CN213402757U - Bearing installation equipment for rotor - Google Patents

Abstract

The utility model discloses a bearing installation device for a rotor, which comprises a base, a first support plate, a second support plate, a third L-shaped support plate, a fourth support plate, a support component and an automatic feeding device, wherein the first support plate, the second support plate, the third L-shaped support plate and the fourth support plate are fixed on the base, the first support plate and the automatic feeding device are arranged on the fourth support plate, the automatic feeding device comprises a feeding pipe and a first feeding plate, a through hole is arranged on the first support plate, the outer wall of the feeding pipe is fixed in the through hole, one end of the feeding pipe is fixed with the fourth support plate, the other end of the feeding pipe is provided with a pushing component, the first driving source is fixed on the third L-shaped support plate, a piston rod of the first driving source penetrates through the third L-shaped support plate and is fixed with a pushing column, the first feeding plate is obliquely, the feeding plate II is internally provided with a plurality of rotors in a sliding mode, and the feeding plate has the advantage that equipment can be automatically pushed into the feeding plate II to complete installation of the equipment.

Description

Bearing installation equipment for rotor

Technical Field

The utility model relates to a motor manufacturing assembly technical field, in particular to bearing erection equipment for rotor.

Background

The rotor indicates the rotator that is supported by the bearing, present rotor assembly bearing is still manual work mostly, its efficiency is very low, the workman is manual fills in the rotor with the bearing, can reduce the work efficiency of motor assembly like this, and can increase the possibility that bearing or rotor damaged, and the electronic erection equipment structure of those bearings is also comparatively simple, the manual work of using always puts into equipment with bearing and rotor, in utilizing the driving source to pack the rotor into with the bearing, though practice thrift the cost like this, but have very big potential safety hazard.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a bearing erection equipment for rotor has the advantage that can push equipment automatically and accomplish the installation with equipment.

The above technical purpose of the present invention can be achieved by the following technical solutions:

a bearing mounting device for a rotor comprises a base, a first support plate, a second support plate, a third L-shaped support plate, a fourth support plate, a support assembly and an automatic feeding device, wherein the first support plate, the second support plate, the third L-shaped support plate and the fourth support plate are fixed on the base, the support assembly and the automatic feeding device are arranged on the fourth support plate, the automatic feeding device comprises a feeding pipe and a first feeding plate, a through hole is formed in the first support plate, the outer wall of the feeding pipe is fixed in the through hole, one end of the feeding pipe is fixed with the fourth support plate, a pushing assembly is arranged at the other end of the feeding pipe, a first driving source is fixed on the third L-shaped support plate, a first pushing column is fixed on a piston rod of the first driving source, the first feeding plate is obliquely fixed on the fourth support plate, a plurality of bearings are, the feeding plate II is obliquely fixed on the supporting plate IV, and a plurality of rotors are arranged in the feeding plate II in a sliding mode.

By adopting the technical scheme, the bearing is installed in the rotor, the rotor which is arranged in the feeding plate II in a sliding manner is firstly dropped into the support plate IV through gravity, the bearing which is arranged in the feeding plate I in a sliding manner is firstly dropped into the support plate IV through gravity, the pushing assembly is started, the bearing in the feeding pipe is pushed through the pushing assembly, the bearing enters the support plate IV, the bearings on two sides are supported through the support assembly, the bearing is prevented from falling down, the driving source I is started, the piston rod drives the pushing column to slide by utilizing the pushing of the piston rod of the driving source I, the pushing column drives the right bearing to slide, the right bearing drives the rotor to slide, the rotor slides to enable the left bearing to enter the rotor, the right bearing is further pushed to enter the rotor, the installation of the rotor and the bearing is realized, the rotor provided with the bearing is manually taken out, the driving source I is closed, and the new rotor and the new bearing fall into the support IV through gravity, and the operation is continued, so that the continuous installation of the rotor and the bearing is realized.

Preferably, the supporting assembly comprises a first supporting block, a second supporting block and a spring, the first supporting block is symmetrically fixed on the upper surface of the four left sides of the supporting plate, sliding grooves are symmetrically formed in the right side of the supporting plate, one end of the spring is fixed in the sliding grooves, the other end of the spring is fixed with the second supporting block, and the second supporting block is slidably arranged in the sliding grooves.

By adopting the technical scheme, when the bearing enters the supporting plate IV, the bearing is fixed through the first supporting block and the second supporting block, when the driving source is started to install the rotor and the bearing, the pushing column drives the right bearing to slide, the right bearing drives the second supporting block to slide, the supporting block slides to pull the spring, the spring generates elastic force, after the equipment is installed, the equipment is manually taken away, the piston rod retracts to enable the supporting block not to be pushed, the spring is not pulled, the second supporting block rebounds to the original position through the elastic force, and the bearing is continuously supported.

Preferably, the pushing assembly comprises a support plate five and a pushing column two, the support plate five is fixed on the base, a cylinder two is fixed on the support plate five, a piston rod of the cylinder two penetrates through the support plate five and is fixed with the pushing column two, and the pushing column two is arranged in the feeding pipe in a sliding mode.

By adopting the technical scheme, the second air cylinder is started, the piston rod of the second air cylinder extends out to drive the pushing column to slide, and the pushing column drives the bearing in the feeding pipe to slide, so that the bearing slides to the fourth supporting plate.

Preferably, the upper surface of the support plate four is provided with a deep groove, the rotor is arranged in the deep groove in a sliding manner, shallow grooves are formed in two sides of the support plate four, and the bearing is arranged in the shallow grooves in a sliding manner.

By adopting the technical scheme, the rotor in the feeding plate II falls into the deep groove through gravity, and the bearing falls into the shallow groove through gravity and the pushing column II, so that the mounting hole of the bearing is aligned with the mounting shaft of the rotor, and the bearing can be mounted in the rotor.

Preferably, the feeding pipe is provided with a semicircular groove.

By adopting the technical scheme, after the bearing in the feeding pipe is used up, a new bearing is placed into the feeding pipe through the semicircular groove.

Preferably, the first pushing column is slidably arranged in the fourth supporting plate.

By adopting the technical scheme, the bearing is driven to be assembled with the rotor by the sliding of the first pushing column.

Preferably, the first driving source is a first cylinder.

By adopting the technical scheme, the cylinder plays a role in pushing the bearing.

Preferably, a first controller is fixed on the base.

By adopting the technical scheme, the controller plays a role of controlling the second air cylinder together.

Preferably, a second controller is fixed on the base.

By adopting the technical scheme, the first controller and the second controller are pressed simultaneously to play a role in controlling the first cylinder.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment;

FIG. 2 is an enlarged partial schematic view of a support assembly;

FIG. 3 is a partially enlarged schematic view for showing the pushing device;

reference numerals: 1. a base; 2. a first support plate; 3. a second support plate; 4. an L-shaped support plate III; 5. a support plate IV; 6. a support assembly; 7. an automatic feeding device; 8. a feed pipe; 9. a feeding plate I; 10. a through hole; 11. a pushing assembly; 12. a first driving source; 13. pushing the first column; 14. a bearing; 15. a feeding plate II; 16. a rotor; 17. a first supporting block; 18. a second supporting block; 19. a spring; 20. a chute; 21. a fifth support plate; 22. pushing the second column; 23. a second air cylinder; 24. deep grooves; 25. shallow-groove; 26. a semicircular groove; 27. a first cylinder; 28. a first controller; 29. and a second controller.

Detailed Description

The following is only the preferred embodiment of the present invention, the protection scope is not limited to this embodiment, and all technical solutions belonging to the idea of the present invention should belong to the protection scope of the present invention. It should also be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and such modifications and decorations should also be regarded as the protection scope of the present invention.

Referring to fig. 1 to 3, a bearing mounting device for a rotor comprises a base 1, a first support plate 2 fixed on the base 1, a second support plate 3, a third L-shaped support plate 4, a fourth support plate 5 fixed on the second support plate 3, and an automatic feeding device 7 arranged on the fourth support plate 5, wherein the device is fed into the fourth support plate 5 through the automatic feeding device 7, the automatic feeding device 7 comprises a feeding pipe 8 and a feeding plate 9, the feeding plate 15 is fixed on the fourth support plate 5, the feeding plate 15 is obliquely fixed on the fourth support plate 5, a rotor 16 is arranged in the feeding plate 15 in a sliding manner, a deep groove 24 is formed in the fourth support plate 5, the rotor 16 automatically falls into the deep groove 24 of the fourth support plate 5 through gravity, a through hole 10 is formed in the first support plate 2, the outer wall of the feeding pipe 8 is fixed in the through hole 10, one end of the feeding pipe 8 is fixed with the, a bearing 14 is arranged in the feeding pipe 8 in a sliding manner, a pushing assembly 11 is arranged at the other end of the feeding pipe 8, so that the bearing 14 can be pushed into a support plate four 5, the pushing assembly 11 comprises a support plate five 21 and a pushing column two 22, the support plate five 21 is fixed on the base 1, a cylinder two 23 is fixed on the support plate five 21, a controller one 28 is fixed on the base 1, the cylinder two 23 is started by the controller, the pushing column two 22 is fixed on a piston rod of the cylinder two 23, the piston rod of the cylinder two 23 drives the pushing column two 22 to slide, the pushing column two 22 is arranged in the feeding pipe 8 in a sliding manner, the bearing 14 is pushed out of the feeding pipe 8 to the support plate four 5 by pushing the column two 22, the conveying of the left bearing 14 is completed, supporting blocks one 17 are symmetrically fixed on the upper surface on the left side of the support plate four 5, the bearing 14 on the left side is fixed by the supporting blocks, preventing the bearing 14 from being displaced.

As shown in fig. 2 to 3, a feeding plate I9 is obliquely fixed on a supporting plate IV 5, a bearing 14 is arranged in the feeding plate I9 in a sliding manner, shallow grooves 25 are formed in two sides of the supporting plate IV 5, the bearing 14 automatically falls into the shallow grooves of the supporting plate IV 5 through gravity, so that a mounting hole of the bearing is aligned with a mounting shaft of a rotor, sliding grooves 20 are symmetrically formed in the right side of the supporting plate IV 5, a supporting block II 18 is arranged in the sliding grooves 20 in a sliding manner, the right-side bearing 14 is fixed through the supporting block II 18, a cylinder I27 is fixed on one side of an L-shaped supporting plate III 4, the rotor 16 and the bearing 14 are mounted through the pushing of the piston rod of the cylinder I27, a controller II 29 is fixed on the base 1, the cylinder I27 is started through the controller I28 and the controller II 29, the piston rod of the cylinder I27 penetrates through the L, the first pushing column 13 is arranged in the fourth supporting plate 5 in a sliding mode, the first pushing column 13 drives the bearing 14 to move, the spring 19 is fixed on one side of the sliding groove 20, the second supporting block 18 is fixed at one end of the spring 19, the second supporting block 18 is driven to move through the movement of the bearing 14, the second supporting block 18 pulls the spring 19 to enable the spring 19 to generate elastic force, after the bearing 14 is pushed to be matched with the rotor 16, the matched rotor 16 is taken out, the rotor 16 on the feeding plate 15 is not blocked, the new rotor 16 falls into the deep groove 24 again, the first air cylinder 27 is closed through the first controller 28 and the second controller 29, the piston rod of the first air cylinder 27 is retracted to drive the first pushing column 13 to retract, the bearing in the feeding plate 9 is not blocked by the first pushing column 13 and falls into the shallow groove 25, the first pushing column 13 retracts to enable the second supporting block 18 not to be pushed, the second supporting block 18 is rebounded to fix the bearing 14, and pushing out the left bearing 14 by using the second air cylinder 23, and continuously installing the rotor 16 and the bearing 14.

Claims (9)

1. The bearing installation equipment for the rotor comprises a base (1), a first support plate (2), a second support plate (3), a third L-shaped support plate (4) and a fourth support plate (5), wherein the first support plate (2), the second support plate (3) and the third L-shaped support plate (4) are fixed on the base (1), the bearing installation equipment is further characterized by further comprising a support assembly (6) and an automatic feeding device (7), the support assembly (6) and the automatic feeding device (7) are arranged on the fourth support plate (5), the automatic feeding device (7) comprises a feeding pipe (8) and a first feeding plate (9), a through hole (10) is formed in the first support plate (2), the outer wall of the feeding pipe (8) is fixed in the through hole (10), one end of the feeding pipe (8) is fixed with the fourth support plate (5), the other end of the feeding pipe (8) is provided with a pushing assembly (11), the third L-shaped support plate (4) is fixedly provided with a first driving source (12), and 13) the feeding device comprises a supporting plate I (5), a feeding plate I (9) is obliquely fixed on the supporting plate II (5), a plurality of bearings (14) are arranged in the feeding pipe I (8) and the feeding plate I (9) in a sliding mode, a feeding plate II (15) is fixed on the supporting plate II (5), the feeding plate II (15) is obliquely fixed on the supporting plate II (5), and a plurality of rotors (16) are arranged in the feeding plate II (15) in a sliding mode.

2. The bearing mounting device for the rotor according to claim 1, wherein the support assembly (6) comprises a first support block (17), a second support block (18) and a spring (19), the first support block (17) is symmetrically fixed on the upper surface of the left side of a fourth support plate (5), a sliding groove (20) is symmetrically formed in the right side of the fourth support plate (5), one end of the spring (19) is fixed in the sliding groove (20), the other end of the spring (19) is fixed with the second support block (18), and the second support block (18) is slidably arranged in the sliding groove (20).

3. The bearing mounting equipment for the rotor according to claim 2, wherein the pushing assembly (11) comprises a support plate five (21) and a pushing column two (22), the support plate five (21) is fixed on the base (1), an air cylinder two (23) is fixed on the support plate five (21), a piston rod of the air cylinder two (23) penetrates through the support plate five (21) and is fixed with the pushing column two (22), and the pushing column two (22) is arranged in the feeding pipe (8) in a sliding mode.

4. A bearing mounting device for a rotor according to claim 3, characterized in that the upper surface of the support plate four (5) is provided with a deep groove (24), the rotor (16) is slidably arranged in the deep groove (24), both sides of the support plate four (5) are provided with shallow grooves (25), and the bearing (14) is slidably arranged in the shallow grooves (25).

5. A bearing mounting arrangement for a rotor according to claim 4, characterised in that the feed pipe (8) is provided with a semi-circular groove (26).

6. A bearing mounting arrangement for a rotor according to claim 5, characterised in that the push studs one (13) are slidably arranged in shallow grooves (25) in the support plate four (5).

7. A bearing mounting arrangement for a rotor according to claim 6, characterised in that the first drive source (12) is a first cylinder (27).

8. A bearing mounting arrangement for a rotor according to claim 7, characterised in that a first controller (28) is secured to the base (1).

9. A bearing mounting arrangement for a rotor according to claim 8, characterised in that a second control (29) is secured to the base (1).

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