JP2009268207A - Rotary electric machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotary electric machine in which the number of parts is reduced and cost is lowered by providing a power supply terminal usable in common irrespective of the presence of noise prevention elements including a choke coil. <P>SOLUTION: The rotary electric machine M includes the power supply terminal 13. The power supply terminal 13 is composed of: at least a terminal connection part 13a, which receives electric power from an external power supply; a brush connection part 13c; an extension part 13b, which connects the terminal connection part 13a to the brush connection part 13c; and a noise prevention element mounting part 136, which is connected to a noise prevention element T. When the power supply terminal 13 is mounted on an end housing 11, a distance in the axial direction of the rotary electric machine M from the bottom of the end housing 11 is configured such that a distance from the bottom of the end housing 11 up to the noise prevention element mounting part 136 becomes larger than that from the bottom of the end housing 11 up to at least a part 133 of the extension part 13b. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a rotating electrical machine, and more particularly to a rotating electrical machine capable of reducing the number of parts and reducing the cost.

In a rotating electrical machine having a rotating shaft and an armature, a brush for supplying electric power for rotating the armature is used.
The brush is normally stored in a brush holder, and the brush holder is fitted into the yoke housing opening.

The brush holder is provided with a terminal. One end of the terminal is connected to the brush, and the other end is connected to an external terminal connected to an external power source.
Since it is connected in this way, the electric power supplied from the external power source is transmitted from the terminal to the brush and becomes a driving force for rotating the armature.
Various structures have been proposed for parts such as the brush holder used in this way and terminals arranged on the brush holder in order to reduce the size and thickness of the motor.

For example, in such a rotating electrical machine, components such as a choke coil may be provided in order to suppress electrical noise generated by the sliding contact of the brush. When assembling such components, a brush holder and It is necessary to provide a separate structural component or to secure an arrangement space in the brush holder, and it is necessary to design a brush holder that can arrange an electric element.
Therefore, the applicant has proposed a technique that can use a common brush holder regardless of the presence or absence of a choke coil (see Patent Document 1).

JP 2003-079109 A

In the technique of Patent Document 1, when a conductive member such as a choke coil connected to a brush via a lead wire is accommodated in the accommodating member, the conductive member such as the choke coil is inserted so as to be continuous from the power feeding unit. It is in a state where it is molded and coupled with a part of the terminal exposed to the housing portion, and is in a state where power can be supplied to the brush.
For this reason, even if it changes the kind of electrically-conductive members, such as a choke coil, an electricity supply path is ensured and the structure of a brush holder can be simplified.

However, in the housing member (brush holder) described in Patent Document 1, an energization path can be secured even if the type of the conductive member such as the choke coil is changed. However, depending on the presence or absence of the choke coil or the type of the choke coil, There is a problem that the shape needs to be changed and the number of parts increases.
In addition, when a noise prevention element such as a capacitor is provided, it is necessary to take a structure to avoid this, and the development of a commonly used power supply terminal is possible regardless of the presence or absence of this noise prevention element. It was desired.

  An object of the present invention is to solve the above-mentioned problems, and by providing a power supply terminal that can be used in common regardless of the presence or absence of a noise prevention element such as a choke coil, the number of parts can be reduced and the cost can be reduced. An object of the present invention is to provide a rotating electrical machine that is realized.

  According to the rotating electrical machine according to the present invention, the above-described problem is a rotating electrical machine that is incorporated in an end housing and includes a power feeding terminal that feeds power in the axial direction of the rotating electrical machine. A terminal connection part for receiving power, a brush connection part connected directly or indirectly to a brush, an extension part for connecting the terminal connection part and the brush connection part, and a miscellaneous element for connecting to a noise prevention element An anti-element mounting portion, and when the power supply terminal is attached to the end housing, the distance from the end housing bottom surface portion to the rotating electrical machine axial direction is the end housing bottom surface portion. A distance from the noise prevention element mounting portion to a distance from the bottom surface of the end housing to at least a part of the extension. It is solved by Rukoto.

Thus, in the present invention, when the power feeding terminal is attached to the end housing, the distance from the bottom surface of the end housing to the rotating electric machine axial direction is the distance from the bottom surface of the end housing to the noise prevention element mounting portion. The distance between the bottom surface of the housing and at least a part of the extension is greater than the distance.
That is, the extension portion and the noise prevention element mounting portion are arranged so as to have a step.
For this reason, a noise prevention element such as a capacitor can be incorporated in the space of the step portion.
In other words, since the space of the step portion exists, it is possible to dispose a power feeding terminal avoiding a noise prevention element such as a capacitor.
Therefore, it is possible to use a common power supply terminal regardless of the presence or absence of noise prevention elements, and it is possible to provide a rotating electrical machine in which the number of parts is reduced and the cost is reduced.

  Further, at this time, if the part of the extension portion and the noise prevention element mounting portion are disposed on different planes orthogonal to the rotating electric machine axial direction, the noise prevention element such as a capacitor is surely avoided. This is preferable because a power feeding terminal can be provided.

  Further, at this time, it is preferable that a part of the extension portion is adjacent to the noise prevention element because each member can be compactly accommodated in a small space.

At this time, the power supply terminal further includes a choke coil mounting portion for disposing the choke coil. The choke coil mounting portion includes the choke coil, and the brush is interposed via the choke coil. It is comprised so that it may be fed to.
Thus, the power supply terminal according to the present invention includes both the brush connection portion and the choke coil attachment portion.
For this reason, when using a choke coil, it can respond by attaching a choke coil to this choke coil attachment part.
If a choke coil is not required, the power supply terminal and the brush may be electrically connected to the brush connection portion via a power supply line such as a pigtail.

Further, at this time, the power supply terminal further includes a choke coil mounting portion for disposing the choke coil, and a part of the extension portion is electrically connected between the terminal connection portion and the choke coil mounting portion. Are formed continuously.
Since it is configured in this manner, the power feeding terminal can be accommodated in a compact manner while avoiding the noise prevention elements, and a common power feeding terminal can be used regardless of the presence or absence of a choke coil or the like.
Therefore, it is possible to provide a rotating electrical machine in which the number of parts is reduced and the cost is reduced.

  According to the present invention, it is not necessary to change the structure depending on the shape of the presence or absence of the anti-noise element such as the choke coil by providing the power supply terminal that can be used in common regardless of the presence or absence of the anti-noise element such as the choke coil. The number of parts can be reduced, and the rotating electrical machine manufacturing cost is reduced.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
Note that the configuration described below does not limit the present invention and can be variously modified within the scope of the gist of the present invention.
The present embodiment relates to a rotating electrical machine that is provided with a power supply terminal that can be used in common regardless of the presence or absence of a noise prevention element such as a choke coil, thereby reducing the number of components and reducing the cost.

  1 to 8 show an embodiment of the present invention. FIG. 1 is an explanatory view showing a motor. FIG. 2 is a plan view of an end housing including a brush holder as viewed from the motor main body. FIG. 4 is a perspective view showing the first terminal, FIG. 5 is a plan view showing the second terminal, FIG. 6 is a plan view showing the third terminal, and FIG. 7 is a case where a choke coil is used. FIG. 8 is an assembly diagram of each terminal when a choke coil is not used.

With reference to FIG. 1, the configuration of a motor M as a rotating electrical machine according to the present embodiment will be described.
The motor M according to this embodiment includes a motor main body 2 and a brush holder 3.
The motor main body 2 according to this embodiment includes a yoke housing 4, a magnet 5, an armature 6, a rotating shaft 7, and a commutator 9.
The yoke housing 4 is a substantially cylindrical member with a bottom, covers an armature 6 described later, and stores it inside.

The magnet 5 is a permanent magnet attached to the inner wall surface of the yoke housing 4 and supplies a magnetic force that serves as a rotational driving force for the armature 6 described later.
The armature 6 is a rotating body formed by laminating a plurality of thin plates, and a winding is turned on the surface thereof. The electromagnetic force generated by energizing the winding and the magnetic force of the magnet 5 are mutually connected. Rotate by action.

The rotating shaft 7 is a rotating shaft of the armature 6, and one end side (the bottom surface side of the yoke housing 4) is rotatably supported by the bearing 8.
The other end side (output side) is also rotatably supported by the bearing 8.
The commutator 9 is an electrode that makes contact with the brush 16 fed from an external power source and performs rectification, and is disposed on the output side of the armature 6.

The brush holder 3 is fitted into the opening 4 a of the yoke housing 4.
The brush holder 3 includes a resin end housing 11 that covers the opening 4 a of the yoke housing 4 and is integrally configured.
The end housing 11 includes a housing main body portion 11a that is fitted into the opening 4a of the yoke housing 4 and a connector portion 11b that extends radially outward from the housing main body portion 11a.

As shown in FIG. 2, the brush holder 3 and the housing body 11 a according to this embodiment are bottomed cylindrical bodies having a substantially circular shape in plan view, and are disposed on the output shaft side of the rotating shaft 7.
A shaft through hole 11c is formed at the center of the housing body 11a, and a bearing 8 is disposed in the shaft through hole 11c.
The output shaft side of the rotary shaft 7 is rotatably supported by the bearing 8.

The connector portion 11b is configured by a member having a substantially U-shaped cross section.
The base end portion side of the connector portion 11b is continuous with the side surface portion of the housing main body portion 11a, and is integrally formed.

The housing main body 11a and the connector 11b include a first receiving groove 11e and a second groove extending from the vicinity of the shaft through hole 11c of the housing main body 11a toward the base end side of the connector 11b so as to avoid the shaft through hole 11c. An accommodation groove 11f is formed.
The first housing groove 11e and the second housing groove 11f extend in parallel from the connector portion 11b side toward the housing main body portion 11a, and head from the vicinity of the boundary between the connector portion 11b and the housing main body portion 11a toward the shaft through-hole 11c. Accordingly, it is formed so as to be separated so as to avoid the shaft through hole 11c.
That is, the first housing groove 11e and the second housing groove 11f are formed to have a substantially Y shape when the end housing 11 is viewed from the motor main body 2 side.

In the present embodiment, the noise prevention element T is incorporated between the vicinity of the first accommodation groove 11e and the shaft through-hole 11c.
The noise prevention element T is constituted by, for example, a capacitor, and a circuit for eliminating noise is formed together with a choke coil and the like.

A substantially rectangular hole (not shown) is formed in the depth direction of the first receiving groove 11e at the end of the first receiving groove 11e on the connector part 11b side.
Similarly, a hole (not shown) is formed in the depth direction of the second housing portion 11f on the connector 11b side of the second housing groove 11f.
These holes position and fix each terminal.

A first terminal 13, a second terminal 14, and a third terminal 15, which will be described later, are housed in the first housing groove 11e and the second housing groove 11f, respectively.
The first terminal 13, the second terminal 14, and the third terminal 15 are all made of a conductive material having conductivity, and are members for supplying power to the armature 6 through the brushes 16 and 16.
The first terminal 13 and the second terminal 14 are connected to external terminals to be described later, and can receive power from an external power source (not shown).
As will be described later, the third terminal 15 is a terminal for attaching the choke coil C to the second terminal 14.

Brushes 16 and 16 are connected to the first terminal 13 and the second terminal 14 via pigtails 17 and 17, respectively, and the brushes 16 and 16 are in sliding contact with the commutator 9.
FIG. 1 shows only one of the brushes 16 and 16 connected to the first terminal 13 and the second terminal 14.

3 and 4 show the structure of the first terminal 13.
The first terminal 13 is formed by punching one conductive metal plate and bending it into a predetermined shape. As shown in FIGS. 3 and 4, the first terminal connection portion 13a and the first terminal 13 are formed. The first extending portion 13b, the first brush connecting portion 13c, the first branch portion 13d, the first choke coil connecting portion 13e, and the first holder connecting portion 13f are configured.

The 1st terminal connection part 13a which concerns on this embodiment is a site | part of a substantially rectangular plate shape, and is a site | part which contacts the external terminal which is not shown in figure and receives the electric power supply from an external power supply.
In the vicinity of the central portion of the first terminal connection portion 13a, a substantially L-shape projecting in a direction opposite to a side where a first extension portion 13b, which will be described later, is formed, and having a tip side falling in the direction of the first extension portion 13b. A first branch portion 13d is formed.
The first extension portion 13b according to the present embodiment is a plate-like portion that bends and extends from one end side of the first terminal connection portion 13a so as to form approximately 90 degrees with the first terminal connection portion 13a. It is bent so as to match the shape of the one receiving groove 11e and to avoid the noise prevention element T.
The configuration of the first extension portion 13b will be described later.

The 1st brush connection part 13c which concerns on this embodiment is a site | part which stands in the same direction as the 1st terminal connection part 13a from the edge part on the opposite side to the side which contact | connects the 1st terminal connection part 13a among the 1st extension parts 13b. The first brush connecting portion 135 having a substantially rectangular plate shape is formed at the tip.
A first noise prevention element mounting portion 136 for connecting the noise prevention element T is formed slightly below the substantially central portion of the first brush connection portion 13c (the side where the first extension portion 13b is formed). Has been.
The first noise prevention element mounting portion 136 is a substantially rectangular claw-like member, and is bent from a predetermined position of the first brush connection portion 13c so as to form a predetermined angle (acute angle) with the first brush connection portion 13c. Is formed.
A connection groove for connecting the noise prevention element T is formed above the first noise prevention element mounting portion 136 (on the opposite side to the side where the first extension portion 13b is formed).

The first choke coil connection portion 13e according to the present embodiment is a substantially rectangular plate-like portion extending from the first brush connection portion 13c to the opposite side to the first extension portion 13b.
A first choke coil attachment portion 137 is formed on the upper portion of the first choke coil connection portion 13e (on the side opposite to the side on which the first extension portion 13b is formed).
The first choke coil attachment portion 137 is a substantially L-shaped portion with the tip side bent substantially vertically, and serves as a pedestal for supporting and fixing the ferrite portion of the choke coil C.
The tip portion bent substantially vertically is referred to as a “first choke coil support portion 137a”.

  In the first holder connecting portion 13f according to the present embodiment, a first brush connecting portion 135 is formed on one end side of the first choke coil connecting portion 13e (on the side opposite to the first brush connecting portion 13c connecting side). And the choke coil C side of the first terminal 13 is fixed.

The 1st terminal connection part 13a is a site | part accommodated in the connector part 11b side, and a direct contact with an external terminal.
The first extension portion 13b has a shape along the first accommodation groove 11e, and is accommodated and fixed in the first accommodation groove 11e.
The first extension portion 13b has a two-stage configuration.

That is, the connector-side conductive portion 131, the bridging conductive portion 132, and the anti-noise element-side conductive portion 133 are configured in two stages.
The connector-side conductive portion 131 is a plate-like portion that bends and extends from one end side of the first terminal connection portion 13a so as to form approximately 90 degrees with the first terminal connection portion 13a.
A first holder connection projection 138 that falls downward is formed at a substantially central portion of the connector-side conductive portion 131, and the first holder connection projection 138 is connected to the connector portion 11 b side of the first terminal 13. To fix.

Further, the bridging conductive portion 132 falls in a substantially vertical direction from the other end side of the connector-side conductive portion 131 (the side opposite to the side continuously formed with the first terminal connection portion 13a).
Furthermore, from the other end side of the bridging conductive portion 132 (the side opposite to the side continuously formed with the connector-side conductive portion 131), the anti-noise element is bent in a substantially vertical direction and formed substantially parallel to the connector-side conductive portion 131. A side conductive portion 133 is formed.

That is, the connector side conductive portion 131 and the noise prevention element side conductive portion 133 have a height difference corresponding to the height h of the bridging conductive portion 132, that is, a step.
For this reason, the position of the 1st noise prevention element attaching part 136 will be located above the position of the bridge | crosslinking conductive part 131 (rotating shaft 7 axial direction motor main body 2 side).
That is, when the first terminal 13 is attached, if the distance from the bottom surface of the end housing 11 in the direction of the rotation axis 7 is taken, the distance to the first noise prevention element attachment portion 136 is greater than the distance to the bridging conductive portion 131. Also grows.

Therefore, since the difference in the height h is formed, the first terminal 13 can be disposed in the first receiving groove 11e while efficiently avoiding the noise prevention element T.
Hereinafter, a space formed by the connector-side conductive portion 131, the bridging conductive portion 132, and the anti-noise element-side conductive portion 133 is referred to as a “non-anti-noise element arrangement space K”.

The first brush connecting portion 13c is usually a portion to which the brush 16 is connected, and a hole for connecting the pigtail 17 which is a wiring with the brush 16 is formed.
When the choke coil C is connected, the brush 16 is connected via the choke coil C and the pigtail 17, so that the first brush connection portion 13c is not used for electrical connection with the brush 16.

13 d of 1st branch parts are protrusions which have the function for suppressing the inclination of the 1st terminal 13 and performing the retaining from the 1st accommodating groove 11e.
When the first branch portion 13d is pushed into and fitted into a hole formed in the end housing 11, the end portion on the connector portion 11b side of the first terminal 13 is positioned and does not move.

When the first terminal 13 is accommodated in the first accommodation groove 11e, the first terminal connection portion 13a is exposed in the connection hole 11d of the connector portion 11b and protrudes in parallel with the rotation shaft 7.
The first brush connection portion 13c protrudes in the direction parallel to the rotation shaft 7 from the vicinity of the shaft through hole 11c.
When the motor main body 2 and the brush holder 3 are connected, the free end side of the first brush connecting portion 13c is located in the vicinity of the commutator 9.
Therefore, when the choke coil C is not connected, the brush 16 connected to the brush contact portion 13c via the pigtail 17 comes into contact with the commutator 9, and the first terminal 13 is connected to the pigtail 17, brush 16, commutator. 9 is electrically connected to the armature 6.

In addition, the tip side end portion of the choke coil C attached to the first choke coil connection portion 13e also projects in the direction parallel to the rotary shaft 7 from the vicinity of the shaft through hole 11c.
Therefore, when the choke coil C is connected, the brush 16 connected to the tip of the choke coil C via the pigtail 17 contacts the commutator 9, and the first terminal 13 is connected to the choke coil C, the pigtail 17, The armature 6 is electrically connected through the brush 16 and the commutator 9.

The structure of the second terminal 14 will be described with reference to FIG.
Since the function of each part is the same as that of the 1st terminal 13, description is abbreviate | omitted.
Like the first terminal 13, the second terminal 14 is formed by punching a single conductive metal plate and bending it into a predetermined shape. As shown in FIG. 5, the second terminal connection portion 14a is formed. And a second extension portion 14b, a second brush connection portion 14c, and a second branch portion 14d.

The 2nd terminal connection part 14a which concerns on this embodiment is a site | part of a substantially rectangular plate shape, and is a site | part which contacts the external terminal which is not shown in figure and receives the electric power supply from an external power supply.
Near the center portion of the second terminal connection portion 14a, a substantially L-shape projecting in the direction opposite to the side where the second extension portion 14b described later is formed and the tip side falling in the direction of the second extension portion 14b. A second branch portion 14d is formed.

The second extension portion 14b according to the present embodiment is a plate-like portion that bends and extends from one end side of the second terminal connection portion 14a so as to form approximately 90 degrees with the second terminal connection portion 14a. 2 Bent to match the shape of the housing groove 11f.
A second noise prevention element mounting portion 146 that rises in the direction in which the second terminal connection portion 14a is formed from below is provided at a position on the second brush connection portion 14c side, which will be described later, slightly from the center portion of the second extension portion 14b. Is formed.
The second noise prevention element mounting portion 146 is a part for connecting the noise prevention element T, and is formed as a substantially rectangular claw-shaped member.
A connection groove for connecting the noise prevention element T is formed on the upper side of the second noise prevention element mounting portion 146 (the direction side in which the second terminal connection portion 14a is formed).

  In addition, a second holder connection projection 148 that falls downward is formed at the end of the second extension portion 14 b on the second terminal connection portion 14 a side, and the second holder connection projection 148 is formed on the second terminal 14. The connector part 11b side is fixed.

  The 2nd brush connection part 14c which concerns on this embodiment is a site | part which stands | starts up in the same direction as the 2nd terminal connection part 14a from the edge part on the opposite side to the side which contact | connects the 2nd terminal connection part 14a among the 2nd extension parts 14b. The second brush connection portion 145 having a substantially rectangular plate shape is formed at the tip.

Next, the structure of the third terminal 15 will be described with reference to FIG.
Since the function of each part is the same as that of the 1st terminal 13, description is abbreviate | omitted.
Similar to the first terminal 13 and the second terminal 14, the third terminal 15 is formed by punching one conductive metal plate and bending it into a predetermined shape. As shown in FIG. It has a three-brush connection portion 15c, a third choke coil connection portion 15e, and a third holder connection portion 15f.

The third brush connection portion 15 c according to the present embodiment is a substantially rectangular plate-shaped portion, and the tip side thereof has a shape that matches the second brush connection portion 145 formed on the second terminal 14.
The third choke coil connection portion 15e according to the present embodiment is a substantially rectangular plate-like portion extending from the third brush connection portion 15c in a substantially vertical direction.
A third choke coil attachment portion 157 is formed on the upper portion of the third choke coil connection portion 15e (the tip side of the third brush connection portion 15c).
Similar to the first choke coil attachment portion 137, the third choke coil attachment portion 157 is a substantially L-shaped portion whose front end is bent substantially vertically and serves as a pedestal for supporting and fixing the ferrite portion of the choke coil C.
The tip portion bent substantially vertically is referred to as a “third choke coil support portion 157a”.

  The third holder connecting portion 15f according to the present embodiment is arranged in a downward direction (on the tip side of the third brush connecting portion 15c) on one end side (the side opposite to the third brush connecting portion 15c connecting side) of the third choke coil connecting portion 15e. The choke coil C side of the third terminal 15 is fixed.

The second terminal 14 and the third terminal 15 can be used in combination.
That is, when the choke coil C is provided, the third terminal 15 provided with the choke coil C can be combined with the second terminal 14 and provided in the second receiving groove 11f.
When the choke coil C is not provided, only the second terminal 14 is used, and only the second terminal 14 is provided in the second receiving groove 11f.
Hereinafter, these arrangement methods will be described.

The case where the choke coil C is disposed will be described with reference to FIG.
A first terminal 13 is disposed in the first receiving groove 11e.
In this case, the first terminal 13 has the first receiving groove with the choke coil C attached to the first choke coil support part 137a of the first choke coil attachment part 137 formed in the first choke coil connection part 13e. 11e.
At this time, the first extension portion 13b is provided with a noise prevention element disposition space K formed by a step, so that the first terminal 13 can be disposed while avoiding the noise prevention element T. .
Further, the noise preventing element T is connected to the first noise preventing element mounting portion 136 formed in the first brush connection portion 13c.
Power is supplied to the brush 16 via a pigtail 17 connected to the tip end side of the choke coil C.

The second terminal 14 is used in combination with the third terminal 15.
First, the choke coil C is attached to the third choke coil attachment portion 157 formed in the third choke coil connection portion 15 e of the third terminal 15.
At this time, the choke coil C is attached to the third choke coil support portion 157a.
The third terminal 15 to which the choke coil C is thus attached is combined with the second terminal 14.

This is combined by overlapping the third brush connection portion 15 c of the third terminal 15 and the second brush connection portion 14 c of the second terminal 14.
At this time, the tip of the third brush connection 15c of the third terminal 15 and the second brush connection 145 of the second terminal 14 are combined and combined (as described above, the tip of the third brush connection 15c. And the shape of the second brush connection portion 145 are formed so as to match.

As described above, the combination of the third terminal 15 and the second terminal 14 to which the choke coil C is attached is disposed in the second accommodation groove 11f.
Further, the noise preventing element T is connected to the second noise preventing element mounting portion 146.
Power is supplied to the brush 16 via a pigtail 17 connected to the tip end side of the choke coil C.

The case where the choke coil C is not provided will be described with reference to FIG.
A first terminal 13 is disposed in the first receiving groove 11e.
The first choke coil mounting portion 137 is disposed in the first receiving groove 11e in a state where the choke coil C is not mounted.
At this time, the first extension portion 13b is provided with a noise prevention element disposition space K formed by a step, so that the first terminal 13 can be disposed while avoiding the noise prevention element T. .
Further, the noise preventing element T is connected to the first noise preventing element mounting portion 136 formed in the first brush connection portion 13c.
Power is supplied to the brush 16 via the pigtail 17 connected to the tip end side of the first brush connection portion 135.

When the choke coil C is not provided, only the second terminal 14 is used and the third terminal 15 is not used.
The second terminal 14 is disposed in the second accommodation groove 11f.
Further, the noise preventing element T is connected to the second noise preventing element mounting portion 146.
Power is supplied to the brush 16 via a pigtail 17 connected to the distal end side of the second brush connection portion 145.

As described above, according to the first terminal 13, the second terminal 14, and the third terminal 15 according to the present embodiment, the choke coil C can be applied as a terminal regardless of whether or not it is used.
Moreover, since the 1st terminal 13 becomes a structure which can avoid the noise prevention element T, it can be applied as a terminal irrespective of the presence or absence of the noise prevention element T.

It is explanatory drawing which shows the motor which concerns on one Embodiment of this invention. It is the top view which looked at the end housing containing the brush holder which concerns on one Embodiment of this invention from the motor main-body part. It is a top view showing the 1st terminal concerning one embodiment of the present invention. It is a perspective view showing the 1st terminal concerning one embodiment of the present invention. It is a top view showing the 2nd terminal concerning one embodiment of the present invention. It is a top view showing the 3rd terminal concerning one embodiment of the present invention. It is an assembly drawing of each terminal at the time of using the choke coil which concerns on one Embodiment of this invention. It is an assembly drawing of each terminal when not using the choke coil which concerns on one Embodiment of this invention.

Explanation of symbols

2. Motor body, 3. Brush holder,
4 ... Yoke housing, 4a ... Opening,
5. Magnet, 6 Armature, 7 Rotating shaft, 8 Bearing, 9 Commutator
11. End housing,
11a... Housing main body, 11b. Connector portion, 11c... Shaft through hole, 11e... First housing groove, 11f.
13 ... Terminal 1
13a ... 1st terminal connection part, 13b ... 1st extension part, 13c ... 1st brush connection part,
13d ... 1st branch part, 13e ... 1st choke coil attachment part, 13f ... 1st holder connection part,
131 ... Connector side conductive part, 132 ... Cross-linked conductive part, 133 ... Noise prevention element side conductive part,
135... 1st brush connection portion, 136... First noise prevention element mounting portion,
137... First choke coil mounting portion, 137 a. First choke coil support portion,
138 ... 1st holder connection protrusion,
14 ... Terminal 2
14a ... 2nd terminal connection part, 14b ... 2nd extension part, 14c ... 2nd brush connection part,
14d ... the second branch,
145 ... 2nd brush connection part, 146 ... 2nd noise prevention element attachment part,
148 ... second holder connection protrusion,
15 ... 3rd terminal 15c ... 3rd brush connection part, 15e ... 3rd choke coil attachment part,
15f ... Third holder connection part,
157, third choke coil mounting portion, 157a, third choke coil support part,
16 ... Brush, 17 ... Pigtail,
C: Choke coil, K: Space for preventing noise elements, M: Motor, T: Noise preventing elements

Claims (5)

A rotating electrical machine incorporated in an end housing and provided with a power feeding terminal for feeding power in the axial direction of the rotating electrical machine,
The power supply terminal is
A terminal connection that receives power from an external power source;
A brush connection that is connected directly or indirectly to the brush;
An extension for connecting the terminal connection portion and the brush connection portion;
The anti-noise element mounting portion for connecting to the anti-noise element is configured to have at least,
When the power supply terminal is attached to the end housing, the distance from the bottom surface of the end housing to the rotating electric machine axial direction is the distance from the bottom surface of the end housing to the noise prevention element mounting portion. The rotating electrical machine is configured to be larger than a distance from a portion to at least a part of the extension portion.   2. The rotating electrical machine according to claim 1, wherein a part of the extension portion and the noise prevention element mounting portion are disposed on different planes orthogonal to the rotating electrical machine axial direction.   The rotating electrical machine according to claim 1, wherein a part of the extension portion is adjacent to the noise prevention element. The power supply terminal is
It further comprises a choke coil mounting portion for arranging the choke coil,
2. The rotating electrical machine according to claim 1, wherein the choke coil mounting portion is provided with the choke coil and is supplied with power to the brush through the choke coil. The power supply terminal is
It further comprises a choke coil mounting portion for arranging the choke coil,
2. The rotating electrical machine according to claim 1, wherein a part of the extension portion is electrically continuously formed between the terminal connection portion and the choke coil mounting portion.

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