JP2008199719A - Rotary electric machine, and manufacturing method of field coil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotary electric machine employing an edgewise winding in the field coil 3, and to provide a field coil 3 having a high space factor in which unbalance of magnetic flux generated in each magnetic pole 2 can be suppressed. <P>SOLUTION: Two field coils 3 having two winding portions 3a connected in series through a transient wire portion 3b are formed by winding one flat wire from the opposite sides in the edgewise direction respectively. The transient wire portion 3b connecting the two winding portions 3a crosses a coil end 3c led out from the winding portion 3a of one field coil 3A, and the intersection X is set at a position separated from the winding portion 3a of the field coil 3A not to overlap the winding portion 3a. Since the number of layers at two winding portions 3a attached to respective magnetic poles 2 can be equalized substantially, unbalance of magnetic flux generated in respective magnetic poles 2 can be suppressed. As a result, variation in output performance and aggravation of commutation can be suppressed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a rotating electrical machine using edgewise windings as field coils.

Conventionally, an edgewise winding formed by winding a rectangular wire in an edgewise direction is known. For example, Patent Document 1 discloses a method of manufacturing two edgewise windings from one flat wire. The manufacturing method of the edgewise winding will be described with reference to FIG.
First, as shown in FIG. 5A, both ends of one flat wire 100 are clamped and set on the core 110.
Subsequently, as shown in FIGS. 4B to 4D, the rectangular wire 100 is wound around the core 110 in the edgewise direction while rotating the core 110.
By winding up a predetermined number of times, two winding portions 130 connected by the crossover portion 120 are formed as shown in FIG. Further, as shown in FIG. 5 (f), the two edgewise windings 140 are continuously formed by folding back the two winding portions 130 at the crossover portion 120.
JP 2006-271121 A

  By the way, when the edgewise winding 140 is used for a field coil of a direct current motor (for example, a starter motor), as shown in FIG. The lead wire 170 of the positive electrode brush 160 is connected to one coil end portion 131 drawn from the combined winding portion 130. In this case, since the crossover portion 120 connecting the two winding portions 130 and the one coil end portion 131 intersect, the intersection portion X overlaps with the winding portion 130 fitted to the boss portion 150. The state is one layer higher than other parts. For example, when the flat wire 100 is wound around the winding core 110 three times, a three-layer winding portion 130 is formed, but at the portion where the crossing portion X overlaps with the winding portion 130, one layer is formed. There are many 4 layers.

In the above field coil, as shown in FIG. 6B, it is necessary to secure a space S0 for four layers between the pole core flange 151 and the yoke 200. However, the actual winding portion 130 has three layers, and a gap corresponding to one layer is generated in the reserved space S0. Therefore, the space factor of the winding is reduced, and the physique of the motor is increased as a result. turn into.
Moreover, since the two coil | winding parts 130 connected by the crossover part 120 are connected in series as an electric circuit, the electric current of the same value flows in a DC motor. Therefore, if the number of turns in the two winding portions 130 is different, the magnetic flux generated in each pole core is unbalanced, resulting in variations in output performance and a problem that rectification deteriorates.
The present invention has been made based on the above circumstances, and its purpose is to reduce unbalance of magnetic flux generated in each magnetic pole in a rotating electrical machine using edgewise windings as field coils, and It is to provide a field coil having a high rate.

(Invention of Claim 1)
The present invention includes a field coil formed by winding a rectangular wire in an edgewise direction, and a magnetic pole that is assembled to the field coil and fixed to the inner periphery of the yoke, and is adjacent to the circumferential direction. A rotating electric machine in which field coils are connected in series via a crossover portion, and one of the two field coils connected in series by the crossover portion is an outer periphery of a magnetic pole And a coil end portion that is drawn out from the winding portion and intersects the crossover portion, and a portion where the coil end portion and the crossover portion intersect is a winding. It is characterized by being set at a position deviating from the winding part without overlapping with the part.

  According to said structure, the two winding parts assembled | attached to each magnetic pole adjacent to the circumferential direction by setting the site | part which the coil edge part and the crossover part cross | intersected in the position remove | deviated from the winding part The number of layers (the number of windings) can be made substantially the same (with a difference of one layer with respect to the smallest number of layers). As a result, it is possible to suppress a variation in output performance by suppressing an imbalance of magnetic flux generated in each magnetic pole.

(Invention of Claim 2)
The rotating electrical machine according to claim 1, wherein one field coil has a region where one layer of the rectangular wire is less between the connecting wire portion and the coil end portion in the circumferential direction of the winding portion. The flat wire of each layer to be arranged is provided with a step for one layer.
According to the above configuration, a region with one flat wire is formed between the connecting wire portion and the coil end portion in the circumferential direction of the winding portion, so that one layer is formed on the flat wire using the region. By providing a level difference, the number of layers of the winding portion can be made substantially the same over the entire circumference of the magnetic pole without causing a useless gap between the flange portion of the magnetic pole and the yoke. As a result, a high space factor can be secured, and the physique can be reduced in size.

(Invention of Claim 3)
A method of manufacturing a field coil in a rotating electrical machine according to claim 2, wherein the two winding portions connected via the crossover portion are expanded in a planar shape to the inner peripheral shape of the yoke. It is characterized in that press molding for applying a curvature along the surface is performed, and a step is formed in the flat wire by this press molding.
According to said method, it is not necessary to provide the process for forming a level | step difference in a flat wire. That is, the step of giving curvature to the field coil and the step of forming a step on the flat wire can be simultaneously performed by press molding. For this reason, a manufacturing process does not increase and the field coil which has a level | step difference in a flat wire can be manufactured easily.

  The best mode for carrying out the present invention will be described in detail with reference to the following examples.

FIG. 1A is a development view of the yoke ASSY, and FIG. 1B is a cross-sectional view taken along line AA.
The rotating electrical machine of the present embodiment is, for example, a starter motor for starting an automobile engine, and includes a yoke ASSY shown in FIGS.
The yoke assembly includes a yoke 1 forming a magnetic circuit, four magnetic poles 2 fixed to the inner periphery of the yoke 1, and four field coils 3 (3A, 3B) assembled to the magnetic poles 2. Composed.
The yoke 1 is formed by rolling an iron plate, which is a ferromagnetic material, into a cylindrical shape.
As shown in FIG. 1B, the magnetic pole 2 is provided with a boss portion 2 a into which the field coil 3 is fitted and a flange portion 2 b that holds the field coil 3 between the yoke 1.

The four field coils 3 are connected in 2 series-2 parallel. That is, two sets of two field coils 3 connected in series are provided, and the two sets are connected in parallel.
A method of manufacturing the field coil 3 will be described with reference to FIG.
First, as shown in FIG. 1A, one flat wire 4 having a rectangular cross section is prepared, and both ends of the flat wire 4 are set on the core 5. The left and right winding cores 5 have the same shape as the boss 2a of the magnetic pole 2, respectively.
Subsequently, while holding the end portion of the flat wire 4 set on the winding core 5 to the winding core 5 by a clamping device (not shown), as shown in FIGS. And the rectangular wire 4 is wound around the core 5 in the edgewise direction.

By winding a predetermined number of times, two winding portions 3a wound around the core 5 are formed, and the two winding portions 3a are connected by a connecting portion (hereinafter referred to as a crossover portion 3b). ing.
Thereafter, as shown in FIG. 5E, a bending jig 6 is applied to the crossover portion 3b, and the jig 6 is bent as a fulcrum in the direction of the arrow shown in FIG. In the same manner, two field coils 3 in which two winding portions 3a are connected in series via the crossover portion 3b are completed. Finally, press molding is performed to give a curvature to the entire coil so that the two field coils 3 developed in a planar shape can be arranged along the inner peripheral shape of the yoke 1.

As shown in FIG. 1A, the two field coils 3 manufactured by the above method are connected to the coil end portion 3c drawn from the winding portion 3a of one field coil 3A. A lead wire 7a is connected, and a motor lead plate 8 is connected to a coil end 3d drawn from the winding 3a of the other field coil 3B. As shown in FIG. 2, the motor lead plate 8 is held by a rubber grommet 9 fixed between a yoke 1 and an end frame (not shown), and is taken out to the outside of the motor. Is connected to a motor terminal of an electromagnetic switch (not shown).
Here, the crossover portion 3b connecting the two winding portions 3a intersects with the coil end portion 3c drawn from the winding portion 3a of the one field coil 3A as shown in FIG. 1 (a). The crossing portion X is set at a position away from the winding portion 3a so that it does not overlap the winding portion 3a of one of the field coils 3A.

(Effect of Example 1)
According to the configuration of the present embodiment, the crossing portion X where the crossover portion 3b intersects the coil end portion 3c is set at a position deviated from the winding portion 3a, so that the two windings assembled to the respective magnetic poles 2 are provided. It is possible to make the number of layers of the line part 3a substantially the same. That is, in the above manufacturing method, for example, when the flat wire 4 is wound around the core 5 three times, a three-layer winding portion 3a is formed, but in the conventional technique shown in FIG. Since the crossing portion X of the crossover portion 120 and the coil end portion 131 is set at a position overlapping the winding portion 130, only that portion has four layers. However, since the winding portion 130 of the other field coil partially has a two-layer region, a difference of two layers is generated between one winding portion 130 and the other winding portion 130.

  On the other hand, in the present embodiment, by setting the crossing portion X of the crossover portion 3b and the coil end portion 3c to a position away from the winding portion 3a, the four-layer portion is eliminated, and the winding portion 3a The whole is 3 layers (partially 2 layers). As a result, in one winding part 3a and the other winding part 3a, it is possible to make the number of layers of both the same (with a difference of one layer with respect to the smallest number of layers), The imbalance of the magnetic flux generated in each magnetic pole 2 can be suppressed. As a result, variations in output performance and deterioration of rectification can be suppressed.

4A is a development view of the yoke assembly, and FIG. 4B is a plan view of the field coil 3 viewed from the axial direction (view B in FIG. 4A). FIGS. 4B and 4C show a state where the field coil 3 is developed in a planar shape.
The present embodiment is an example in which the space factor is increased by effectively utilizing the winding space S1 secured between the flange portion 2b of the magnetic pole 2 and the yoke 1.
One field coil 3A shown on the right side of FIG. 4A is set at a position where the crossing portion X of the crossover portion 3b and the coil end portion 3c deviates from the winding portion 3a, as in the first embodiment. Accordingly, a region C in which the flat wire 4 is reduced by one layer is formed between the connecting wire portion 3b and the coil end portion 3c in the circumferential direction of the winding portion 3a, and each layer disposed in this region C is formed. Each rectangular wire 4 is provided with a level difference [see FIG.

That is, for example, when one field coil 3A is formed by winding the flat wire 4 around the core 5 three times to form a three-layer winding portion 3a, the crossing portion X becomes the winding portion 3a. 4, it is necessary to secure a four-layer winding space S 0 between the flange 2 b of the magnetic pole 2 and the yoke 1, as shown in FIG. 4B.
On the other hand, when the crossing portion X between the crossover portion 3b and the coil end portion 3c is set at a position removed from the winding portion 3a, the winding portion 3a is viewed on the drawing as shown in FIG. In this case, a two-layer region C which is smaller by one layer is formed between the coil end 3c and the crossover portion 3b. By providing a step for one layer on each of the rectangular wires 4 of each layer disposed in this region C, the number of layers of the winding portion 3a is substantially the same over the entire circumference of the magnetic pole 2 as shown in FIG. Can be. Thereby, since it is sufficient to secure a winding space S1 for three layers between the flange portion 2b of the magnetic pole 2 and the yoke 1, no useless gap is generated. As a result, a high space factor can be secured, and the motor can be downsized.

  In addition, the process of providing the level | step difference for one layer in the rectangular wire 4 of each layer arrange | positioned in the area | region C can be performed simultaneously with the press molding for attaching a curvature to the whole coil described in Example 1, respectively. That is, the step of giving a curvature to the entire coil and the step of forming a step on the flat wire 4 can be simultaneously performed by press molding. For this reason, a manufacturing process does not increase and the field coil 3A which has a level | step difference in the flat wire 4 can be manufactured easily.

(A) The developed view of yoke ASSY, (b) It is AA sectional drawing (Example 1). It is an axial direction top view of yoke ASSY. It is a manufacturing-process figure of a field coil (Example 1). (A) Development view of yoke assembly, (b) Plan view of field coils for four layers viewed from the axial direction, (c) Plan view of field coils for three layers viewed from the axial direction (implementation) Example 2). It is a manufacturing-process figure of a field coil (prior art). It is a development view of the yoke assembly (prior art).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Yoke 2 Magnetic pole 3 Field coil 3A One field coil 3B The other field coil 3a Winding part 3b Crossover part 3c Coil end part 4 Flat wire X Intersection part (a coil end part and a crossover part cross | intersect) Part)
B Area with less flat wire for one layer

Claims (3)

A field coil formed by winding a flat wire in an edgewise direction;
A magnetic pole fixed to the inner periphery of the yoke by assembling the field coil;
A rotating electrical machine in which two field coils adjacent in the circumferential direction are connected in series via a crossover portion,
Of the two field coils connected in series by the crossover portion, one of the field coils is an annular winding portion fitted to the outer periphery of the magnetic pole, and is drawn out from the winding portion and the crossover A coil end portion that intersects the wire portion, and a portion where the coil end portion and the crossover wire portion intersect is set at a position that is out of the winding portion without overlapping the winding portion. A rotating electric machine characterized by In the rotating electrical machine according to claim 1,
The one field coil has a region where the rectangular wire is less by one layer between the crossover portion and the coil end portion in the circumferential direction of the winding portion, and each layer arranged in this region A rotating electric machine characterized in that a step for one layer is provided on each flat wire. A method of manufacturing the field coil in the rotating electrical machine according to claim 2,
From the state where the two winding portions connected via the crossover portion are developed in a planar shape, press molding is performed to give a curvature along the inner peripheral shape of the yoke. A method of manufacturing a field coil, wherein a step is formed in a flat wire.

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