JP2016023657A - Electromagnetic clutch, and motor with speed reducer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a motor having an electromagnetic clutch mechanism and a speed reducer, which can be small-sized while reducing the parts number and facilitating the assembly work.SOLUTION: A yoke salient 57 is formed in the peripheral edge of the opening 51b of a clutch yoke 51; a movable first salient 63 and a movable second salient 64 are formed in a movable plate 61; a stationary salient 68 is formed in a stationary plate 65 so that the relative rotations of the movable plate 61 with respect to the clutch yoke 51 are regulated by the yoke salient 57 and the movable first salient 63; and the relative rotations of the stationary plate 65 relative to the movable plate 61 are regulated by the movable second salient 64 and the stationary salient 68.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an electromagnetic clutch mechanism and a motor with a reduction gear.

  As a motor with a reduction gear, for example, there is one used for a power window device of an automobile. In this type of motor with a speed reducer, a worm speed reducer and an electric motor are connected. The worm speed reducer includes a worm coupled to the rotation shaft of the electric motor and a worm wheel meshed with the worm. The window glass can be opened and closed by connecting the worm wheel to the output shaft of the power window device.

By the way, there is a possibility that the window glass may be opened due to the rotational force of the window glass due to the external force such as the weight of the window glass or the vibration when the vehicle travels. Therefore, in order to prevent the rotating shaft of the electric motor from rotating due to the rotational force due to the external force, the electric motor and the worm speed reducer are divided and a clutch mechanism is provided between the electric motor and the worm speed reducer. The technology to provide is proposed.
As the clutch mechanism, for example, a driving rotator provided at one end of the rotating shaft of the electric motor and rotating together with the rotating shaft, a driven rotating body that engages with the driving rotating body and is connected to the output shaft, and these driving rotations Some include an outer ring that accommodates the body and the driven rotator, and a plurality of cylindrical rollers provided between the driven rotator and the outer ring (for example, see Patent Document 1).

In this type of clutch mechanism, when the drive rotator is rotated by the electric motor, the rollers rotate around the axis of the drive rotator while being maintained in a free state. For this reason, the driven rotator and the drive rotator rotate together, and the window glass is opened and closed.
On the other hand, when the driven rotator is rotated by external force such as the weight of the window glass or vibration during vehicle running, the roller is sandwiched between the driven rotator and the outer ring, thereby preventing the rotation of the driven rotator. Is done. For this reason, it is possible to prevent the window glass from being opened due to its own weight, vibration during vehicle travel, or the like.

Thus, a so-called mechanical clutch mechanism that uses a roller or the like to form a clutch mechanism has a large number of parts, and the assembly work becomes complicated. For this reason, it is conceivable to employ an electromagnetic clutch mechanism in place of the mechanical clutch mechanism.
Generally, an electromagnetic clutch mechanism mainly includes an exciting coil, a movable portion that can be moved by excitation and demagnetization of the coil, and a fixed portion. Then, the rotation of the driven rotating body can be prevented by using the frictional resistance generated by the movable part and the fixed part engaging with each other or overlapping each other.

JP 2003-143804 A

  By the way, when an electromagnetic clutch mechanism is employed, it is necessary to generate a sufficient magnetic attraction force when exciting the coil in order to ensure reliable movement of the movable portion. For this reason, the whole clutch mechanism will enlarge, As a result, the subject that the motor with a reduction gear will enlarge.

  Accordingly, the present invention has been made in view of the circumstances described above, and provides an electromagnetic clutch mechanism and a motor with a reduction gear that can be reduced in size while reducing the number of parts and facilitating assembly work. It is.

  In order to solve the above problems, an electromagnetic clutch mechanism according to the present invention includes a cylindrical bobbin that can be inserted through a rotating shaft, a coil that is wound around an outer peripheral surface of the bobbin, and the coil that is mounted on the rotating shaft. A cylindrical yoke is formed so as to cover from the outside in the radial direction, and a clutch yoke through which the rotary shaft can be inserted and an insertion hole through which the rotary shaft can be inserted are formed inside the radial direction. A movable plate that is disposed on the opening side and is attracted by a magnetic flux formed on the clutch yoke; an elastic member that biases the movable plate away from the opening of the clutch yoke; and the movable plate A fixed plate that is disposed on a surface opposite to the clutch yoke and that rotates integrally with the rotating shaft, and includes a peripheral edge of the opening of the clutch yoke and the movable plate. First engaging means for restricting the rotation of the clutch yoke and the movable plate is provided on the movable plate, the position of the movable plate avoiding the first engaging means, and the movable plate at the fixed plate. And a second engagement means for restricting the rotation of the fixed plate.

  By comprising in this way, a movable plate can be efficiently attracted | sucked using the magnetic flux formed in a clutch yoke. For this reason, it is not necessary to increase the size of the bobbin or the yoke in order to ensure the magnetic attractive force with respect to the movable plate, and the electromagnetic clutch mechanism can be reduced in size.

  In the electromagnetic clutch mechanism according to the present invention, the first engagement means includes a yoke convex portion extending along an axial direction of the rotation shaft from an outer peripheral edge of the opening of the clutch yoke, and an outer side of the movable plate. A movable first convex portion that extends from the periphery toward the outer side in the radial direction and is engageable with the yoke convex portion in the rotational direction, and the second engagement means is the movable plate of the movable plate. A movable second convex portion that is formed radially inward of the first convex portion and protrudes toward the fixed plate, and is formed to extend radially outward from an outer peripheral edge of the fixed plate, and the rotational direction And a fixed convex portion engageable with the movable second convex portion.

  With this configuration, leakage of magnetic flux formed to magnetically attract the movable plate around the opening of the clutch yoke can be minimized. Therefore, the movable plate can be efficiently magnetically attracted by the clutch yoke while the electromagnetic clutch mechanism has a simple structure.

  In the electromagnetic clutch mechanism according to the present invention, the engaging surface of each of the movable second convex portion and the fixed convex portion is applied with a force in the rotational direction on the movable second convex portion and the fixed convex portion, respectively. In this case, it is formed so as to be inclined so that forces in directions away from each other act.

  By comprising in this way, a movable plate can be efficiently attracted | sucked using the magnetic flux formed in a clutch yoke. For this reason, an electromagnetic clutch mechanism can be reduced in size more reliably.

  In the electromagnetic clutch mechanism according to the present invention, a lead-out hole for pulling out the coil is formed on the outer peripheral wall of the clutch yoke at a position overlapping the portion where the yoke convex portion is formed in the axial direction. It is characterized by that.

  Here, the electromagnetic clutch mechanism needs to draw the coil to the outside in order to energize. For this reason, by comprising as mentioned above, a coil can be pulled outside, without inhibiting the magnetic path of the magnetic flux utilized in order to attract a movable plate among magnetic flux formed in a clutch yoke. . Therefore, a small and high-performance electromagnetic clutch mechanism can be provided.

  In the electromagnetic clutch mechanism according to the present invention, the clutch yoke has an inner wall yoke extending from the bottom toward the opening through the bobbin and the rotating shaft. .

  By comprising in this way, when exciting a coil, the magnetic flux leak to a rotating shaft can be suppressed. For this reason, it becomes possible to efficiently form a magnetic flux in the clutch yoke.

  In the electromagnetic clutch mechanism according to the present invention, the elastic member is a coil spring, the inner wall yoke has a reduced diameter portion disposed on the opening side of the clutch yoke, and a step on the bottom side of the reduced diameter portion. The elastic member is formed so as to be in contact with the stepped portion on the outer peripheral side of the reduced diameter portion. It is characterized by that.

By comprising in this way, since the coil spring which is an elastic member can be accommodated using a level | step-difference part, the free length of a coil spring can be set short.
Further, by forming the enlarged diameter portion in the inner wall yoke, the clutch yoke (inner wall yoke) at a location corresponding to the enlarged diameter portion can be separated from the rotation shaft. For this reason, magnetic flux leakage from the clutch yoke to the rotating shaft can be reliably suppressed.

  A motor with a reduction gear according to the present invention includes the electromagnetic clutch mechanism described above, an electric motor provided integrally with the rotary shaft on one end side of the rotary shaft, and the other end side of the rotary shaft. A reduction mechanism provided integrally with the rotating shaft, and the electric motor has a power supply terminal accommodating portion in which a power supply terminal for supplying power to the electric motor is accommodated. The electromagnetic clutch mechanism is incorporated in the power supply terminal accommodating portion.

By comprising in this way, the motor with a reduction gear which can reduce in size can be provided, reducing a number of parts and making an assembly operation easy.
In addition, since the power feeding terminal of the electric motor and the clutch mechanism can be arranged close to each other, it is possible to collectively perform the lead wires for connecting the power feeding terminal and the external power source and the coil of the clutch mechanism. For this reason, electrical connection between the external power source, the power feeding terminal, and the coil of the clutch mechanism can be easily performed.
Furthermore, since the electric motor and the speed reduction mechanism are integrated with one rotating shaft, the number of parts can be reduced as compared with the case where the electric motor and the speed reduction mechanism are completely divided as in the prior art. Furthermore, the assembly work of the motor with a reduction gear can be facilitated by reducing the number of parts.

According to the present invention, the movable plate can be efficiently attracted using the magnetic flux formed in the clutch yoke. For this reason, it is not necessary to increase the size of the bobbin or the yoke in order to ensure the magnetic attractive force with respect to the movable plate, and the electromagnetic clutch mechanism can be reduced in size.
Further, by incorporating such an electromagnetic clutch mechanism, it is possible to provide a motor with a reduction gear that can be reduced in size while reducing the number of parts and facilitating assembly work.

It is sectional drawing which shows the structure of the motor with a reduction gear in 1st Embodiment of this invention. It is a cross-sectional enlarged view of the electromagnetic clutch mechanism in 1st Embodiment of this invention. It is a disassembled perspective view of the electromagnetic clutch mechanism in 1st Embodiment of this invention. It is a perspective view of the electromagnetic clutch mechanism in 1st Embodiment of this invention. It is the A section enlarged view of FIG. It is a longitudinal cross-sectional view which shows the energization ON state of the electromagnetic clutch mechanism in 1st Embodiment of this invention. It is a perspective view of the energization-on state of the electromagnetic clutch mechanism in the first embodiment of the present invention. It is sectional drawing which shows the structure of the motor with a reduction gear in the modification of 1st Embodiment of this invention. It is a perspective view of the electromagnetic clutch mechanism in 2nd Embodiment of this invention. It is a disassembled perspective view of the electromagnetic clutch mechanism in 2nd Embodiment of this invention. It is sectional drawing which shows the structure of the electromagnetic clutch mechanism in 2nd Embodiment of this invention. It is sectional drawing which shows the electricity supply ON state of the electromagnetic clutch mechanism in 2nd Embodiment of this invention. It is a perspective view of the electromagnetic clutch mechanism in 3rd Embodiment of this invention. It is a disassembled perspective view of the electromagnetic clutch mechanism in 3rd Embodiment of this invention.

  Next, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
(Motor with reduction gear)
FIG. 1 is a cross-sectional view showing a configuration of a motor 1 with a speed reducer.
As shown in the figure, a motor 1 with a speed reducer serves as a drive source for a power window device mounted on a vehicle, for example, and includes a DC motor 2 and a worm connected to a rotating shaft 3 of the DC motor 2. A speed reduction mechanism 4 and an electromagnetic clutch mechanism 50 provided between the DC motor 2 and the worm speed reduction mechanism 4 on the rotary shaft 3 are provided.

(DC motor)
The DC motor 2 has a configuration in which an armature 6 is rotatably arranged in a bottomed cylindrical yoke 5. Four tile-shaped permanent magnets 7 divided in the circumferential direction are fixed to the inner peripheral surface 5a of the yoke 5 at equal intervals. These permanent magnets 7 are formed using rare earth magnets such as neodymium sintered magnets and ferrite magnets.
The armature 6 includes an armature core 8 that is externally fitted and fixed to the rotary shaft 3, an armature coil 9 that is wound around the armature core 8, and an external fitting that is fixedly fitted to the rotary shaft 3. And a commutator 10 arranged on the left side in FIG.

  The armature core 8 is formed by laminating a plurality of electromagnetic steel plates in the axial direction of the rotating shaft 3 (hereinafter simply referred to as the axial direction) or by pressure-molding soft magnetic powder. A plurality of T-shaped teeth (not shown in detail) are radially formed on the outer peripheral portion of the armature core 8 at regular intervals along the circumferential direction. Slots (not shown) are formed between teeth adjacent in the circumferential direction.

  Then, enamel-coated windings (coils, not shown in detail) are inserted into the slots, and these windings are wound from above an insulator (not shown) attached to the armature core 8. As a result, a plurality of armature coils 9 are formed on the armature core 8. The winding 14 is connected to a plurality of segments 15 arranged on the rotational sliding surface (outer peripheral surface) of the commutator 10.

  One end of the rotating shaft 3 opposite to the worm reduction mechanism 4 (the right end in FIG. 1) is rotatably supported by a bearing 18 built in a bearing housing 19 that is formed to protrude from the yoke 5. . On the other hand, the inner diameter of the opening 5b of the yoke 5 is slightly larger than the inner peripheral surface 5a of the yoke 5, and a part of the brush holder 20 is accommodated therein.

  The brush holder 20 is formed in a stepped bottomed cylindrical shape with resin. That is, the brush holder 20 is formed through the small diameter cylindrical portion 20b formed on the bottom 20a side of the brush holder 20, the small diameter cylindrical portion 20b and the stepped portion 20c, and is formed with a diameter larger than that of the small diameter cylindrical portion 20b. The large-diameter cylindrical portion 20d is integrally formed, and an opening 20e is formed on the large-diameter cylindrical portion 20d side. And it arrange | positions in the state which orient | assigned the opening part 20e to the yoke 5 side.

  In addition, an insertion hole 41 through which the rotary shaft 3 can be inserted is formed in the bottom portion 20a of the brush holder 20, and a bearing housing 42 is integrally formed on the outer surface opposite to the large-diameter cylindrical portion 20d. . The bearing housing 42 is provided with a bearing 32 for rotatably supporting the approximate center in the axial direction of the rotary shaft 3.

The electromagnetic clutch mechanism 50 is housed and fixed in the small diameter cylindrical portion 20b of the brush holder 20. Details of the electromagnetic clutch mechanism 50 will be described later.
Further, the commutator 10 is accommodated in the large diameter cylindrical portion 20 d of the brush holder 20. A plurality of brushes 21 are arranged on the large diameter cylindrical portion 20 d of the brush holder 20. Each brush 21 is urged toward the commutator 10 side (inside the radial direction of the rotating shaft 3 (hereinafter simply referred to as the radial direction)) by a spring (not shown). Thereby, the tip of each brush 21 is in sliding contact with each segment 15 of the commutator 10. Further, the brush 21 is electrically connected to a bus bar terminal 34 of a connector unit 31 to be described later via a pigtail (not shown).

  Further, an outer flange portion 17 is integrally formed on the periphery of the opening 5 b of the yoke 5. A bolt hole 24 for fastening the DC motor 2 to the gear housing 23 of the worm reduction mechanism 4 is formed in the outer flange portion 17. The bolt 39 is inserted into the bolt hole 24 and screwed into the female screw portion 38 formed in the gear housing 23 of the worm reduction mechanism 4, whereby the DC motor 2 is fastened and fixed to the gear housing 23.

(Worm reduction mechanism)
The gear housing 23 constituting the worm speed reduction mechanism 4 has an accommodation recess 29 in which a part of the small-diameter cylindrical portion 20b and the large-diameter cylindrical portion 20d of the brush holder 20 is accommodated on the side surface 23a to which the outer flange portion 17 of the yoke 5 is attached. Is formed.
In the gear housing 23, a connector unit storage portion 30 that communicates with the storage recess 29 is formed on the opposite side of the storage recess 29 from the DC motor 2. A connector unit 31 for supplying power from an external power source to the brush 21 and the electromagnetic clutch mechanism 50 is stored in the connector unit storage portion 30. The connector unit 31 includes a connector 33 that can be connected to an external power source, and a plurality of bus bar terminals 34 that are partially disposed in the connector 33.

  The worm speed reduction mechanism 4 includes a worm 25 and a worm wheel 26 meshed with the worm 25. The worm 25 is externally fitted and fixed to the other end opposite to the DC motor 2 from the axial center of the rotating shaft 3. A worm accommodating portion 27 for accommodating the worm 25 is formed at a position corresponding to the worm 25 of the gear housing 23. The worm housing portion 27 is provided with a bearing 35 for rotatably supporting the other end of the rotating shaft 3 at a position corresponding to the other end of the rotating shaft 3. The worm storage portion 27 and the storage recess portion 29 formed in this way communicate with each other.

  Further, a worm wheel housing portion 28 is formed at a position corresponding to the worm wheel 26 of the gear housing 23. The worm wheel 26 is provided with an output shaft (not shown) along a direction orthogonal to the rotating shaft 3 of the DC motor 2. The power window device is driven by the rotation of the output shaft.

(Electromagnetic clutch mechanism)
Next, the electromagnetic clutch mechanism 50 will be described in detail with reference to FIGS.
2 is an enlarged cross-sectional view of the electromagnetic clutch mechanism 50, FIG. 3 is an exploded perspective view of the electromagnetic clutch mechanism 50, FIG. 4 is a perspective view of the electromagnetic clutch mechanism 50, and FIG. is there.
As shown in FIGS. 2 to 5, the electromagnetic clutch mechanism 50 has a bottomed cylindrical clutch yoke 51. The outer peripheral surface of the clutch yoke 51 is fitted and fixed to the small diameter cylindrical portion 20b of the brush holder 20 by, for example, press fitting.

The bottom 51a of the clutch yoke 51 is integrally provided with an inner wall cylindrical yoke 52 that is formed so as to be folded back toward the opening 51b at a substantially radial center. The inner wall cylindrical yoke 52 is formed so that the tip thereof is located substantially on the same plane as the tip of the peripheral wall 51 c of the clutch yoke 51.
The inner wall cylindrical yoke 52 has an inner diameter that is slightly larger than the shaft diameter of the rotary shaft 3 so that the rotary shaft 3 can be inserted into the inner wall cylindrical yoke 52. Further, when the rotary shaft 3 is inserted into the inner wall cylindrical yoke 52, a clearance K <b> 1 is formed between the rotary shaft 3 and the inner wall cylindrical yoke 52.

  Further, a pull-out hole 56 is formed in the peripheral wall 51c of the clutch yoke 51 from the substantially axial center to the bottom 51a. The lead hole 56 is for pulling out an excitation coil 55 described later to the outside of the clutch yoke 51. In addition, three yoke convex portions 57 projecting from the peripheral wall 51c along the axial direction are formed in the opening 51b of the clutch yoke 51. The three yoke convex portions 57 are arranged at equal intervals in the circumferential direction, and one of the three yoke convex portions 57 is arranged at a position overlapping the drawing hole 56 formed in the peripheral wall 51c in the axial direction. ing.

  A cylindrical bobbin 54 is accommodated in the accommodating portion 53 formed between the peripheral wall 51 c of the clutch yoke 51 and the inner wall cylindrical yoke 52. The bobbin 54 is made of resin and includes a cylindrical portion 54a and outer flange portions 54b that are integrally formed at both ends of the cylindrical portion 54a in the axial direction.

  An exciting coil 55 is wound around a coil storage portion 54c formed in the cylindrical portion 54a and the outer flange portion 54b. A terminal portion of the exciting coil 55 is drawn to the outside of the clutch yoke 51 through a drawing hole 56 formed in the peripheral wall 51 c of the clutch yoke 51. A terminal portion of the exciting coil 55 drawn out of the clutch yoke 51 is routed in the brush holder 20 and electrically connected to the bus bar terminal 34 of the connector unit 31. As a result, external power is supplied to the exciting coil 55 via the connector unit 31.

On the inner peripheral surface of the cylindrical portion 54a, a diameter-increased portion 58 that is enlarged through a stepped portion 58a is formed from the substantially center in the axial direction to the end portion on the opening 51b side of the clutch yoke 51. . A spring accommodating portion 59 is formed by the enlarged diameter portion 58 and the inner wall cylindrical yoke 52. A coil spring 60 formed of a nonmagnetic material is stored in the spring storage portion 59.
The free length of the coil spring 60 is set to be longer than about half of the axial length of the bobbin 54. For this reason, the coil spring 60 is housed in the spring housing portion 59 and has one end (lower end in FIG. 2) in contact with the step portion 58a and the other end (upper end in FIG. 2) is axially outward from the bobbin 54. Protruding state.

  A substantially disc-shaped movable plate 61 formed of a metal plate is disposed at the other end of the coil spring 60. The outer diameter of the movable plate 61 is set to be substantially the same as the outer diameter of the peripheral wall 51 c of the clutch yoke 51. Further, an insertion hole 61a through which the rotation shaft 3 can be inserted through the clearance K2 is formed at the center in the radial direction of the movable plate 61.

  Further, on the outer peripheral portion of the movable plate 61, three movable concave portions 62 for receiving the yoke convex portions 57 are formed at positions corresponding to the yoke convex portions 57 formed on the clutch yoke 51. The circumferential width of the movable recess 62 is set to be slightly larger than the circumferential width of the yoke protrusion 57 of the clutch yoke 51. And by forming the movable recessed part 62, the outer peripheral part of the movable plate 61 will be in the state provided with the three movable 1st convex parts 63 extended and formed toward the radial direction outer side.

In addition, on the surface 61 b of the movable plate 61 opposite to the bobbin 54, movable second convex portions 64 are formed so as to protrude inward in the radial direction of the movable concave portion 62. In other words, the movable second convex portions 64 are formed so as to protrude from the surface of the movable plate 61 opposite to the bobbin 54 and at positions avoiding the three movable first convex portions 63.
The movable second convex portion 64 extends in a substantially arc shape along the circumferential direction of the movable plate 61 when viewed from the axial direction. As shown in detail in FIG. 5, the movable second convex portion 64 has an isosceles trapezoidal shape so as to taper toward the tip when viewed from the radial direction. That is, the side surfaces 64a at both ends in the circumferential direction of the movable second convex portion 64 are formed so as to be inclined so that an angle between the movable plate 61 and the one surface 61b is θ.

Here, as shown in FIG. 2, in the movable plate 61, the axial direction from the tip of the movable second convex portion 64 to the surface opposite to the surface on which the movable second convex portion 64 is formed. The height H1 and the protruding height H2 of the yoke convex portion 57 that protrudes from the peripheral wall 51c of the clutch yoke 51 are as follows:
H1 <H2 (1)
It is set to satisfy.

As shown in FIGS. 2 and 3, a fixed plate 65 formed in a substantially disc shape by a nonmagnetic material is disposed on the opposite side of the movable plate 61 from the bobbin 54. The outer diameter of the fixed plate 65 is set so that the outer peripheral edge of the fixed plate 65 and the radially outer side surface of the movable second convex portion 64 are positioned on substantially the same circle.
Further, a boss portion 67 protruding toward the opposite side of the movable plate 61 is formed at the center of the fixed plate 65 in the radial direction, and the boss portion 67 penetrates in the thickness direction of the fixed plate 65. A hole 65a is formed. The rotary shaft 3 is press-fitted into the through hole 65a. That is, the rotating shaft 3 and the fixed plate 65 rotate together.

Further, in the fixed plate 65, the gap K3 between the fixed plate 65 and the peripheral wall 51c (inner wall cylindrical yoke 52) of the clutch yoke 51 protrudes from the yoke convex portion 57 formed so as to protrude from the peripheral wall 51c of the clutch yoke 51. It is fixed so as to be substantially the same as the height H2.
In this state where the fixed plate 65 is fixed, the coil spring 60 is slightly compressed by the movable plate 61 and the stepped portion 58 a of the bobbin 54. That is, the movable plate 61 is constantly biased toward the fixed plate 65 by the coil spring 60.

Further, on the outer peripheral portion of the fixed plate 65, three fixed concave portions 66 that receive the movable second convex portions 64 are formed at positions corresponding to the movable second convex portions 64 of the movable plate 61. The circumferential width of the fixed recess 66 is set to be slightly larger than the circumferential width of the movable second convex portion 64. Then, by forming the fixed concave portion 66, the outer peripheral portion of the fixed plate 65 is provided with three fixed convex portions 68 formed to extend outward in the radial direction.
Here, as shown in detail in FIG. 5, one surface 65 b of the fixed plate 65 so that the side surfaces 68 a at both ends in the circumferential direction of the fixed convex portion 68 correspond to the side surfaces 64 a at both ends in the circumferential direction of the movable second convex portion 64. Is formed so as to be inclined at θ. That is, the fixed convex portion 68 is formed in an isosceles trapezoidal shape so as to taper toward the movable plate 61 when viewed from the radial direction.

(Operation of electromagnetic clutch mechanism)
Next, the operation of the electromagnetic clutch mechanism 50 will be described with reference to FIGS.
First, based on FIGS. 2 and 4, the electromagnetic clutch mechanism 50 in a state when the energization of the excitation coil 55 of the electromagnetic clutch mechanism 50 is off (hereinafter simply referred to as an energization off state; the same applies to the following embodiments). Will be described.
As shown in FIGS. 2 and 4, when the electromagnetic clutch mechanism 50 is turned off, the movable plate 61 is pressed toward the fixed plate 65 by the coil spring 60, so that one surface 61 b of the movable plate 61 faces the one surface 61 b. The other surface 65c of the fixed plate 65 is in contact with and overlapped.

  Here, in the fixed plate 65, a gap K3 between the fixed plate 65 and the peripheral wall 51c (inner wall cylindrical yoke 52) of the clutch yoke 51 is formed so as to protrude from the peripheral wall 51c of the clutch yoke 51. It is fixed so as to be substantially the same as the protruding height H2. Therefore, even when the fixed plate 65 and the movable plate 61 are overlapped, the yoke convex portion 57 of the clutch yoke 51 exists on the same plane as the movable plate 61.

In this state, when the rotating shaft 3 tries to rotate, the fixed plate 65 integrated with the rotating shaft 3 rotates. Then, the side surface 68a of the fixed convex portion 68 of the fixed plate 65 and the side surface 64a of the movable second convex portion 64 of the movable plate 61 are brought into contact with each other and engaged. Thereby, the rotational force of the fixed plate 65 is applied to the movable plate 61, and the movable plate 61 tries to rotate integrally with the fixed plate 65.
When the movable plate 61 tries to rotate, the movable first convex portion 63 of the movable plate 61 and the yoke convex portion 57 of the clutch yoke 51 are brought into contact with and engaged with each other in the rotational direction. For this reason, the rotation of the movable plate 61 is blocked, and further, the rotation of the fixed plate 65 is blocked. Therefore, rotation of the rotating shaft 3 is prevented.

Next, based on FIGS. 6 and 7, the electromagnetic clutch mechanism in a state where energization to the excitation coil 55 of the electromagnetic clutch mechanism 50 is on (hereinafter simply referred to as energization on state; the same applies to the following embodiments). The operation of 50 will be described.
6 is a longitudinal sectional view showing the energization-on state of the electromagnetic clutch mechanism 50, and FIG. 7 is a perspective view of the electromagnetic clutch mechanism 50 in the energization-on state.
As shown in FIGS. 6 and 7, when the excitation coil 55 of the electromagnetic clutch mechanism 50 is energized, the excitation coil 55 is excited and a magnetic flux is formed in the clutch yoke 51. Due to this magnetic flux, a magnetic attractive force toward the clutch yoke 51 acts on the movable plate 61, and the movable plate 61 slides toward the clutch yoke 51 against the spring force of the coil spring 60. Then, the tip of the peripheral wall 51 c in the clutch yoke 51 and the movable first convex portion 63 of the movable plate 61 abut. Further, the tip of the inner wall cylindrical yoke 52 and the other surface 61c of the movable plate 61 abut.

  Here, as shown in FIG. 5, the side surface 68a of the fixed convex portion 68 of the fixed plate 65 and the side surface 64a of the movable second convex portion 64 of the movable plate 61 are in contact with each other when the electromagnetic clutch mechanism 50 is turned off. A case where the electromagnetic clutch mechanism 50 is energized from the engaged state will be described.

As described above, the side surfaces 64a at both ends in the circumferential direction of the movable second convex portion 64 are inclined so that the angle with the one surface 61b of the movable plate 61 is θ. Further, the side surfaces 68a at both ends in the circumferential direction of the fixed convex portion 68 are inclined so that the angle with the one surface 65b of the fixed plate 65 is θ so as to correspond to the side surface 64a of the movable second convex portion 64. .
For this reason, when the force is acting in the direction in which the movable second convex portion 64 and the fixed convex portion 68 are pressed against each other, that is, the rotational force F1 is applied to the movable second convex portion 64 and the fixed convex portion 68, respectively. Is acting, a slight force F <b> 2 is applied to the movable plate 61 in a direction away from the fixed plate 65.

Accordingly, when the electromagnetic clutch mechanism 50 is switched from the energized off state to the energized on state, the movable plate resists the frictional force generated between the side surface 64a of the movable second convex portion and the side surface 68a of the fixed convex portion 68. 61 can be easily slid to the clutch yoke 51 side.
The angle θ between the one surface 61b of the movable plate 61 and the side surface 64a of the movable second convex portion 64 (the angle θ between the one surface 65b of the fixed plate 65 and the side surface 68a of the fixed convex portion 68) is the movable first. Even when a rotational force F1 is applied to each of the two convex portions 64 and the fixed convex portion 68, it does not slide until the movable plate 61 moves away from the fixed plate 65 (for example, θ ≧ 75 °).

  Further, as can be seen from the fact that the movable first convex portion 63 of the movable plate 61 is magnetically attracted to the tip of the peripheral wall 51 c of the clutch yoke 51, it is formed between the clutch yoke 51 and the movable plate 61. Of the magnetic flux, the density of the magnetic flux formed between the tip of the peripheral wall 51c and the movable first convex portion 63 of the movable plate 61 is important. For this reason, in the peripheral wall 51c of the clutch yoke 51, the extraction hole 56 is formed at a position overlapping with the yoke convex portion 57 in the axial direction. Prevents a decrease in magnetic flux density.

Further, since the clutch yoke 51 is provided with the inner wall cylindrical yoke 52, the tip of the inner wall cylindrical yoke 52 also generates a magnetic attractive force to the movable plate 61, so that the movable plate 61 is securely attached to the clutch yoke 51. Can be sucked to the side.
In addition, by providing the inner wall cylindrical yoke 52, it is possible to prevent the magnetic flux generated from the exciting coil 55 from leaking to the rotating shaft 3.

  Further, the movable plate 61 is formed with a movable second convex portion 64 protruding at a position avoiding the movable first convex portion 63. In other words, the movable second convex portion 64 is formed at a position separated from the movable first convex portion 63. For this reason, the magnetic flux formed by the clutch yoke 51 leaks to the movable second convex portion 64 in a state where the tip of the peripheral wall 51 c in the clutch yoke 51 and the movable first convex portion 63 of the movable plate 61 are in contact with each other. This can be suppressed. Therefore, the contact state between the clutch yoke 51 and the movable plate 61 can be reliably maintained.

  Here, in the movable plate 61, the axial height H1 between the tip of the movable second convex portion 64 and the surface opposite to the surface on which the movable second convex portion 64 is formed, and the clutch yoke The protruding height H2 of the yoke protrusion 57 protruding from the peripheral wall 51c of 51 is set to satisfy the above formula (1). For this reason, when the movable plate 61 is in contact with the clutch yoke 51, the movable second convex portion 64 of the movable plate 61 and the fixed plate 65 are separated in the axial direction.

  Under such a state, even if the rotating shaft 3 rotates and the fixed plate 65 rotates together with the rotating shaft 3, the rotation of the fixed plate 65 is blocked by the movable plate 61 and the clutch yoke 51. There is nothing. For this reason, rotation of the rotating shaft 3 is continued.

(Operation of motor with reduction gear)
Next, based on FIG. 1, operation | movement of the motor 1 with a reduction gear is demonstrated.
Here, the case where the motor 1 with a reduction gear is used as a drive source of a power window device mounted on a vehicle will be described.
When the window glass is opened and closed, external power is supplied to the DC motor 2 and the electromagnetic clutch mechanism 50 via the connector unit 31. Then, a magnetic flux is formed in the armature 6 of the DC motor 2, and a magnetic attractive force or a repulsive force is generated between this magnetic flux and the permanent magnet 7 provided on the yoke 5. Thereby, the armature 6 rotates.

At the same time, since the electromagnetic clutch mechanism 50 is energized, the armature 6 continues to rotate, and the rotational force of the armature 6 is output via the worm 25 and the worm wheel 26. Thereby, opening / closing operation | movement of a window glass is performed.
On the other hand, when the supply of external power to the DC motor 2 and the electromagnetic clutch mechanism 50 is cut off, the armature 6 is stopped and the electromagnetic clutch mechanism 50 is turned off. At this time, a rotational force acts on the rotating shaft 3 through the worm 25 and the worm wheel 26 by the dead weight of the window glass. However, since the electromagnetic clutch mechanism 50 is in the energized off state, the rotation of the rotating shaft 3 is prevented and the window glass is prevented from opening.

  As described above, the electromagnetic clutch mechanism 50 according to the first embodiment described above extends from the peripheral wall 51c of the clutch yoke 51 along the axial direction, and from the outer peripheral portion of the movable plate 61 to the radially outer side. The movable first convex portion 63 formed to extend is engaged, and the movable first convex portion 63 is formed at a position radially inward of the movable first convex portion 63 and avoiding the movable first convex portion 63. The two convex portions 64 and the fixed convex portion 68 of the fixed plate 65 are engaged with each other to prevent the rotation shaft 3 from rotating. For this reason, the movable plate 61 can be slid with the minimum magnetic flux formed in the clutch yoke 51, and the electromagnetic clutch mechanism 50 can be downsized.

  In addition, by forming an extraction hole 56 at a position overlapping the yoke convex portion 57 in the axial direction on the peripheral wall 51c of the clutch yoke 51, the magnetic flux at a position corresponding to the movable first convex portion 63 of the peripheral wall 51c by the extraction hole 56. Prevents a decrease in density. For this reason, it is possible to efficiently increase the density of a desired portion of the magnetic flux formed in the clutch yoke 51, and to further reduce the size of the electromagnetic clutch mechanism 50.

  Further, the side surface 64a of the movable second convex portion 64 and the side surface 68a of the fixed convex portion 68 are formed to be inclined. For this reason, when the rotational force F1 is acting on the movable second convex portion 64 and the fixed convex portion 68 respectively, the movable plate 61 is slightly subjected to the force F2 in the direction away from the fixed plate 65. To do. For this reason, the movable plate 61 can be efficiently attracted to the clutch yoke 51 side with a small magnetic force. Therefore, the electromagnetic clutch mechanism 50 can be effectively downsized.

  Further, since the clutch yoke 51 is provided with the inner wall cylindrical yoke 52, the tip of the inner wall cylindrical yoke 52 also generates a magnetic attractive force to the movable plate 61, so that the movable plate 61 is securely attached to the clutch yoke 51. Can be sucked to the side. In addition, by providing the inner wall cylindrical yoke 52, it is possible to prevent the magnetic flux generated from the exciting coil 55 from leaking to the rotating shaft 3. For this reason, the electromagnetic clutch mechanism 50 can be further downsized.

Further, the electromagnetic clutch mechanism 50 can be accommodated in the brush holder 20 by reducing the size of the electromagnetic clutch mechanism 50. For this reason, since the brush 21 and the electromagnetic clutch mechanism 50 can be disposed close to each other, the routing of the bus bar terminal 34 of the connector unit 31 can be simplified. For this reason, the structure of the motor 1 with a reduction gear can be simplified, and manufacturing cost and assembly man-hours can be reduced.
Furthermore, since the motor 1 with a speed reducer is integrated with a single rotating shaft 3, the number of parts is smaller than when the DC motor 2 and the worm speed reduction mechanism 4 are completely divided as in the prior art. Can be reduced. Furthermore, the assembly work of the motor 1 with a reduction gear can be made easier by reducing the number of parts.

  In the first embodiment described above, the case where the side surface 64a of the movable second convex portion 64 and the side surface 68a of the fixed convex portion 68 are formed to be inclined has been described. However, the present invention is not limited to this, and the side surface 64a of the movable second convex portion 64 may be formed at right angles to the one surface 61b of the movable plate 61, and the side surface 68a of the fixed convex portion 68 may be It may be formed at right angles to one surface 65b of 65. Furthermore, only one of the side surface 64a of the movable second convex portion 64 or the side surface 68a of the fixed convex portion 68 may be formed to be inclined.

  Furthermore, in the above-described first embodiment, the case where the yoke convex portion 57, the movable first convex portion 63, the movable second convex portion 64, and the fixed convex portion 68 are formed in three each has been described. However, the number of the convex portions 57, 63, 64, 68 is not limited to three, and the rotation of the movable plate 61 is restricted with respect to the clutch yoke 51 by the convex portions 57, 63, 64, 68. In addition, the number may be any number as long as it can restrict the rotation of the fixed plate 65 with respect to the movable plate 61.

  Further, the case has been described in which the rotation of the movable plate 61 with respect to the clutch yoke 51 and the rotation of the fixed plate 65 with respect to the movable plate 61 are restricted by the convex portions 57, 63, 64, and 68. However, the present invention is not limited to these, and any configuration that can restrict the rotation of the movable plate 61 with respect to the clutch yoke 51 and restrict the rotation of the fixed plate 65 with respect to the movable plate 61 may be used.

  Further, in the first embodiment described above, the enlarged diameter portion 58 is formed on the inner peripheral surface of the cylindrical portion 54 a of the bobbin 54, and the spring accommodating portion 59 formed by the enlarged diameter portion 58 and the inner wall cylindrical yoke 52 is formed. The case where the coil spring 60 is stored has been described. However, the present invention is not limited to this, and the inner wall cylindrical yoke 52 of the clutch yoke 51 may have a stepped shape as shown in FIG.

  More specifically, the diameter-enlarged portion 49 is formed through a step portion 49 a between the substantially central portion in the axial direction of the inner wall cylindrical yoke 52 and the bottom portion 51 a of the clutch yoke 51. That is, the inner wall cylindrical yoke 52 includes a reduced diameter portion 48 disposed between the axial center of the inner wall cylindrical yoke 52 and the opening 51b of the clutch yoke 51, and the reduced diameter portion 48 and the stepped portion 49a. The arranged enlarged diameter portion 49 is continuously formed.

  Further, the inner diameter of the cylindrical portion 54 a of the bobbin 54 is set to be substantially the same as the outer diameter of the enlarged diameter portion 49 of the inner wall cylindrical yoke 52. As a result, the spring accommodating portion 159 is formed between the axial center of the inner wall cylindrical yoke 52 and the end on the opening 51b side of the clutch yoke 51 (the reduced diameter portion 48). The coil spring 60 is stored in the spring storage portion 159. The stored coil spring 60 is slightly compressed between the stepped portion 49 a of the inner wall cylindrical yoke 52 and the movable plate 61.

  Thus, by forming the enlarged diameter portion 49 in the inner wall cylindrical yoke 52, the clearance K4 between the enlarged diameter portion 49 and the rotary shaft 3 can be increased. For this reason, magnetic flux leakage from the inner wall cylindrical yoke 52 to the rotary shaft 3 can be more reliably suppressed.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS.
9 is a perspective view of the electromagnetic clutch mechanism 250 according to the second embodiment, FIG. 10 is an exploded perspective view of the electromagnetic clutch mechanism 250 according to the second embodiment, and FIG. 11 is a configuration of the electromagnetic clutch mechanism 250 according to the second embodiment. FIG.
In the second embodiment, the electromagnetic clutch mechanism 250 is housed in the brush holder 20 (see FIG. 1) of the motor 1 with speed reducer, as in the first embodiment described above (the following embodiments). The same applies to.

(Electromagnetic clutch mechanism)
As shown in FIGS. 9 to 11, the electromagnetic clutch mechanism 250 has a bottomed cylindrical clutch yoke 251. The outer peripheral surface of the clutch yoke 251 is internally fitted and fixed to the small diameter cylindrical portion 20b of the brush holder 20 shown in FIG.
The opening 251b of the clutch yoke 251 is provided with a flange portion 271 that closes the opening 251b. Three caulking claws 273 project from the opening 251 b of the clutch yoke 251, and the flange portion 271 is fixed to the clutch yoke 251 by bending the caulking claws 273.

An opening 271a is formed in most of the radial center of the flange portion 271. Three claw portions 272 projecting radially inward are formed at equal intervals in the circumferential direction on the inner peripheral edge of the opening 271a. That is, the flange portion 271 is in a state in which the concave portion 272a is formed between the claw portions 272 adjacent in the circumferential direction.
The protruding length of the claw portion 272 is set to a length that allows the rotation shaft 3 to be inserted radially inward of the opening portion 271a from the tip of the claw portion 272.

In addition, a pole hole 274 is formed in the bottom portion 251a of the clutch yoke 251 in the most part in the center in the radial direction, and a substantially cylindrical pole 275 is press-fitted into the pole hole 274 from the outside in the axial direction.
The pole 275 is made of a magnetic material such as iron. The pole 275 includes a cylindrical portion 276 through which the rotation shaft 3 can be inserted, and an outer flange portion 277 integrally formed at one axial end of the cylindrical portion 276 (the lower end in FIGS. 8 and 9). Then, the pole 275 is press-fitted into the pole hole 274 of the clutch yoke 251, and the outer flange portion 277 of the pole 275 contacts the bottom portion 251 a of the clutch yoke 251, thereby positioning the pole 275.

On the outer peripheral surface of the cylindrical portion 276, a reduced diameter portion 278 that is reduced in diameter via a stepped portion 278a is formed from the substantially axial center to the other end opposite to the outer flange portion 277. A coil spring 279 is inserted into the reduced diameter portion 78a.
In addition, a tapered hole 280 is formed on the inner peripheral surface of the cylindrical portion 276 so that the diameter gradually increases from the substantially axial center toward the other end of the cylindrical portion 276 (the upper end in FIGS. 8 and 9). One end of a substantially cylindrical plunger 281 is inserted into the tapered hole 280.

The plunger 281 is formed of a magnetic material such as iron so that the rotary shaft 3 can be inserted radially inward. A taper protrusion 282 that is tapered is integrally formed at one end of the plunger 281 so as to correspond to the taper hole 280 of the pole 275. The outer diameter of the base end of the taper protrusion 282 is set to be smaller than the outer diameter of the plunger 281. As a result, a stepped portion 282 a is formed at the proximal end of the tapered protrusion 282.
Here, both ends of the coil spring 279 are in contact with the step 282a and the step 278a of the pole 275, respectively. The free length of the coil spring 279 is set to such a length that the tapered hole 280 of the pole 275 and the tapered protrusion 282 of the plunger 281 do not contact each other.

  Further, the axial length of the plunger 281 is set such that the other end of the plunger 281 is located substantially on the same plane as the flange portion 271 when the coil spring 279 has a free length. Further, at the other end of the plunger 281, three plunger convex portions 283 projecting along the axial direction are formed at a position corresponding to the concave portion 272 a of the flange portion 271. These three plunger convex portions 283 are in a state of protruding from the flange portion 271 through the concave portion 272a of the flange portion 271.

  A cylindrical bobbin 254 is accommodated in the accommodating portion 253 formed between the plunger 281 and the clutch yoke 251. The bobbin 254 is made of resin, and includes a cylindrical portion 254a and outer flange portions 254b that are integrally formed at both ends of the cylindrical portion 254a in the axial direction. And the exciting coil 255 is wound around the coil storage part 254c formed in the cylindrical part 254a and the outer flange part 254b.

  On the opposite side of the flange portion 271 from the bobbin 254, a fixed plate 265 formed in a substantially ring shape with a nonmagnetic material is disposed. The outer diameter of the fixed plate 265 is set to be slightly smaller than the inner diameter of the opening 271a of the flange portion 271. That is, the axially upper portion of the concave portion 272a of the flange portion 271 is covered with the fixing plate 265.

  Further, the inner diameter of the fixed plate 265 is set so that the rotary shaft 3 can be press-fitted. That is, the fixed plate 265 is fixed to the rotary shaft 3 and rotates together with the rotary shaft 3. In a state where the fixed plate 265 is fixed to the rotating shaft 3, the plunger convex portion 283 of the plunger 281 is slightly pressed against the spring force of the coil spring 279 by the fixed plate 265. That is, the plunger 281 is always urged toward the fixed plate 265 by the coil spring 279.

  In addition, fixed protrusions 284 that protrude toward the flange portion 271 are integrally formed on the outer peripheral portion of the fixed plate 265 at positions corresponding to the claw portions 272 of the flange portion 271. The protruding height of the fixed convex portion 84 is set such that the tip of the fixed convex portion 84 does not contact the claw portion 272 of the flange portion 271.

(Operation of electromagnetic clutch mechanism)
Next, the operation of the electromagnetic clutch mechanism 250 will be described with reference to FIGS.
First, the energization-off state of the electromagnetic clutch mechanism 250 will be described with reference to FIG.
As shown in the figure, in this state, the plunger 281 is pressed toward the fixed plate 265 by the coil spring 279. For this reason, the plunger convex portion 283 of the plunger 281 is in a state of protruding from the flange portion 271 to the fixed plate 265 side via the concave portion 272a of the flange portion 271. The distal end of the plunger convex portion 283 is in contact with the fixed plate 265.

  In this state, when the rotary shaft 3 tries to rotate, the fixed plate 265 integrated with the rotary shaft 3 rotates. Then, the circumferential side surface of the fixed convex portion 284 of the fixed plate 265 comes into contact with and engages with the circumferential side surface of the plunger convex portion 283. The plunger 281 is restricted from rotating by inserting the plunger convex portion 283 into the concave portion 272 a of the flange portion 271. For this reason, the rotation of the fixed plate 265 engaged with the plunger convex portion 283 is prevented, and the rotation of the rotating shaft 3 is further prevented.

Next, the energization-on state of the electromagnetic clutch mechanism 250 will be described with reference to FIG.
FIG. 12 is a cross-sectional view showing the energization-on state of the electromagnetic clutch mechanism 250.
As shown in the figure, when the excitation coil 255 of the electromagnetic clutch mechanism 250 is energized, the excitation coil 255 is excited and a magnetic flux is formed in the clutch yoke 251. This magnetic flux is transmitted to the pole 275 via the bottom 251 a of the clutch yoke 251.

  When magnetic flux is formed on the pole 275, a magnetic attractive force acts on the plunger 281. The plunger 281 slides toward the pole 275 against the spring force of the coil spring 279. Then, the taper projection 282 of the plunger 281 contacts the taper hole 280 of the pole 275. Further, the plunger convex portion 283 of the plunger 281 is separated from the fixed plate 265, and the engagement state between the fixed convex portion 284 of the fixed plate 265 and the plunger convex portion 283 of the plunger 281 is released.

Thereby, even if the rotating shaft 3 rotates and the fixed plate 265 rotates integrally with the rotating shaft 3, the rotation of the fixed plate 265 is not blocked by the plunger 281 and the rotation of the rotating shaft 3 is prevented. Will continue.
Therefore, according to the second embodiment described above, the same effects as those of the first embodiment described above can be achieved.

  Here, even when the plunger 281 slides to the pole 275 side, the plunger convex portion 283 is still inserted into the concave portion 272a of the flange portion 271. Thus, the plunger 281 is configured not to rotate relative to the rotation shaft 3 regardless of the slide position.

  Further, the pole 275 and the plunger 281 are configured so that the tapered surfaces (tapered holes 280 and tapered protrusions 282) are brought into contact with and separated from each other. For this reason, with respect to the stroke amount L1 of the plunger 281 (see FIG. 11, the two-dot chain line in FIG. 11 indicates the state in which the plunger convex portion 283 is retracted), the taper hole 280 of the pole 275 and the taper protrusion 282 of the plunger 281 The air gap amount L2 can be set small.

  In the second embodiment described above, the case where the claw portions 272 of the flange portion 271, the plunger convex portions 283 of the plunger 281, and the fixed convex portions 284 of the fixed plate 265 are each formed in three. However, the number of the claw portions 272 and the convex portions 283 and 284 is not limited to three, and the claw portion 272 and the convex portions 283 and 284 allow the fixing plate 265 to be fixed to the flange portion 271 and the plunger 281. Any number can be used as long as rotation can be regulated.

  Moreover, the case where the claw part 272, the plunger convex part 283, and the fixed convex part 284 were provided as described above as a configuration for restricting the rotation of the fixed plate 265 with respect to the flange part 271 and the plunger 281 has been described. However, the configuration is not limited to these, and any configuration that can regulate the rotation of the fixed plate 265 relative to the flange portion 271 and the plunger 281 may be used.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIGS.
FIG. 13 is a perspective view of an electromagnetic clutch mechanism 350 according to the third embodiment, and FIG. 14 is an exploded perspective view of the electromagnetic clutch mechanism 350 according to the third embodiment.
As shown in FIGS. 13 and 14, the difference between the second embodiment and the third embodiment is that the electromagnetic clutch mechanism 250 in the second embodiment has a clutch yoke 251 disposed on the radially outer side of the bobbin 254, and the bobbin The electromagnetic clutch mechanism 350 according to the third embodiment has a pole 375 disposed on the radially outer side of the bobbin 354 and a clutch yoke disposed on the radially inner side of the bobbin 354. 351 is located.

(Electromagnetic clutch mechanism)
The electromagnetic clutch mechanism 350 will be described in more detail.
As shown in FIGS. 13 and 14, the electromagnetic clutch mechanism 350 has a substantially cylindrical clutch yoke 351 into which the rotating shaft 3 can be inserted. A substantially ring-shaped flange portion 371 is provided at one axial end of the clutch yoke 351 (the upper end in FIGS. 13 and 14).

  A through hole 371a is formed in most of the radial center of the flange portion 371, and the clutch yoke 351 and the flange portion 371 are integrated by press-fitting one end of the clutch yoke 351 into the through hole 371a. ing. Further, three claw portions 372 are formed on the outer peripheral portion of the flange portion 371 so as to protrude outward in the radial direction. Each claw part 372 is arranged at equal intervals in the circumferential direction. By these claw portions 372, a recess 372a is formed between the claw portions 372 adjacent in the circumferential direction.

  Further, an outer flange portion 385 is integrally formed at the other axial end of the clutch yoke 351 (the lower end in FIGS. 13 and 14). The outer diameter of the outer flange portion 385 is set to be substantially the same as the outer diameter of the portion where the claw portion 372 of the flange portion 371 is formed. A substantially cylindrical pole 375 is fitted and fixed to the outer peripheral edge of the outer flange portion 385 formed in this manner.

  An inner flange portion (not shown) is formed on the outer flange portion 385 side end (lower end in FIGS. 13 and 14) of the clutch yoke 351 in the pole 375, and the outer flange portion 385 of the clutch yoke 351 is axially outside ( A pole 375 is fitted into the outer flange portion 385 from the lower side in FIGS. Then, the pole 375 is positioned by bringing the inner flange portion of the pole 375 into contact with the outer flange portion 385.

  The length of the pole 375 in the axial direction is set shorter than the length of the clutch yoke 351 in the axial direction. In addition, a taper hole 380 that gradually increases in diameter toward the end on the inner peripheral surface at the end opposite to the inner flange of the clutch yoke 351 (the upper end in FIGS. 13 and 14). Is formed.

A cylindrical bobbin 354 is accommodated between the outer peripheral surface of the clutch yoke 351 and the inner peripheral surface of the pole 375. The bobbin 354 includes a cylindrical portion 354a and outer flange portions 354b integrally formed on both ends of the cylindrical portion 354a in the axial direction. The outer diameter of the outer flange portion 354b is set to be substantially the same as the outer diameter of the portion where the concave portion 372a of the flange portion 371 is formed.
Of the two outer flange portions 354b, the outer flange portion 354b on the flange portion 371 side is integrally provided with a bobbin convex portion 386 that protrudes toward the flange portion 371 along the axial direction at a position corresponding to the recess portion 372a. Molded. An exciting coil 355 is wound around a coil storage portion 354c formed in the cylindrical portion 354a and the outer flange portion 354b.

A coil spring 379 is housed between the bobbin 354 around which the exciting coil 355 is wound and the inner peripheral surface of the pole 375. The free length of the coil spring 379 is set to be slightly longer than the axial length of the pole 375.
Between the coil spring 379 and the flange portion 371, a plunger 381 formed in a substantially ring shape by a magnetic material such as iron is provided. The inner diameter of the plunger 381 is set to be slightly larger than the outer diameter of the outer flange portion 354b of the bobbin 354. On the other hand, the outer diameter of the plunger 381 is set to be substantially the same as the outer diameter of the pole 375, and the plunger 381 can be placed on the axial end of the pole 375.

Further, a tapered protrusion 382 that is tapered is integrally formed at the end of the plunger 381 on the pole 375 side so as to correspond to the tapered hole 380 of the pole 375. The tapered protrusion 382 is formed so as to be inserted into the tapered hole 380 of the pole 375. The end of the coil spring 379 comes into contact with the tip of the tapered protrusion 382 formed in this way.
Here, the free length of the coil spring 379 is set such that the tapered hole 380 of the pole 375 and the tapered protrusion 382 of the plunger 381 do not contact each other.

  Further, at the end portion of the plunger 381 opposite to the tapered protrusion 382, three plunger convex portions 383 projecting along the axial direction are formed to project at positions corresponding to the concave portions 372a of the flange portion 371. These three plunger convex portions 383 are in a state of protruding from the flange portion 371 through the concave portion 372a of the flange portion 371.

  A substantially ring-shaped fixing plate 365 is disposed on the opposite side of the flange portion 371 from the plunger 381 with a gap from the flange portion 371. The outer diameter of the fixed plate 365 is set to be substantially the same as the outer diameter of the pole 375. Further, the inner diameter of the fixed plate 365 is set so that the rotary shaft 3 can be press-fitted. That is, the fixed plate 365 is fixed to the rotary shaft 3 and rotates together with the rotary shaft 3.

Fixing recesses 387 are formed on the outer periphery of the fixing plate 365 at positions corresponding to the recesses 372 a of the flange portion 371. The tip of the plunger convex portion 383 of the plunger 381 is in contact with the bottom of the fixed concave portion 387.
Here, in a state where the fixed plate 365 is fixed to the rotating shaft 3, the plunger convex portion 383 of the plunger 381 is slightly pressed against the spring force of the coil spring 379 by the bottom portion of the fixed concave portion 387. That is, the plunger 381 is always biased toward the fixed plate 365 by the coil spring 379.

(Operation of electromagnetic clutch mechanism)
Next, the operation of the electromagnetic clutch mechanism 350 will be described.
First, the energization-off state of the electromagnetic clutch mechanism 350 will be described.
In this state, the plunger 381 is pressed toward the fixed plate 365 by the coil spring 379. For this reason, the plunger convex portion 383 of the plunger 381 is in a state of protruding from the flange portion 371 toward the fixed plate 365 via the concave portion 372a of the flange portion 371. The tip of the plunger protrusion 383 is in contact with the bottom of the fixing recess 387 formed in the fixing plate 365.

  In this state, when the rotating shaft 3 tries to rotate, the fixed plate 365 integrated with the rotating shaft 3 rotates. Then, the circumferential side surface of the fixing recess 387 of the fixing plate 365 comes into contact with and engages with the circumferential side surface of the plunger projection 365. The plunger 381 is restricted from rotating because the plunger convex portion 383 is inserted into the concave portion 372 a of the flange portion 371. For this reason, the rotation of the fixed plate 365 engaged with the plunger convex portion 383 is prevented, and the rotation of the rotating shaft 3 is further prevented.

Next, the energization on state of the electromagnetic clutch mechanism 350 will be described.
When the exciting coil 355 of the electromagnetic clutch mechanism 350 is energized, the exciting coil 355 is excited and a magnetic flux is formed in the clutch yoke 351. This magnetic flux is transmitted to the pole 375 through the outer flange portion 385 of the clutch yoke 351.

By forming magnetic flux on the pole 375, a magnetic attractive force acts on the plunger 381, and the plunger 381 slides toward the pole 375 against the spring force of the coil spring 379. At this time, the bobbin convex portion 386 formed on the outer flange portion 354b of the bobbin 354 functions as a guide for the plunger 381 to slide.
The tapered protrusion 382 of the plunger 381 comes into contact with the tapered hole 380 of the pole 375. Further, the plunger convex portion 383 of the plunger 381 is separated from the fixed concave portion 387 of the fixed plate 365, and the engagement state between the fixed plate 365 and the plunger convex portion 383 of the plunger 381 is released.

Thereby, even if the rotating shaft 3 rotates and the fixed plate 365 rotates integrally with the rotating shaft 3, the rotation of the fixed plate 365 is not blocked by the plunger 381, and the rotation of the rotating shaft 3 is prevented. Will continue.
Therefore, according to the above-described third embodiment, the same effects as those of the above-described second embodiment can be achieved.

  In the third embodiment described above, the case where the claw portion 372 of the flange portion 371, the plunger convex portion 383 of the plunger 381, and the fixing concave portion 387 of the fixing plate 365 are each formed in three. However, the number of the claw portions 372, the plunger convex portions 383, and the fixed concave portions 387 is not limited to three, and the claw portions 372, the plunger convex portions 383, and the fixed concave portions 387 are used for the flange portion 371 and the plunger 381. Any number may be used as long as the rotation of the fixed plate 365 can be restricted.

  Further, the case where the claw portion 372, the plunger convex portion 383, and the fixing plate 365 are provided as described above as a configuration for restricting the rotation of the fixing plate 365 with respect to the flange portion 371 and the plunger 381 has been described. However, the configuration is not limited to these, and any configuration that can restrict the rotation of the fixed plate 365 relative to the flange portion 371 and the plunger 381 may be used.

The present invention is not limited to the above-described embodiment, and includes various modifications made to the above-described embodiment without departing from the spirit of the present invention.
For example, in the above-described embodiment, the case where the motor 1 with a reduction gear is a drive source for a power window device mounted on a vehicle, for example, has been described. However, it is not restricted to this, The motor 1 with a reduction gear can be applied to various apparatuses.
Moreover, in the above-mentioned embodiment, the motor 1 with a reduction gear demonstrated the case where the worm reduction mechanism 4 was provided as a reduction mechanism. However, the present invention is not limited to this, and various reduction mechanisms can be applied in place of the worm reduction mechanism 4.

DESCRIPTION OF SYMBOLS 1 ... Motor with reduction gear 2 ... DC motor (electric motor)
3 ... Rotating shaft 4 ... Worm reduction mechanism 20 ... Brush holder (feeding terminal accommodating portion)
21 ... Brush (power supply unit)
48 ... Reduced diameter portion 49 ... Expanded diameter portion 50 ... Electromagnetic clutch mechanism 51 ... Clutch yoke 51b ... Opening 52 ... Inner wall cylindrical yoke (inner wall yoke)
54 ... Bobbin 55 ... Excitation coil (coil)
56 ... Drawing hole 57 ... Yoke convex part 60 ... Coil spring 61 ... Movable plate 63 ... Movable first convex part 64 ... Movable second convex part 64a, 68a ... Side surface 65 ... Fixed plate 68 ... Fixed convex part

Claims (7)

A cylindrical bobbin that can be inserted through the rotating shaft;
A coil wound around the outer peripheral surface of the bobbin;
A clutch yoke that is formed in a bottomed cylindrical shape so as to cover the coil from the outer side in the radial direction of the rotating shaft, and is capable of inserting the rotating shaft into the inner side in the radial direction;
An insertion hole through which the rotating shaft can be inserted, a movable plate that is disposed on the opening side of the clutch yoke and is attracted by magnetic flux formed in the clutch yoke;
An elastic member that biases the movable plate away from the opening of the clutch yoke;
A fixed plate that is disposed on a surface of the movable plate opposite to the clutch yoke and rotates integrally with the rotating shaft;
Provided on the periphery of the opening of the clutch yoke and the movable plate are first engagement means for restricting rotation of the clutch yoke and the movable plate;
An electromagnetic clutch characterized in that a position of the movable plate avoiding the first engagement means and a second engagement means for restricting the rotation of the movable plate and the fixed plate are provided at the fixed plate. mechanism. The first engaging means includes
A yoke protrusion extending along the axial direction of the rotation shaft from the outer peripheral edge of the opening of the clutch yoke;
A movable first convex portion that extends from the outer peripheral edge of the movable plate toward the radially outer side and is engageable with the yoke convex portion in the rotational direction;
The second engaging means includes
A movable second convex portion formed radially inward of the movable first convex portion of the movable plate and projecting toward the fixed plate side;
2. A fixed projection that is formed to extend radially outward from the outer peripheral edge of the fixed plate and is engageable with the movable second projection in the rotation direction. The electromagnetic clutch mechanism described in 1.   The engagement surfaces of the movable second convex portion and the fixed convex portion are separated from each other when a force in the rotational direction is applied to the movable second convex portion and the fixed convex portion, respectively. The electromagnetic clutch mechanism according to claim 2, wherein the electromagnetic clutch mechanism is formed so as to be inclined so that a force directed toward the center acts.   3. A pull-out hole for pulling out the coil is formed in an outer peripheral wall of the clutch yoke at a position overlapping the portion where the yoke convex portion is formed in the axial direction. The electromagnetic clutch mechanism according to claim 3.   5. The clutch yoke according to claim 1, further comprising an inner wall yoke extending from the bottom portion toward the opening through the bobbin and the rotating shaft. The electromagnetic clutch mechanism according to claim 1. The elastic member is a coil spring;
The inner wall yoke is
A reduced diameter portion disposed on the opening side of the clutch yoke;
The diameter-reduced part is continuously formed on the bottom side of the diameter-reduced part via a stepped part, and the diameter-increased part is larger than the diameter-reduced part.
The electromagnetic clutch mechanism according to claim 5, wherein the elastic member is disposed on the outer peripheral side of the reduced diameter portion so as to contact the stepped portion. The electromagnetic clutch mechanism according to any one of claims 1 to 6,
An electric motor provided integrally with the rotary shaft at one end of the rotary shaft;
A reduction mechanism provided integrally with the rotation shaft on the other end side of the rotation shaft, and
The electric motor has a power feeding terminal accommodating portion in which a power feeding terminal for feeding power to the electric motor is accommodated,
A motor with a reduction gear, wherein the electromagnetic clutch mechanism is incorporated in the power supply terminal accommodating portion.

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