The present invention relates to a device for adhering magnetic shoes on a rotor.
As shown in
Glue is applied to the outer circumferential wall of the rotor core between two adjacent positioning ribs, and then magnetic shoes are adhered on the rotor core at one end of the rotor. Then, the rotor is placed on a support seat that is opened upward, and the rotor is fitted with the support seat so that the lower end of the rotor shaft of the rotor is located in the support seat. The axial face of the rotor core adhered with the magnetic shoes is attached to the upper end face of the support seat, so that the magnetic shoes are limited between the positioning ribs on the middle section of the rotor core and the upper end face of the support seat. Subsequently, magnetic shoes will be adhered on the middle section of the rotor core and the upper section of the rotor core. The magnetic shoes on the middle section of the rotor core can be limited up and down by the positioning ribs on the upper and lower sections of the rotor core, respectively. However, as for the uppermost section of the rotor core, due to the influence from the magnetic shoes on the middle section of the rotor core, the magnetic shoes on the uppermost section of the rotor core will be deviated upward due to a repulsive force. Therefore, it is very troublesome to adhere magnetic shoes on the uppermost section.
An object of the present invention is to provide a device for adhering magnetic shoes on a rotor, which can improve the assembly accuracy of magnetic shoes.
In order to achieve the object, the present invention employs the following technical solutions. A device for adhering magnetic shoes on a rotor is provided, comprising a soleplate or a substrate plate, wherein a support seat for keeping the rotor arranged vertically is provided on the soleplate; a magnetic steel positioning seat is arranged above the support seat; the magnetic steel positioning has a support frame; the support frame includes an upper plate and a lower plate, with the lower plate having a first evading groove for evading a rotor core, and the upper plate having a second evading groove for evading an upper end of a rotor shaft; the support frame includes a upper plate and a lower plate, with a plurality of fixation units and a plurality of positioning plates being provided between the upper plate and the lower plate, each fixation unit including a push rod which is in sliding fit with the support frame so that the push rod can move axially, a magnetic steel positioning block being fixed at an inner end of the push rod, an inner edge of the magnetic steel positioning block being the same as an outer edge of a magnetic shoe in shape and size, each positioning plate being located between two adjacent fixation units, a recess (concave) and a bump (convex) matched with each other being respectively arranged on an inner end face of the positioning plate and an outer end face of a positioning rib of the rotor core, and the bump being able to enter the recess or escape from the recess; and, when the magnetic steel positioning seat is fitted with the rotor core, an inner edge of the second evading groove on the upper plate is located on an inner side of an outer edge of the positioning rib of the rotor core.
The rotor is placed on the support seat, and magnetic shoes are adhered on the lower section of the rotor core and the middle section of the rotor core by a conventional method. When in use of the device of the present invention, glue is applied to the end face of the rotor core between positioning ribs, and the magnetic steel positioning seat is placed on the rotor. The lower end face of the upper plate is supported on the upper end face of the uppermost rotor core, and the bump on the inner end face of the positioning plate is aligned with the recess on the outer end face of the rotor core, so that the magnetic steel positioning block at the end of each push rod is located between two adjacent positioning ribs. Then, magnetic shoes are placed on inner sides of the magnetic steel positioning blocks. Finally, the push rods are pushed, so that the magnetic shoes are allowed to move to the rotor core side and adhered on the end face of the rotor core between two adjacent positioning ribs. In the present invention, by limiting magnetic shoes by the upper plate of the magnetic steel positioning seat, the magnetic shoes are prevented from moving up under the action of the magnetic shoes on the middle section of the rotor core, thereby realizing high-accuracy assembly of magnetic shoes.
Preferably, the support seat has a lower mating groove that is opened upward to evade the lower end of the rotor shaft; the plurality of fixation units on the support frame are annularly arranged at uniform intervals; a press is arranged above the support seat; a press block is rotatably fixed at a lower end of a press lifting rod of the press; and, the press block moves down under the action of the press so as to press on the magnetic steel positioning seat.
When in use of the device of the present invention, after the magnetic shoe at one place is adhered and assembled, the rotor is rotated so that the surface of the rotor core without magnetic shoes assembled thereon is moved to the front of a worker, so that the worker does not need to move or lean to one side, and it is more convenient to use the device of the present invention.
Preferably, the support seat is fixed on a rotary mechanism, and the rotary mechanism is fixed on the soleplate, so that the support seat is rotatably fixed on the soleplate. With the above arrangement, the friction during rotation of the rotor is lower, so it is more convenient to use the device of the present invention. The rotary mechanism may be any existing device which can be electrically controlled and can realize the rotation of the support seat, for example, commercially-available indexing plates, rotary platforms or the like. With the above arrangement, it is more convenient to use the device of the present invention.
Preferably, the upper plate extends upward to form a top cover; the top cover has an upper mating groove running upward through the top cover to evade the upper end of the rotor shaft; and, when the magnetic steel positioning seat is sheathed on the rotor, an upper end face of the top cover is located above an upper end face of the rotor shaft, and the press block moves down under the action of the press to come into contact with the upper end face of the top cover. With the above arrangement, the structure at the press block becomes simpler.
Preferably, a lower end of the press lifting rod is fixed to an inner ring of a bearing; the press block has an annular cross-section; an inner wall of the press block is fixed to an outer ring of the bearing; and, a lower end face of the press block is located below a lower end face of the bearing. With the above arrangement, it is easier to rotatably fix the press block, and it is convenient to manufacture and process the device of the present invention.
Preferably, the plurality of fixation units are annularly arranged in the support frame at uniform intervals; the plurality of positioning plates are annularly arranged in the support frame at uniform intervals; the magnetic steel of each fixation unit is located between two adjacent positioning plates; and, the positioning plates are in one-to-one correspondence to the positioning ribs of the rotor core.
Preferably, upper ends of the positioning plates are fixed to the upper plate, while lower ends thereof are fixed to the lower plate; an annular plate extending upward is arranged on an outer circumferential edge of the upper plate; the push rods of the fixation units are slidingly fitted to the annular plate; and, an accommodating groove for accommodating magnetic shoes is formed between an inner circumferential edge of the annular plate and the outer circumferential edge of the upper plate. With the above arrangement, it is convenient to load magnetic shoes.
Preferably, push blocks are fixed at outer ends of the push rods, compression springs are arranged between the push blocks and the annular plate, and the compression springs are sheathed on the push rods. With the above arrangement, it is convenient to reset the push blocks.
Preferably, guide strips and guide slots matched with each other are arranged between the fixation units and the upper plate or the lower plate; the guide strips and the guide slots extend in a radial direction of the rotor core; the guide strips extending downward are provided on lower end faces of the magnetic steel positioning blocks of the fixation units; and, an upper end face of the lower plate is recessed downward to form the guide slots. With the above arrangement, the magnetic steel positioning blocks are prevented from deviating from the set positions, and the accuracy of adhesion and fixation of magnetic shoes is higher.
Preferably, a guide surface with a lower inner side and a higher outer side is formed on an outer edge of the lower end face of the upper plate; the guide surface is located on an outer circumferential side of the rotor core; the upper end faces of the magnetic steel positioning blocks are slopes that are gradually elevated from inside to outside; and, the push rods drive the magnetic steel positioning blocks to move to the rotor core side, so that the guide surface comes into contact with the upper end faces of the magnetic steel positioning blocks. The slopes come into contact with the guide surface to press down the magnetic steel positioning blocks, so that the magnetic shoes are prevented from deviating upward and the accuracy of adhesion and fixation of magnetic shoes is improved.
The present invention is more convenient to use and can improve the assembly accuracy of magnetic shoes.
The present invention will be further described below by specific embodiments with reference to the accompanying drawings.
As shown in
The support seat 2 is fixed on a rotary mechanism 21, and the rotary mechanism 21 is fixed on the soleplate 10, so that the support seat 2 is rotatably fixed on the soleplate 20. The rotary mechanism 21 is a commercially-available rotary platform or indexing plate. The support seat 2 has a lower matching groove that is opened upward to evade the lower end of the rotor shaft 11.
The magnetic steel positioning seat 3 has a support frame. The support frame includes an upper plate 31 and a lower plate 32. The lower plate 32 has a first evading groove 30 for evading the rotor core 12, and the upper plate 31 has a second evading groove for evading the upper end of the rotor shaft 11. A plurality of fixation units and a plurality of positioning plates 33 are arranged between the upper plate 31 and the lower plate 32. Each fixation unit includes a push rod 34. The push rod 34 is in sliding fit with the support frame so that the push rod 34 can move axially, and a magnetic steel positioning block 35 is fixed at an inner end of the push rod 34. An inner edge of the magnetic steel positioning block 35 is the same as an outer edge of a magnetic shoe 16 in shape and size, so that the inner end face of the magnetic steel positioning block is of a cambered surface structure 350. Each positioning plate 35 is located between two adjacent fixation units. A bump 36 matched with a recess 17 on the outer end face of an upper positioning rib 15 of the rotor core is arranged on an inner end face of the positioning plate 35. The bump 36 is able to enter the recess 17 or escape from the recess 17. When the magnetic steel positioning seat 3 is fitted with the rotor core 12, an inner edge of the second evading groove on the upper plate 31 is located on an inner side of an outer edge of the upper positioning rib 15 of the rotor core 12. The plurality of fixation units are annularly arranged in the support frame at uniform intervals, and the plurality of positioning plates 33 are annularly arranged in the support frame at uniform intervals. The magnetic steel positioning block 35 of each fixation unit is located between two adjacent positioning plates 33. The positioning plates 33 are in one-to-one correspondence to the upper positioning ribs 15 of the rotor core 11.
The upper plate 31 extends upward to form a top cover 37. The top cover 37 has an upper mating groove running upward through the top cover 37 to evade the upper end of the rotor shaft 11. When the magnetic steel positioning seat 35 is sheathed on the rotor, an upper end face of the top cover 36 is located above an upper end face of the rotor shaft 11, and the press block 43 moves down under the action of the press 4 to come into contact with the upper end face of the top cover 36. The top cover 36 has an inner diameter greater than that of the inner ring of the bearing 42.
Upper ends of the positioning plates 33 are fixed to the upper plate 31, while lower ends thereof are fixed to the lower plate 32. An annular plate 38 extending upward is arranged on an outer circumferential edge of the upper plate 31. The push rods 34 of the fixation units are slidingly fitted to the annular plate 38. An accommodating groove 39 for accommodating magnetic shoes 16 is formed between an inner circumferential edge of the annular plate 38 and the outer circumferential edge of the upper plate 31.
Push blocks 341 are fixed at outer ends of the push rods 34, compression springs 342 are arranged between the push blocks 341 and the annular plate 38, and the compression springs 342 are sheathed on the push rods 34. Guide strips and guide slots matched with each other are arranged between the fixation units and the upper plate or the lower plate, and the guide strips and the guide slots extend in a radial direction of the rotor core. The guide strips extending downward are provided on lower end faces of the magnetic steel positioning blocks 35, and an upper end face of the lower plate 32 is recessed downward to form the guide slots 321. The guide strips and the guide slots 321 extend in the radial direction of the rotor core 12.
A guide surface 311 with a lower inner side and a higher outer side is formed on an outer edge of the lower end face of the upper plate 31. The guide surface 311 is located on an outer circumferential side of the rotor core 12. The upper end faces of the magnetic steel positioning blocks 35 are slopes 355 that are gradually elevated from inside to outside. The push rods 34 drive the magnetic steel positioning blocks 35 to move to the rotor core 35 side, so that the guide surface 311 comes into contact with the slopes 355 on the upper end faces of the magnetic steel positioning blocks.
The rotor is placed on the support seat, glue is applied to the circumferential surfaces of the middle section of the rotor core and the lower section of the rotor core of the rotor, and magnetic shoes are successively adhered and fixed. The support seat is rotated, so that the surface of the rotor core without magnetic shoes fixed thereon are moved to the front of a worker or an operator.
After magnetic shoes are adhered and fixed on the middle section of the rotor core and the lower section of the rotor core, glue is applied to the circumferential surface of the upper section of the rotor core, and the magnetic steel positioning seat is sheathed on the rotor. The upper plate of the magnetic steel positioning seat is supported on the upper end face of the upper section of the rotor core, and the bump on the inner end face of the positioning plate is aligned with the recess on only the outer end face of the rotor core, so that the magnetic steel positioning block at the end of each push rod is located between two adjacent positioning ribs. Then, magnetic shoes are placed on inner sides of the magnetic steel positioning blocks, and the press is controlled to be activated to press the press block on the top cover. Finally, the worker pushes the push rods, so that the magnetic shoes are allowed to move to the upper section of the rotor core and adhered on the end face of the upper section of the rotor core between two adjacent positioning ribs. By controlling the rotate mechanism to rotate the support seat, magnetic steel is successively adhered and fixed to the upper section of the rotor core.
The present invention is more convenient to use and can improve the assembly accuracy of magnetic shoes.
Number | Date | Country | Kind |
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201911421132.0 | Dec 2019 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2020/089103 | 5/8/2020 | WO | 00 |