting mechanism 4 again for subsequent press-mounting, and the conveying and press-mounting efficiency of the micro motor shell 6 is improved.

Referring to fig. 1 and 2, when the telescopic device 33 retracts, because the lock rod 36 is not fixed and slides reversely and is not limited to be in a movable state, most of the pulling force conversion connecting plates 35 rotate to pull the lock rod 36 to slide reversely in the limiting sliding groove 121, and the static friction force of the slide block 32 cannot be overcome, so that the slide block 32 cannot slide on the pushing sliding rail 31 at this time, the rotating connecting plates 35 drive the lock rod 36 to move away from the conveying sliding rail 12, so as to drive the push rod 34 to retract reversely and completely exit the conveying sliding rail 12, at this time, the lock rod 36 props against one end of the limiting sliding groove 121 away from the conveying sliding rail 12, when the lock rod 36 is clamped on the limiting sliding groove 121, the telescopic device 33 continues to retract inwards, the pulling force of the telescopic device 33 directly acts on the slide block 32 through the lock rod 36, so that all the pulling force directly acts on the slide block 32, therefore, in the process of retracting the telescopic device 33, the push rod 34 is completely withdrawn from the conveying slide way 12, and the micro motor shell 6 is prevented from being reversely pushed.

Referring to fig. 1 and 2, wherein the limiting mechanism 4 includes a fixing frame 41, a limiting block 42, and a limiting elastic member 43, the fixing frame 41 is fixed on the side surface of the conveying chute 12, the limiting block 42 is slidably connected to the fixing frame 41, one end of the limiting block 42 penetrates and extends into the conveying chute 12, the limiting elastic member 43 pushes the limiting block 42 to move towards the conveying chute 12, a clamping component is disposed in the fixing frame 41, the clamping component limits the length of the limiting block 42 extending into the conveying chute 12 to be less than half of the width of the conveying chute 12, the clamping component includes a clamping groove 51 disposed on the fixing frame 41, and a clamping rod 5 sliding in the clamping groove 51, the clamping rod 5 is threadedly connected to the limiting block 42, wherein one end of the limiting block 42 extending into the conveying chute 12 is provided with a limiting arc surface 44 near the pushing mechanism 3, when limiting is required, the limiting block 42 extends into the conveying chute 12, the moving micro motor casing 6 is clamped on the limiting arc, when the pushing mechanism 3 pushes the material, because the side surface of the micromotor housing 6 is arc-shaped and the arrangement of the limiting arc surface 44 provides an effective guiding function, the limiting block 42 slides along the outer wall of the micromotor housing 6, retracts into the fixing frame 41 by overcoming the elasticity of the limiting elastic part 43, so that the micromotor housing 6 with the assembled bearing 61 continues to move, after the micromotor housing 6 moves, the limiting block 42 extends into the conveying slideway 12 again by the elastic action of the limiting elastic part 43 to block the next micromotor housing 6, the micromotor housing 6 moving to the limiting mechanism 4 is limited in the position of the bearing jacking mechanism 2 by the sliding limitation of the clamping rod 5 in the clamping groove 51 in the process that the limiting block 42 extends into the conveying slideway 12 excessively, so that the micromotor housing 6 moving to the limiting mechanism 4 is directly limited by the limiting mechanism 4, and is limited in the position of the bearing jacking mechanism 2 by the jacking action of the bearing jacking mechanism 2, the bearing 61 is jacked up to the interior of the inverted micromotor shell 6 to be fixed, and after the jacking process is finished, the material is continuously pushed by the material pushing mechanism 3, so that the micromotor shell 6 provided with the bearing 61 pushes away the limiting mechanism 4, and the micromotor shell 6 not provided with the bearing 61 enters.

Referring to fig. 1 and 2, the two ends of the pushing slide rail 31 are respectively provided with a positioning block 39 for the sliding block 32 to abut against, the positioning blocks 39 are respectively in threaded connection with a positioning adjusting rod 391 facing the sliding block 32, the positioning blocks 39 effectively limit the sliding distance of the sliding block 32 and prevent the sliding block 32 from sliding out of the pushing slide rail 31, and the positioning adjusting rod 391 is in threaded connection with the sliding block 32, so that the positioning adjusting rod 391 can be directly rotated to effectively change the sliding distance of the sliding block 32, thereby facilitating the adaptation of the micro-motor housings 6 with different sizes.

The application principle of the bearing press-mounting device for the micromotor shell is as follows: the conveyor belt 11 pushes the micro-motor shells 6 into the conveying slideway 12 one by one, at the moment, the limiting block 42 extends into the conveying slideway 12, so that the micro-motor shells 6 are abutted against the limiting cambered surface 44, thereby ensuring the stability of the micro-motor shells 6 abutted against the limiting block 42, and as the conveyor belt 11 continuously conveys inwards, each micro-motor shell 6 in the conveying slideway 12 generates mutual abutting force, so that the micro-motor shells 6 abutted against the limiting block 42 are more stable, at the moment, the bearing abutting mechanism 2 works to abut against the bearings 61 into the micro-motor shells 6 abutted against the limiting block 42, after the bearing 61 is abutted, the pushing mechanism 3 works, the expansion piece 33 extends out to push the connecting plate 35 to rotate by taking the position connected with the sliding block 32 as the center, the rotating connecting plate 35 drives the locking rod 36 to move towards the conveying slideway 12, and drives the push rod 34 to slide towards the conveying slideway 12, after the push rod 34 extends into the conveying slide way 12 and then is inserted between the two micromotor shells 6, when the push rod 34 cannot continue to extend into the conveying slide way 12, the expansion piece 33 continues to extend outwards, the thrust of the expansion piece 33 directly acts on the slide block 32 through the lock rod 36, the slide block 32 is pushed to move towards the bearing jacking mechanism 2 on the material pushing slide way 31, the push rod 34 moves towards the bearing jacking mechanism 2 in the conveying slide way 12, so that the micromotor shells 6 are pushed towards the bearing jacking mechanism 2, the micromotor shells 6 are mutually pushed, the pressed micromotor shells 6 are pushed out of the limiting mechanism 4, the micromotor shells 6 which are not pressed enter the limiting mechanism 4 again for subsequent pressing, after the material pushing is completed, the expansion piece 33 retracts, the connecting plate 35 rotates to pull the lock rod 36 to reversely slide in the limiting slide groove 121, the push rod 34 is driven to reversely retract and completely exit from the conveying slide way 12, when the lock rod 36 is clamped on the limit chute 121 and the slide cannot continue to slide, the expansion piece 33 continues to retract inwards, the pulling force of the expansion piece 33 directly acts on the sliding block 32 through the lock rod 36, the sliding block 32 is pulled to move reversely on the material pushing sliding rail 31, so that the push rod 34 completely exits from the conveying slide 12 in the retraction process of the expansion piece 33, the micro motor shell 6 is prevented from being pushed reversely, the continuous conveying force of the conveying belt 11 acts on the micro motor shell 6, and the micro motor shell 6 can effectively abut against the limit block 42.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a little motor case bearing press-fitting device, includes frame (1), bearing roof pressure mechanism (2), its characterized in that: the conveying belt (11) and the conveying slide way (12) are arranged on the rack (1), the conveying belt (11) is communicated with the conveying slide way (12) end to end, a material pushing mechanism (3) and a limiting mechanism (4) are sequentially arranged on the conveying slide way (12), the bearing jacking mechanism (2) is arranged at the position, close to the limiting mechanism (4), of the conveying slide way (12), the material pushing mechanism (3) comprises a material pushing slide rail (31) which is the same as the conveying slide way (12) in length direction, a sliding block (32) which slides on the material pushing slide rail (31) and a telescopic device (33) which pushes the sliding block (32) to move on the material pushing slide rail (31), a strip-shaped sliding groove (121) is formed in one side, close to the material pushing slide rail (31), of the sliding block (32) close to one end of the bearing jacking mechanism (2) is provided with a sliding hole (321) facing, the sliding hole (321) is internally provided with a push rod (34) which extends into the conveying slide way (12) through a sliding groove (121) in a sliding mode, one end, far away from the bearing jacking mechanism (2), of the sliding block (32) is hinged to a connecting plate (35), one end of the expansion piece (33) is hinged to the other end of the connecting plate (35), and the edge, close to the push rod (34), of the connecting plate (35) is hinged to the push rod (34).

2. The apparatus of claim 1, wherein: the push rod (34) is provided with a lock rod (36) penetrating through the sliding block (32), and the connecting plate (35) is close to a clamping groove (37) which is formed in the edge of the push rod (34) and used for clamping the lock rod (36).

3. The apparatus of claim 2, wherein: the lock rod (36) is connected to the push rod (34) in a threaded mode.

4. The apparatus of claim 1, wherein: and a material pushing cambered surface (38) is arranged on one side, close to the bearing jacking mechanism (2), of one end, extending into the conveying slide way (12), of the push rod (34).

5. The apparatus of claim 1, wherein: and positioning blocks (39) for the sliding block (32) to abut against are arranged at the two ends of the pushing sliding rail (31).

6. The apparatus of claim 5, wherein: the positioning blocks (39) are all in threaded connection with positioning adjusting rods (391) facing the sliding blocks (32).

7. The apparatus of claim 1, wherein: stop gear (4) are including mount (41), stopper (42), spacing elastic component (43), mount (41) are fixed and are being carried slide (12) side, stopper (42) sliding connection is on mount (41), stopper (42) one end is run through and is stretched into in carrying slide (12), spacing elastic component (43) promote stopper (42) and remove to carrying slide (12), be equipped with the screens subassembly in mount (41), the length that the screens subassembly restriction stopper (42) stretched into and carry slide (12) is less than half of carrying slide (12) width.

8. The apparatus of claim 7, wherein: the screens subassembly is including setting up screens groove (51) on mount (41) to and gliding screens pole (5) in screens groove (51), screens pole (5) threaded connection is on stopper (42).

9. The apparatus of claim 7, wherein: one end of the limiting block (42) extending into the conveying slide way (12) and close to one side of the pushing mechanism (3) is provided with a limiting cambered surface (44).

Images