JP2001095188A - Insulator for motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an insuator for a motor which can increase the efficiency of the motor by increasing a space factor and can improve the quality of the windings and reduce the material cost. SOLUTION: This insulator includes a part 3 to be wound with a winding which is installed in each tooth 32 projecting in the radial direction of a core, covering axial end face and both side faces of the tooth 32. From the edges of the part 3 at the root side and at the end side of the tooth 32, a stopper section 5 at the root side and a stopper section 4 at the end side are projecting respectively only in the axial direction to prevent the radial movement of a winding 5 wound around the part 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to an insulator for a motor, and more particularly to an insulator for insulating a motor core and a winding.

[0002]

2. Description of the Related Art As shown in FIG. 11, a stator core 130 of a general motor has a cylindrical portion 131 having a circular outer periphery.
And teeth 132 projecting from the cylindrical portion 131 in the radial direction. At the tip of each tooth 132, projections 133 and 133 projecting from both sides in the circumferential direction are provided.
A gap 13 is provided between the projections 133 and 133 facing each other.
4 are provided. When winding the stator core 130, an insulator 105 having a shape that covers the surface of the cylindrical portion 131, the teeth 132, and the surface of the slot 135 existing between the adjacent teeth 132 is fitted and provided. A winding nozzle 140 is inserted into the slot 135 through a gap between the projections 133 and 133 facing each other, and the winding nozzle 140 rotates around each tooth 132 to put the insulator 105 around each tooth 132. The wire is wound through the wire to form a winding 150.

As shown in FIG. 10, a conventional insulator 105 is provided corresponding to a ring portion 106 corresponding to a cylindrical portion 131 of a stator core 130, and corresponding to each tooth 132. And a coiled portion 107 covering the surface. A locking portion 108 for preventing the winding wound on the wound portion 107 from coming off in the inner diameter direction is formed at the edge of the tooth end of the wound portion 107. The locking portion 108 extends in both the axial direction and the circumferential direction.

[0004]

However, when the conventional insulator 105 is used, there are the following problems.

When the wire is wound, FIG.
As shown in FIG. 12, the winding nozzle 140 causes each of the teeth 132 to move due to the protrusions 133 and 133 and the locking portion 108 of the insulator 105 (not shown in FIG. 12A).
Of the winding nozzle 140 is relatively remote from the end surface 132a and the side surface 132b (the trajectory of the winding nozzle 140 is indicated by a dashed line). Even if used, the wire 151
It is difficult to align winding. Therefore, the space factor cannot be increased, and the efficiency of the motor cannot be improved. FIG.
As shown in (b), the SR (switched reluctance) motor that has recently been put into practical use has no protrusion projecting to both sides in the circumferential direction at the tip of the teeth 132 ′ in the inner diameter direction. There is a possibility that an orbit (indicated by a dashed line in FIG. 12B) can pass through the end face 132a 'and the side face 132b' of the tooth 132 '. Therefore, when the insulator 105 having the locking portion 108 is applied to the SR motor as it is, this problem is noticeable.

[0006] The locking portion 10 is attached to the insulator 105.
When the wire 8 does not exist, as shown in FIGS. 14 (a) and 14 (b), the wire 151 that has already been wound receives the component force f of the tension of the wire 151 ′ that is wound thereon, and , The windings are disturbed and the coils are missing. FIG. 14A shows a cross section of the stator core 130 cut perpendicularly to the center axis, and FIG. 14B shows a cross section taken along line BB in FIG. 14A.

[0007] As shown in FIG.
When R (R) 132c is provided at the root of the insulator 32, the surface of the insulator 105 also has a shape reflecting the R132c. (The range indicated by A), the winding of the wire 151 is disturbed, and it is difficult to arrange and wind.

In order to give priority to alignment, FIG.
As shown in (b), a method is conceivable in which the wire is not wound near the root of the tooth 132, but is wound only on a flat portion on the distal end side. However, although this improves the alignment, the effective slot area for the winding is reduced, so that the space factor cannot be increased and the efficiency of the motor cannot be improved.

As shown in FIG. 13, a portion 107a of the wound portion 107 of the conventional insulator 105 that covers the axial end surface 132a of the tooth 132 is formed flat, and the corners 107c, 107c are at right angles. When the wire 151 is wound around the wound part 107 with a finite tension, the wire 151 is wound around the corner 107 c of the wound part 107 due to the elasticity of the wire 151.
The portion other than the portion 107c is swelled far away from the insulator surface. As a result, the teeth 132
Distance Δ between the wire 151 and the insulator surface on the side of
And the space factor cannot be increased, and the efficiency of the motor cannot be improved.

SUMMARY OF THE INVENTION An object of the present invention is to provide a motor insulator capable of increasing the space factor and improving the efficiency of a motor, and improving the quality of a winding and reducing material costs.

[0011]

In order to achieve the above object, an insulator for a motor according to claim 1 is mounted on a tooth projecting in a radial direction of a core, and covers an axial end surface and both side surfaces of the tooth. The wound part and the winding wound around the wound part protruding only in the axial direction from the edge of the wound part corresponding to the root side and the tip side of the teeth, respectively, in the radial direction. And a base-side locking portion and a distal-side locking portion for prohibiting movement to the front side.

In the motor insulator according to the first aspect, the distal end locking portion protrudes from the edge of the wound portion corresponding to the distal end side of the teeth. However, since the distal locking portion projects only in the axial direction, when the wire is wound around the wound portion, the distal locking portion is located on both circumferential sides from the edge of the wound portion. As compared with the case in which the teeth protrude, the winding nozzle can pass along a track close to the side surface of each tooth, and the aligned winding of the wire is facilitated as compared with the related art. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to a second aspect of the present invention, there is provided an insulator for a motor, which is mounted on a core having a plurality of teeth projecting in a radial direction, and insulates the core and a winding wound around the teeth. An annular ring portion along the core body, and a wound portion provided at a position corresponding to each of the teeth along the circumferential direction of the ring portion and covering the axial end surfaces and both side surfaces of the teeth. , Protruding only in the axial direction from the edge of the wound portion corresponding to the root side and the tip side of the teeth, and prohibits the winding wound around the wound portion from moving in the radial direction. It is characterized by having a root side locking part and a tip side locking part.

In the motor insulator according to the second aspect, the front end side locking portion projects from the edge of the wound portion corresponding to the front end side of the teeth. However, since the distal locking portion projects only in the axial direction, when the wire is wound around the wound portion, the distal locking portion is located on both circumferential sides from the edge of the wound portion. As compared with the case in which the teeth protrude, the winding nozzle can pass along a track close to the side surface of each tooth, and the aligned winding of the wire is facilitated as compared with the related art. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to a third aspect of the present invention, there is provided an insulator for a motor, which is mounted on a core having a plurality of teeth projecting in a radial direction and insulates the core from a winding wound around the teeth. An annular ring portion along the core body, and a wound portion provided at a position corresponding to each of the teeth along the circumferential direction of the ring portion and covering the axial end surfaces and both side surfaces of the teeth. , Projecting in a direction perpendicular to the wound portion from the edges of the wound portion corresponding to the root side and the tip side of the teeth, the winding wound around the wound portion is radially A base side locking portion and a front side locking portion for inhibiting movement of the base side locking portion, and a dimension that the front side locking portion protrudes is set smaller than a size of the base side locking portion protruding. It is characterized by.

In the motor insulator according to the third aspect of the present invention, the distal end side locking portion projects vertically from the edge of the wound portion corresponding to the distal end side of the teeth. However, the size at which the distal locking portion protrudes is set smaller than the size at which the base locking portion protrudes. Therefore, when the wire is wound around the wound portion, the winding nozzle has a smaller diameter than that of the case where the tip side locking portion protrudes larger than the base side locking portion protrudes. Can be passed along the track close to the end face of the wire, and the aligned winding of the wire is easier than in the past. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to a fourth aspect of the present invention, in the motor insulator according to the first or second aspect, the dimension at which the distal locking portion projects is larger than the dimension at which the root locking portion projects. It is characterized by being set small.

The motor insulator according to the fourth aspect of the present invention includes a root-side locking portion and a distal-side locking portion that protrude only in the axial direction from the edges of the wound portion corresponding to the root side and the distal side of the teeth. When the wire is wound around the wound portion, the tip-side locking portion is set smaller than the dimension of the base-side locking portion protruding. In comparison with the case where the projecting dimension is larger than the projecting dimension of the base side locking portion, the winding nozzle can pass through the track close to the axial end faces and both side faces of each tooth, and Can be easily wound. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

The motor insulator according to claim 5 is the motor for insulator according to any one of claims 1 to 4, the dimension in which the front end side locking portion is protruded as h _1, the winding Where d is the diameter of the wire constituting d, the relationship d / 2 <h ₁ holds.

In the motor insulator according to the present invention, when the dimension at which the distal end side locking portion projects is h ₁ and the diameter of the wire forming the winding is d, d / 2 <.
Since the relationship h ₁ is established, it is possible to reliably prevent the winding wound on the wound portion from shifting in the inner diameter direction by the front-end-side locking portion.

A motor insulator according to a sixth aspect of the present invention is the motor insulator according to any one of the first to fifth aspects, wherein the dimension at which the root locking portion projects is h ₂ , and the winding is Let d be the diameter of the constituent wire,
When the distance between the roots of adjacent teeth is W _sb , the relationship of (W _sb −d) / 2 <h ₂ is established.

In the motor insulator according to the present invention, the dimension at which the base side locking portion protrudes is defined as h ₂ , the diameter of the wire forming the winding is defined as d, and the distance between the roots of adjacent teeth is defined as h ₂ . When W _sb is satisfied, the relationship of (W _sb −d) / 2 <h ₂ is satisfied. Therefore, the root-side locking portion prevents the winding wound on the wound portion from shifting in the outer diameter direction. Can be locked securely.

According to a seventh aspect of the present invention, there is provided the motor insulator according to the first, second, fourth, fifth or sixth aspect of the present invention, wherein the distal end side locking portion protrudes in the axial direction. Or, it is characterized by being chamfered.

In the motor insulator according to the seventh aspect, since the distal end side locking portion is rounded or chamfered at the corner at the distal end projecting in the axial direction, the wire is wound around the wound portion. When this is done, the winding nozzle can pass along a trajectory closer to the end face of each tooth, further facilitating aligned winding of the wire. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to an eighth aspect of the present invention, there is provided the motor insulator according to the first, second, fourth, fifth or sixth aspect, wherein the root-side locking portion is provided at a tip portion where it projects in the axial direction. An element for processing the portion to bind the winding is formed.

Here, the term "winding" is a concept including a lead wire added to the winding to connect the winding to an external terminal.

In the motor insulator according to the eighth aspect, the element for binding the winding is formed at the tip of the base side locking portion projecting in the axial direction. The wound winding is easily bound using the elements. Moreover, a lead wire added to the winding for connecting the winding to an external terminal is also bound using this element. As a result, the winding can be prevented from loosening and the lead wire can be fixed, and the quality of the winding can be improved. Also, since the element is formed by processing the tip portion of the base side locking portion,
The material for binding the windings can be saved.

According to a ninth aspect of the present invention, there is provided a motor insulator mounted on a tooth protruding in a radial direction of a core, the wound portion covering an axial end face and both side faces of the tooth,
The windings wound around the wound portions project in the direction perpendicular to the wound portions from the edges of the wound portions corresponding to the root side and the tip side of the teeth, respectively. A root-side locking portion and a tip-side locking portion for inhibiting movement are provided, and the surface of the root-side locking portion on the side of the wound portion has a step-like shape according to the diameter of a wire constituting the winding. It is characterized by being formed in.

In the motor insulator according to the ninth aspect, the surface of the base side locking portion on the side of the wound portion is formed stepwise according to the diameter of the wire constituting the winding. Even when R is provided at the base of the wire, the winding of the wire is not disturbed near the base of the wound portion, and the aligned winding can be performed. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

The motor insulator according to a tenth aspect of the present invention is the motor insulator according to the ninth aspect, wherein the step of each step on the side of the wound portion of the base side locking portion is H,
When the depth of each step is D, and the diameter of the wire forming the winding is d, the relationship of H = d × 3 ^1/2 / 2 D = d / 2 holds substantially. I do.

Here, “substantially” means that minor differences that are not essential, such as errors caused by machining accuracy, are included.

In the motor insulator according to the tenth aspect, the step of each step on the side of the wound portion of the base side locking portion is H, the depth of each step is D, and the diameter of the wire forming the winding is When d is satisfied, the relationship of H = d × 3 ^1/2 / 2 D = d / 2 holds, so that the aligned winding can be reliably performed. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to an eleventh aspect of the present invention, in the motor insulator according to any one of the first to tenth aspects, a portion of the wound portion that covers the axial end surface of the teeth has a diameter. The dimension extending flat in the direction is L _1, and the diameter of the wire constituting the winding is d.
Where N ₁ is a natural number, and a relation of L ₁ = d × N _{1 is} substantially established.

In the motor insulator according to the eleventh aspect, the dimension of the portion of the wound portion covering the axial end surface of the tooth extending flat in the radial direction is L _1, and the diameter of the wire constituting the winding is d. When N ₁ is a natural number, the relationship of L ₁ = d × N ₁ holds substantially, so that the surface of the wound portion between the distal locking portion and the root locking portion is a wire. Filled without gaps. Therefore, it is possible to prevent the already wound wire from being displaced in the radial direction due to the component force of the tension of the wire wound on the upper layer, thereby preventing the winding error.

According to a twelfth aspect of the present invention, there is provided a motor insulator mounted on a tooth protruding in a radial direction of a core, a wound portion covering an axial end face and both side faces of the tooth, a root side and a tip end of the tooth. A root that protrudes from the edge of the wound portion corresponding to the side in a direction perpendicular to the wound portion to prohibit the winding wound around the wound portion from moving in the radial direction. The surface of a portion of the wound portion that covers the axial end surface of the tooth is provided with a side locking portion and a tip side locking portion, and a central portion of the surface protrudes in the axial direction from both circumferential end portions. It is characterized by the following.

In the motor insulator according to the twelfth aspect, the surface of the portion of the wound portion that covers the axial end surfaces of the teeth has a central portion projecting in the axial direction more than the ends on both sides in the circumferential direction. At the end, the angle at which the wire should be bent becomes dull compared to the conventional (right angle). Therefore,
The distance (the bulge of the wire) Δ between the wire and the surface of the insulator on the side of the tooth is reduced. As a result, the space factor can be increased, and the efficiency of the motor can be improved. Further, since the angle at which the wire should be bent becomes dull compared to the conventional (right angle), the wire is less likely to be damaged, and the quality of the winding can be improved.

A motor insulator according to a thirteenth aspect is the motor insulator according to any one of the first to twelfth aspects, wherein the core is a stator core of an SR motor.

As is known, the stator core of the SR motor differs from a normal motor in that it does not have a protrusion at the radial end of the teeth that protrudes on both sides in the circumferential direction. Therefore, the motor insulator according to the thirteenth aspect can reliably achieve the functions and effects of the first to twelfth aspects.

[0039]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a motor insulator according to the present invention will be described in detail with reference to the illustrated embodiments.

FIG. 1A shows the insulator 1 of one embodiment viewed in the axial direction, and FIG. 1B shows a cross section taken along the line BB in FIG. 1A. The insulators 1 are prepared as a pair and are to be fitted to and mounted on the stator core of the SR motor (not shown) from both sides in the axial direction. In this example, the stator core of the SR motor has a cylindrical portion as a core body having a circular outer periphery, and twelve teeth projecting in an inner diameter direction from the cylindrical portion (in the same manner as shown in FIG. 12B). Without protrusions on both sides in the direction). However, the outer periphery of the core may be square, and the number of teeth may be six or eight. This is because the present invention is not limited to the outer peripheral shape of the core or the number of teeth. FIG.
In (a), the arrangement of two adjacent teeth 32, 32 is indicated by broken lines.

The insulator 1 is provided at a position corresponding to each of the teeth 32 along the circumferential direction of the ring portion 2 along the cylindrical portion of the stator core. And a wound part 3 covering the end face and both side faces. 3 shown in FIG.
a is a rectangular plate-shaped portion that covers the axial end surface of the tooth 32,
Reference numeral 3b denotes a rectangular plate-like portion that covers the side surface of the tooth 32. In FIGS. 2 to 5 described later, a portion 3b of the wound portion 3 that covers the side surface of the tooth 32 is omitted for simplicity.

The windings wound around the wound portion 3 move in the radial direction on the edges of the wound portion 3 corresponding to the root side and the tip side of the teeth 32, respectively. A base side locking portion 5 and a front side locking portion 4 are formed to prohibit the operation. The root-side locking portion 5 and the distal-side locking portion 4 protrude only axially from the root-side and distal-side edges of the wound portion 3. As can be clearly seen from FIG.
In this example, each of the distal end side locking portions 4 has a rectangular plate shape having the same horizontal width (width in the circumferential direction) of the wound portion 3, and has a height h ₂ from the surface of the wound portion 3. and protrudes in the axial direction by h _1. The height h ₁ of the tip side locking portion 4 is lower than the height h ₂ of the root side locking portion 5, and is set as h ₁ <h ₂ (1). As described above, the distal locking portion 4 protrudes only in the axial direction from the edge of the wound portion 3, and the height h ₁ of the distal locking portion 4 is greater than the height h _{2 of the} root locking portion 5. When the wire 51 is wound around the wound portion 3 as shown in FIGS. 3 (a) and 3 (b), the winding nozzles are set to the side surface and the axial end surface of each tooth 32. , And the wire 51 can easily be aligned and wound. As a result, the space factor can be increased, and the efficiency of the motor can be improved. FIG. 3A shows a wire 51.
Is schematically shown in the axial direction when one of the wound portions 3 is wound, and FIG.
It shows a cross section taken along the line arrow.

Here, the relationship between the height h ₁ of the distal locking portion 4 and the diameter d of the wire 51 is set to d / 2 <h ₁ (2). This allows the leading end side locking portion 4 to reliably lock the winding 50 wound on the wound portion 3 from shifting in the radial direction.

Further, the relationship between the height h _{2 of the} base side locking portion 5 and the diameter d of the wire 51 is such that the adjacent teeth 32, 3
_Assuming that the interval between the roots of No. 2 is W _sb (see FIG. 1A), (W _sb −d) / 2 <h ₂ (3) is set. This allows the root side locking portion 5 to reliably lock the winding 50 wound on the wound portion 3 from shifting in the outer diameter direction.

Further, L ₁ (the distance between the distal end side engaging portion 4 and the base side engaging portion 5) radial length of the winding section 3, when the N ₁ is a natural number, L ₁ = D × N ₁ (4) As a result, the surface of the wound portion 3 between the distal locking portion 4 and the root locking portion 5 is filled with the wire 51 without any gap. Therefore, the wire 51 that has already been wound is not displaced in the radial direction due to the component force of the tension of the wire 51 that is wound on the upper layer, thereby preventing the wire 51 from being wound.

The corner at the tip from which the tip locking portion 4 projects in the axial direction may be rounded or chamfered. For example, in the distal locking portion 4A shown in FIG. 4A, the corners 4Ac, 4Ac on both sides of the distal end are rounded so that the corners are rounded outward. The tip side locking portion 4B shown in FIG. 4B has corners 4Bc, 4Bc on both sides of the tip.
The corners are chamfered and the corners are cut off diagonally. Thereby, when winding the wire 51 around the wound part 3, the winding nozzle can pass along the track closer to the side face and the axial end face of each tooth 32, and furthermore, the wire is aligned and wound. Becomes easier. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

Further, an element for binding the winding 50 may be formed at the end of the root-side locking portion 5 protruding in the axial direction by processing the portion. For example, in the root side locking portion 5C shown in FIG. 5A, a through hole 11 is formed at the center of the tip, and V-shaped notches 12,
12 are formed. Protrusions 13, 13 are formed on both sides of the distal end of the base side locking portion 5D shown in FIG. 5 (b). If these elements 11, 12, and 13 are used, the winding 50 wound on the wound portion 3 and the lead wire for connecting the winding 50 to an external terminal (not shown) can be easily formed. You can unite. As a result, the winding can be prevented from being loosened and the lead wire can be fixed, and the quality of the winding 50 can be improved. Further, since these elements 11, 12, and 13 are formed by processing the distal end portion of the base side locking portion, the material for binding the winding 50 and the like can be saved.

As shown in FIGS. 6 (a) and 7 (a), when the R (R) 32c is provided at the root of the tooth 32, the root side connection is made over the range where the R 32c exists in the radial direction. The surface of the stop portion 5 (represented by 5E and 5F in FIGS. 6 and 7) on the side of the wound portion 3 is
It is desirable to form it in a step-like manner according to the diameter of 1. FIG.
In the examples (a) and (b) (FIG. 6 (b) shows a cross section taken along line BB in FIG. 6 (a)), a portion of the wound part 3 which covers the axial end surface of the tooth 32. 3a and root side locking part 5
The surface 5Ea between E and E is formed stepwise. FIG.
In the examples (a) and (b) (FIG. 7 (b) shows a cross section taken along the line BB in FIG. 7 (a)), a portion of the wound part 3 covering the axial end surface of the tooth 32. 3a and root side locking part 5
The stairs are extended not only to the front surface 5Fa between the front end F and the side 5Fb in a range corresponding to the wound portion 3 of the root side locking portion 5F.

Here, the wound portion 3 and the base side locking portion 5E,
The number of steps between 5F is set to a natural number obtained by dividing the radius of curvature of R32c by (d / 2), where d is the diameter of the wire 51, and rounding down the decimal point of the quotient. As illustrated in FIG. 8, a step H of each step and a depth D of each step between the wound part 3 and the root side locking part 5E are respectively H = d × 3 ^1/2 / 2. .. (5) D = d / 2 (6) The same applies to the step H of each step and the depth D of each step between the wound part 3 and the base side locking part 5F. By this, even if the root of the tooth 32 is R32c
Is provided, the winding of the wire is not disturbed in the vicinity of the root of the wound portion 3, and the aligned winding can be reliably performed. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

FIG. 9 (a-1), (a-2),
As shown in (b) and (c), the tee
(See 3G, 3H, 3I)
Center) protrudes more axially at the center than at both ends
It is desirable to do. In the example shown in FIG.
A portion 3G of the wire portion 3 covering the axial end surface of the tooth 32;
R is applied to the corners 3Gc, 3Gc on both sides,
The na is round toward the outside. FIG. 9 (a-
The wire 51 is wound around the wound part 3 as shown in 2).
When the corners 3Gc, 3Gc
The angle at which the hook 51 should be bent is conventional (as shown in FIG. 13).
(Right angle). Therefore, teeth 32
The distance between the wire 51 and the insulator surface (side
Bulge) Δ ₁Becomes smaller. As a result, the space factor
And the efficiency of the motor can be improved. Also,
The angle at which the ear 51 should be bent is duller than the conventional (right angle)
Less damage to the wire and improve winding quality
it can. In the example shown in FIG.
The portion 3H covering the axial end face of the wire 32 is
Corners 3Hc, 3Hc are chamfered and corners are slanted
It has a cut-out shape. Also, as shown in FIG.
In the example, the axial end surface of the tooth 32 of the wound portion 3
3I, the corners 3Ic, 3Ic on both sides are cut
It is taken out and dented in steps. Also in these cases,
As in the cases (a-1) and (a-2), the wire 51
Since the angle to be bent becomes dull compared to the conventional (right angle),
Wire 51 and insulator surface beside teeth 32
Distance (wire bulge) Δ_Two, Δ_ThreeBecomes smaller,
As a result, the space factor can be increased and the motor efficiency can be improved.
I can do it. In addition, the wire is less likely to be damaged, and the winding quality
Can be improved.

In this embodiment, the front end locking portion 4
Is projected only in the axial direction from the edge on the distal end side of the wound portion 3, but the projected size is smaller than the size of the base side locking portion 5 projected, and when the winding nozzle rotates, If it does not get in the way, it may protrude laterally (circumferentially) from the edge on the tip side of the wound portion 3.

In this embodiment, the insulator 1 to be mounted on the stator core of the SR motor has been described. However, the present invention can also be applied to an insulator to be mounted on the stator core of an outer rotor type motor. In other words, the present invention can be applied to the insulator of the present invention, even if the teeth protrude in the outer diameter direction from the core body provided on the inner side, and the same effects can be obtained.

[0053]

As is apparent from the above description, in the motor insulator according to the first aspect, since the distal locking portion projects only in the axial direction, the wire is wound around the wound portion. When compared to the case where the distal end side locking portion protrudes from the edge of the wound portion to both sides in the circumferential direction, the winding nozzle can pass through the track close to the side surface of each tooth, As a result, the wire can be easily aligned and wound. As a result,
The space factor can be increased, and the efficiency of the motor can be improved.

Similarly, in the motor insulator according to the second aspect, since the distal locking portion projects only in the axial direction, when the wire is wound around the wound portion, the distal locking portion protrudes. In comparison with the case where the part protrudes from the edge of the part to be wound on both sides in the circumferential direction, the winding nozzle can pass through the track close to the side surface of each tooth, and the wire Alignment winding becomes easy. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

In the motor insulator according to the third aspect,
The distal end locking portion projects vertically from the edge of the wound portion corresponding to the distal end side of the tooth, and the dimension at which the distal locking portion protrudes is that the root locking portion protrudes. Because it is set smaller than the dimensions, when winding the wire around the wound part, the size that the tip side locking part protrudes is larger than the case where the root side locking part protrudes. hand,
The winding nozzle can pass along the track close to the end face of each tooth, and the aligned winding of the wire is easier than before. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to the motor insulator of the fourth aspect,
It has a root-side locking portion and a distal-side locking portion that protrude only in the axial direction from the edges of the wound portion corresponding to the root side and the distal side of the teeth, respectively. Since the base side locking portion is set smaller than the projecting size, when the wire is wound around the wound portion, the size at which the tip side locking portion protrudes is such that the base side locking portion protrudes. As compared with the case where the size is larger than the size, the winding nozzle can pass along a track close to the axial end face and both side faces of each tooth, and furthermore, it becomes easy to align and wind the wires. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

In the motor insulator according to the fifth aspect,
Dimensions the distal end side engaging portion is projected and h _1, when the diameter of the wire constituting the winding was d, d / 2 <since h ₁ becomes relationship holds, wound onto the winding section The deviation of the wound winding in the radial direction can be reliably locked by the distal end locking portion.

According to the motor insulator of the sixth aspect,
Assuming that the dimension at which the base side locking portion protrudes is h ₂ , the diameter of the wire constituting the winding is d, and the distance between the bases of adjacent teeth is W _sb , (W _sb −d) / Since the relationship of 2 <h ₂ holds, the displacement of the winding wound on the wound portion in the outer diameter direction can be reliably locked by the base side locking portion.

According to the motor insulator of claim 7,
The tip end locking portion projects R in the axial direction.
Or, since the chamfer is applied, when winding the wire around the wound portion, the winding nozzle can pass along a track closer to the end face of each tooth, and furthermore, the aligned winding of the wire is It will be easier. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

In the motor insulator according to claim 8,
An element for bundling the winding is formed at the tip of the base side locking portion projecting in the axial direction, so that the winding or lead wound on the part to be wound takes the element. Easy to use and unite. As a result, the winding can be prevented from loosening and the lead wire can be fixed, and the quality of the winding can be improved. Further, since the element is formed by processing the tip portion of the base side locking portion, the material for binding the windings and the lead wires can be saved.

In the motor insulator according to the ninth aspect,
Since the surface on the wound portion side of the root side locking portion is formed in a step-like shape according to the diameter of the wire constituting the winding, even if R is provided at the root of the tooth, Also,
Disturbance of the winding of the wire does not occur near the root of the wound portion, and aligned winding becomes possible. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

According to a tenth aspect of the present invention, the step of each step on the side of the wound portion of the root side locking portion is H, the depth of each step is D, and the diameter of the wire forming the winding is d. In this case, since the relation of H = d × 3 ^1/2 / 2 D = d / 2 holds, the aligned winding can be performed reliably. As a result, the space factor can be increased, and the efficiency of the motor can be improved.

In the motor insulator according to the eleventh aspect, the dimension of the portion of the wound portion covering the axial end face of the tooth extending flat in the radial direction is L _1, and the diameter of the wire forming the winding is d. , N ₁ is a natural number, the relationship of L ₁ = d × N ₁ holds substantially. Therefore, the surface of the wound portion between the distal-side locking portion and the root-side locking portion has a wire gap. Buried without. Accordingly, it is possible to prevent the already wound wire from being displaced in the radial direction due to the component force of the tension of the wire wound on the upper layer, thereby preventing the winding from being shifted.

In the motor insulator according to the twelfth aspect, the surface of the portion of the wound portion that covers the axial end surface of the tooth has a central portion projecting in the axial direction more than the ends on both sides in the circumferential direction. The angle at which the wire should be bent at the end becomes dull compared to the conventional (right angle). Therefore, the distance (swelling of the wire) Δ between the wire and the surface of the insulator on the side of the tooth is reduced. As a result, the space factor can be increased, and the efficiency of the motor can be improved. Further, since the angle at which the wire should be bent becomes dull compared to the conventional (right angle), the wire is less likely to be damaged, and the quality of the winding can be improved.

In the motor insulator according to the thirteenth aspect, since the core is the stator core of the SR motor, the effects of the first to twelfth aspects can be reliably achieved.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of an insulator according to an embodiment of the present invention.

FIG. 2 is a view showing a root side locking portion and a distal side locking portion which protrude only in the axial direction from a wound portion of the insulator.

FIG. 3 is a diagram showing a state in which a wire is wound around a wound portion of the insulator.

FIG. 4 is a view showing a modified example of the distal end side locking portion.

FIG. 5 is a view showing a modified example of the base side locking portion.

FIG. 6 is a view showing a modification in which the surface between the wound portion and the base side locking portion is formed in a step shape.

FIG. 7 is a view showing another modified example in which the surface between the wound portion and the base side locking portion is formed in a step shape.

FIG. 8 is a diagram illustrating the design of each stage between the wound portion and the base side locking portion.

FIG. 9 is a view showing a modified example of a portion of the wound portion that covers the axial end surface of the tooth.

FIG. 10 is a diagram illustrating a conventional motor insulator.

FIG. 11 is a diagram illustrating a conventional insulator mounted on a stator core of a motor.

FIG. 12 shows a conventional motor insulator.
It is a figure explaining a problem about a track of a winding nozzle.

FIG. 13 shows a conventional motor insulator.
It is a figure explaining the problem regarding the swelling of a winding.

FIG. 14 is a diagram illustrating a problem in a case where a base side locking portion and a distal end side locking portion are not provided in a wound portion;

FIG. 15 is a diagram illustrating a problem in a conventional motor insulator when R (R) is provided at the base of a tooth.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Insulator 2 Ring part 3 Winding part 4, 4A, 4B Tip side locking part 5, 5C, 5D, 5E, 5F Root side locking part

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5H604 AA05 BB01 BB10 BB14 CC01 CC05 CC14 CC16 PB03 5H619 AA03 AA05 BB01 BB06 BB13 BB15 BB24 PP01 PP05 PP14 PP17

Claims (13)

[Claims] A tooth (3) protruding in a radial direction of a core.
2) The wound portion (3) mounted on the tooth (32) and covering the axial end surface and both side surfaces of the tooth (32); and the wound portion (3) corresponding to the root side and the tip side of the tooth (32). ) Protrudes only in the axial direction from the edge of each of the windings (5) wound around the wound portion (3).
A motor comprising: a base side locking portion (5, 5C, 5D, 5E, 5F) and a front end side locking portion (4, 4A, 4B) for prohibiting radial movement of the (0). For insulator. 2. A plurality of radially projecting teeth (3).
An insulator attached to a core having a core (2) and insulating the core and a winding (50) wound around the teeth (32), the insulator including an annular ring portion (2) along the core body. ), Provided at positions corresponding to the respective teeth (32) along the circumferential direction of the ring portion (2).
Winded part (3) covering the axial end face and both side faces of 2)
And windings wound around the wound portion (3), protruding only in the axial direction from the edges of the wound portion (3) corresponding to the root side and the tip side of the teeth (32). (50) prohibits the radial movement of the base side locking portion (5, 5).
C, 5D, 5E, 5F) and the front end locking portion (4, 4
(A, 4B). 3. A plurality of teeth (3) projecting radially.
An insulator attached to a core having a core (2) and insulating the core and a winding (50) wound around the teeth (32), the insulator including an annular ring portion (2) along the core body. ), Provided at positions corresponding to the respective teeth (32) along the circumferential direction of the ring portion (2).
Winded part (3) covering the axial end face and both side faces of 2)
And projecting in a direction perpendicular to the wound portion (3) from the edges of the wound portion (3) corresponding to the root side and the tip side of the tooth (32), respectively. Root-side locking portions (5, 5C, 5D, 5E, 5) that prohibit the winding (50) wound around (3) from moving in the radial direction.
F) and distal locking portions (4, 4A, 4B), and the dimensions of the distal locking portions (4, 4A, 4B) protruding are the root locking portions (5, 5C, 5D, 5E). , 5F) is set to be smaller than the projecting dimension. 4. The insulator for a motor according to claim 1, wherein the dimension at which the tip-side locking portions (4, 4A, 4B) protrude is equal to the base-side locking portions (5, 5C, 5D, 5E). , 5F) is set to be smaller than the projecting dimension. 5. A motor insulator according to any one of claims 1 to 4, the distal end side engaging portion (4, 4A, 4B) dimensioned to protrude as h _1, the winding (50 ) Constituting wire (51)
Where d is the diameter of d and d / 2 <h ₁ . 6. The motor insulator according to claim 1, wherein the dimension at which the base side locking portions (5, 5C, 5D, 5E, 5F) protrude is h ₂ , and the winding length is h ₂ . When the diameter of the wire (51) constituting the wire (50) is d, and the distance between the roots of the adjacent teeth (32) is W _sb , the relationship of (W _sb −d) / 2 <h ₂ is obtained. An insulator for a motor, wherein the insulator is satisfied. 7. The motor insulator according to claim 1, 2, 4, 5, or 6, wherein the front end side locking portions (4A, 4B) are provided at the front end corners (4Ac, 4Bc) projecting in the axial direction. An insulator for a motor, wherein the insulator is rounded or chamfered. 8. The insulator for a motor according to claim 1, wherein the root-side locking portions (5C, 5D) are formed into a portion at a tip end projecting in the axial direction. And an element (11, 12, 13) for binding the winding (50). 9. A tooth (3) projecting in a radial direction of a core.
2) The wound portion (3) mounted on the tooth (32) and covering the axial end surface and both side surfaces of the tooth (32); and the wound portion (3) corresponding to the root side and the tip side of the tooth (32). ) Protrudes in a direction perpendicular to the wound part (3) from the edge of the winding part (3), and prevents the winding (50) wound around the wound part (3) from moving in the radial direction. It has a base side locking part (5E, 5F) and a tip side locking part (4, 4A, 4B), and the surface (5Ea) of the base side locking part (5E, 5F) on the side of the wound part (3). , 5Fa, 5Fb) are connected to the winding (50).
A motor insulator characterized in that it is formed stepwise according to the diameter of a wire (51) constituting the motor insulator. 10. The insulator for a motor according to claim 9, wherein the step of each step on the side of the wound portion (3) of the root side locking portion (5E, 5F) is H, and the depth of each step is D. And the winding (5
When the diameter of the wire (51) constituting 0) is d,
An insulator for a motor, wherein a relation of H = d × 3 ^1/2 / 2 D = d / 2 is substantially satisfied. 11. The insulator for a motor according to claim 1, wherein a portion of the wound portion (3) covering an axial end surface of the tooth (32) is flat in a radial direction. the dimension extending and L _1, the diameter of the wire (51) constituting the winding (50) is d, when the N ₁ is a natural number, essentially L ₁ = d × N ₁ becomes relationship holds that An insulator for a motor characterized by the above-mentioned. 12. A tooth (3) projecting radially of a core.
2) The wound portion (3) mounted on the teeth (32) and covering the axial end surface and both side surfaces of the teeth (32), and the wound portion (3) corresponding to the root side and the tip side of the teeth (32). ) Protrudes in a direction perpendicular to the wound portion (3) from the edges of the winding portion (3), and prevents the winding (50) wound around the wound portion (3) from moving in the radial direction. Root side locking part (5, 5C, 5D, 5E, 5
F) and distal end locking portions (4, 4A, 4B), and the surfaces of the portions (3G, 3H, 3I) of the wound portion (3) covering the axial end surfaces of the teeth (32) are A motor insulator characterized in that a central portion protrudes in the axial direction from end portions (3Gc, 3Hc, 3Ic) on both sides in the circumferential direction. 13. The insulator for a motor according to claim 1, wherein the core is a stator core of an SR motor.