JP7130718B2 - VEHICLE INCLUDED WITH A MOTOR, A ROTATING DEVICE INCLUDING THE MOTOR, AND AN AIR CONDITIONING SYSTEM INCLUDING THE ROTATING DEVICE - Google Patents

Description

The present invention relates to a motor, a rotating device including the motor, and a vehicle including an air conditioning system including the rotating device.

For example, Patent Literature 1 discloses a motor actuator (rotating device) that drives a plurality of doors (louvers) provided in the middle of an air passage through which air flows in an air conditioning system for a vehicle.
In such a rotating device, the rotation of the louver is controlled by outputting the rotation of the rotating shaft of the motor through a plurality of gears.

On the other hand, Japanese Patent Laid-Open No. 2002-200000 discloses a brushed motor in which a damper member is provided for the brushes in order to reduce the mechanical noise of the motor.

JP 2015-220969 A JP 2008-22619 A

By the way, in recent years, the environment inside a vehicle tends to be quieter, and in the case of a motor-driven vehicle such as an electric vehicle, the noise generated by the internal combustion engine is not generated, so the quietness inside the vehicle is remarkably high.

If the noise level is improved in this way, even if the noise is not so noticeable inside the vehicle, the noise becomes noticeable inside the vehicle. It is thought that even higher quietness will be required.

One of the sources of noise in the rotating device is the motor. By using a motor that produces less noise than conventional motors, quietness can be further improved.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a motor with reduced noise, a rotating device including the motor, and a vehicle including an air conditioning system including the rotating device.

In order to achieve the above objects, the present invention is grasped by the following configurations.
(1) A motor according to the present invention includes an armature having a commutator, a conductive brush in contact with the commutator, a bracket provided with the conductive brush, and a first a first wall portion having a first surface extending along a surface toward the commutator, and contacting both surfaces of the first surface of the conductive brush and the first surface of the first wall portion; and a first deformable portion that deforms according to movement of the conductive brush.

(2) In the configuration of (1) above, the first deformation portion is always in contact with both the first surface of the conductive brush and the first surface of the first wall portion.

(3) In the configuration of (1) or (2) above, the first surface of the first wall portion is a surface parallel to the first surface of the conductive brush.

(4) In the configuration of any one of (1) to (3) above, the first deformation portion includes a rubber member fixed to the first surface of the conductive brush.

(5) In any one configuration of (1) to (4) above, the first deformable portion contains gel or grease.

(6) In any one configuration of (1) to (3) above, the first deformable portion is gel or grease.

(7) In the configuration of any one of (1) to (6) above, a second surface provided on the bracket and located on the opposite side of the first surface of the conductive brush may extend toward the commutator. a second wall forming an extending second surface, and contacting both the second surface of the conductive brush and the second surface of the second wall and responding to movement of the conductive brush; a second deforming portion that deforms by

(8) In the configuration of (7) above, the second deformation portion is always in contact with both the second surface of the conductive brush and the second surface of the second wall portion.

(9) In the configuration of (7) or (8) above, the second surface of the second wall is parallel to the second surface of the conductive brush.

(10) In the configuration of any one of (7) to (9) above, the second deformation portion includes a rubber member fixed to the second surface of the conductive brush.

(11) In the configuration of any one of (7) to (10) above, the second deformable portion contains gel or grease.

(12) In the configuration of any one of (7) to (11) above, a pair of the conductive brushes in contact with the commutator, and two second conductive brushes provided corresponding to the respective conductive brushes. one wall portion, two first deformation portions provided corresponding to each of the conductive brushes, two second wall portions provided corresponding to each of the conductive brushes, and and the two second deformation portions provided corresponding to the conductive brushes.

(13) In the configuration of any one of (1) to (12) above, the bracket has a hole, and is connected to a terminal led out to the outside through the hole and a second terminal having one end side bent and connected to the terminal. an end of the conductive brush opposite the commutator side is fixed to the first end of the terminal, and the bracket is attached to the terminal. an accommodating portion that accommodates a portion of the first end of the terminal portion, wherein a gap between the accommodating portion and the first end of the terminal portion is provided with the accommodating portion and the first end of the terminal portion; A gel or grease is provided that contacts both sides of the part.

(14) In the configuration of any one of (1) to (13) above, a frame portion and a magnet provided in the frame portion are provided, and the frame portion leads the rotation shaft of the amateur to the outside. and a side wall portion connected to the bottom portion and having an opening on the side opposite to the bottom portion and covering an outer circumference of the armature, wherein the magnet is attached to the side wall portion of the frame portion. and the bracket is attached to the opening of the frame portion.

(15) In the configuration of any one of (1) to (14) above, the first surface of the conductive brush is a surface located opposite to the surface that contacts the commutator.

(16) A rotating device of the present invention comprises a motor having any one of the above configurations (1) to (15), a plurality of gears including an output gear for outputting the rotation of the motor to the outside, and a plurality of the a housing that accommodates the gear and the motor.

(17) A vehicle according to the present invention has an air conditioning system that includes a rotating device having the configuration of (16) above and a louver controlled by the rotating device.

ADVANTAGE OF THE INVENTION According to this invention, the vehicle provided with the motor which reduced the noise, the rotation apparatus provided with the motor, and the air conditioning system provided with the rotation apparatus can be provided.

1 is a perspective view of a motor according to a first embodiment of the invention; FIG. 1 is an exploded perspective view of a motor according to a first embodiment of the invention; FIG. It is a perspective view of an amateur of a 1st embodiment concerning the present invention. 1 is an exploded perspective view of a bracket according to a first embodiment of the invention; FIG. It is a perspective view of a bracket of a 1st embodiment concerning the present invention. FIG. 4A is a plan view of the bracket as seen from the frame side, and FIG. is an enlarged view of the dotted line area A1 in (a). FIG. 4A is a plan view of the bracket as seen from the frame side, and FIG. is an enlarged view of the dotted line area A2 in (a). FIG. 5 is a perspective view of a bracket of a second embodiment according to the invention; It is a perspective view which shows the rotation apparatus of embodiment which concerns on this invention. 1 is a perspective view of a rotating device according to an embodiment of the present invention with a first housing removed; FIG. It is the perspective view which looked at the 2nd surface part side of the 2nd housing|casing of the rotation apparatus of embodiment which concerns on this invention. BRIEF DESCRIPTION OF THE DRAWINGS It is the schematic for demonstrating the air-conditioning system provided with the rotation apparatus of embodiment which concerns on this invention. 11 shows a vehicle equipped with the air conditioning system of FIG. 10; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, modes for carrying out the present invention (hereinafter referred to as "embodiments") will be described in detail with reference to the accompanying drawings.
The same numbers are given to the same elements throughout the description of the embodiment.

(First embodiment)
FIG. 1 is a perspective view of a motor 10 according to the first embodiment of the invention, and FIG. 2 is an exploded perspective view of the motor 10 according to the first embodiment of the invention.

As shown in FIG. 2 , the motor 10 includes a frame portion 20 , a plurality of magnets (not shown) provided inside the frame portion 20 , an armature 30 and a bracket 40 .

(Frame part)
As shown in FIG. 2, the frame portion 20 has a bottom portion 21 provided with a hole portion 21a for leading out the rotating shaft 31 of the armature 30, and an opening portion 22a connected to the bottom portion 21 and opposite to the bottom portion 21. and a side wall portion 22 covering the outer circumference of the armature 30 .

The bracket 40 is attached to the opening 22a of the frame portion 20 so as to close the opening 22a of the frame portion 20. As shown in FIG.
Further, in the present embodiment, the side wall portion 22 of the frame portion 20 has a quadrangular prism shape with curved corners, but the shape may be changed as necessary.

A plurality of magnets are arranged apart from the armature 30 on the inner wall surface of the side wall portion 22 of the frame portion 20 facing the armature 30 .
Further, the bottom portion 21 of the frame portion 20 is provided with a bearing portion 21b formed so as to protrude outward in the direction of the rotating shaft 31 .

A hole portion 21a through which the rotating shaft 31 is led out is provided in the center of the bearing portion 21b.
A bearing that rotatably supports the rotating shaft 31 is housed inside the bearing portion 21b.

(amateur)
As shown in FIG. 2 , the armature 30 includes a core 32 , a coil (not shown) wound around the core 32 , and a rotating shaft 31 fixed to the core 32 .
The rotating shaft 31 is arranged in the center of the core 32 so as to pass through the core 32 .
Note that the core 32 has a configuration in which a plurality of metal plates are laminated and integrated in the direction of the rotating shaft 31 .
Examples of the plurality of metal plates include electromagnetic steel plates.

FIG. 3 is a perspective view of the armature 30. FIG.
As shown in FIG. 3, the armature 30 has a commutator 33 provided along the outer peripheral surface of the rotating shaft 31 in the circumferential direction.
The commutator 33 has a plurality of sheet metals 33a provided on the other end of the rotating shaft 31 located on the opposite side of the one end led out of the motor 10 .

Ends of coils (not shown) wound around the poles 32a of the core 32 are connected to the sheet metal 33a of the commutator 33 by soldering or the like.
The other end 31a of the rotating shaft 31 positioned on the other side of the commutator 33 is rotatably supported by a bearing 41 provided on a bracket 40, which will be described later.

(bracket)
FIG. 4 is an exploded perspective view of the bracket 40. FIG.
As shown in FIG. 4, the bracket 40 includes a bracket body 40a and a bearing plate 40b.
The bracket main body 40a has a bottom portion 40ab, which is located on the side opposite to the frame portion 20 side.
This bearing plate 40b is attached to the outside of the bottom portion 40ab.

A bearing portion 40ba is provided in the center of the bearing plate 40b, and the bearing portion 40ba protrudes to the side opposite to the bracket main body 40a.
The bearing 41 is accommodated in the bearing portion 40ba, and the bearing plate 40b is attached to the bracket main body 40a to integrate the bracket 40 with the bearing 41. As shown in FIG.

The bracket 40 also includes a pair of conductive brushes (a conductive brush 42 and a conductive brush 43) and a pair of terminal portions (a terminal portion 44 and a terminal portion 45) to which the conductive brushes are attached.

The terminal portion 44 and the terminal portion 45 have a symmetrical shape in which one end portion 44ba side of a first end portion 44b and one end portion 45ba side of a first end portion 45b described later are bent in opposite directions. The only difference is the basic configuration.
Specifically, the terminal portion 44 includes a terminal 44a led out to the outside, and a first end portion 44b connected to the terminal 44a and having one end portion 44ba side bent.
The terminal 44a is a portion electrically connected to the outside.

The terminal portion 45 also includes a terminal 45a led out to the outside, and a first end portion 45b connected to the terminal 45a and having one end portion 45ba side bent.
The terminal 45a is a part electrically connected to the outside.

FIG. 5 is a perspective view of the bracket 40. FIG.
As shown in FIG. 4, the bracket body 40a is provided with a groove portion 46 into which the terminal 44a of the terminal portion 44 is inserted. there is
The bottom of this groove 46 faces the bearing plate 40b.
An opening 48 corresponding to the terminal 44a of the terminal portion 44 is provided in the bearing plate 40b.
The opening 48 is arranged at a position facing the terminal 44a.

Therefore, as shown in FIG. 5, when the terminal 44a of the terminal portion 44 to which the conductive brush 42 is fixed is inserted into the groove portion 46 of the bracket body 40a, the terminal 44a is led out through the hole at the bottom of the groove portion 46. It is possible.

Similarly, as shown in FIG. 4, the bracket body 40a is provided with a groove portion 47 into which the terminal 45a of the terminal portion 45 is inserted. It is
An opening 49 corresponding to the terminal 45a of the terminal portion 45 is provided in the bearing plate 40b.
The opening 49 is arranged at a position facing the terminal 45a.

Therefore, as shown in FIG. 5, when the terminal 45a of the terminal portion 45 to which the conductive brush 43 is fixed is inserted into the groove portion 47 of the bracket body 40a, the terminal 45a passes through the hole at the bottom of the groove portion 47 to the outside. can be derived to

A commutator 33 of the armature 30 is positioned near the bearing 41 shown in FIG.
Therefore, as can be seen from FIGS. 4 and 5, the end portion of the conductive brush 42 opposite to the commutator 33 side in the radial direction is fixed to one end side of the first end portion 44b of the terminal portion 44. It is
Specifically, the end portion of the conductive brush 42 is fixed to one end portion 44ba of the first end portion 44b, and this one end portion 44ba is a part of the one end side of the first end portion 44b.
Similarly, the end of the conductive brush 43 on the opposite side of the commutator 33 is fixed to one end 45ba of the first end 45b of the terminal portion 45, and this one end 45ba is a part of one end side of the first end portion 45b.

A more detailed configuration will be described while describing the operation of the motor 10 having such a configuration.
When power is supplied through the terminal portions 44 and 45 , current is supplied to the coil through the sheet metal 33 a of the commutator 33 in contact with the conductive brushes 42 and 43 .

Then, the pole 32a (see FIG. 3) is excited to the N pole or the S pole depending on the winding direction of the coil, and attraction occurs between the magnetic force of the magnet provided in the frame portion 20, and the armature 30 is moved. Rotate.

As the armature 30 rotates, the commutator 33 also rotates, and the conductive brushes 42 and 43 come into contact with the sheet metal 33a different from the sheet metal 33a of the commutator 33 that was previously in contact.

As a result, a current is supplied to the coil connected to the sheet metal 33a of the commutator 33 which is newly in contact with the conductive brushes 42 and 43, and the pole 32a corresponding to the coil to which the current is supplied is connected to the coil. is magnetized to the N pole or the S pole depending on the winding direction.

Then, an attraction occurs again with the magnetic force of the magnet provided in the frame portion 20, and the armature 30 rotates.
By repeating this, the rotary shaft 31 of the motor 10 continues to rotate.

Here, when the conductive brush 42 and the conductive brush 43 contact another sheet metal 33a from the sheet metal 33a of the commutator 33 with which they have been in contact until now, the conductive brush 42 and the conductive brush 43 vibrate. occurs and causes noise.

Therefore, in this embodiment, the first deformation portion 72 and the second deformation portion 70 are provided to suppress the vibration of the conductive brush 42 , and the first deformation portion 73 and the second deformation portion 73 are provided to suppress the vibration of the conductive brush 43 . Two deformation portions 71 are provided, and the configuration related to these deformation portions will be described in detail below.

(Second deformation portion 70)
As shown in FIGS. 4 and 5, the bracket 40 has a second wall portion 60 .
The second wall portion 60 is provided on the bracket main body 40a.
The second wall portion 60 has a second surface 60a extending toward the commutator 33 (center side of the bracket 40) along the second surface 42a of the conductive brush 42 that contacts the commutator 33. have
In this embodiment, the second surface 60a of the second wall portion 60 is formed parallel to the second surface 42a of the conductive brush 42. As shown in FIG.
The second surface 60a of the second wall portion 60 is not limited to being parallel to the second surface 42a of the conductive brush 42, and may be inclined with respect to the second surface 42a of the conductive brush 42. do not have.

5, between the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60, both surfaces (the second surface 42a and the second surface 42a). 60a) is provided with a second deformable portion 70 provided so as to be in constant contact (always close contact).

The constant contact (always close contact) here does not mean that the contact (close contact) state is maintained until the motor 10 becomes unusable.
That is, while the motor 10 continues to be used for a long period of time, separation occurs between the second deformation portion 70 and the second surface 42a, or separation occurs between the second deformation portion 70 and the second surface 60a. It can occur.
Therefore, constant contact (constant close contact) should be understood to mean that they are always in contact (close contact) as long as no peculiar situation such as detachment occurs. Note that it should not be construed as continuing.

Specifically, the second deformation portion 70 includes a flat rubber member 70a fixed to the second surface 42a of the conductive brush 42, and a cushioning member 70b made of gel or grease.
It should be noted that the second deformation section 70 need not be limited to having the rubber member 70a and the cushioning member 70b, and for example, the second deformation section 70 may be composed only of the cushioning member 70b.

For example, the rubber member 70a preferably has a rubber hardness (Shore A hardness) of 25 or more and 60 or less according to JIS K6253 from the viewpoint of suppressing vibration.
The gel used for the cushioning member 70b may be a two-liquid curing type, an ultraviolet curing type, a heat curing type, or the like. is preferably 30 or more and 70 or less.
Further, the grease used for the buffer member 70b preferably has a consistency of No. 5 or more and a consistency of 60 or more and 165 or less from the viewpoint of suppressing vibration.

It should be noted that, by using the gel having the hardness and the grease having the consistency as described above, the fluidity of the cushioning member 70b can be suppressed, and at the same time, the cushioning member 70b can be provided with softness capable of suppressing vibration satisfactorily. Here, softness includes, for example, having viscosity or elasticity.

If such a second deformation portion 70 is provided between the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60 so as to be in constant contact with both surfaces, the conductive brush can be 42 is softly deformed or changed so that the second deformation portion 70 absorbs the movement of the brush 42 in the direction away from the commutator 33, and the resulting vibration of the conductive brush 42 is greatly reduced. can be reduced and the generation of noise can be suppressed.

The state of the second deformable portion 70 when the motor 10 is driven will be described in more detail with reference to FIG. 6 .
6A and 6B are diagrams for explaining the state of the second deformation portion 70 when the motor 10 is driven. FIG. 6A is a plan view of the bracket 40 viewed from the frame portion 20 side, and FIG. b) is an enlarged view of the dotted line area A1 in FIG. 6(a).
6 also shows the sheet metal 33a of the commutator 33 provided in the armature 30. As shown in FIG.

When the motor 10 is driven and the conductive brush 42 vibrates, for example, as shown in FIG. Displacement to the position shown by occurs.
At this time, the second deformable portion 70 deforms according to the movement of the conductive brush 42 .

Specifically, as shown in FIG. 6B, the rubber member 70a moves as indicated by an arrow m2, and the shape of the cushioning member 70b is hatched to match the movement of the rubber member 70a. from the state of , to the state of cross-hatching. Specifically, the shape of the buffer member 70b is the direction in which the second surface 60a of the second wall 60 extends or the direction in which the second surface 42a of the conductive brush 42 extends, transform towards.
That is, part of the buffer member 70b escapes (protrudes) into the space formed between the second surface 42a of the conductive brush 42 without the buffer member 70b and the second surface 60a of the second wall portion 60. .
If the rubber member 70a also has a low rubber hardness, the shape of the rubber member 70a is likely to be deformed similarly to the cushioning member 70b.

This change in shape of the cushioning member 70b is due to the state in which the second deformation portion 70 is in contact with and sandwiched between the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60. phenomenon that occurs.
That is, even if the second deformation portion 70 is in contact with the second surface 42a of the conductive brush 42, if the second surface 60a side of the second wall portion 60 is free, the second deformation portion 70 Since no compressive force is applied, the shape change of the second deformation portion 70 is extremely small.

As the second deformation portion 70 is compressed and changes in shape, a reaction force acts on the conductive brush 42 to stop the movement of the conductive brush 42 .
Therefore, movement of the conductive brush 42 is suppressed.
In addition, depending on the material forming the second deformation portion 70, it has not only elasticity but also viscosity. At the same time, an action that absorbs the force applied is also generated.

On the other hand, when the conductive brush 42 moves in the opposite direction, that is, the second surface 42a of the conductive brush 42 moves in the direction opposite to the arrow m1 from the dotted line position shown in FIG. When trying to move, the shape of the second deformation portion 70 changes.
Specifically, the shape of the buffer member 70b is the direction in which the second surface 60a of the second wall portion 60 extends or the direction in which the second surface 42a of the conductive brush 42 extends, and the shape of the conductive brush 44 is deformed toward the root F1 of .
That is, part of the buffer member 70b returns to the space formed between the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall 60 where the buffer member 70b is located.

Here, since the second deformation portion 70 is not an elastic body such as a spring, it does not immediately return to its original shape by its own elastic force, and when the conductive brush 42 tries to move to the position indicated by the solid line, The change in shape of the second deformation portion 70 of is mainly caused by the force (restoring force) generated by the bending of the conductive brush 42 .

Then, the movement of the conductive brush 42 in the direction opposite to the arrow m1 pulls the second deformation portion 70 from the second wall portion 60 toward the conductive brush 44 .
As the shape of the second deformation portion 70 changes due to this pulling, the second surface 60 a of the second wall portion 60 of the conductive brush 42 is stretched by the second deformation portion 70 with respect to the conductive brush 42 . A reaction force acts to restrain the movement away from the side.
In addition, along with the shape change of the second deformable portion 70, an effect of absorbing (reducing) the force that tends to move the conductive brush 42 also occurs at the same time.

It should be noted that this reaction force, that is, the stopping action, is also a phenomenon that occurs when the second deformation portion 70 is in contact with both the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60, If the second deformation portion 70 is not in contact with the second surface 60 a of the second wall portion 60 , the second deformation portion 70 will move with the conductive brush 42 in the same manner.

In this way, the second deforming portion 70 also moves from the position indicated by the dotted line to the position indicated by the solid line when the conductive brush 42 attempts to move from the position indicated by the solid line to the position indicated by the dotted line in FIG. It acts to suppress the movement of the conductive brush 42 even when it tries to move.

Vibration of the conductive brush 42 means that the conductive brush 42 repeatedly moves between the position indicated by the solid line and the position indicated by the dotted line in FIG. Thus, regardless of which position the conductive brush 42 faces, it acts to suppress the movement of the conductive brush 42, thereby suppressing the vibration of the conductive brush 42.

By the way, if the volume before the shape change is T, the volume of the portion whose shape is changed by compression or tension is ΔT, and the shape change rate VC is ΔT/T, the degree of suppression of vibration accompanying the shape change is: The larger the shape change rate VC, the higher.
Therefore, in order to increase the shape change rate VC, it is preferable to reduce the volume of the second deformation portion 70 set before the motor 10 is driven.

As can be seen from FIG. 6B, the second deformation portion 70 is provided so as to contact both the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60. Therefore, the volume of the second deformation portion 70 is adjusted by adjusting the distance between the second surface 42 a of the conductive brush 42 and the second surface 60 a of the second wall portion 60 .

Specifically, since the length of the conductive brush used varies depending on the size of the motor, the second surface 42a of the conductive brush 42 and the second surface 42a of the conductive brush 42 for making the second deformation portion 70 have an appropriate volume. The distance between the second surfaces 60a of the wall portion 60 is preferably set based on the length of the conductive brushes 42. As shown in FIG.

Therefore, the commutator 33 of the conductive brush 42 is brought into contact with the base of the conductive brush 42 on the terminal portion 44 side (see position F1 in FIG. 6B where the terminal portion 44 of the conductive brush 42 is no longer supported). The second surface 42a of the conductive brush 42 and the second surface 60a of the second wall 60 have a length of 0.5 or less when the length to the position F11 (see FIG. 6A) is 1. It is preferable that the distance between them (hereinafter also referred to as the first distance) is set, and more preferably set to 0.3 or less.
The second wall portion 60 is provided on the bracket body 40a such that the first distance between the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60 is a predetermined distance. do it.

Note that this first distance does not contact the commutator 33 with the conductive brushes 42 and extends substantially straight at each point along the second surface 60 a of the second wall 60 . The distance between the second surface 42a of the conductive brush 42 and the second surface 60a of the second wall portion 60 when a perpendicular line is drawn from , is the longest distance among the obtained distances.

On the other hand, if the first distance is too short, the second deformation portion 70 may not be sufficiently deformed. More preferably.

Furthermore, the second deformable portion 70 is preferably provided with a certain length along the second surface 42a of the conductive brush 42, so that the second surface 60a of the second wall portion 60 extends along the conductive brush. It is preferable to provide a certain length along the second surface 42a of 42 .

Specifically, the position F11 (see FIG. 6A) where the conductive brush 42 contacts the commutator 33 from the root of the conductive brush 42 on the terminal portion 44 side (see position F1 in FIG. 6B). When the length to the second wall portion 60 is 1, the second wall portion 60 It is preferable that the second surface 60a extend toward the commutator 33 to the extent that a perpendicular can be drawn from the point of the second surface 60a.
At this time also, the conductive brushes 42 are not brought into contact with the commutator 33, and a perpendicular line is drawn to the conductive brushes 42 extending substantially straight.

That is, when a perpendicular line is drawn to the conductive brush 42 from the position G2 (see FIG. 6B) closest to the commutator 33 side of the second surface 60a of the second wall portion 60, the perpendicular line and the conductive brush 42 of the second wall portion 60 so that the intersection point of the crossing of the second wall portion 60 is 0.4 or more in length from the root of the conductive brush 42 on the terminal portion 44 side (see position F1 in FIG. 6B)). Preferably, two surfaces 60a are provided.
By doing so, the second surface 60a corresponding to a range of 0.4 or more from the base of the conductive brush 42 on the terminal portion 44 side to the commutator 33 side is provided. The second deformable portion 70 can be provided over four or more ranges.

(Second deformation portion 71)
The bracket 40 is provided on a bracket body 40a and extends toward the commutator 33 (center side of the bracket 40) along a second surface 43a, which is a surface of the conductive brush 43 in contact with the commutator 33. It has a second wall 61 with a surface 61a.
The second surface 61 a of the second wall portion 61 is formed parallel to the second surface 43 a of the conductive brush 43 .
The second surface 61a of the second wall portion 61 is not limited to being parallel to the second surface 43a of the conductive brush 43, and may be inclined with respect to the second surface 43a of the conductive brush 43. do not have.

Then, the motor 10 is in constant contact with both surfaces (the second surface 43a and the second surface 61a) between the second surface 43a of the conductive brush 43 and the second surface 61a of the second wall portion 61 (always It has a second deformable portion 71 provided so as to be in close contact.

It should be noted that the constant contact (always close contact) here does not mean that the contact (close contact) state is maintained until the motor 10 becomes unusable, as described in the second deforming portion 70. is used, peeling occurs between the second deforming portion 71 and the second surface 43a, or peeling occurs between the second deforming portion 71 and the second surface 61a. It should be noted that it means that they are always in contact (adhesion) while no .

Specifically, the second deformation portion 71 includes a flat rubber member 71a fixed to the second surface 43a of the conductive brush 43, and a cushioning member 71b made of gel or grease.
The second deformation portion 71 is not limited to having the rubber member 71a and the cushioning member 71b. For example, the second deformation portion 71 may be composed only of the cushioning member 71b.

For example, the rubber member 71a preferably has a rubber hardness (Shore A hardness) of 25 or more and 60 or less according to JIS K6253 from the viewpoint of suppressing vibration, as described above.
The gel used for the cushioning member 71b may be a two-liquid curing type, an ultraviolet curing type, a heat curing type, or the like. is preferably 30 or more and 70 or less.
Furthermore, from the viewpoint of suppressing vibration, the grease used for the buffer member 71b preferably has a consistency of No. 5 or more and a consistency of 60 or more and 165 or less.

It should be noted that, by using the gel having the hardness and the grease having the consistency described above, the fluidity of the cushioning member 71b can be suppressed, and at the same time, the cushioning member 71b can be provided with softness capable of suppressing vibration satisfactorily.

If such a second deformation portion 71 is provided between the second surface 43a of the conductive brush 43 and the second surface 61a of the second wall portion 61 so as to be in constant contact with both surfaces, the conductive brush can be deformed. 43 is softly deformed or changed so that the second deformation portion 71 absorbs the movement of the brush 43 in the direction away from the commutator 33, and the resulting vibration of the conductive brush 43 is greatly reduced. can be reduced and the generation of noise can be suppressed.

Since this second deformation portion 71 is a portion that exerts the same action on the conductive brush 43 as the second deformation portion 70 on the conductive brush 42, the second deformation portion 71 is in the same position as the second deformation portion 70 on the conductive brush 42 when the motor 10 is being driven. The state of 71 is the same as that described for the second deformation portion 70 .

Therefore, although detailed description is omitted, the base of the conductive brush 43 on the terminal portion 45 side (the position where the terminal portion 45 of the conductive brush 43 in FIG. 6A is not supported) F2))) to the position F21 (see FIG. 6A) of the conductive brush 43 in contact with the commutator 33 is set to 1, the length of the conductive brush 43 is 0.5 or less. The distance between the second surface 43a and the second surface 61a of the second wall portion 61 (hereinafter also referred to as the first distance) is preferably set, and more preferably set to 0.3 or less. .
The second wall portion 61 is provided on the bracket body 40a such that the first distance between the second surface 43a of the conductive brush 43 and the second surface 61a of the second wall portion 61 is a predetermined distance. do it.

It should be noted that this first distance is similar to the first distance described for the second deformation portion 70 , and does not contact the commutator 33 . The distance between the second surface 43a of the conductive brush 43 and the second surface 61a of the second wall portion 61 when a perpendicular line is drawn from each point along the second surface 61a of the second wall portion 61 is obtained. It is the longest distance among the distances

Also, as described for the first distance of the second deformation portion 70, if the first distance corresponding to the second deformation portion 71 is also short, the second deformation portion 71 may not be sufficiently deformed. Therefore, the first distance corresponding to the second deformation portion 71 is also preferably set to 0.1 or more, and more preferably set to 0.2 or more.

Furthermore, in order to provide the second deformation portion 71 with a certain length along the second surface 43 a of the conductive brush 43 , the terminal portion 45 is formed in the same manner as described for the second deformation portion 70 . The length from the root of the side conductive brush 43 (see position F2 in FIG. 6A) to the position F21 (see FIG. 6A) where the conductive brush 43 contacts the commutator 33 is set to 1. From the point on the second surface 61a of the second wall portion 61 to the point on the conductive brush 43 that is 0.4 or more from the base of the conductive brush 43 on the terminal portion 45 side to the commutator 33 side. It is preferable that the second surface 61a extend toward the commutator 33 to the extent that a vertical line can be drawn.
At this time also, the conductive brushes 43 are not brought into contact with the commutator 33, and a perpendicular line is drawn to the conductive brushes 43 extending substantially straight.

By doing so, similarly to the second deformation portion 70 , the second deformation portion 71 also has a range of 0.4 or more from the base of the conductive brush 43 on the terminal portion 45 side toward the commutator 33 side. Therefore, the second deformation portion 71 can be provided over a range of 0.4 or more.

(First deformation portion 72)
As shown in FIG. 5, the bracket 40 is provided on the bracket main body 40a, and along the first surface 42b located on the opposite side of the second surface 42a of the conductive brush 42, the commutator 33 side (center of the bracket 40). a first wall portion 62 forming a first surface 62a extending from the side).
The first surface 62a of the first wall portion 62 is formed parallel to the first surface 42b of the conductive brush 42. As shown in FIG.

As shown in FIG. 5, the motor 10 is provided between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 so as to be in constant contact (always close contact) with both surfaces. and a first deformation portion 72 made of gel or grease.

It should be noted that the constant contact (always close contact) here does not mean that the contact (close contact) state is maintained until the motor 10 becomes unusable, as described in the second deforming portion 70. is used, peeling occurs between the first deforming portion 72 and the first surface 42b, or peeling occurs between the first deforming portion 72 and the first surface 62a. It should be noted that it means that they are always in contact (adhesion) while no .

For example, the gel that forms the first deformation portion 72 may be of a two-liquid curing type, an ultraviolet curing type, a heat curing type, or the like. The type 00 hardness is preferably 30 or more and 70 or less.
Further, the grease forming the first deformation portion 72 preferably has a consistency of No. 5 and a consistency of 60 or more and 165 or less from the viewpoint of suppressing vibration.

Note that the first deformation portion 72 may be configured to include a rubber member having a rubber hardness (Shore A hardness) of 25 or more and 60 or less according to JIS K6253, like the second deformation portion 70 .

Then, by using the gel having the hardness or the grease having the consistency as described above, the first deformation portion 72 has a softness capable of suppressing vibration while suppressing the fluidity of the first deformation portion 72 . can do.

When such a first deformation portion 72 is provided between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 so as to be in constant contact with both surfaces, the conductive brush can The first deforming portion 72 can be softly deformed or modified so as to absorb the force that tends to move the commutator 42 away from the commutator 33, thereby significantly reducing noise generation.

The state of the first deformation portion 72 when the motor 10 is driven will be described in more detail with reference to FIG.
7A and 7B are diagrams for explaining the state of the first deformation portion 72 when the motor 10 is being driven. FIG. 7A is a plan view of the bracket 40 as seen from the frame portion 20 side, b) is an enlarged view of the dotted line area A2 in FIG. 7(a).
7 also shows the sheet metal 33a of the commutator 33 provided in the armature 30. As shown in FIG.

When the motor 10 is driven and the conductive brush 42 vibrates, for example, as shown in FIG. Displacement to the position shown by occurs.
At this time, the first deformation portion 72 deforms according to the movement of the conductive brush 42 .

Specifically, as shown in FIG. 7(b), the shape of the first deformation portion 72 changes from the hatched state to the crossed state so as to match the movement of the conductive brush 42 as indicated by the arrow m3. Change to a hatched state.
Specifically, the shape of the first deformation portion 72 is the direction in which the second surface 62a of the first wall portion 62 extends or the direction in which the first surface 42b of the conductive brush 42 extends, Deform towards 33.
That is, part of the first deformation portion 72 escapes into the space formed between the first surface 42b of the conductive brush 42 without the first deformation portion 72 and the first surface 62a of the first wall portion 62. (protruding).

This shape change of the first deformation portion 72 is a state in which the first deformation portion 72 is in contact with and sandwiched between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62. This is a phenomenon caused by
That is, even if the first deformation portion 72 is in contact with the first surface 42b of the conductive brush 42, if the first surface 62a side of the first wall portion 62 is free, the first deformation portion 72 is Since no compressive force is applied, the shape change of the first deformation portion 72 is extremely small.

As the first deformation portion 72 is compressed and changes in shape, a reaction force acts on the conductive brush 42 to stop the movement of the conductive brush 42 . Therefore, movement of the conductive brush 42 is suppressed.
In addition, since the material forming the first deformation portion 72 has not only elasticity but also viscosity, the conductive brush 42 tries to move as the first deformation portion 72 is compressed and changes its shape. At the same time, a force-absorbing action also occurs.

On the other hand, when the conductive brush 42 moves in the opposite direction, that is, the first surface 42b of the conductive brush 42 moves from the dotted line position shown in FIG. When trying to move, the shape of the first deformation portion 72 changes.
Specifically, the shape of the first deformation portion 72 is the direction in which the first surface 62a of the first wall portion 62 extends or the direction in which the first surface 42b of the conductive brush 42 extends, and is electrically conductive. The brush 44 is deformed toward the base F1.
That is, part of the first deformation portion 72 returns to the space formed between the first surface 42b of the conductive brush 42 where the first deformation portion 72 is located and the first surface 62a of the first wall portion 62. .

Here, since the first deformation portion 72 is not an elastic body such as a spring, it does not immediately return to its original shape by its own elastic force, and when the conductive brush 42 tries to move to the position indicated by the solid line, The change in shape of the first deformation portion 72 of is mainly caused by the force (restoring force) generated by the bending of the conductive brush 42 .

Then, the movement of the conductive brush 42 in the direction opposite to the arrow m1 pulls the first deformation portion 72, and as the shape changes, the conductive brush 42 is moved to the first deformation portion 72 of the conductive brush 42. A reaction force acts to stop the movement of the wall portion 62 away from the first surface 62a side.
In addition, along with this change in shape, an action of absorbing the force that tends to move the conductive brush 42 also occurs at the same time.

This restraining action is also a phenomenon caused by the contact of the first deformation portion 72 with both the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62. If 72 were not in contact with first surface 62 a of first wall 62 , first deformation 72 would move with conductive brush 42 in the same manner.

In this way, the first deforming portion 72 also moves from the position indicated by the dotted line to the position indicated by the solid line when the conductive brush 42 attempts to move from the position indicated by the solid line to the position indicated by the dotted line in FIG. It acts to suppress the movement of the conductive brush 42 even when it tries to move.

Vibration of the conductive brush 42 means that the conductive brush 42 repeatedly moves between the solid line position and the dotted line position shown in FIG. Thus, regardless of which position the conductive brush 42 faces, it acts to suppress the movement of the conductive brush 42, thereby suppressing the vibration of the conductive brush 42.

By the way, as shown in FIG. 7(b), when the first surface 42b of the conductive brush 42 moves from the position indicated by the solid line to the position indicated by the dotted line as indicated by the arrow m3, the second surface 42b of the conductive brush 42 is moved from the position indicated by the solid line to the position indicated by the dotted line. Surface 42a will move in the same way.

Then, the rubber member 71a of the second deformation portion 70 also moves as indicated by the arrow m4, and the shape of the cushioning member 70b of the second deformation portion 70 changes (see cross hatched portion H).
If the rubber member 71a also has a low rubber hardness, the shape of the rubber member 71a changes in the same manner as the cushioning member 70b.

Then, when the shape of the second deformable portion 70 changes, as already explained, a reaction force is generated to stop the movement of the conductive brush 42 in the direction away from the second surface 60a of the second wall portion 60. As it works, the second deformation portion 70 absorbs the force of the conductive brush 42 trying to move.

Conversely, when the first surface 42b of the conductive brush 42 moves in the direction opposite to the arrow m3 from the dotted line position shown in FIG. changes shape.

As described above, even when the shape of the second deformation portion 70 changes, a reaction force acts on the conductive brush 42 to stop the movement of the conductive brush 42, and the second deformation portion 70 becomes conductive. It absorbs the force that the sex brush 42 tries to move.

Therefore, in the present embodiment, both the first deformation section 72 and the second deformation section 70 work together to suppress the movement of the conductive brush 42 .
Therefore, the vibration of the conductive brush 42 can be suppressed to a higher degree, and the noise can be greatly reduced.

On the other hand, in the first deformation portion 72, similarly to the second deformation portions 70 and 71, in order to increase the shape change rate VC, the volume of the first deformation portion 72 is set before the motor 10 is driven. is preferred to be small.

As can be seen from FIG. 7(b), the first deformation portion 72, like the second deformation portion 70, has the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62. , the volume of the first deformation portion 72 is adjusted by the distance between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62. .

In the first deformation portion 72 as well, the length of the conductive brush used changes depending on the size of the motor, as in the case of the second deformation portion 70. Therefore, the first deformation portion 72 has an appropriate volume. The distance between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 is preferably set based on the length of the conductive brush 42. As shown in FIG.

Therefore, the commutator 33 of the conductive brush 42 is brought into contact with the base of the conductive brush 42 on the terminal portion 44 side (see position F1 in FIG. 7B where the terminal portion 44 of the conductive brush 42 is no longer supported). The first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 are arranged such that the distance between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 is 0.5 or less when the length to the position F11 (see FIG. 7A) is 1. It is preferable that the distance between the two (hereinafter also referred to as the second distance) is set, and more preferably set to 0.3 or less.
The first wall portion 62 is provided on the bracket body 40a such that the second distance between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 is a predetermined distance. do it.

As in the case of the first distance, the second distance is such that the conductive brushes 42 are not brought into contact with the commutator 33, and the first wall portion 62 is positioned between the conductive brushes 42 extending substantially straight. Find the distance between the first surface 42b of the conductive brush 42 and the first surface 62a of the first wall portion 62 when a perpendicular is drawn from each point along the first surface 62a, and It's a long distance.

On the other hand, if the second distance is too short, the first deformation portion 72 may not be sufficiently deformed. more preferably.

Furthermore, in the first deformation portion 72 as well as the second deformation portion 70, it is preferable that the first deformation portion 72 is provided with a certain length along the first surface 42b of the conductive brush 42. Therefore, it is preferable that the first surface 62a of the first wall portion 62 is provided along the first surface 42b of the conductive brush 42 for a certain length.

Specifically, the position F11 (see FIG. 7A) where the conductive brush 42 contacts the commutator 33 from the base of the conductive brush 42 on the terminal portion 44 side (see position F1 in FIG. 7B). When the length to the conductive brush 42 is 1, the point closest to the base of the conductive brush 42 (see position F1 in FIG. 7B) on the first surface 62a of the first wall portion 62 to the conductive brush 42. With reference to the position F12 (see FIG. 7B) where the perpendicular line is drawn, the first wall portion 62 of It is preferable that the first surface 62a extend toward the commutator 33 to the extent that a perpendicular line can be drawn from the point of the first surface 62a.
At this time also, the conductive brushes 42 are not brought into contact with the commutator 33, and a perpendicular line is drawn to the conductive brushes 42 extending substantially straight.

By doing so, the first surface 62a corresponding to the range of 0.4 or more from the position F12 near the root of the conductive brush 42 on the terminal portion 44 side to the commutator 33 side is provided. , the first deformation portion 72 can be provided over a range of 0.4 or more.

(First deformation portion 73)
As shown in FIG. 5, the bracket 40 is provided on the bracket main body 40a, and along the first surface 43b located on the opposite side of the second surface 43a of the conductive brush 43, the commutator 33 side (the center of the bracket 40). a first wall portion 63 forming a first surface 63a extending on the side).
The first surface 63a of the first wall portion 63 is formed so as to be substantially parallel to the first surface 43b of the conductive brush 43. As shown in FIG.

Then, the motor 10 is provided with gel or grease between the first surface 43b of the conductive brush 43 and the first surface 63a of the first wall portion 63 so as to be in constant contact (always close contact) with both surfaces. It has a first deformed portion 73 that is formed.

It should be noted that the constant contact (always close contact) here does not mean that the contact (close contact) state is maintained until the motor 10 becomes unusable, as described in the second deforming portion 70. is used, peeling occurs between the first deforming portion 73 and the first surface 43b, or peeling occurs between the first deforming portion 73 and the first surface 63a. It should be noted that it means that they are always in contact (adhesion) while no .

For example, the gel that forms the first deformation portion 73 may be of a two-liquid curing type, an ultraviolet curing type, a heat curing type, or the like. The type 00 hardness is preferably 30 or more and 70 or less.
Further, from the viewpoint of suppressing vibration, the grease forming the first deformation portion 73 preferably has a consistency of No. 5 or more and a consistency of 60 or more and 165 or less.

Note that the first deformation portion 73 may be configured to include a rubber member having a rubber hardness (Shore A hardness) of 25 or more and 60 or less according to JIS K6253, like the second deformation portion 71 .

Then, by using the gel having the hardness and the grease having the consistency as described above, the first deformation portion 73 has a softness that can satisfactorily suppress vibration while suppressing the fluidity of the first deformation portion 73 . can do.

When such a first deformation portion 73 is provided between the first surface 43b of the conductive brush 43 and the first surface 63a of the first wall portion 63 so as to be in constant contact with both surfaces, the conductive brush can be The first deforming portion 73 is softly deformed or modified so as to absorb the force that tends to move the 43 away from the commutator 33, thereby significantly reducing noise generation.

Since this first deformation portion 73 is a portion that exerts the same action on the conductive brush 43 as the first deformation portion 72 on the conductive brush 42 , the first deformation portion 73 when the motor 10 is driven The state of 73 is the same as that described for the first deformation portion 72 .

Therefore, although detailed description is omitted, the base of the conductive brush 43 on the terminal portion 45 side (the position where the terminal portion 45 of the conductive brush 43 in FIG. 7A is no longer supported) F2))) to the position F21 (see FIG. 7A) of the conductive brush 43 that contacts the commutator 33 is 1, and the length of the conductive brush 43 is 0.5 or less. The distance between the first surface 43b and the first surface 63a of the first wall portion 63 (hereinafter also referred to as the second distance) is preferably set, and more preferably set to 0.3 or less. .
The first wall portion 63 is provided on the bracket body 40a such that the second distance between the first surface 43b of the conductive brush 43 and the first surface 63a of the first wall portion 63 is a predetermined distance. do it.

Note that this second distance is also similar to the second distance described for the first deformed portion 72 , and does not contact the commutator 33 with the conductive brushes 43 . The distance between the first surface 43b of the conductive brush 43 and the first surface 63a of the first wall portion 63 when a perpendicular line is drawn from each point along the first surface 63a of the first wall portion 63 is obtained. It is the longest distance among the distances

In addition, similarly to the first distance of the second deformation portion 70, if the second distance corresponding to the first deformation portion 73 is also short, the first deformation portion 73 may not be sufficiently deformed. Therefore, the second distance corresponding to the first deformation portion 73 is also preferably set to 0.1 or more, and more preferably set to 0.2 or more.

Furthermore, in order to provide the first deformation portion 73 with a certain length along the first surface 43 b of the conductive brush 43 , the terminal portion 45 is formed in the same manner as described for the first deformation portion 72 . The length from the base of the side conductive brush 43 (see position F2 in FIG. 7B) to the position F21 (see FIG. 7A) where the conductive brush 43 contacts the commutator 33 is set to 1. Sometimes, a perpendicular line is drawn to the conductive brush 42 from a point closest to the base of the conductive brush 42 (see position F1 in FIG. 7B) on the second surface 60a of the second wall portion 60 (see position F1 in FIG. 7(a)), a perpendicular line from a point on the first surface 63a of the first wall portion 63 to a point on the conductive brush 43 that is 0.4 or more on the commutator 33 side from the position F22. It is preferable that the first surface 63a extend toward the commutator 33 to the extent that
At this time also, the conductive brushes 43 are not brought into contact with the commutator 33, and a perpendicular line is drawn to the conductive brushes 42 extending substantially straight.

By doing so, the first surface 63a corresponding to a range of 0.4 or more from the position F22 near the base of the conductive brush 43 on the terminal portion 45 side toward the commutator 33 side is provided. , the first deformation portion 73 can be provided over a range of 0.4 or more.

The relationship between the first deformation portion 73 and the second deformation portion 71 with respect to the conductive brush 43 is the same as the relationship between the first deformation portion 72 and the second deformation portion 70 with respect to the conductive brush 42 .
Therefore, both the first deformation portion 73 and the second deformation portion 71 work together to suppress the movement of the conductive brush 43 in the same manner as described for the first deformation portion 72 .
Therefore, the vibration of the conductive brush 43 can be suppressed to a higher degree, and noise can be greatly reduced.

On the other hand, as shown in FIG. 5, the bracket 40 is provided on the bracket main body 40a, and at least a portion of the first end portion 44b of the terminal portion 44 (see FIG. 4) (one end portion on the one end side of the first end portion 44b). 44ba).

Also, in the gap between the accommodation portion 80 and the one end portion 44ba of the first end portion 44b of the terminal portion 44 (see FIG. 4), the accommodation portion 80 and the first end portion 44b of the terminal portion 44 A cushioning member 80a made of gel or grease is provided in contact with both ends 44ba on the one end side, which reduces the vibration of the conductive brush 42 or makes it difficult for the vibration to be transmitted to the bracket 40, further increasing the noise. can be reduced.

Similarly, as shown in FIG. 5, the bracket 40 is provided on the bracket main body 40a, and at least a portion of the first end portion 45b of the terminal portion 45 (see FIG. 4) (one end on the one end side of the first end portion 45b). It has an accommodation portion 81 that accommodates the portion 45ba).

Also, in the gap between the accommodation portion 81 and one end portion 45ba of the first end portion 45b of the terminal portion 45 (see FIG. 4), the accommodation portion 81 and the first end portion 45b of the terminal portion 45 A cushioning member 81a made of gel or grease is provided in contact with both ends 45ba on the one end side, so that the vibration from the conductive brush 43 is hardly transmitted to the bracket 40, so that the noise can be further reduced. It's becoming

By the way, as already described, the motor 10 having the configuration described above can significantly reduce noise. It is also possible to suppress the occurrence of the phenomenon in which the brush 42 is momentarily separated from the commutator 33 .

Therefore, the occurrence of sparks between the commutator 33 and the conductive brushes 42 is suppressed, and wear of the conductive brushes 42 can be greatly reduced.

Similarly, the first deformation portion 73 and the second deformation portion 71 prevent the conductive brush 43 from momentarily separating from the commutator 33 under the influence of vibration or the like. 43 is suppressed, and wear of the conductive brush 42 can be greatly reduced.

Therefore, the lives of the conductive brushes 42 and 43 are lengthened, and the life of the motor 10 can be significantly lengthened.
Although not limited, the first deforming portion 72 and the second deforming portion 70 are preferably provided in a range of ⅓ or more of the length of the conductive brush 42 .
Similarly, the first deformation portion 73 and the second deformation portion 71 are preferably provided in a range of ⅓ or more of the length of the conductive brush 43 .

(Second embodiment)
Next, a motor 10 according to a second embodiment of the invention will be described with reference to FIG.
The basic configuration of the second embodiment is the same as that of the first embodiment, and only the configuration of the bracket 40 is different from the first embodiment.
Therefore, the bracket 40 of the second embodiment will be mainly described below, and descriptions of the same points as those of the first embodiment may be omitted.

As shown in FIG. 8, the bracket 40 of the second embodiment is formed by integrally forming the bracket main body 40a and the bearing plate 40b of the first embodiment.
And in 1st Embodiment, as shown in FIG.4 and FIG.5, the 1st wall parts 62 and 63 and the 2nd wall parts 60 and 61 were formed individually.

On the other hand, in the second embodiment, as shown in FIG. 8, one concave portion 85 is formed in the thick bracket 40, and the inner surface of the concave portion 85 (hereinafter referred to as the inner wall surface) is the first The surfaces 62a, 63a, the second surfaces 60a, 61a, the housing portions 80, 81, etc. are integrally constructed.

In this case, the portions forming the first surfaces 62a, 63a and the second surfaces 60a, 61a of the recess 85 are the first walls 62, 63 and the second walls 60, 61 in the first embodiment.

In the second embodiment, the first surface 62a formed by part of the inner wall surface of the concave portion 85 of the bracket 40 is located on the commutator 33 side (the center of the bracket 40) with respect to the first surface 42b of the conductive brush 42. side), the distance from the first surface 42b of the conductive brush 42 increases.

Thus, even in the first surface 62a formed as an inclined surface whose distance from the first surface 42b of the conductive brush 42 is large, the perpendicular line from the first surface 62a to the first surface 42b of the conductive brush 42 is preferably set to the second distance described in the first embodiment.
Moreover, it is preferable that the state in which the first surface 62a extends toward the commutator 33 is the same as that described in the first embodiment.

Similarly, with respect to the first surface 43b of the conductive brush 43, the first surface 63a formed by part of the inner wall surface of the concave portion 85 of the bracket 40 gradually increases toward the commutator 33 (center side of the bracket 40). , is formed as an inclined surface whose distance from the first surface 43b of the conductive brush 43 increases.

Also in this first surface 63a, it is preferable to set the distance between the first surface 43b of the conductive brush 43 and the first surface 63a to the second distance described in the first embodiment.
Moreover, it is preferable that the state in which the first surface 63a extends toward the commutator 33 is the same as that described in the first embodiment.

Although not shown in FIG. 8, gel or grease is injected between the first surface 62a formed by the inner wall surface of the recess 85 and the first surface 42b of the conductive brush 42, A first deforming portion is provided that is always in contact (always in close contact) with the first surface 62 a formed by the inner wall surface of the recess 85 and the first surface 42 b of the conductive brush 42 .

In addition, gel or grease is injected between the first surface 63a composed of the inner wall surface of the recess 85 and the first surface 43b of the conductive brush 43, and the first surface composed of the inner wall surface of the recess 85 is injected. 63a and the first surface 43b of the conductive brush 43 are provided with a first deformation portion that is always in contact (always in close contact).

Further, gel or grease is injected between the second surface 60a formed by the inner wall surface of the recess 85 and the second surface 42a of the conductive brush 42, and the second surface formed by the inner wall surface of the recess 85 is injected. A second deformable portion is provided that always contacts (always adheres to) the second surface 42a of the conductive brush 42 and the second surface 42a of the conductive brush 42 .

In addition, gel, grease, or the like is injected between the second surface 61a formed by the inner wall surface of the recess 85 and the second surface 43a of the conductive brush 43, and the second surface 61a formed by the inner wall surface of the recess 85 is injected. The surface 61a and the second surface 43a of the conductive brush 43 are provided with a second deformation portion that is always in contact (always in close contact).

Furthermore, in addition, gel or grease is also injected into the housing portions 80 and 81 .
It should be noted that the above-described gel or grease injection work does not need to be performed individually. Just inject grease.
Similarly, gel or grease may be injected at once into the portions forming the first deforming portion, the housing portion 81 and the second deforming portion provided for the conductive brush 43 .
The bracket 40 of the second embodiment configured in this manner can also exhibit advantages similar to those of the first embodiment.

Also in the second embodiment, as shown in FIG. 8, the second surface 42a of the conductive brush 42 is provided with a rubber member 70a.
However, the rubber member 70a may be omitted, or may be provided on the first surface 42b side of the conductive brush 42, or may be provided on both the first surface 42b and the second surface 42a of the conductive brush 42. You may make it provide.

Similarly, a rubber member 71a is provided on the second surface 43a of the conductive brush 43, but the rubber member 71a may be omitted, and the rubber member 71a may be provided on the first surface 43b side of the conductive brush 43. Alternatively, it may be provided on both the first surface 43 b and the second surface 43 a of the conductive brush 43 .

The constant contact (constant close contact) in the second embodiment should also be understood to have the same meaning as explained in the first embodiment.
In other words, it means that they are always in contact (close contact) as long as no peculiar situation such as peeling occurs in the process of using the motor 10, and it means that they continue to be in contact (close contact) forever. Note that you shouldn't.

(Rotating device)
Next, as an example using the motor 10 having the configuration described above, a rotation device 50 for controlling rotation of a louver 104 (see FIG. 12) used in an air-conditioning system 100 (see FIG. 12) of an automobile or the like will be described below. ,explain.

9 is a perspective view showing a rotating device 50 using the motor 10, FIG. 10 is a perspective view of the rotating device 50 with the first housing 53 removed, and FIG. 11 is a second housing 56 of the rotating device 50. is a perspective view of the second surface portion 54 side of the.

As shown in FIG. 9, the rotating device 50 includes a first housing 53 having a first surface portion 51 as a surface portion and a first side wall portion 52 provided on the outer peripheral portion of the first surface portion 51, and a second housing 53 as a surface portion. A housing 57 is provided by combining the surface portion 54 and a second housing 56 having a second side wall portion 55 provided on the outer peripheral portion of the second surface portion 54 .

The housing 57 is made of a resin material such as polypropylene, polybutylene terephthalate, ABS, or the like.

Attachment portions A, B, C, and D for attaching the rotating device 50 to the air conditioning system 100 (see FIG. 12) are formed integrally with the first side wall portion 52 on the outer periphery of the first housing 53. there is

On the other hand, as shown in FIG. 10, the rotation device 50 includes the motor 10 having the configuration described in the first and second embodiments as various parts accommodated in a housing 57 (see FIG. 9). , a plurality of gears 90 including an output gear 95 for mechanically outputting the rotation of the rotating shaft 31 (see FIG. 1) of the motor 10 to the outside, and a sensor 97 for detecting the rotation angle of the output gear 95. .

The second surface portion 54 of the second housing 56 is provided with an opening 54a (see FIG. 11) in a portion corresponding to the center side of the output gear 95. As shown in FIG. The engaging portion 95a of the output gear 95 can be accessed from the outside through the opening 54a provided in the second surface portion 54 of the body 56. As shown in FIG.

Then, for example, the drive shaft (see rotary shaft 104a in FIG. 12) of the louver 104 (see FIG. 12) of the air conditioning system 100 provided in a vehicle such as an automobile (not shown) is engaged with the engaging portion 95a of the output gear 95. Rotation control of the louver 104 is performed by controlling the rotation of the motor 10 .

The rotation control of the motor 10 is performed based on the relationship between the rotation of the output gear 95 and the driving of the louver 104 (see FIG. 12).
Therefore, as shown in FIG. 10, a sensor 97 arranged on the output gear 95 outputs a signal corresponding to the rotation of the output gear 95, and the rotation of the motor 10 is controlled based on the output signal. It's like

In this embodiment, as shown in FIG. 10, the rotating shaft 31 (see FIG. 1) of the motor 10 is rotated through a plurality of transmission gears 94 (a worm gear 91, a first two-stage gear 92, and a second two-stage gear 93). ) is transmitted to the output gear 95 .

Specifically, the transmission gear 94 includes a worm gear 91 fixed to the rotating shaft 31 (see FIG. 1) of the motor 10, and a first gear having a large diameter gear 92a and a small diameter gear 92b connected to the worm gear 91. A two-step gear 92 and a second two-step gear 93 having a large diameter gear 93a connected to the small diameter gear 92b of the first two-step gear 92 and a small diameter gear connected to the output gear 95. have.

By doing so, the rotation of the rotary shaft 31 (see FIG. 1) of the motor 10 is transmitted to the output gear 95 at a predetermined gear ratio by utilizing a small space.
However, it is not always necessary to transmit the rotation to the output gear 95 with three transmission gears, and the first two-stage gear 92 and the second two-stage gear 93 may be omitted as necessary.

(vehicles with air conditioning systems)
The rotating device 50 as described above is used, for example, in the air conditioning system 100 of a vehicle such as an automobile, and the case of being used in the air conditioning system 100 of the vehicle will be briefly described below.

FIG. 12 is a schematic diagram for explaining an air conditioning system 100 that includes the rotating device 50 of the embodiment, and FIG. 13 is a diagram showing a vehicle that includes the air conditioning system 100 of FIG.

As shown in FIG. 12, the air conditioning system 100 includes a blower fan 101, an evaporator 102, a heater 103, and louvers 104 arranged in the front portion FR of the vehicle (see FIG. 13).

More specifically, a blower fan 101 is arranged on the suction port 100a side of the air conditioning system 100, and an evaporator 102 for cooling the air sent out from the blower fan 101 is arranged downstream in the air flow direction.

Furthermore, a heater 103 is arranged downstream of the evaporator 102 in the direction of air flow, and a louver 104 is arranged between the evaporator 102 and the heater 103, and the louver 104 allows air to flow from the evaporator 102 side to the heater 103 side. By controlling the amount of air supplied, the temperature of the air is adjusted to an appropriate temperature.

Then, the air adjusted to an appropriate temperature is further supplied to the vehicle interior from an air outlet provided in the vehicle interior via a duct or the like. A rotating shaft 104a of the louver 104 is connected to an engaging portion 95a (see FIG. 11) of the output gear 95 of the rotating device 50 described above.
Therefore, as described above, the rotating device 50 controls the rotation of the louver 104 (see the double-headed arrow in FIG. 12) to bring it into a predetermined state.

The above is just an example of the rotating device 50 in the air conditioning system 100. For example, the air conditioning system 100 circulates air in the vehicle interior and takes air from outside the vehicle into the vehicle interior. In some cases, the flow path (duct path) is switched, and a louver is also provided at the switching portion.
For this reason, the rotating device 50 can also be suitably used to control the louver provided in this switching portion.

Although the present invention has been described above based on the embodiments, it goes without saying that the present invention is not limited to the embodiments, and that various modifications are possible without departing from the gist of the present invention.
Therefore, various modifications without departing from the gist of the invention are also included in the technical scope of the present invention, which is obvious to those skilled in the art from the description of the claims .

Reference Signs List 10 Motor 20 Frame 21 Bottom 21a Hole 21b Bearing 22 Side wall 22a Opening 30 Armature 31 Rotating shaft 31a Other end 32 Core 32a... Pole 33... Commutator 33a... Sheet metal 40... Bracket 40a... Bracket body 40ab... Bottom part 40b... Bearing plate 40ba... Bearing part 41... Bearing 42... Conductive brush 42a... Second surface 42b First surface 43 Conductive brush 43a Second surface 43b First surface 44 Terminal portion 44a Terminal 44b First end 44ba One end 45 Terminal portion 45a Terminal 45b First end 45ba One end 46 Groove 47 Groove 48 Opening 49 Opening 50 Rotating device 51 First surface 52 1st side wall 53 1st housing 54 2nd surface 54a opening 55 2nd side wall 56 2nd housing 57 housing 60 2nd wall 60a...Second surface 61...Second wall 61a...Second surface 62...First wall 62a...First surface 63...First wall 63a...First surface 70...Second deformation Part 70a...Rubber member 70b...Buffer member 71...Second deformation part 71a...Rubber member 71b...Buffer member 72...First deformation part 73...First deformation part 80...Accommodating part 80a... Buffer member 81 Accommodating portion 81a Buffer member 85 Recess 90 Gear 94 Transmission gear 91 Worm gear 92 First two-stage gear 92a Large diameter gear 92b Small diameter Gear 93 Second stage gear 93a Large diameter gear 95 Output gear 95a Engaging portion 97 Sensor 100 Air conditioning system 101 Blower fan 102 Evaporator 103 Heater 104... Louver, 104a... Rotating shaft, A, B, C, D... Mounting part, FR... Front part

Claims (6)

a terminal part;
a commutator;
a conductive brush having a first surface and a second surface extending radially of the commutator;
a bracket having a wall portion having a first surface facing the first surface of the conductive brush;
a deformation portion that contacts the first surface of the conductive brush and the first surface of the wall;
the conductive brushes are in contact with the commutator;
The deformation portion extends in a direction in which the first surface of the conductive brush extends,
the first surface of the wall portion has a portion that contacts the deformable portion and extends in the direction in which the first surface of the conductive brush extends;
the first surface of the conductive brush has a portion in contact with the deformation portion extending in the direction in which the first surface of the conductive brush extends;
the portion of the first surface of the wall portion is inclined with respect to the portion of the first surface of the conductive brush;
The length of the deformed portion between the portion of the first surface of the conductive brush on the commutator side and the portion of the first surface of the wall portion is the length of the conductive brush on the terminal portion side. less than a length of said deformed portion between said portion of said first surface and said portion of said wall first surface;
The length of the deformed portion in the direction in which the first surface of the conductive brush extends is equal to the portion of the first surface of the conductive brush on the commutator side and the portion of the first surface of the wall portion. longer than the distance of
The motor, wherein the deformation portion extends long in a radial direction of the commutator. 2. The motor according to claim 1, wherein the length of said deformation portion in the direction in which said first surface of said conductive brush extends is 0.4 or more relative to the length of said conductive brush . 3. The motor according to claim 1, wherein said deformable portion contains gel or grease. an amateur having the commutator;
a frame part;
a magnet provided on the frame,
The frame portion has a bottom portion provided with a hole for leading the rotation shaft of the amateur to the outside,
a side wall covering the outer periphery of the armature having an opening on the side opposite to the bottom,
The magnet is provided on an inner wall surface of the side wall portion of the frame portion facing the armature,
4. The motor according to any one of claims 1 to 3, wherein the bracket is attached to the opening of the frame portion. a motor according to any one of claims 1 to 4;
a plurality of gears including an output gear that outputs the rotation of the motor to the outside;
A rotating device comprising: a housing that accommodates the plurality of gears and the motor. a rotating device according to claim 5;
louvers controlled by said rotating device.

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