JP4598592B2 - Clutch device, motor device, and wiper motor - Google Patents

Description

  The present invention relates to a clutch device, a motor device, and a wiper motor.

  Among wiper motors applied to wiper devices for wiping a windshield of a vehicle, a wiper motor is known that has a built-in swing mechanism and a wiper arm having a wiper blade connected to an output shaft, and that wipes the wiping surface back and forth. .

  In this type of wiper motor, if the operation of the wiper arm is hindered and an excessive load acts on the output shaft of the wiper motor, the built-in swing mechanism and speed reduction mechanism may be damaged. Therefore, it is necessary to design the strength of each member constituting these mechanisms.

  In order to prevent this, a clutch device is further built in the output shaft of the wiper motor having a built-in swing mechanism, and each member constituting each of the above mechanisms does not require excessive strength assuming an excessive load action. The applicant has already proposed a small, lightweight, and inexpensive wiper motor having a configuration.

  The built-in clutch device has an input disk and a clutch disk for transmitting a rotational driving force, and these are engaged with each other in the axial direction of the output shaft so that the rotational driving force is generated around the axis of the output shaft. It is to be transmitted. When an overload of a predetermined value or more is applied to the output shaft, the output shaft is resisted by the urging force of the urging member that maintains the meshing engagement between the input disk and the clutch disk by the rotational driving force input to the input disk. A component force acts in the direction of the axis, the engagement convex portion and the engagement concave portion disengage from each other, and both of them idle to prevent damage to each member from overload.

  The engagement convex part and the engagement concave part of such an input disk and a clutch disk are simple meshing engagement (refer patent document 1), Specifically, it is engaged at the time of the rotational force transmission surface of a rotation direction, ie, an overload effect | action. A component force is generated upward in the axial direction due to the inclination of the surface (upward inclined surface with respect to the direction of rotational force action), but the engaging surfaces are in surface contact with each other, and the transmission force in the rotational direction is strengthened. Yes.

However, since the engaging convex portion and the engaging concave portion are in surface contact with each other as described above, if wear occurs in the engaging convex portion and / or the engaging concave portion due to repeated engagement and disengagement, The magnitude and direction of the force will change greatly. For this reason, there is a problem that it is difficult to accurately disengage the input disk and the clutch disk with an overload of a predetermined value or more.
Japanese Utility Model No. 2505881

  In consideration of the above fact, the present invention provides a clutch device, a motor device, and a clutch device, a motor device, in which the disengagement load between the input disk and the clutch disk is stable (small change from the setting time) even when wear due to repeated engagement and disengagement occurs. An object is to provide a wiper motor.

According to a first aspect of the present invention, there is provided a clutch device that is rotatably supported by a housing, is rotatably supported with respect to the output shaft, and is driven around an axis of the output shaft by inputting a driving force. The rotating input disk and the output shaft are supported so as to be non-rotatable around the axis line, and are arranged to face the input disk in the axial direction of the output shaft, and are arranged in the axial direction of the output shaft. A clutch disk meshingly engaged with the input disk; an engagement protrusion formed on one of the input disk and the clutch disk in the axial direction of the output shaft; and any of the input disk and the clutch disk An engagement recess formed to be engaged with the engagement protrusion on the other side, the input disc supported to be movable in the axial direction with respect to the output shaft, and the front An elastic member that applies a drag force to either the input disk or the clutch disk when any one of the clutch disks tries to disengage from the meshing engagement state between the engagement protrusion and the engagement recess. And one of the engaging convex part and the engaging concave part has a copying surface inclined at a predetermined angle with respect to the axis of the output shaft, and the engaging convex part and the engaging concave part the other, have a curved control surface which engages circumferentially in line contact of the output shaft to the following surface, said the scanning surface and the curved control surface profiling the following the shape of the curved control surfaces of the The surface is controlled to generate a component force of the rotational driving force in the axial direction, and the input disk and the clutch disk are set to have higher hardness on the side having the curvature control surface than the side having the copying surface. That It is a symptom.

  In the clutch device according to the first aspect, in the normal use state, the engaging convex portion and the engaging concave portion of the input disk and the clutch disc are engaged with each other, and the engaging convex portion and the engaging concave portion are engaged. Even when trying to leave the meshing engagement state, the elastic member gives a predetermined drag force, so that the meshing engagement state is maintained. For this reason, when a driving force is input to the input disk and rotated around the output shaft, the rotational driving force is transmitted from the input disk to the clutch disk via the engaging convex portion and the engaging concave portion. Since the clutch disk is supported so as not to rotate around the axis with respect to the output shaft, the rotational driving force transmitted to the clutch disk is transmitted from the clutch disk to the output shaft and integrated with the clutch disk. The output shaft is rotated.

  On the other hand, for example, when an excessive external force (load) is applied to the output shaft, the output shaft is reversed or restrained. Then, a rotational force acts on the clutch disk that rotates integrally with the output shaft in the direction of relative rotation with the input disk. A part of this rotational force acts as a component force for moving the input disk and / or the clutch disk in the axial direction of the output shaft to release the meshing engagement between the engaging convex part and the engaging concave part (output) When the rotational force (component force) exceeds a predetermined value, the input disk and / or the clutch disk moves in the output axis direction. And the mesh engagement state is released, the rotation transmission between the input disk and the clutch disk is disconnected, and the clutch disk, that is, the output shaft, idles with respect to the input disk.

  Thereby, it is possible to prevent damage to each component and burning of a motor connected to the input disk, for example. Furthermore, it is not necessary to set the strength of each part assuming the action of such an excessive external force (load).

  Moreover, at this time, the input disk and the clutch disk (engagement convex part and engagement concave part) are set so that the hardness on the side having the curvature control surface is higher than the hardness on the side having the copying surface. When the engagement convex portion and the engagement concave portion are repeatedly separated (the copying surface and the curve control surface), the wear on the side having the curve control surface is less than the wear on the side having the copy surface. (Wear progress is slow). In addition, the side having the curvature control surface is maintained in the engaged state by the line contact with the side having the copying surface. Therefore, on the side having the curvature control surface of the engaging convex portion and the engaging concave portion, the shape change from the initial convex shape or concave shape is small. Therefore, the engagement convex portion and the engagement concave portion are in line contact with each other and are separated from each other by the action of the component force following the shape of the curve control surface, and the load required for disengagement when the meshing engagement state is released. Change is also smaller. Therefore, the set load fluctuation of the clutch operation is stabilized over a long period.

According to a second aspect of the present invention, there is provided a clutch device comprising: an output shaft rotatably supported by a housing; and a rotationally supported and rotatably supported on one side in the axial direction with respect to the output shaft; An input disk that rotates about the axis of the output shaft, and is positioned on the other side in the axial direction of the output shaft with respect to the input disk and cannot rotate about the axis with respect to the output shaft and moves in the axial direction A clutch disk that is supported so as to mesh with and engage with the input disk in the axial direction of the output shaft, and an engagement formed on one of the input disk and the clutch disk so as to protrude in the axial direction of the output shaft A convex portion, an engaging concave portion formed so as to be engaged with the other one of the input disc and the clutch disc, and the output of the clutch disc The resistance against the axial movement of the clutch disk toward the other side in the axial direction of the output shaft from the meshing engagement state of the engagement convex portion and the engagement concave portion One of the engaging convex part and the engaging concave part has a copying surface inclined at a predetermined angle with respect to the axis of the output shaft, and the engaging convex part. and the other of said engagement recesses, have a curved control surface which engages circumferentially in line contact of the output shaft to the following surface, the shape of the curved control surface and the scanning surface and the curved control surface The copying surface is controlled to generate a component of the rotational driving force in the axial direction, and the input disk and the clutch disk have a side having the curvature control surface rather than a side having the copying surface. The feature is that it is set to high hardness To have.

  The clutch device according to claim 2 exhibits the same operations and effects as the clutch device according to claim 1.

Furthermore , as described above, the drag by the elastic member applied to the axial movement of the clutch disk from the meshing engagement state in order to maintain the meshing engagement state of the engagement convex portion and the engagement concave portion. Is received by the output shaft and an input disk supported in a state of being secured to one side in the axial direction with respect to the output shaft. That is, the force for maintaining the meshing engagement state is received by a component (input disk) attached to the output shaft. That is, the clutch device has a configuration that is completed as an “output shaft subassembly”, and is not a configuration that is completed depending on other components such as a housing. Therefore, the clutch device can be handled as a single component that is an “output shaft subassembly”.

  A clutch device according to a third aspect of the present invention is the clutch device according to the first or second aspect, wherein the elastic member is a coil that is wound around the axis of the output shaft and is compressible in the axial direction of the output shaft. The coil spring is disposed between the clutch disk and a large diameter portion that is large in the radial direction of the output shaft and cannot move in the axial direction.

  In the clutch device according to the third aspect, since the elastic member is a coil spring wound around the output shaft and compressible in the axial direction of the output shaft, the spring characteristics are stable. That is, for example, when the elastic member is a rubber member, grease applied to the clutch device may adhere to the rubber member and deteriorate, but in the case of a coil spring, there is a risk of deterioration due to adhesion of grease or the like. The spring characteristics are stable because there is no. In addition, since this coil spring is disposed between the clutch disk and the large-diameter portion that has a large diameter in the radial direction of the output shaft and cannot move in the axial direction, the clutch disk is stable with respect to the input disk. It is possible to apply a stable drag force.

  A clutch device according to a fourth aspect of the present invention is the clutch device according to any one of the first to third aspects, wherein the engaging convex portion and the engaging concave portion are provided on the input disc and the clutch disc. A plurality of arrays are arranged on each of the opposing surfaces at intervals around the axis, and each has a circumferential edge formed in a shape that coincides with a radial straight line passing through the axis.

  In the clutch device as described above, when the engaging convex portion and the engaging concave portion are in the engaged state to transmit the rotational force and when the meshing engagement is about to be disengaged, the engaging convex portion is engaged with the engaging convex portion. A force in the rotational direction acts on the contact portion (the copying surface and the curvature control surface) with the joint recess. At this time, for example, when both circumferential edges of the engaging convex part and the engaging concave part are formed in parallel shapes, the radial inner side has a higher surface pressure than the radial outer side, It becomes a factor in which uneven wear occurs.

  On the other hand, in the clutch device according to the fourth aspect, the engaging convex portion and the engaging concave portion are formed in a shape in which the circumferential end edge coincides with the radial straight line passing through the axis. The contact pressure is uniform between the radially inner side and the radially outer side of the contact portion between the joint convex portion and the engaging concave portion. Therefore, uneven wear of the part can be prevented.

  A clutch device according to a fifth aspect of the present invention is the clutch device according to any one of the first to fourth aspects, wherein at least one of the input disk and the clutch disk is made of a sintered metal material. The sintered metal contains lubricating oil.

  In the clutch device according to the fifth aspect, since lubricating oil is contained in the sintered metal, self-lubricating properties can be provided, and wear and abnormal noise can be prevented.

  The clutch device according to a sixth aspect of the present invention is the clutch device according to any one of the first to fifth aspects, wherein the input disk has an outer periphery on the side of the clutch disk in the axial direction and the output shaft. Gear teeth are formed on the outer periphery of the concentric circumferential surface opposite to the clutch disk in the axial direction, and the driving force is input to the gear teeth, and the circumferential surface is formed with respect to the housing. It is characterized by being held rotatably.

  In the clutch device according to claim 6, the input disk supported by the output shaft has an outer periphery on the clutch disk side in the axial direction as a circumferential surface, and the circumferential surface is rotatably held by the housing. . That is, in this clutch device, an input disk to which driving force is input is supported by the housing, and an output shaft is supported by the housing via the input disk. Accordingly, the support strength of the input disk and the output shaft with respect to the housing can be improved.

  On the other hand, a motor device according to a seventh aspect includes the clutch device according to any one of the first to sixth aspects and a motor body, and the input disk of the clutch device includes the motor. It is characterized in that it rotates at a reduced speed by meshing with a worm gear provided on the rotating shaft of the main body.

  In the motor device according to claim 7, the same effect as that of the clutch device according to any one of claims 1 to 6 is obtained, and the motor device is quiet and has a high efficiency with little sliding loss. .

  Moreover, since the input disk meshes with a worm gear provided on the rotation shaft of the motor body and is rotated at a reduced speed, the output shaft can be driven with a large torque, for example, as a drive source for a vehicle wiper device or sunroof device. Is preferred. In particular, in this case, for example, when applied as a drive source (wiper motor) of a wiper device, a drive force transmission component (deceleration mechanism such as a worm gear, rotation of the motor body) after the output shaft when an excessive external force (load) is applied. The configuration from the shaft toward the armature side, etc.) can be protected. In addition, a wiper arm or the like (driven member) fixed or coupled to the output shaft can also be protected from breakage because the shock is absorbed by idling by the clutch device.

  According to an eighth aspect of the present invention, there is provided a wiper motor according to any one of the first to sixth aspects, the clutch device according to any one of the first to sixth aspects, a motor main body, a worm gear provided on a rotating shaft of the motor main body, and the worm gear. A worm wheel that rotates about a rotation axis perpendicular to the axis of the rotation shaft, and one end connected to a position different from the rotation axis of the worm wheel and the other end to the input disk of the clutch device A motion converting mechanism that engages and reciprocally swings by rotation of the worm wheel to drive reciprocating rotation of the input disk, and directly or indirectly to the output shaft. It is characterized by reciprocally driving the connected wipers.

  The wiper motor according to claim 8 has the same effect as that of the clutch device according to any one of claims 1 to 6, and is a quiet and high-efficiency wiper driving motor with little sliding loss. Become.

  In addition, since the input disk is driven to reciprocate at a reduced speed by a motion conversion mechanism (worm gear, worm wheel, and oscillating member) built in the motor, the output shaft can be driven with a large torque. The connected wipers can be suitably driven back and forth.

  In addition, by providing the clutch device, driving force transmission components after the output shaft when excessive external force (load) is applied (from the output shaft of the swinging member, worm wheel, worm gear, motor body, etc. to the armature side) Can be protected. In addition, the wiper connected to the output shaft can also be protected from breakage because the shock is absorbed by idling by the clutch device.

  1 and 2 are perspective views showing the overall configuration of the wiper motor 90 according to the embodiment of the present invention, and FIG. 3 is an exploded perspective view showing the configuration of the wiper motor 90. Yes. Further, in FIG. 4 to FIG. 8, the configuration of the wiper motor 90 is shown in cross-sectional views.

  The wiper motor 90 is a wiper driving motor for driving a wiper device of the vehicle, and includes a motor main body 92, a swing mechanism 94, and a clutch device 10.

  As shown in FIGS. 4 and 6, the motor main body 92 includes a yoke housing 98. The yoke housing 98 has a bottomed shape whose one end in the axial direction is drawn, and a cross section in the orthogonal direction of the rotating shaft 110 is formed in a flat cylindrical shape with the axial direction of the output shaft 12 as a short direction. The side is integrally attached to the housing 96. A bearing 102 is disposed on the bottom wall 100 of the yoke housing 98. On the other hand, an end housing 104 made of an insulating resin is fixed to the other end of the yoke housing 98.

  A bearing 106 is disposed at the center portion of the end housing 104. The rotating shaft 110 of the armature 108 is supported by the bearing 106 and the bearing 102 of the yoke housing 98, and the armature 108 is accommodated in the yoke housing 98. A magnet 112 is fixed to the inner peripheral wall of the yoke housing 98 facing the armature 108.

  The end housing 104 holds a brush 114 via a brush case. The brush 114 is formed in a prismatic shape and is pressed against the commutator 116 of the armature 108. Further, a coupling pigtail 118 is drawn out from the brush 114, and the tip of the pigtail 118 is connected to a connection line for power feeding.

  The rotating shaft 110 of the motor main body 92 (armature 108) is coupled to the worm gear 122 of the swing mechanism 94 by a coupling 120.

  One end of the worm gear 122 is rotatably supported by the housing 96 via the bearing 124, and the other end is rotatably supported by the housing 96 via the bearing 126. The worm gear 122 meshes with the worm wheel 128.

  The worm wheel 128 is disposed on one side with respect to the axis of the worm gear 122 and is housed in the housing 96 in a state of meshing with the worm gear 122, and rotates around the rotation axis 130 perpendicular to the axis of the worm gear 122 (rotation axis 110). Rotate to.

  The worm wheel 128 is connected to a sector gear 132 as a swing member. The sector gear 132 is rotatably connected at one end by a support shaft (crank pin) 134 provided at a position different from the rotating shaft 130 of the worm wheel 128 (position displaced in the radial direction), and at the other end is an engaging portion. The tooth part 136 is formed. The teeth 136 are engaged (engaged) with an input disk 28 of the clutch device 10 described later.

  Furthermore, a holding lever 138 is disposed on one side of the sector gear 132 in the thickness direction (the side opposite to the worm wheel 128). One end of the holding lever 138 is connected to the swing center shaft 140 (support shaft provided at the center of the pitch circle of the tooth portion 136) in the tooth portion 136 of the sector gear 132, and the other end rotates to the housing 96. It is rotatably connected to an output shaft 12 that is freely supported. As a result, the inter-axis distance (inter-axis pitch) between the oscillation center shaft 140 and the output shaft 12 is maintained, and the meshing state of the sector gear 132 and the input disk 28 along the radial direction of the output shaft 12 is maintained. Thus, the sector gear 132 is reciprocally swung as the worm wheel 128 rotates, and the input disk 28 described later is reciprocally rotated by the reciprocating swing operation of the sector gear 132.

  A sliding member 147 made of a resin material or the like is attached to the holding lever 138 on the side opposite to the sector gear 132, and the sliding member 147 can slide on a cover 148 that closes the back side of the housing 96. Abut. Thereby, the movement along the thickness direction of the holding member 138 (the axial direction of the output shaft 12) is restricted. Further, since the output shaft 12 is disposed on the opposite side of the worm wheel 128 with respect to the axis of the worm gear 122, the sector gear 132 having one end connected to the worm wheel 128 intersects the axis of the worm gear 122 (a state of a twisted position). ) And the other end tooth portion 136 meshes with the input disk 28.

  On the other hand, as shown in FIGS. 9 and 10, the output shaft 12 has a distal end side (upper side in FIGS. 9 and 10) formed in a circular cross section to form a cylindrical portion 13, and a proximal end side (in FIGS. 9 and 10). The lower side has a substantially rectangular cross section (a so-called “cross-sectional double D-cut shape”) including a pair of planes formed on opposite sides 180 degrees in the circumferential direction and a pair of circumferential surfaces continuous with these planes. The relative rotation restricting portion 14 is formed.

  As shown in FIGS. 5 and 7, the cylindrical portion 13 of the output shaft 12 is rotatably supported by a bearing member 50 fixed to the housing 96. On the other hand, on the distal end side (the cylindrical portion 13 side) of the relative rotation restricting portion 14, a plurality of protrusions along the axial direction are formed on the circumferential surface portion, and a rotation stop portion 16 is provided. A retaining portion 18 is provided at the base end protruding end.

  An engagement base 20 as a large-diameter portion having a large diameter in the radial direction of the output shaft 12 is fixed to the rotation stop portion 16 of the relative rotation restricting portion 14 coaxially with the output shaft 12. The engagement base 20 is formed in a disk shape in which a support hole 22 having a substantially rectangular cross section (cross section double D-cut shape) corresponding to the relative rotation restricting portion 14 of the output shaft 12 is formed in the center portion. Is fixed to the rotation stop 16 so that it always rotates integrally with the output shaft 12 (it is impossible to move in the axial direction with respect to the output shaft 12). In addition, a stopper portion 26 that protrudes along the radial direction (the radial direction of the output shaft 12) is provided on the periphery of the engagement base 20. This stopper portion 26 corresponds to a stopper protrusion 142 described later formed on the housing 96.

  As described above, the output shaft 12 and the engagement base 20 are not limited to be formed separately and fixed. For example, the output shaft 12 and the engagement base 20 are integrally formed by cold forging or the like. (A configuration in which a flange-shaped large-diameter portion is integrally formed on the output shaft) may be employed.

  On the other hand, the aforementioned input disk 28 is coaxially attached to the output shaft 12 in the retaining portion 18 of the relative rotation restricting portion 14. The input disk 28 is formed in a cylindrical shape in which a shaft hole 30 having a circular cross section is formed in the central portion, and the retaining portion 18 of the output shaft 12 is inserted into the shaft hole 30 and attached to the protruding end of the retaining portion 18. By being prevented from being removed by the retaining clip 32, it is supported in a state of being secured to the one side in the axial direction (opposite side of the engagement base 20) with respect to the output shaft 12 so as to be rotatable. In the present embodiment, the input disk 28 is a sintered metal manufactured by a so-called “powder metallurgy method” in which a powder alloy is put into a molding die, compression molded, and heated and sintered. Contains lubricating oil.

  Gear teeth 34 are formed on the outer circumference of one end side of the input disk 28 in the axial direction (the side opposite to the engagement base 20). The gear teeth 34 mesh with the teeth 136 of the sector gear 132 of the swing mechanism 94 described above, and the input disk 28 rotates around the output shaft 12 when a driving force is input from the sector gear 132. ing.

  Also, as shown in FIG. 10, the input disk 28 is connected to the end of the gear teeth 34 on the other axial end of the gear teeth 34 (on the engagement base 20 side, opposite to the holding lever 138 described above). A connecting wall 35 is formed. As shown in FIG. 11, the connecting wall 35 sandwiches the tooth portion 136 of the sector gear 132 together with the holding lever 138 on both sides in the thickness direction (the connecting wall 35 faces the end surface on one side in the thickness direction of the tooth portion 136. At the same time, the holding lever 138 faces the other end surface of the tooth portion 136 in the thickness direction, so that the movement of the sector gear 132 in the tooth portion 136 in the thickness direction is restricted.

  Further, the outer periphery of the input disk 28 opposite to the gear teeth 34 through the connecting wall 35 is a circumferential surface 36 concentric with the output shaft 12, and this circumferential surface 36 is shown in FIGS. 7, the bearing member 52 fixed to the housing 96 is rotatably held (supported). That is, the input disk 28 is provided with a disc-shaped flange portion coaxial with the output shaft 12 on the other axial end side of the gear teeth 34, and the outer peripheral surface (circumferential surface 36) of this flange portion is a bearing member. 52 is supported.

  Still further, the end surface of the input disk 28 on the other end side in the axial direction (on the side of the engagement base 20 and on the other side of the output shaft 12 in the axial direction) has four peripheral edges projecting toward the engagement base 20 side. An engagement convex portion 37 is provided. These four engaging projections 37 are arranged concentrically with respect to the input disk 28 and are not evenly spaced from each other along the circumferential direction of the input disk 28 (the adjacent distances along the circumferential direction are spaced apart). Are arranged differently). These engaging projections 37 correspond to a clutch disk 38 to be described later.

  On the other hand, the relative rotation restricting portion 14 of the output shaft 12 supports the clutch disk 38 coaxially with the output shaft 12 between the engagement base 20 and the input disk 28 described above. The clutch disk 38 is formed in a disk shape in which a shaft hole 40 having a substantially rectangular cross section (double D cut shape in cross section) corresponding to the relative rotation restricting portion 14 is formed in the central portion, and the output shaft 12 ( When the relative rotation restricting portion 18) is inserted, it is positioned on the other side in the axial direction of the output shaft 12 (on the engagement base 20 side) with respect to the input disk 28 and is not rotatable about the axis with respect to the output shaft 12. And it is supported so as to be movable along the axial direction. Thus, the clutch disk 38 always rotates integrally with the output shaft 12 and can move relative to the input disk 28 along the axial direction of the output shaft 12. In this embodiment, the clutch disk 38 is a sintered metal manufactured by the so-called “powder metallurgy method” described above, and lubricating oil is contained in the sintered metal.

  On the rear surface side of the clutch disk 38 (on the input disk 28 side, one side in the axial direction of the output shaft 12), four engagement recesses 42 are provided in the peripheral edge portion (indented). These engagement recesses 42 correspond to the above-described four engagement projections 37 of the input disk 28, are arranged concentrically with respect to the clutch disk 38, and extend along the circumferential direction of the clutch disk 38. It arrange | positions so that it may not become equal intervals mutually (an adjacent space | interval differs along the circumferential direction).

  The four engagement convex portions 37 of the input disk 28 can be fitted into these four engagement concave portions 42 (that is, the clutch disk 38 can be engaged with the input disk 28). . Thereby, in a normal use state (rotation state), when the input disk 28 rotates, the rotational force of the input disk 28 is transmitted to the clutch disk 38 and the clutch disk 38 is rotated together.

  However, as described above, the engaging protrusions 37 and the engaging recesses 42 are not equally spaced along the circumferential direction of the input disk 28 and the clutch disk 38 (the adjacent distances are different from each other). Therefore, the clutch disk 38 (the output shaft 12 and the wiper) and the input disk 28 are engaged with each other only when the relative position along the circumferential direction is at a predetermined position. Yes. That is, at a position other than the predetermined one position, even if one engaging convex portion 37 corresponds to the engaging concave portion 42, the other three engaging convex portions 37 do not correspond to the engaging concave portion 42. It has become. Therefore, in a state in which the engaging convex portion 37 has come out of the engaging concave portion 42, the clutch disk 38 comes into contact with the input disk 28 through at least three engaging convex portions 37 (three-point support). It is a configuration that becomes a state).

  Here, as shown in FIG. 12, the engagement convex portion 37 of the input disk 28 and the engagement concave portion 42 of the clutch disk 38 have respective circumferential end edges (side wall portions) that are arranged on respective member axis lines CL (output shafts). 12), a shape that coincides with a radial straight line K passing through (12 axis lines) (that is, a shape that opens in a radial shape outward in a fan shape). Accordingly, the contact pressure between the engagement convex portion 37 and the engagement concave portion 42 is uniform between the radially inner side and the radially outer side (the Hertz contact surface pressure due to sliding is reduced). Has been.

  Further, here, the engaging convex part 37 of the input disk 28 and the engaging concave part 42 of the clutch disk 38 are each formed in a so-called substantially trapezoidal cross section, but in this embodiment, the engaging part of the input disk 28 is engaged. The mating convex portion 37 has a copying surface 51, and the engagement concave portion 42 of the clutch disk 38 has a bending control surface 53. That is, as shown in FIG. 13, the copying surface 51 of the engaging projection 37 is inclined by a predetermined angle θ (so-called operation angle necessary for setting the clutch operating torque) with respect to the axis of the clutch disk 38 (output shaft 12). Further, the bending control surface 53 of the engaging concave portion 42 is in line contact with the copying surface 51 of the engaging convex portion 37 in the circumferential direction of the input disk 28 (output shaft 12) (shown in FIG. 13). In the sectional view in the axial direction, it is formed so as to be bent so as to engage with the contact S. As a result, the output shaft 12 (clutch disk 38) is rotated by the rotation transmission force from the input disk 28 to the clutch disk 38 or the external force when the input disk 28 is rotated with the output shaft 12 being restrained. The copying surface 51 and the curve control surface 53 are caused to rotate in the axial direction by the rotational force that causes the input disk 28 and the clutch disk 38 to rotate relative to each other, such as a rotational transmission force from the clutch disk 38 to the input disk 28. Thus, a moving force along the axial direction of the output shaft 12 (toward the engagement base 20) is generated in the clutch disc 38.

  Moreover, the input disk 28 and the clutch disk 38 are arranged on the side having the curvature control surface 53 (that is, on the side having the copying surface 51 (i.e., the input disk 28 on which the engagement convex portion 37 is formed) (i.e. The clutch disk 38) in which the engagement recess 42 is formed has a higher hardness. Therefore, the wear on the side having the curvature control surface 53 is less than the wear on the side having the copying surface 51 (the wear progresses slowly). The inclination angle θ is maintained at a predetermined inclination angle (a change in the inclination angle θ due to wear is prevented), and the side having the curvature control surface 53 remains engaged with the side having the copying surface 51 by the line contact. It is the composition maintained by.

  In the present embodiment, for example, the engaging convex portion 37 (input disk 28) having the copying surface 51 is HV607 (Vickers hardness: measured by a micro Vickers hardness meter) and has a curvature control surface 53. The engaging recess 42 (clutch disk 38) is HMV648 (Vickers hardness: measured by a micro Vickers hardness meter), and a hardness difference of about 5% to 10% on the higher hardness side is set as the hardness difference. Yes.

  Further, as described above, the configuration is not limited to the configuration in which the copying surface 51 is provided on the engagement convex portion 37 of the input disk 28 and the curvature control surface 53 is provided on the engagement concave portion 42 of the clutch disc 38, but the configuration in which both are reversed. That is, a configuration may be adopted in which the bending control surface 53 is provided on the engaging convex portion 37 of the input disk 28 and the copying surface 51 is provided on the engaging concave portion 42 of the clutch disk 38. Even in this case, the side having the curvature control surface 53 (that is, the engagement convex portion 37 is formed more than the side having the copying surface 51 (that is, the clutch disk 38 having the engagement concave portion 42). The input disk 28) is set to a higher hardness.

  On the other hand, a coil spring 44 is disposed between the clutch disk 38 and the engagement base 20 as an elastic member that is wound around the output shaft 12 and can be compressed in the axial direction of the output shaft 12. . This coil spring 44 is located on the other side in the axial direction of the output shaft 12 of the clutch disk 38 from the engagement state of the engagement convex part 37 of the input disk 28 and the engagement concave part 42 of the clutch disk 38 (on the side of the engagement base 20). ) Is given a predetermined drag force (restoring force when the clutch disk 38 is elastically deformed by the axial movement).

  In other words, the engagement convex portion 37 of the input disk 28 normally enters the engagement concave portion 42 of the clutch disk 38, and the coil spring 44 maintains this fitted state. When the portion 37 attempts to move out of the engagement recess 42 of the clutch disc 38 and the clutch disc 38 moves in the axial direction toward the engagement base 20, it exerts an urging force (restoring force) against this. It is configured.

  Further, as described above, the engaging convex portion 37 of the input disk 28 enters the engaging concave portion 42 of the clutch disk 38, so that the rotational force is transmitted from the input disk 28 to the clutch disk 38. The urging force exerted by the coil spring 44 even when the engaging projection 37 of the clutch disc 38 is pulled out from the engaging recess 42 of the clutch disc 38 (even when the clutch disc 38 is moved toward the engagement base 20). Due to the (restoring force), a predetermined frictional force is generated between the engaging convex portion 37 of the input disk 28 and the back surface of the clutch disk 38, so that the input disk 28 and the clutch disk 38 are rotated. The urging force of the coil spring 44 is set.

  In the normal state (the state in which the clutch disk 38 does not move toward the engagement base 20), the coil spring 44 is already applied with a pressing force between the engagement base 20 and the clutch disk 38. Or only when the clutch disk 38 moves from the engaged state toward the engagement base 20 (when the engagement protrusion 37 is about to come out of the engagement recess 42). ), The coil spring 44 may be configured to exert an urging force (restoring force) against this.

  On the other hand, as shown in FIGS. 4 and 6, a stopper projection 142 is formed on the housing 96 corresponding to the stopper portion 26 of the engagement base 20 described above.

  The stopper protrusion 142 is formed in an arc shape and is located in the rotation locus of the stopper portion 26. One end portion in the circumferential direction and the other end portion in the circumferential direction of the stopper protrusion 142 are a rotation limiting portion 144 and a rotation limiting portion 146, respectively. In other words, the rotation restricting portion 144 and the rotation restricting portion 146 of the stopper protrusion 142 can be brought into contact with the stopper portion 26, respectively, and the stopper portion 26 comes into contact with the rotation restricting portion 144 or the rotation restricting portion 146 of the stopper protrusion 142. In this state, the engagement base 20 (output shaft 12) is prevented from rotating further. Therefore, after the engagement base 20 (the output shaft 12) is rotated together with the clutch disk 38 by the rotational driving force of the input disk 28, the stopper portion 26 comes into contact with the rotation limiting portion 144 or the rotation limiting portion 146 of the stopper projection 142. Since the subsequent rotation of the engagement base 20 (output shaft 12) is forcibly blocked, the input disk 28 is relatively rotated (idle) (see FIGS. 14 and 15).

  Further, a wiper (not shown) is directly connected to the output shaft 12 driven to reciprocate by the input disk 28, or indirectly connected via a link, a rod or the like. In this configuration, the output shaft 12 is driven to reciprocate as the output shaft 12 reciprocates.

  Next, the operation of the present embodiment will be described.

  In the wiper motor 90 configured as described above, when the motor main body 92 (armature 108) rotates, the rotational force is transmitted to the worm wheel 128 through the worm gear 122, and the worm wheel 128 rotates (in this embodiment, continuous rotation in one direction). To do. When the worm wheel 128 rotates, the sector gear 132 connected to the worm wheel 128 is reciprocally swung, and the input disk 28 is driven to reciprocate by the reciprocating swing operation of the sector gear 132 (see FIGS. 4 to 7). .

  Here, in a normal use state, for example, as shown in FIGS. 5 and 14, the engagement convex portion 37 of the input disk 28 is engaged with the engagement concave portion 42 of the clutch disk 38 (they are fitted to each other). In addition, even if the clutch disk 38 tries to move in the axial direction of the output shaft 12 from the engaged state of the engaging convex portion 37 and the engaging concave portion 42, a predetermined drag force is applied by the coil spring 44. State is maintained. The clutch disk 38 is not rotatable about the axis with respect to the output shaft 12. Therefore, when the input disk 28 is driven to reciprocately rotate, the rotational driving force is transmitted from the input disk 28 to the clutch disk 38 via the engaging convex part 37 and the engaging concave part 42, and is integrated with the clutch disk 38. The output shaft 12 is rotated.

  As a result, the wiper connected to the output shaft 12 reciprocates as the output shaft 12 reciprocates.

  On the other hand, for example, when an excessive external force (load) is applied to the output shaft 12 via the wiper, the output shaft 12 is reversed or restrained. Then, a rotational force acts on the clutch disk 38 that rotates integrally with the output shaft 12 in the direction of relative rotation with the input disk 28. Here, the engaging convex part 37 of the input disk 28 and the engaging concave part 42 of the clutch disk 38 are each formed in a so-called substantially trapezoidal cross section, and the engaging convex part 37 of the input disk 28 is a copying surface. 51, and the engagement recess 42 of the clutch disk 38 has a curved control surface 53. Therefore, the relative rotational force between the input disk 28 and the clutch disk 38 causes the clutch disk 38 to have an output shaft 12 axis line. A component force is generated along the direction (toward the engagement base 20). That is, a part of the relative rotational force between the input disk 28 and the clutch disk 38 moves the clutch disk 38 in the direction of the axis of the output shaft 12 to engage the engagement convex portion 37 of the input disk 28 with the clutch disk 38. This acts as a component force for releasing the engagement with the recess 42. When this relative rotational force (component force) exceeds a predetermined value, the drag force applied by the coil spring 44 is overcome and the clutch disk 38 is forcibly moved in the direction of the axis of the output shaft 12 as shown in FIGS. Thus, the engagement state is released (the engagement convex portion 37 of the input disk 28 comes out of the engagement concave portion 42 of the clutch disk 38 and the fitting is released). As a result, the clutch disk 38, that is, the output shaft 12 rotates idly with respect to the input disk 28 (the clutch disk 38, that is, the output shaft 12 and the input disk 28 rotate relatively).

  Therefore, in the wiper motor 90, for example, the wiper freezes at the regular stop position within the rotation range and sticks to the surface to be wiped, or snow accumulates on the wiper located at the regular stop position. When the motor main body 92 is operated in a restrained state and an excessive load or a sudden load is applied to the output shaft 12, it is in the middle of operation within the wiper rotation range (within the normal wiping range). When an excessive external force is applied to the output shaft 12 via the wiper (for example, when the wiper is wiped, snow accumulated on the roof falls on the wiper at a position other than the reverse position on the lower side along the glass surface. In the case where the driving force transmission components (sector gear 132, worm wheel 128, warp, etc.) after the input disk 28 are caused by idling by the clutch device 10. Gears 122, excessive external force to the structure) toward the output shaft 12 such as a motor main body 92 in the armature 108 side can be prevented from acting. Thereby, each said part after the input disk 28 can be protected, and damage to each said part, burning of the motor main body 92, etc. can be prevented.

  Further, since the strength design of each component after the input disk 28 may be set based on the rotational transmission force (clutch release force) between the input disk 28 and the clutch disk 38, the excessive external force (load) is not affected. It is not necessary to set the excessive strength of each component assuming the action, and an inexpensive configuration can be achieved.

  Moreover, the driven member (such as a wiper) connected to the output shaft 12 can also be protected from breakage because the shock is absorbed by the idling by the clutch device 10.

  Further, in the clutch device 10 of the present wiper motor 90, the input disk 28 is driven by the swing mechanism 94 (worm gear 122, worm wheel 128, and sector gear 132) in a reciprocating manner so that the output shaft 12 is driven with a large torque. Therefore, the wiper connected to the output shaft 12 can be suitably reciprocated. Accordingly, in the wiper motor 90, an excessive external force (load) acts on the output shaft 12 via the wiper (for example, snow accumulated on the roof of the vehicle falls substantially vertically along the glass surface and hits the wiper arm, and a large external force is applied. It is also suitable as a motor for driving a wiper for a vehicle having high probability, such as a truck having a cab over type cockpit or a construction machine.

  Further, in this wiper motor 90, the swinging central shaft 140 of the sector gear 132 and the output shaft 12 are connected by a holding lever 138 provided on one side in the thickness direction of the sector gear 132. The inter-axis distance (inter-axis pitch) between the dynamic center shaft 140 and the output shaft 12 is kept constant. In addition, the tooth portion 136 of the sector gear 132 is sandwiched on both sides in the thickness direction by the holding lever 138 on one side in the thickness direction and the connecting wall 35 of the input disk 28 on the other side (clutch disc 38 side). Therefore, even if there are no holding members (holding levers) on both sides in the thickness direction of the sector gear 132, the meshing margin between the gear teeth 136 and the tooth portions 34 along the thickness direction of the sector gear 132 is maintained (the thickness of the sector gear 132 is The disengagement in the vertical direction is prevented). Thereby, the good meshing state of the sector gear 132 and the input disk 28 can be maintained.

  Further, in this wiper motor 90, the engagement base 20 (large diameter portion) is fixed and integrated with the rotation stop portion 16 of the output shaft 12 formed with a plurality of protrusions, particularly in the rotation direction around the axis. On the other hand, it is firmly fixed. On the other hand, the input disk 28 is prevented from being removed by the retaining portion 18 of the output shaft 12, and further, the relative rotation restricting portion 14 of the output shaft 12 (that is, between the engagement base 20 and the input disk 28) A clutch disk 38 is supported so as to be movable in the axial direction. That is, any component is configured with the output shaft 12 as a reference, and a configuration in which the clutch disk 38 and the coil spring 44 are provided in a fixed space (fixed dimension) between the engagement base 20 and the input disk 28. It is. Therefore, it is possible to easily set the force (clutch release force) required for the axial movement of the clutch disk 38 as described above.

  Further, in the wiper motor 90, since the elastic member is the coil spring 44, the spring characteristics are stable. That is, for example, when the elastic member is a rubber member, the grease applied to the clutch device 10 may adhere to the rubber member and deteriorate, but in the case of the coil spring 44, the grease or the like is attached. There is no fear of deterioration and the spring characteristics are stable.

  In addition, the coil spring 44 is wound around the output shaft 12 and is disposed between the clutch base 38 and the engagement base 20 that has a large diameter in the radial direction of the output shaft 12 and cannot move in the axial direction. It is the structure which was made. For this reason, the clutch disk 38 can be stably pressed against the input disk 28 and a stable drag can be applied. That is, the elastic force of the coil spring 44 is evenly distributed by the clutch disk 38 to the engaging portion between the input disk 28 and the clutch disk 38. Therefore, the engagement state between the input disk 28 and the clutch disk 38 is stabilized, and the rotational transmission force (clutch release) between the input disk 28 and the clutch disk 38 (between the engagement convex part 37 and the engagement concave part 42). The value of force is also stable. Thereby, since the value of the clutch releasing force can be set more suitably, each component of the wiper motor 90 can be protected more reliably.

  In the wiper motor 90, the input disk 28 supported by the output shaft 12 has a circumferential surface 36 on the side opposite to the gear teeth 34 via the connecting wall 25. The bearing member 52 fixed to the housing 96 is rotatably held (supported). That is, the wiper motor 90 is configured such that the input disk 28 to which a load is input from the sector gear 132 is directly supported by the bearing member 52 of the housing 96. Therefore, the support rigidity of the input disk 28 is improved, and this also stabilizes the meshing state of the input disk 28 and the sector gear 132. Moreover, the output shaft 12 is configured such that the base end portion thereof is supported by the housing 96 (bearing member 52) via the input disk 28. This eliminates the need for a special space for supporting the base end portion of the output shaft 12 to the housing 96 (the installation space for the input disk 28 and the support space for the base end portion of the output shaft 12 are common), and the output shaft 12 It is possible to ensure a long distance dimension along the axial direction of the output shaft 12 between the bearing member 52 that supports the base end portion side and the bearing member 50 that supports the distal end side of the output shaft 12. Thereby, the support rigidity with respect to the housing 96 of the output shaft 12 is also improved.

  Further, in the wiper motor 90, since both the input disk 28 and the clutch disk 38 are sintered metal obtained by molding a powder alloy, these members can be manufactured with high accuracy by the powder metallurgy method, and the material yield is good. . Further, since the input disk 28 and the clutch disk 38 made of sintered metal contain lubricating oil in the sintered metal, they engage with each other (such as the engaging convex part 37 and the engaging concave part 42). Can be made self-lubricating, and the gear teeth 34 of the input disk 28 that engage with the teeth 136 of the sector gear 132 and the bearing member 52 that supports rotation can also be made self-lubricating. Is preferred.

  Furthermore, in the wiper motor 90, the engagement convex portions 37 of the input disk 28 and the engagement concave portions 42 of the clutch disk 38 are not equally spaced along the circumferential direction of the input disk 28 and the clutch disk 38, respectively. Even in the clutch release state in which the respective engagement convex portions 37 have come out of the respective engagement concave portions 42, the clutch disk 38 is provided with at least three engagement convex portions 37. Is engaged with the input disk 28 (because of the three-point support state), the engagement state between the clutch disk 38 and the input disk 28 in the clutch released state is stabilized.

  In addition, the input disk 28 and the clutch disk 38 (the output shaft 12 and the wiper) can be engaged only when the relative positional relationship along the circumferential direction is at a predetermined position. For this reason, in a clutch release state in which each engagement convex portion 37 has come out of each engagement recess 42 (when the input disk 28 and the clutch disk 38 are in a relative positional relationship other than a predetermined position), for example, an occupant or the like If the wiper is manually rotated, the input disk 28 and the clutch disk 38 are always engaged at a predetermined position. Therefore, the clutch disk 38 (the output shaft 12 and the wiper) can be easily and quickly returned to the original set state (initial setting state) with respect to the input disk 28, and is operated again without damaging the wiper device. Can be made.

  Further, here, in the clutch device 10 as described above, when the engaging convex portion 37 and the engaging concave portion 42 are transmitting the rotational force in the engaged state and when the meshing engagement is operating to be disengaged. A force in the rotational direction acts on the contact portion between the engaging convex portion 37 and the engaging concave portion 42 (the copying surface 51 and the bending control surface 53). At this time, for example, when both circumferential edges of the engaging convex portion 37 and the engaging concave portion 42 are formed in parallel shapes, the surface pressure on the radially inner side is higher than that on the radially outer side. Thus, this causes uneven wear.

  On the other hand, in the clutch device 10 according to the present embodiment, the engagement convex portion 37 of the input disk 28 and the engagement concave portion 42 of the clutch disk 38 have respective circumferential edges (side wall portions). Since it is formed in a shape that coincides with a straight line in the radial direction passing through the member axis (the axis of the output shaft 12) (that is, a shape that is fanned out radially outward), the engagement convex portion 37 and the engagement concave portion 42 The surface pressure is uniform between the radially inner side and the radially outer side of the contact portion (the Hertz contact surface pressure due to sliding is reduced). Therefore, uneven wear of the part can be prevented and wear resistance is improved.

  Further, in the wiper motor 90, in the normal use state (rotation state), as described above, when the rotational driving force is transmitted from the input disk 28 to the output shaft 12 of the clutch device 10, the engaging convex portion 37 of the input disk 28 is engaged. In order to maintain the engagement state between the clutch disk 38 and the engagement recess 42 of the clutch disk 38, the drag force applied to the axial movement of the clutch disk 38 from the engagement state is wasted as a sliding frictional force. Is not consumed. Therefore, it is possible to prevent a decrease in rotation transmission efficiency. In addition, since the rotational driving force can be transmitted without causing the sliding of the member, the generation of noise due to the sliding of the member is also prevented.

  Moreover, as described above, the drag force applied by the coil spring 44 to the axial movement of the clutch disk 38 from the engaged state in order to maintain the engaged state of the engaging convex portion 37 and the engaging concave portion 42. Is received by the engagement base 20 fixed to the output shaft 12 and the input disk 28 supported in a state of being secured to the output shaft 12 in one axial direction. That is, the force for maintaining the engaged state is received by the two components (the engagement base 20 and the input disk 28) attached to the output shaft 12. In other words, the clutch device 10 of the wiper motor 90 is configured to be completed as “a subassembly of the output shaft 12”, and is not configured to be completed depending on other components such as the housing 96. Therefore, the clutch device 10 can be handled as one component which is an “output shaft 12 subassembly”.

  Further, in the clutch device 10 of the wiper motor 90, as described above, the engaging convex portion 37 of the input disk 28 enters the engaging concave portion 42 of the clutch disk 38, so that the rotational force is applied from the input disk 28 to the clutch disk 38. Therefore, it is possible to transmit the driving force between the input disk 28 and the clutch disk 38 more reliably, damage each part, and the driving force transmitting parts connected to the input disk 28. Damage and the like can be prevented, and it is not necessary to set the strength of each component assuming the action of an excessive external force (load). In addition, the set load fluctuation of the clutch operation is stabilized over a long period of time.

  That is, when an excessive external force (load) is applied to the output shaft 12 via the wiper and the clutch disk 38, that is, the output shaft 12 rotates idly with respect to the input disk 28, the input disk 28 and the clutch disk 38 (engagement projection) 37 and the engagement recess 42) are the side having the curvature control surface 53 (that is, the engagement recess) than the side having the copying surface 51 (that is, the input disk 28 on which the engagement protrusion 37 is formed). Since the clutch disk 38 formed with 42 is made of a sintered metal material so as to have a higher hardness, (the copying surface 51 and the curve control surface 53) between the engagement convex portion 37 and the engagement concave portion 42. When the separation is repeated, the wear on the side having the curvature control surface 53 is less than the wear on the side having the copying surface 51 (the wear progress is slow). Engaging recess 42 having a curved control surface 53 of the engaging portion 37 and the engaging recess 42, a small change from the initial recess shape setting. That is, even when worn as described above, the shape of the bending control surface 53 having high hardness is maintained, so that the copying surface 51 of the engaging convex portion 37 that comes into line contact with the bending control surface 53 is curved with less wear. Control is performed following the shape of the control surface 53. Therefore, the change in the load required for disengagement when the engagement convex part 37 and the engagement concave part 42 are separated from each other by the action of the component force and the meshing engagement state is released is also reduced. Therefore, the set load fluctuation (clutch operating torque) of the clutch operation is stabilized over a long period.

  As described above, in the wiper motor 90 (clutch device 10) according to the present embodiment, the disengagement load between the input disk 28 and the clutch disk 38 is stabilized even when wear due to repeated engagement and disengagement occurs (at the time of setting). Change from is smaller).

  In the above embodiment, the input disk 28 and the clutch disk 38 constituting the clutch device 10 are configured such that the input disk 28 is provided with the engaging convex part 37 and the clutch disk 38 is provided with the engaging concave part 42. However, the present invention is not limited to this, and the engaging recess 42 may be provided on the input disk 28 and the engaging protrusion 37 may be provided on the clutch disk 38.

It is a perspective view which shows the structure of the wiper motor which concerns on embodiment of this invention. It is the perspective view which saw through a part which shows the structure of the wiper motor which concerns on embodiment of this invention. It is a disassembled perspective view which shows the structure of the wiper motor which concerns on embodiment of this invention. It is a plane sectional view showing the composition of the wiper motor concerning an embodiment of the invention. FIG. 5 is a cross-sectional view taken along line 5-5 of FIG. 4 illustrating the configuration of the wiper motor according to the embodiment of the present invention. It is a plane sectional view showing the composition of the wiper motor concerning an embodiment of the invention. FIG. 7 is a cross-sectional view taken along the line 7-7 in FIG. 6 illustrating the configuration of the wiper motor according to the embodiment of the present invention. FIG. 8 is a view corresponding to FIG. 7 in a clutch released state, showing a configuration of a wiper motor according to an embodiment of the present invention. It is a disassembled perspective view which shows the structure of the clutch apparatus which is a structural member of the wiper motor which concerns on embodiment of this invention. It is a disassembled perspective view which shows the structure of the clutch apparatus which is a structural member of the wiper motor which concerns on embodiment of this invention. It is sectional drawing which shows the partial structure of the rocking | fluctuation mechanism and clutch apparatus which are the structural members of the wiper motor which concerns on embodiment of this invention. It is a back view of the clutch disk which shows the shape and arrangement | positioning state of the engagement recessed part provided in the clutch disk of the clutch apparatus which is a structural member of the wiper motor which concerns on embodiment of this invention. It is sectional drawing which shows the structure of the engagement convex part provided in the input disk of the clutch apparatus which is a structural member of the wiper motor which concerns on embodiment of this invention, and the engagement recessed part provided in the clutch disk. It is a perspective view which shows the structure of the peripheral components containing the rocking | fluctuation mechanism which is a structural member of the wiper motor which concerns on embodiment of this invention, and a clutch apparatus, and shows a clutch connection state. It is a perspective view which shows the structure of the peripheral components containing the rocking | fluctuation mechanism and clutch device which are the structural members of the wiper motor which concerns on embodiment of this invention, and shows a clutch release state.

Explanation of symbols

  10 .... Clutch device, 12 .... output shaft, 20 .... engagement base (large diameter part), 28 ... input disc, 37 ... engagement projection, 38 ... clutch disc, 42 ... engagement recess , 44 .. Coil spring (elastic member), 51 .. Copying surface, 53 .. Curve control surface, 90 .. Wiper motor, 94 .. Swing mechanism, 96.

Claims (8)

An output shaft rotatably supported by the housing;
An input disk that is rotatably supported with respect to the output shaft and rotates around an axis of the output shaft by inputting a driving force;
The output shaft is supported to be non-rotatable around the axis, and is disposed opposite to the input disk in the axial direction of the output shaft, and is engaged with the input disk in the axial direction of the output shaft. The clutch disc
An engagement convex portion formed on one of the input disk and the clutch disk so as to protrude in the axial direction of the output shaft;
An engagement recess formed so as to engage with the engagement protrusion on the other of the input disk and the clutch disk;
Any one of the input disk and the clutch disk supported so as to be movable in the axial direction with respect to the output shaft is about to be disengaged from the meshing engagement state of the engagement convex part and the engagement concave part. An elastic member for applying a drag force to any one of the input disk and the clutch disk;
In the clutch device provided with
One of the engaging convex part and the engaging concave part has a copying surface that is inclined at a predetermined angle with respect to the axis of the output shaft, and the other of the engaging convex part and the engaging concave part is on the copying surface. have a curved control surface which engages circumferentially in line contact of the output shaft, said copying surface and the following surface along the shape of the curved control surface and the curved control surface is controlled in the axial direction Generating a component of the rotational driving force;
The input disk and the clutch disk have a higher hardness on the side having the curvature control surface than the side having the copying surface,
A clutch device characterized by that. An output shaft rotatably supported by the housing;
An input disk that is supported in a state where it is secured to the one side in the axial direction relative to the output shaft and is rotatable, and rotates around the axis of the output shaft when a driving force is input.
The input disk is positioned on the other side in the axial direction of the output shaft and supported so as to be non-rotatable around the axis and movable in the axial direction with respect to the output shaft. A clutch disc engagingly engaged;
An engagement convex portion formed on one of the input disk and the clutch disk so as to protrude in the axial direction of the output shaft;
An engagement recess formed so as to engage with the engagement protrusion on the other of the input disk and the clutch disk;
The clutch disk is disposed on the other side in the axial direction of the output shaft of the clutch disk, and is directed toward the other side in the output shaft axial direction of the clutch disk from the meshing engagement state of the engagement convex portion and the engagement concave portion. An elastic member that provides resistance to axial movement;
In the clutch device provided with
One of the engaging convex part and the engaging concave part has a copying surface that is inclined at a predetermined angle with respect to the axis of the output shaft, and the other of the engaging convex part and the engaging concave part is on the copying surface. have a curved control surface which engages circumferentially in line contact of the output shaft, said copying surface and the following surface along the shape of the curved control surface and the curved control surface is controlled in the axial direction Generating a component of the rotational driving force;
The input disk and the clutch disk have a higher hardness on the side having the curvature control surface than the side having the copying surface,
A clutch device characterized by that. The elastic member is a coil spring that is wound around the axis of the output shaft and is compressible in the axial direction of the output shaft, and the coil spring moves in the axial direction having a large diameter in the radial direction of the output shaft. It is arranged between the impossible large diameter part and the clutch disk,
The clutch device according to claim 1 or 2, characterized by the above. A plurality of the engaging convex portions and the engaging concave portions are arranged on the opposing surfaces of the input disc and the clutch disc with a space around the axis, and each has a circumferential edge passing through the axis. It is formed in a shape that matches the direction line,
The clutch device according to any one of claims 1 to 3, wherein the clutch device is characterized. At least one of the input disk and the clutch disk is made of a sintered metal material, and lubricating oil is contained in the sintered metal.
The clutch device according to any one of claims 1 to 4, wherein the clutch device is characterized. The input disk has an outer periphery on the clutch disk side in the axial direction that is concentric with the output shaft, and gear teeth are formed on an outer periphery on the opposite side to the clutch disk in the axial direction. The driving force is input to the housing, and the circumferential surface is rotatably held with respect to the housing.
The clutch device according to any one of claims 1 to 5, wherein the clutch device is characterized. A clutch device according to any one of claims 1 to 6, and a motor body,
The input disk of the clutch device meshes with a worm gear provided on a rotation shaft of the motor body and rotates at a reduced speed.
The motor apparatus characterized by the above-mentioned. The clutch device according to any one of claims 1 to 6,
A motor body;
One end at a position different from the rotation axis of the worm wheel, a worm gear provided on the rotation shaft of the motor body, a worm wheel meshing with the worm gear and rotating about a rotation axis perpendicular to the axis of the rotation shaft A motion conversion mechanism having a swinging member that is coupled and has the other end engaged with the input disk of the clutch device and reciprocally swung by rotation of the worm wheel, thereby driving the input disk to reciprocate. ,
With
Reciprocatingly drive a wiper directly or indirectly connected to the output shaft;
A wiper motor characterized by that.

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