JP3129874U - Stator structure - Google Patents

Abstract

Provided is a stator structure that can be easily assembled and can increase an internal volume fraction.
A stator base has a plurality of pole columns, and each pole column extends inward along a diameter from an inner peripheral surface of the stator base and surrounds a central axis of the stator base. . An insulating groove 28 is formed between two adjacent poles, and each insulating groove 28 has a first outer groove 282, a second outer groove 284, and one inner groove 286. There is a first wire bracket 30 and a second wire bracket 40. The plurality of insulating pieces 50 are provided in the respective insulating grooves 28, and are attached to the peripheral edges of the first positioning portion 34 and the second positioning portion 44 and the groove walls of the inner grooves 286, respectively. For this reason, the stator structure 10 is considerably easy to assemble, and the insulating groove 50 does not occupy an excessive space.
[Selection] Figure 1

Description

  The present invention relates to a stator structure of a motor, and particularly relates to a kind of stator structure that can be easily assembled.

  Conventional motors mainly include one stator and one rotor, of which the stator mainly includes: There is a stator base, which has a shaft hole in the center of the stator base and is used for housing the rotor. The inner circumferential surface of the stator base has a plurality of pole columns extending inward along the diameter, and an insulating groove is formed between two adjacent pole columns, and the coil winding Used for. The two opposite ends of the stator are respectively fitted into the respective insulating grooves by using the positioning portions of the wire brackets, and are mutually coupled to complete the stator assembly.

  However, in the above structure, the length of the positioning portion of one wire bracket must be longer than the length of the positioning portion of the other wire bracket, and the relatively long positioning portion is passed through the insulating groove, so By assembling with the positioning part, the assembly is completed. When the length of the positioning part is relatively long, the positioning part cannot be smoothly passed through the insulating groove unless it has the necessary and sufficient thickness and strength, whereas if the positioning part is too thick, The space that occupies the insulating groove is increased, and the volume ratio of the coil in the insulating groove is lowered, causing difficulty in coil winding. In addition, when the positioning portion having a relatively long length is passed through the insulating groove and fitted with the positioning portion having a relatively short length, the number of the two positioning portions in the insulating groove that fit in the insulating groove Therefore, aiming between the positioning portion and the positioning portion is not easy, and it is extremely difficult to assemble.

  The main object of the present invention is to provide a kind of stator structure, which is easy to assemble and increases the volume fraction inside the stator structure.

In order to achieve the above object, the stator structure of the present invention includes the following. A stator base, two wire brackets and a plurality of insulating pieces. The stator base has a plurality of pole columns, and each pole column extends inward along the diameter of the stator base from the inner peripheral surface of the stator base, and the stator base has a central axis. An insulating groove is formed between two surrounding pole poles. Each of the insulating grooves has two outer grooves and one inner groove, and the width of the two outer grooves is larger than the width of each inner groove. Each wire bracket has a plurality of positioning portions corresponding to each outer groove, each positioning portion is positioned in each outer groove, and the thickness of each positioning portion is the same as that of each outer groove. It is equal to the distance from the groove wall to the groove wall of each inner groove, and the two wire brackets can be respectively fixed to both ends of the stator base. The insulating pieces are respectively provided in the insulating grooves, and are attached to the peripheral edges of the positioning portions and the groove walls of the inner grooves, respectively.
Therefore, when assembling, it is only necessary to fit each of the insulating pieces into each of the insulating grooves, and the assembling is extremely easy. Further, the thickness of each of the insulating pieces is considerably thin, and the periphery of each positioning portion and each Since each of the insulating pieces does not occupy a large space in each of the insulating grooves because it is attached to the groove wall of the inner groove, the volume ratio of the coil in each of the insulating grooves can be increased.

Here, a combination of diagrams is given, and a comparatively excellent example is given below, and the structure and effects of the present invention are described in detail. Among them, a simple explanation of the scheme is as follows.
FIG. 1 is an exploded schematic view showing a stator structure according to one relatively excellent embodiment of the present invention.
FIG. 2 is a front view showing a stator base of a stator structure according to one relatively excellent embodiment of the present invention.

FIG. 3 is another exploded schematic view showing a stator structure according to one relatively excellent embodiment of the present invention.
FIG. 4 is a perspective view showing a wire bracket having a stator structure according to one relatively excellent embodiment of the present invention.
FIG. 5 is an exploded schematic view showing a state in which a wire bracket is assembled to a stator base of a stator structure according to one relatively excellent embodiment of the present invention.

FIG. 6 is a schematic view showing a stator structure according to one relatively excellent embodiment of the present invention.
Reference is first made to FIG. This is a stator structure 10 according to a relatively excellent embodiment of the present invention. The stator structure 10 includes a stator base 20, a first wire bracket 30, a second wire bracket 40, and a plurality of insulating pieces 50. .

  Please refer to FIG. The stator base 20 is formed by stacking a plurality of silicon steel pieces 22a, silicon steel pieces 22b, and silicon steel pieces 22c, and a shaft hole 24 is provided at the center to accommodate the rotor. Used for. The stator base 20 has a plurality of pole columns 26 extending inward along the diameter of the stator base 20 on the inner peripheral surfaces of the silicon steel pieces 22a, silicon steel pieces 22b, and silicon steel pieces 22c. 26 surrounds the central axis of the stator base 20 at equal intervals, and an insulating groove 28 is formed between the two adjacent pole columns 26 so as to penetrate both front and rear ends, and is used for coil winding. The insulating groove 28 has a first outer groove 282, a second outer groove 284, and an inner groove 286. As shown in FIG. 3, the first outer groove 282 and the second outer groove 284 are formed in the two outermost silicon steel pieces 22a and 22b, respectively. The width of the second outer groove 284 is the same, the inner groove 286 is formed in the silicon steel pieces 22c stacked between the silicon steel pieces 22a and the silicon steel pieces 22b, and the inner groove 286 is the first groove 286. It is located between the outer groove 282 and the second outer groove 284, and the width of the inner groove 286 is smaller than that of the first outer groove 282 and the second outer groove 284.

  Please refer to FIG. The first wire bracket 30 has a first bracket body 32 and a plurality of first positioning portions 34 in which the first bracket body 32 extends outward. The position of each first positioning portion 34 matches the position of each first outer groove 282, and the thickness of each first positioning portion 34 varies from the groove wall of each first outer groove 282 to the groove of each inner groove 286. Equal to the distance to the wall. Further, the first bracket body 32 is formed with a first shoulder 36 on the inner periphery of each first positioning portion 34, and each first positioning portion 34 is fitted in each first outer groove 282. Each first shoulder 36 is in contact with one end surface of the stator base 20, and the first wire bracket 30 is fixed to one end of the stator base 20.

  The shape of the second wire bracket 40 and the shape of the first wire bracket 30 are the same. The second wire bracket 40 has a second bracket body 42 and a second positioning portion 44 extending outward from the second bracket body 42, and each second positioning portion 44. Is aligned with the position of each second outer groove 284, and the thickness of each second positioning portion 44 is thinner than the distance from the groove wall of each second outer groove 284 to the groove wall of each inner groove 286. Or equal. In the present embodiment, the thickness of each second positioning portion 44 is equal to the distance from the groove wall of each second outer groove 284 to the groove wall of each inner groove 286. Further, the second bracket body 42 is formed with a second shoulder 46 at the inner periphery of each second positioning portion 44, and each second positioning portion 44 is fitted into each second outer groove 284. Each second shoulder 46 is in contact with the other end surface of the stator base 20 and fixes the second wire bracket 40 to the other end of the stator base 20.

  Each insulating piece 50 is a thin piece made of a resin material, or may be insulating paper. Each insulating piece 50 can be bent in accordance with the shape of each insulating groove 28. The length of each insulating piece 50 is equal to the length of each insulating groove 28, and each insulating piece 50 enters into each insulating groove 28, the peripheral edge of each first positioning portion 34, the groove wall of each inner groove 286, and It sticks to the periphery of each second positioning part 44. And the stopper of the shoulder part 36 and each 2nd shoulder part 46 is fixed in each insulation groove | channel 28, and is as shown in FIG.

When the present embodiment is assembled with the above-described structure, first, the first positioning portion 34 of the first wire bracket 30 and the second positioning portion 44 of the second wire bracket 40 are respectively connected to the first positioning portion 34 of the stator base 20. In accordance with the outer groove 282 and the second outer groove 284, and further fitted into the first outer groove 282 and the second outer groove 284, respectively, the first shoulder portion 36 and the second shoulder portion 46, respectively. Are in contact with both end faces of the stator base 20 as shown in FIG. The thickness of each first positioning portion 34 is equal to the distance from the groove wall of each first outer groove 282 to the groove wall of each inner groove 286. The thickness of each second positioning portion 44 is equal to the distance from the groove wall of each second outer groove 284 to the groove wall of each inner groove 286. Therefore, when the first positioning portions 34 and the second positioning portions 44 are fitted into the first outer grooves 282 and the second outer grooves 284, the first outer grooves 282 and the second outer grooves 284 are fitted. The width of the outer groove 284 is reduced to be equal to the width of each inner groove 286, and finally, each insulating piece 50 enters the inside from each first outer groove 282, as shown in FIG. The thickness of each insulating piece 50 is considerably thin, and the length of each insulating piece 50 is equal to the length of each insulating groove 28, that is, each of the first outer groove 282, the second outer groove 284, and the inner groove 286. The total length. Therefore, when each insulating piece 50 enters into each insulating groove 28, both ends thereof are pressed by the first shoulder portions 36 and the second shoulder portions 46, respectively. It is fixed inside and sticks to the peripheral edge of each first positioning portion 34, the groove wall of each inner groove 286, and the peripheral edge of each second positioning portion 44, and does not occupy excessive space in each insulating groove 28. .
Therefore, the stator structure of this embodiment not only makes the assembly considerably easier by utilizing the design of the insulating piece, but also the insulating groove does not occupy an excessive space, and the coil is relatively not in the insulating groove. It becomes possible to occupy a large space, and the volume ratio in each insulating groove increases.

1 is an exploded schematic view showing a stator structure according to an embodiment of the present invention. 1 is a front view showing a stator base of a stator structure according to an embodiment of the present invention. FIG. 5 is another exploded schematic view showing a stator structure according to an embodiment of the present invention. 1 is a perspective view illustrating a wire bracket having a stator structure according to an embodiment of the present invention. 1 is an exploded schematic view showing a state in which a wire bracket is assembled to a stator base of a stator structure according to an embodiment of the present invention. It is a schematic diagram showing a stator structure according to an embodiment of the present invention.

Explanation of symbols

  10: Stator structure, 20: Stator base, 22a: Silicon steel piece, 22b: Silicon steel piece, 22c: Silicon steel piece, 24: Shaft hole, 26: Polar pole, 28: Insulating groove, 30: First wire bracket 32: first bracket body, 34: first positioning part, 36: first shoulder part, 40: second wire bracket, 42: second bracket body, 44: second positioning part, 46 : Second shoulder, 50: insulating piece, 282: first outer groove, 284: second outer groove, 286: inner groove

Claims (3)

The stator base has a plurality of pole columns, and each of the pole columns extends inward along the diameter of the stator base from the inner peripheral surface of the stator base, and surrounds the central axis of the stator base An insulating groove is formed between two adjacent poles, and each of the insulating grooves has two outer grooves and one inner groove, and the inner groove has two outer grooves. The width of the two outer grooves is wider than the width of the inner groove,
The two wire brackets are combined in a plurality with respect to the positioning portions of the respective outer grooves, the positioning portions are positioned in the outer grooves, and the thicknesses of the positioning portions are set to the outer grooves. Less than or equal to the distance from the groove wall to the groove wall of each inner groove,
A plurality of insulating pieces are provided in each of the insulating grooves, respectively, and are respectively attached to a peripheral edge of each positioning portion and a groove wall of each of the inner grooves.   The stator is formed by stacking a plurality of silicon steel pieces on each other, and the two outermost silicon steel pieces of the insulating groove respectively form two outer grooves, and the two silicon steel pieces are interposed between the two silicon steel pieces. The stator structure according to claim 1, wherein the stacked silicon steel pieces form the inner groove.   Each of the two wire brackets has a shoulder portion, and each of the shoulder portions extends inward from an inner peripheral edge of each positioning portion, and is in contact with both end faces of the stator base, respectively. The stator structure according to claim 2.

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