JP2002272051A - Stator for generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provided a stator of a generator, which can prevent breaking of a crossover wire, even if vibration is applied under the condition that coils are wound in succession in the reverse order. SOLUTION: A circular part 1, corresponding to the base of each pole 2a-2c and 2e-2g, is provided, severally with coil locking parts 5a-5t. The winding end line of the coil 4a wound on one pole 2a is so regulated by the coil locking part 5d, as to be led to the end face side in the stacking direction of the circular part 1, being annexed to a pole 4a. The winding end line having reached the end face side in the stacking direction of the circular part 1 is laid over as a crossover 4w to the neighboring pole 2b, along the circular part 1 by the coil locking parts 5d, 5e, and 5f. In the neighboring pole 2b, it is wound on this pole, being regulated by the coil locking part 5f. The winding end line of the coil 4b wound on this pole 2c is regulated by the coil locking part 5q, so as to be led to the end face side in the stacking direction of the circular part 1 along the pole 2b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stator for a generator in which a coil is continuously wound around an adjacent pole in an opposite direction.

[0002]

2. Description of the Related Art A conventional stator for a generator is shown in FIGS.
(A) As shown in FIG. (B), a stator laminated core 3 in which a plurality of poles 2a to 2h protrude radially from an annular portion 1,
The poles 2d and 2h facing each other are used as mounting poles, and the surfaces of the remaining poles 2a to 2c and 2e to 2g and the peripheral portion of the annular portion 1 are covered with an insulating material 3i such as plastic, and the poles coated with these insulating materials 3i. 2a ~ 2c and Paul 2e ~
Of the 2g, the center poles 2b and 2f are empty poles,
The coil 4a is attached to the pole 2a of the stator laminated core 3 as described above.
Is wound around the coil winding start 4as as a start until the coil winding end 4ae, and the coil winding end 4ae is located on one end face side of the annular portion 1 of the laminated structure, and the connecting wire 4w connected to the coil winding end 4ae The annular part 1
Lead to the pole 2c along one end face of the
c, the coil 4c is wound around the coil 4c so that the end of the coil 4c is present on the other end face side of the annular portion 1 of the laminated structure. The coil 4c is wound around a pole 2e over the mounting pole 2d along the other end face of the coil 4c.
The coil winding end 4ce was taken out, and another coil 4g was wound around the pole 2g starting from 4gs and winding up to 4ge at the coil winding end.
Reference numeral 7 denotes a mounting hole provided in the mounting poles 2d and 2h, which is mounted on a case or the like of the internal combustion engine with screws (not shown).

According to the generator stator having such a structure, since the crossover 4w is passed along any one end surface of the annular portion 1 of the laminated structure, the generator stator is, for example, used. Each pole 2a is attached to a vibration source such as an internal combustion engine.
Even if 2h vibrates, each of the poles 2a-
The breaking of the crossover wire 4w can be prevented without a change in tension due to the vibration of 2h.

[0004] However, in the generator stator having such a structure, the poles 2b, 2b, and 2c are provided so that the crossover wire 4w can be crossed along any one end face of the annular portion 1 of the laminated structure.
Since 2f is an empty pole, there is a problem that a large output cannot be obtained due to an insufficient number of turns of the coil. Further, in such a structure, unlike a general winding in which a coil is sequentially wound around an adjacent pole by reverse winding, when there is no load, the magnetic flux densities of the empty poles 2b and 2f become high and the poles become unbalanced, and the heat generated by the coil There was a problem that the amount was about 10 ° C. higher than that of a general winding.

[0005] Such a problem is caused by the fact that coils 4a to 4d are successively wound around the poles 2a to 2d in reverse order as shown in FIG. This can be solved by a generator stator which crosses the crossover wire 4w obliquely from above or below one pole to below or above the other pole.

[0006]

However, in a generator stator as shown in FIG. 6, when a pole attached to a vibration source, such as an internal combustion engine, vibrates in the opposite direction, a large crossover wire 4w is formed. There is a possibility that the tension is applied and the crossover wire 4w is disconnected.

SUMMARY OF THE INVENTION An object of the present invention is to provide a generator stator that can prevent breakage of a crossover even when vibration is applied to a plurality of poles in a state where coils are successively wound in reverse order. is there.

[0008]

According to the present invention, a coil is wound via an insulating material on each pole of a stator laminated iron core having a plurality of poles projecting radially from an annular portion. An object of the present invention is to improve a generator stator that is continuously wound around adjacent poles via a crossover with the winding direction reversed.

In the stator for a generator according to the present invention, a coil locking portion is provided on each of the annular portions corresponding to the bases of the poles. The winding end line of the coil wound around one pole is regulated by the coil engaging portion so as to be guided along the pole to the end face side of the annular portion in the laminating direction.
The winding end line reaching the end face side in the stacking direction of the annular portion is
It becomes a crossover. This crossover is passed to the adjacent pole along the annular portion by the coil locking portion. In the adjacent pole, the coil is regulated by the coil locking portion and wound around the pole. The winding end line of the coil wound on the pole is
It is regulated by the coil engaging portion so as to be guided along the pole to the end face side in the stacking direction of the annular portion.

When the coil and the crossover are thus regulated by the coil locking portion, the crossover does not cross diagonally between the adjacent poles, but crosses the adjacent pole at any end face side in the stacking direction of the annular portion. That is, even if each pole vibrates, the crossover can be prevented from being disconnected.

In this case, even if the coil locking portion is constituted by a plurality of pins protruding from the insulating material portion on the annular portion side, it is constituted by a groove provided on the insulating material portion on the annular portion side. Or any of them.

[0012]

1 (A) to 1 (C) to 3 show an embodiment of a generator stator according to the present invention, and FIG. 1 (A) shows an embodiment of the present invention. 1B is a front view of a stator laminated core used in a generator stator, and FIG.
FIG. 1 (C) is a rear view of a stator laminated core used in the generator stator of the present embodiment, FIG. 2 (A) is a front view of the generator stator of the present embodiment, FIG. (B) is B-0 in FIG.
FIG. 2C is a rear view of the generator stator of the present embodiment, and FIG. 3 is a side view of the generator stator of the present embodiment. Parts corresponding to those in FIGS. 4 to 6 are denoted by the same reference numerals.

In the generator stator of this embodiment, each pole 2
a, 2b, 2c, 2e, 2f, 2g, coil engaging portions 5a, 5b, 5c formed of pins on the annular portion 1 corresponding to the base portions.
Are provided in plurality.

In this state, the winding start 4as of the coil 4a wound around one pole 2a is connected to the terminal 6a by soldering, and is hung on the outward surface of the coil locking portion 5a. After being hung on the inward face and the position is regulated, the coil is wound around the pole 2a as a coil 4a. The winding end line 4ae of the coil 4a is hung and regulated on the inward surface of the coil locking portion 5d so as to be guided along the pole 2a toward the end face of the annular portion 1 in the laminating direction. The winding end line 4ae reaching the end face side in the stacking direction of the annular portion 1 becomes the crossover line 4w. This crossover 4w
Is hung on the outward surface of the coil engagement portion 5e, and then is hung on the inward surface of the coil engagement portion 5f, and is passed along the annular portion 1 to the adjacent pole 2b. In the adjacent pole 2b, the coil 4b is regulated by the coil locking portion 5f,
b. Coil 4b wound around the pole 2b
The winding end line 4be of the coil engaging portion 5 is guided along the pole 2b toward the end face of the annular portion 1 in the stacking direction.
q. The winding end wire 4be reaching the end face side in the stacking direction of the annular portion 1 becomes the crossover wire 4w.
The crossover wire 4w is hung on the outward surface of the coil engagement portion 5r, and then is hung on the inward surface of the coil engagement portion 5s, and is passed along the annular portion 1 to the adjacent pole 2c. In the adjacent pole 2c, the coil 4c is regulated by the coil locking portion 5s and wound around the pole 2c. The winding end wire 4be of the coil 4c wound on the pole 2c is
c is hung on the inward surface of the coil locking portion 5j so as to be guided to the end surface side of the annular portion 1 in the laminating direction along with c. Next, the winding end wire 4be of the coil 4c is connected to the terminal 6b by soldering.

As described above, the coils 4a to 4c and the crossover 4
When w is regulated by the coil locking portions 5a to 5t, the connecting wire 4w does not cross diagonally between the adjacent poles 2a and 2b and between the poles 2b and 2c, and Since the end faces cross the adjacent poles 2c and 2c, it is possible to prevent the crossover wire 4w from breaking even if each pole vibrates.

In the above example, the coil locking portion is formed by a pin. However, the coil locking portion may be formed as a groove along a plurality of pins existing at the base of each pole.
When a wire is inserted into these grooves and locked, the same effect as the pin can be obtained.

The mounting holes 7 are provided for mounting poles 2d, 2d.
h, it is not limited to that provided on the annular portion 1 but can be provided on the annular portion 1.

[0018]

In the stator for a generator according to the present invention, a coil locking portion is provided on each of the annular portions corresponding to the bases of the respective poles, and the winding end wire of the coil wound on one pole is attached to the pole. It is regulated by the coil engaging portion so as to be guided to the end face side in the stacking direction of the annular portion. Along with passing the coil to the next pole, the next pole is regulated by the coil locking portion and the coil is wound around the pole, and the winding end line of the coil wound around the pole is attached to the pole and the annular portion is laminated. Is regulated by the coil locking part so that it is guided to the end face in the direction, so that the crossover does not cross diagonally between adjacent poles, but crosses to the adjacent pole at any end face side in the stacking direction of the annular part. And even if each pole vibrates, It is possible to prevent the disconnection.

In this case, the coil locking portion can be constituted by a plurality of pins or grooves protruding from the portion of the insulating material on the annular portion side.

[Brief description of the drawings]

FIG. 1A is a front view showing an example of an embodiment of a stator laminated iron core used in a generator stator according to the present invention,
(B) is a sectional view taken along the line AOA of (A), and (C) is (A).
FIG.

2A is a front view showing an example of an embodiment of a generator stator according to the present invention, and FIG. 2B is BOB of FIG. 2A;
FIG. 2C is a rear view of FIG.

FIG. 3 is a side view of a main part of an example of an embodiment of a generator stator according to the present invention.

FIG. 4 is a front view of a stator laminated iron core used in a conventional generator stator.

5A and 5B are a front view and a side view of a conventional stator for a generator.

FIG. 6 is a side view showing a winding structure of another conventional stator for a generator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Annular part 2a-2h Pole 3 Stator laminated iron core 4a-4c, 4-4g Coil 4w Crossover 5a-5t Coil locking part 6a, 6b Terminal 7 Mounting hole

 ──────────────────────────────────────────────────続 き Continued on the front page F-term (reference) SS15

Claims (3)

[Claims] A coil is wound around each of said poles of a stator laminated iron core having a plurality of poles projecting radially from an annular portion via an insulating material, and each of said coils is connected to each of said adjacent poles. In a generator stator that is continuously wound via a crossover with a winding direction reversed, a coil locking portion is provided on each of the annular portions corresponding to the bases of the poles, and the one The winding end line of the coil wound around the pole is regulated by the coil locking portion so as to be guided along the pole to the end face side of the annular portion in the stacking direction, and is located on the end face side of the annular portion in the stacking direction. The reached winding end line becomes the crossover line, and the crossover line is transferred to the next pole along the annular portion by the coil locking portion, and is regulated by the coil locking portion at the adjacent pole. Wrapped around a pole An end winding of the coil wound on the pole is regulated by the coil locking portion so as to be guided along the pole toward the end face of the annular portion in the stacking direction. For stator. 2. The generator stator according to claim 1, wherein the coil locking portion is constituted by a plurality of pins protruding from a portion of the insulating material on the side of the annular portion. 3. The generator stator according to claim 1, wherein the coil locking portion is formed by a groove provided in a portion of the insulating material on the annular portion side.