JP6870504B2 - Power transmission mechanism - Google Patents

Description

Embodiments of the present invention relate to a power transmission mechanism.

Conventionally, a power transmission mechanism including a damper device provided between a crankshaft of an engine and an input shaft of a transmission is known. The power transmission mechanism includes, for example, a clutch cover connected to a crankshaft via a flywheel, a clutch hub connected to an input shaft, a clutch disc rotatable with respect to the clutch hub, and a clutch hub and a clutch disc. It has a coil spring arranged between the two and a pressure plate that presses the clutch disc against the flywheel. In such a power transmission mechanism, the rotation fluctuation input from the engine is damped by the coil spring.

Further, a power transmission mechanism having a mass body for applying an additional moment of inertia to the input shaft and an auxiliary clutch for connecting and disconnecting the mass body and the input shaft is known (Patent Document 1). The mass body is rotatably supported, for example, on a pressure plate. The mass body is interlocked with the pressure plate that engages and disengages the clutch, and the position where the auxiliary clutch engages and can rotate together with the input shaft and the position where the auxiliary clutch disengages and disconnects from the input shaft. Move to.

Jitsufuku No. 2-32890

However, in the conventional configuration, the amount of movement of the mass body is equal to the amount of movement of the pressure plate. For this reason, the degree of freedom in designing the power transmission mechanism is reduced, and it is difficult to adjust, for example, the amount of movement of the mass body with respect to the amount of movement of the pressure plate and the load for moving the mass body.

Therefore, the present invention has been made in view of the above, and provides a power transmission mechanism capable of adjusting the movable amount of the mass body with respect to the moving amount of the pressure plate and the load for making the mass body movable. To do.

As an example, the power transmission mechanism according to the embodiment of the present invention has a clutch cover that is attached to a fly wheel and can rotate around the center of rotation, and a clutch cover that can rotate around the center of rotation and moves in the axial direction. A possible clutch disc, a clutch hub that can rotate around the center of rotation with respect to the clutch disc, and the clutch disc and the clutch hub located between the clutch disc and the clutch hub in the circumferential direction. A spring that is compressed by relative rotation, a pressure plate that can be moved to a first position that presses the clutch disc against the flywheel, and a second position that separates the clutch disc from the clutch disc, and the pressure. A diaphragm spring that urges the plate to the first position, a mass body that can rotate around the center of rotation and can move in the axial direction with respect to the clutch hub, and a fulcrum portion supported by the clutch cover. It has an action point portion that presses the mass body against the clutch hub so that rotation can be transmitted, and a force point portion that is pushed by the pressure plate that moves from the first position to the second position. A pressure member is provided, wherein the action point portion is separated from the mass body by being pushed by the pressure plate that moves the portion from the first position to the second position. Therefore, as an example, by adjusting the positions of the fulcrum portion, the action point portion, and the force point portion, the movable amount of the mass body with respect to the moving amount of the pressure plate, the load for making the mass body movable, and Can be adjusted.

In the power transmission mechanism, for example, the distance between the fulcrum portion and the action point portion is longer than the distance between the fulcrum portion and the power point portion. Therefore, as an example, the amount of the action point portion separated from the mass body can be increased as compared with the amount of the pressure plate pushing the force point portion. Therefore, the mass body can be reliably separated from the pressurizing member and the clutch hub, and the connection between the mass body and the clutch hub can be reliably cut off.

In the power transmission mechanism, for example, the distance between the fulcrum portion and the action point portion is shorter than the distance between the fulcrum portion and the power point portion. Therefore, as an example, the load applied by the pressure plate to the force point portion in order to separate the action point portion from the mass body can be made smaller. Therefore, the driver can cut off the connection between the mass body and the clutch hub with a lighter force.

In the power transmission mechanism, as an example, the mass body includes a first member pressed against the clutch hub, a second member in contact with the action point portion of the pressurizing member, and the first member. It has a bearing that is interposed between the second member and supports the first member and the second member so as to be relatively rotatably around the center of rotation. Therefore, as an example, when the clutch cover on which the pressurizing member is supported and the clutch hub on which the first member is pressed rotate relative to each other around the center of rotation, between the pressurizing member and the mass body. Friction is suppressed. Therefore, damage to the pressurizing member due to friction is suppressed.

As an example, the power transmission mechanism is interposed between the mass body and the clutch hub, and the mass body and the clutch hub are relatively rotatable around the center of rotation and relatively movable in the axial direction. Further provided with a resin bush to support as much as possible. Therefore, as an example, the mass body can smoothly rotate in the circumferential direction and move in the axial direction with respect to the clutch hub.

FIG. 1 is a cross-sectional view showing an example of a power transmission mechanism in an engaged state according to the first embodiment. FIG. 2 is an enlarged cross-sectional view showing a part of an example of the power transmission mechanism in the engaged state of the first embodiment. FIG. 3 is a cross-sectional view showing an example of the power transmission mechanism in the released state of the first embodiment. FIG. 4 is an enlarged cross-sectional view showing a part of an example of the power transmission mechanism in the released state of the first embodiment. FIG. 5 is a cross-sectional view showing an example of the power transmission mechanism in the engaged state according to the second embodiment.

(First Embodiment)
Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 4. In addition, in this specification, a plurality of expressions may be described about the component element which concerns on embodiment and the description of the element. The components and descriptions in which a plurality of expressions are expressed may be expressed in other expressions not described. Further, components and explanations that are not expressed in a plurality of expressions may be expressed in other expressions that are not described.

FIG. 1 is a cross-sectional view showing an example of the power transmission mechanism 1 in the engaged state according to the first embodiment. The power transmission mechanism 1 is provided in a vehicle such as a four-wheeled vehicle. As shown in FIG. 1, the power transmission mechanism 1 includes a crankshaft 2, an input shaft 3, a flywheel 4, and a damper device 5.

The crankshaft 2 is the output shaft of the engine. The crankshaft 2 is not limited to this example, and may be indirectly connected to the engine, or may be an output shaft of another drive source such as a motor.

The input shaft 3 is an input shaft of the transmission. The input shaft 3 is not limited to this example, and may be indirectly connected to a transmission or may be connected to another drive source such as a motor. The input shaft 3 is arranged coaxially with the crankshaft 2.

Each of the crankshaft 2 and the input shaft 3 extends along the central axis Ax shown in FIG. 1 and is rotatable around the central axis Ax. The central axis Ax is an example of the center of rotation. Hereinafter, the direction orthogonal to the central axis Ax is referred to as a radial direction, the direction along the central axis Ax is referred to as an axial direction, and the direction of rotation around the central axis Ax is referred to as a circumferential direction or a rotation direction, respectively. The crankshaft 2 and the input shaft 3 are rotatable relative to each other.

The flywheel 4 is connected to the crankshaft 2. The flywheel 4 is formed in a substantially disk shape extending in the radial direction, and can rotate integrally with the crankshaft 2 around the central axis Ax. The flywheel 4 has a first friction surface 4a that faces in the axial direction.

The damper device 5 includes a clutch cover 11, a clutch disc 12, a clutch hub 13, a damper spring 14, a pressure plate 15, a diaphragm spring 16, two pivot rings 17, a clutch release device 18, and a mass body. It has 21, a resin bush 22, and a pressurizing member 23.

The clutch disc 12 may also be referred to as, for example, a drive plate. The clutch hub 13 may also be referred to as, for example, a driven plate. The damper spring 14 is an example of a spring.

The clutch cover 11 has a cover member 31, a support member 32, and a first connecting member 33. The cover member 31 has a tubular portion 31a and a wall portion 31b. The tubular portion 31a is formed in a substantially cylindrical shape. The tubular portion 31a is attached to the flywheel 4 by a bolt, for example, radially outside the first friction surface 4a. As a result, the clutch cover 11 can rotate integrally with the flywheel 4 around the central axis Ax. The wall portion 31b is formed in a substantially annular shape that protrudes inward in the radial direction from the tubular portion 31a and extends in the radial direction. The first friction surface 4a of the flywheel 4 faces the wall portion 31b.

FIG. 2 is an enlarged cross-sectional view showing a part of an example of the power transmission mechanism 1 in the engaged state of the first embodiment. As shown in FIG. 2, the support member 32 is located between the wall portion 31b and the first friction surface 4a, and is formed in a substantially annular shape extending in the radial direction. The support member 32 has a protrusion 32a that projects toward the first friction surface 4a. The protrusion 32a is formed, for example, in a substantially annular shape extending in the circumferential direction. The plurality of protrusions 32a may be arranged in a substantially annular shape.

As shown in FIG. 1, the first connecting member 33 is attached to the support member 32 and the wall portion 31b of the cover member 31 by, for example, caulking. The first connecting member 33 supports the support member 32 and the wall portion 31b at positions separated from each other in the axial direction.

The clutch disc 12 is formed in a substantially disk shape extending in the roughly radial direction, and can rotate around the central axis Ax with respect to the flywheel 4 and the clutch cover 11. The clutch disc 12 is located between the flywheel 4 and the wall portion 31b of the cover member 31 in the axial direction.

The clutch disc 12 has two bushes 41, two disc plates 42, a second connecting member 43, a support plate 44, and two clutch facings 45 in order from the one closest to the central axis Ax. The support plate 44 may also be referred to as, for example, a cushion spring. The clutch facing 45 may also be referred to as a friction material, for example.

The two bushes 41 are formed in a substantially cylindrical shape extending along the central axis Ax, and are arranged in the axial direction with an interval. The bush 41 has a plurality of locking portions 41a that project outward in the radial direction and are arranged in the circumferential direction with an interval.

Each of the two disc plates 42 is formed in a substantially annular shape extending in the roughly radial direction. The two disc plates 42 are arranged axially at intervals. Each disc plate 42 is provided with a spline portion 42a and a plurality of openings 42b. The spline portion 42a extends radially from the inner peripheral portion of the disc plate 42 and is formed by a plurality of grooves arranged in the circumferential direction with an interval. The plurality of openings 42b are provided at substantially equal intervals in the circumferential direction to expose the inside of the disc plate 42.

The bush 41 fits inside the disc plate 42 in the radial direction. The locking portion 41a of the bush 41 is fitted into the spline portion 42a of the disc plate 42. As a result, the disc plate 42 and the bush 41 can be integrally rotated around the central axis Ax.

The second connecting member 43 is attached to the two disc plates 42 by, for example, caulking, and supports the two disc plates 42 at positions axially separated from each other. The second connecting member 43 allows the two disc plates 42 to integrally rotate around the central axis Ax.

The support plate 44 is formed in a substantially annular shape larger than the disc plate 42. The inner peripheral portion of the support plate 44 is attached to one of the disc plates 42 by, for example, a screw or a second connecting member 43. The support plate 44 projects radially outward from the disc plate 42. The support plate 44 may be attached to another portion.

The clutch facing 45 is formed, for example, in an annular shape surrounding the disc plate 42 with an interval. The two clutch facings 45 are attached to both sides of the support plate 44 in the axial direction in the outer peripheral portion of the support plate 44. The clutch facing 45 can be slightly moved in the axial direction by the leaf spring-like portion provided on the support plate 44. The clutch facing 45 is provided with a plurality of grooves extending in the substantially radial direction from the inner peripheral portion to the outer peripheral portion of the clutch facing 45.

The clutch hub 13 can rotate about the central axis Ax with respect to the clutch disc 12. The clutch hub 13 includes an inner hub 51, an outer hub 52, a pre-damper spring 53, a flange member 54, a friction member 55, and a cushion spring 56.

The inner hub 51 is formed in a substantially cylindrical shape extending along the central axis Ax. The input shaft 3 is inserted inside the inner hub 51 in the radial direction. The clutch hub 13 and the input shaft 3 are fitted to each other so as to be movable in the axial direction and to transmit rotation. Further, the inner hub 51 is fitted inside the bush 41 in the radial direction. The inner hub 51 and the bush 41 are relatively rotatable around the central axis Ax.

The inner hub 51 has a plurality of locking portions 51a that project outward in the radial direction and are arranged in the circumferential direction with an interval. The locking portion 51a is arranged between the two bushes 41 of the clutch disc 12 in the axial direction.

The outer hub 52 is located between the two disc plates 42 in the axial direction. The outer hub 52 has an intermediate portion 52a and a plurality of arms 52b. The intermediate portion 52a is formed in an annular shape extending in the radial direction. A spline portion 52c is provided in the intermediate portion 52a. The spline portion 52c extends radially from the inner peripheral portion of the intermediate portion 52a and is formed by a plurality of grooves arranged in the circumferential direction with an interval.

The inner hub 51 is fitted radially inside the outer hub 52. The locking portion 51a of the inner hub 51 is fitted into the spline portion 52c of the outer hub 52. In the circumferential direction, a gap is provided between the end of the spline portion 52c of the outer hub 52 and the end of the locking portion 51a of the inner hub 51. As a result, the inner hub 51 and the outer hub 52 are relatively rotatable around the central axis Ax over a predetermined angle.

The pre-damper spring 53 is arranged in the gap between the end of the spline portion 52c of the outer hub 52 and the end of the locking portion 51a of the inner hub 51 in the circumferential direction. The pre-damper spring 53 is a coiled compression spring. The pre-damper spring 53 is elastically compressed by the outer hub 52 and the inner hub 51 as the inner hub 51 and the outer hub 52 rotate relative to each other around the central axis Ax. The pre-damper spring 53 is compressed to damp the rotational fluctuation of the engine.

The plurality of arms 52b of the outer hub 52 extend radially from the intermediate portion 52a. The plurality of arms 52b are arranged at regular intervals in the circumferential direction. For example, when no external force acts on the clutch disc 12 and the clutch hub 13, the openings 42b are located between the adjacent arms 52b in the circumferential direction.

The damper spring 14 is a coil-shaped compression spring (coil spring). The damper spring 14 is located inside the opening 42b of the disc plate 42 and is located between two adjacent arms 52b of the outer hub 52 in the circumferential direction. The damper spring 14 is located between the edge of the clutch disc 12 defining the opening 42b and the arm 52b of the clutch hub 13 in the circumferential direction, and is supported by the clutch disc 12 and the clutch hub 13.

When torque acts on the damper device 5, the clutch disc 12 and the clutch hub 13 rotate relatively around the central axis Ax. As a result, a twist angle is generated between the clutch disc 12 and the clutch hub 13, and the damper spring 14 is elastically compressed by the clutch disc 12 and the clutch hub 13. The damper spring 14 is compressed to damp the rotational fluctuation of the engine.

The flange member 54 is formed in a substantially annular shape extending in the radial direction, and is located between the clutch disc 12 and the wall portion 31b of the cover member 31 in the axial direction. The inner hub 51 is inserted inside the flange member 54 in the radial direction. The flange member 54 is fixed to the inner hub 51 by, for example, a bolt. Therefore, the flange member 54 and the inner hub 51 can rotate integrally around the central axis Ax.

The friction member 55 is formed in a substantially annular shape extending in the radial direction, and is located between the flange member 54 and the wall portion 31b of the cover member 31 in the axial direction. The friction member 55 is supported by the support portion 54a of the flange member 54.

The support portion 54a extends in the axial direction and supports the friction member 55 so as to be movable in the axial direction. Further, the support portion 54a limits the friction member 55 from being separated from the flange member 54 by a predetermined distance.

As shown in FIG. 2, the friction member 55 has a second friction surface 55a facing the wall portion 31b in the axial direction. The second friction surface 55a is provided with a plurality of grooves extending in the substantially radial direction from the inner peripheral portion to the outer peripheral portion of the second friction surface 55a.

As shown in FIG. 1, the cushion spring 56 is, for example, a disc spring, and is provided between the flange member 54 and the friction member 55. The cushion spring 56 urges the friction member 55 in a direction away from the flange member 54 along the axial direction.

The clutch disc 12, the clutch hub 13, and the damper spring 14 can be integrally moved in the axial direction with respect to the input shaft 3, the flywheel 4, and the clutch cover 11 by being assembled as described above. The input shaft 3, the flywheel 4, and the clutch cover 11 may be relatively movable in the axial direction.

As shown in FIG. 2, the pressure plate 15 is located between the first friction surface 4a of the flywheel 4 and the clutch cover 11 in the axial direction. The pressure plate 15 is movable in the axial direction with respect to the flywheel 4, the clutch cover 11, and the clutch disc 12. The pressure plate 15 has a friction plate 61, a pressing plate 62, a plurality of bolts 63, and a hook 64.

The friction plate 61 is formed in a substantially annular shape extending in the radial direction. The friction plate 61 has a third friction surface 61a, a mounting surface 61b, and a protruding portion 61c. The third friction surface 61a faces the first friction surface 4a of the flywheel 4. The mounting surface 61b is located on the opposite side of the third friction surface 61a and faces the wall portion 31b of the clutch cover 11. The protruding portion 61c is formed in a substantially cylindrical shape that protrudes from the mounting surface 61b toward the wall portion 31b of the clutch cover 11.

The support plate 44 and the clutch facing 45 of the clutch disc 12 are located between the flywheel 4 and the pressure plate 15. The first friction surface 4a of the flywheel 4 and one of the clutch facings 45 of the clutch disc 12 face each other. The third friction surface 61a of the pressure plate 15 and the other clutch facing 45 face each other.

The pressing plate 62 is located between the mounting surface 61b and the wall portion 31b of the clutch cover 11 in the axial direction, and is located inside the protruding portion 61c in the radial direction. The pressing plate 62 has a mounting portion 62a and a pressing portion 62b. The mounting portion 62a is formed in a substantially annular shape extending in the radial direction. The pressing portion 62b is formed in a substantially cylindrical shape protruding from the inner peripheral portion of the mounting portion 62a toward the wall portion 31b of the clutch cover 11 along the axial direction. The shape of the pressing plate 62 is not limited to this example.

The bolt 63 attaches the attachment portion 62a of the pressing plate 62 to the attachment surface 61b of the friction plate 61. The pressure plate 15 is not limited to this example, and for example, the friction plate 61 and the pressing plate 62 may be integrally formed.

The hook 64 is elastically deformable and is attached to, for example, the protrusion 61c. The hook 64 is not limited to this example. The tip of the hook 64 faces the tip of the protrusion 61c in the axial direction through a gap.

FIG. 3 is a cross-sectional view showing an example of the power transmission mechanism 1 in the released state of the first embodiment. FIG. 4 is an enlarged cross-sectional view showing a part of an example of the power transmission mechanism 1 in the released state of the first embodiment. The pressure plate 15 can move along the axial direction to the engagement position P1 shown in FIGS. 1 and 2 and the release position P2 shown in FIGS. 3 and 4. The engagement position P1 is an example of the first position. The release position P2 is an example of the second position.

As shown in FIG. 2, at the engagement position P1, the pressure plate 15 presses the clutch disc 12 against the flywheel 4 so that the rotation can be transmitted. At this time, one of the clutch facings 45 of the clutch disc 12 comes into contact with the first friction surface 4a of the flywheel 4. Further, the other clutch facing 45 comes into contact with the third friction surface 61a of the pressure plate 15.

When the engine rotates the flywheel 4 via the crankshaft 2, the clutch disc 12 is rotated by the frictional force between the clutch facing 45 and the first friction surface 4a and the third friction surface 61a. That is, the rotation generated by the engine is transmitted to the clutch disc 12 via the flywheel 4. Therefore, the flywheel 4 and the clutch disc 12 rotate integrally. The rotation of the clutch disc 12 is transmitted to the input shaft 3 via the damper spring 14 and the clutch hub 13.

As shown in FIG. 4, at the release position P2, the pressure plate 15 is separated from the clutch disc 12. At this time, one clutch facing 45 of the clutch disc 12 is separated from the first friction surface 4a of the flywheel 4. Further, the other clutch facing 45 is separated from the third friction surface 61a of the pressure plate 15. As a result, the clutch disc 12 can rotate around the central axis Ax with respect to the flywheel 4, the clutch cover 11, and the pressure plate 15. The pressure plate 15 located at the release position P2 may temporarily come into contact with the clutch disc 12.

The power transmission mechanism 1 is provided with a clutch C1 having the clutch disc 12 and the pressure plate 15 described above. The clutch C1 engages when the pressure plate 15 is arranged at the engagement position P1, and connects the clutch disc 12 and the flywheel 4 so that rotation can be transmitted to each other. The clutch C1 is disengaged by arranging the pressure plate 15 at the release position P2, and the clutch disc 12 and the flywheel 4 are separated from each other.

The diaphragm spring 16 is formed in a substantially annular shape extending in the roughly radial direction. The diaphragm spring 16 is swingably supported by the clutch cover 11 via the pivot ring 17.

The diaphragm spring 16 is located between the wall portion 31b of the cover member 31 of the clutch cover 11 and the support member 32. One pivot ring 17 is located between the diaphragm spring 16 and the wall portion 31b. The other pivot ring 17 is located between the diaphragm spring 16 and the support member 32. That is, the clutch cover 11 sandwiches the diaphragm spring 16 via the pivot ring 17. The diaphragm spring 16 can swing around the pivot ring 17 as a fulcrum by elastically deforming.

The diaphragm spring 16 has an inner lever portion 71 and an outer lever portion 72. The inner lever portion 71 is located radially inside the pivot ring 17. The outer lever portion 72 is located radially outside the pivot ring 17. The inner lever portion 71 and the outer lever portion 72 swing integrally with the pivot ring 17 as a fulcrum.

The outer lever portion 72 comes into contact with the protruding portion 61c of the pressure plate 15. Further, the hook 64 of the pressure plate 15 is caught by the outer lever portion 72. The outer lever portion 72 is located between the protruding portion 61c and the hook 64. The hook 64 and the protruding portion 61c hold the outer lever portion 72. As a result, the pressure plate 15 is supported by the clutch cover 11 via the diaphragm spring 16.

The diaphragm spring 16 can be changed between the pressurized state S1 shown in FIG. 1 and the released state S2 shown in FIG. 3 by swinging. As shown in FIG. 2, in the pressurized state S1, the outer lever portion 72 pushes the protruding portion 61c of the pressure plate 15 toward the clutch disc 12 and the flywheel 4. The pressed pressure plate 15 presses the clutch disc 12 against the flywheel 4. That is, the diaphragm spring 16 in the pressurized state S1 urges the pressure plate 15 to the engaging position P1. The diaphragm spring 16 is in the pressurized state S1 in the natural state where no external force acts.

As shown in FIG. 4, in the released state S2, the outer lever portion 72 pulls the hook 64 to separate the pressure plate 15 from the clutch disc 12. That is, the diaphragm spring 16 in the released state S2 urges the pressure plate 15 to the release position P2.

As shown in FIG. 3, the clutch release device 18 pushes the inner lever portion 71 of the diaphragm spring 16 by hydraulic or electromagnetic force according to the operation of the driver, for example, to release the diaphragm spring 16 in the pressurized state S1. Change to the released state S2. That is, the clutch release device 18 moves the pressure plate 15 from the engagement position P1 to the release position P2 by pushing the diaphragm spring 16.

As shown in FIG. 2, the mass body 21 is located between the friction member 55 of the clutch hub 13 and the diaphragm spring 16 in the axial direction. Further, the mass body 21 is located radially inside the pressing portion 62b of the pressing plate 62. The mass 21 has a disc 75, a ring 76, and a bearing 77. The disk 75 is an example of the first member. The ring 76 is an example of a second member.

The disc 75 is formed in a substantially annular shape extending in the radial direction. The disc 75 has a fourth friction surface 75a. The fourth friction surface 75a and the second friction surface 55a of the friction member 55 face each other.

The ring 76 is formed in a substantially annular shape extending in the circumferential direction. The inner diameter of the ring 76 is larger than the outer diameter of the disc 75. The ring 76 surrounds the disc 75 via an interval. The ring 76 has a contact surface 76a facing the diaphragm spring 16.

The bearing 77 is, for example, a ball bearing. The bearing 77 may be another bearing such as a roller bearing. The bearing 77 is interposed between the disc 75 and the ring 76, and supports the disc 75 and the ring 76 so as to be relatively rotatable around the central axis Ax.

As shown in FIG. 1, the resin bush 22 is made of, for example, a synthetic resin having a low coefficient of friction, and is formed in a substantially annular shape extending in the circumferential direction. The resin bush 22 is fitted inside the disc 75 of the mass body 21 in the radial direction.

The inner hub 51 of the clutch hub 13 is inserted inside the resin bush 22 fitted in the mass body 21 in the radial direction. Therefore, the resin bush 22 is interposed between the mass body 21 and the clutch hub 13. The resin bush 22 positions the mass body 21 so that the center of the mass body 21 coincides with the central axis Ax.

The resin bush 22 supports the mass body 21 and the clutch hub 13 so as to be relatively rotatable around the central axis Ax and relatively movable in the axial direction. Therefore, the mass body 21 and the resin bush 22 are integrally rotatable around the central axis Ax and movable in the axial direction with respect to the clutch hub 13.

The mass body 21 can move along the axial direction to the engagement position P3 shown in FIG. 1 and the release position P4 shown in FIG. As shown in FIG. 2, at the engagement position P3, the fourth friction surface 75a of the mass body 21 comes into contact with the second friction surface 55a of the clutch hub 13 so as to be able to transmit rotation.

When the rotation of the engine is transmitted to the clutch hub 13 via the flywheel 4, the clutch disc 12, and the damper spring 14, the frictional force between the fourth friction surface 75a and the second friction surface 55a causes mass. The body 21 is rotated. Therefore, the clutch hub 13, the mass body 21, and the input shaft 3 rotate integrally. The mass body 21 imparts a moment of inertia to the input shaft 3.

As shown in FIG. 4, at the release position P4, the mass body 21 is separated from the second friction surface 55a of the clutch hub 13. As a result, the mass body 21 can rotate around the central axis Ax with respect to the clutch hub 13 and the input shaft 3 integrally with the resin bush 22. That is, the moment of inertia of the mass body 21 is removed from the input shaft 3.

The power transmission mechanism 1 is provided with an auxiliary clutch C2 having the flange member 54, the friction member 55, the cushion spring 56, and the disc 75 described above. The auxiliary clutch C2 engages with the mass body 21 by being arranged at the engaging position P3, and connects the mass body 21 and the clutch hub 13 so as to be able to transmit rotation to each other. The auxiliary clutch C2 is disengaged by arranging the mass body 21 at the release position P4, and disconnects the mass body 21 and the clutch hub 13.

The pressurizing member 23 is an annular disc spring that spreads in the roughly radial direction. The pressurizing member 23 is not limited to this example, and may be, for example, a leaf spring, or may be composed of a swingable rigid member and a coil spring that urges the rigid member.

The pressurizing member 23 is located between the support member 32 of the clutch cover 11 and the mass body 21 in the axial direction. The pressurizing member 23 has a fulcrum portion 81, an action point portion 82, and a force point portion 83.

In the present embodiment, the fulcrum portion 81 is an outer peripheral portion of the pressurizing member 23. The fulcrum portion 81 is supported by the support member 32 of the clutch cover 11 and is arranged inside the substantially annular protrusion 32a in the radial direction. The protrusion 32a positions the pressurizing member 23 so that the center of the pressurizing member 23 coincides with the central axis Ax.

In the present embodiment, the point of action portion 82 is an inner peripheral portion of the pressurizing member 23. The point of action 82 is closer to the mass 21 than the fulcrum 81 in the axial direction. The point of action 82 is aligned with the ring 76 of the mass 21 in the axial direction. The contact surface 76a of the ring 76 faces the point of action 82.

In the present embodiment, the force point portion 83 is provided between the fulcrum portion 81 and the action point portion 82 in the radial direction. Further, the force point portion 83 is located radially inside the protruding portion 61c of the pressure plate 15. The force point portion 83 is a part of the pressurizing member 23 facing the tip of the pressing portion 62b of the pressing plate 62. The distance between the fulcrum portion 81 and the action point portion 82 is longer than the distance between the fulcrum portion 81 and the force point portion 83.

The pressure member 23 can swing with the fulcrum portion 81 as a fulcrum by elastically deforming. The pressurizing member 23 can be changed into the pressurizing state S3 shown in FIG. 1 and the releasing state S4 shown in FIG. 3 by swinging.

As shown in FIG. 2, in the pressurized state S3, the action point portion 82 contacts the contact surface 76a of the ring 76 and pushes the mass body 21 toward the clutch hub 13 along the axial direction. By pushing the mass body 21, the action point portion 82 pushes the disk 75 of the mass body 21 against the second friction surface 55a of the clutch hub 13 so that the rotation can be transmitted. That is, the pressurizing member 23 in the pressurizing state S3 urges the mass body 21 to the engaging position P3. The pressurizing member 23 is in the pressurizing state S3 in a natural state in which no external force acts.

As shown in FIG. 4, in the released state S4, the action point portion 82 is separated from the mass body 21. As a result, the mass body 21 can move from the engaging position P3 to the disengaging position P4. That is, the point of action 82 in the released state S4 is arranged at a position where the mass body 21 can move to the release position P4. The point of action 82 may come into contact with the mass 21 located at the release position P4.

In the power transmission mechanism 1 described above, the clutch C1 and the auxiliary clutch C2 are interlocked and engaged with and disengaged. Hereinafter, the engagement and disengagement of the clutch C1 and the auxiliary clutch C2 will be specifically illustrated.

As shown in FIG. 1, when the driver is not operating the clutch release device 18, the clutch release device 18 does not push the inner lever portion 71, and the diaphragm spring 16 is in the pressurized state S1. The pressure plate 15 pushed by the diaphragm spring 16 in the pressurized state S1 is arranged at the engaging position P1 and pushes the clutch disc 12 against the flywheel 4 so that the rotation can be transmitted. As a result, the clutch C1 is engaged, and the clutch disc 12 and the flywheel 4 can rotate integrally.

As shown in FIG. 2, when the pressure plate 15 is located at the engaging position P1, the pressing portion 62b of the pressing plate 62 is slightly separated from the force point portion 83 of the pressing member 23. As a result, the pressurizing member 23 is in the pressurizing state S3. The pressing plate 62 located at the engaging position P1 may come into contact with the force point portion 83.

The action point portion 82 of the pressurizing member 23 in the pressurized state S3 comes into contact with the ring 76 and pushes the mass body 21. The pressurizing member 23 urges the mass body 21 to the engaging position P3 and presses the disk 75 of the mass body 21 against the second friction surface 55a of the clutch hub 13 so as to transmit the rotation. As a result, the auxiliary clutch C2 is engaged, and the disc 75 of the mass body 21 and the clutch hub 13 can rotate integrally.

The clutch disc 12 can rotate integrally with the flywheel 4 and the clutch cover 11, and can also rotate integrally with the pressurizing member 23 supported by the support member 32 of the clutch cover 11. Therefore, the ring 76 in contact with the pressurizing member 23 can rotate integrally with the clutch disc 12.

The clutch disc 12 and the clutch hub 13 are relatively rotatable around the central axis Ax. Therefore, torque may be generated between the disc 75 that rotates integrally with the clutch hub 13 and the ring 76 that rotates integrally with the clutch disc 12. Since the bearing 77 is interposed between the disc 75 and the ring 76, the disc 75 and the ring 76 rotate relative to each other around the central axis Ax.

When the clutch C1 and the auxiliary clutch C2 are engaged, the diaphragm spring 16 pushes the pressure plate 15, and the pressurizing member 23 pushes the mass body 21. The diaphragm spring 16 and the pressurizing member 23 are independently supported by the clutch cover 11. Therefore, the load applied by the diaphragm spring 16 on the pressure plate 15 and the load applied by the pressurizing member 23 on the mass body 21 are independent of each other.

As shown in FIG. 3, when the driver operates the clutch release device 18, the clutch release device 18 pushes the inner lever portion 71. When the inner lever portion 71 is pushed, the diaphragm spring 16 is elastically deformed and changes from the pressurized state S1 to the released state S2. The pressure plate 15 pulled by the diaphragm spring 16 in the released state S2 moves from the engaging position P1 to the releasing position P2.

As shown in FIG. 4, when the pressure plate 15 moves to the release position P2, the pressure plate 15 separates from the clutch facing 45 of the clutch disc 12. As a result, the clutch disc 12 can be separated from the flywheel 4. For example, the air flowing through the groove of the clutch facing 45 pushes the clutch disc 12 in the axial direction, and the clutch disc 12 is separated from the flywheel 4. As a result, the clutch C1 is disengaged, and the clutch disc 12 and the flywheel 4 are separated from each other.

When the pressure plate 15 moves from the engaging position P1 to the disengaging position P2, the pressing portion 62b of the pressing plate 62 pushes the force point portion 83 of the pressing member 23. When the force point portion 83 is pushed, the pressure member 23 is elastically deformed and changes from the pressure state S3 to the release state S4. That is, by being pushed by the pressure plate 15 that moves from the engaging position P1 to the releasing position P2, the action point portion 82 is separated from the ring 76 of the mass body 21. As a result, the mass body 21 can be separated from the clutch hub 13. For example, the air flowing through the groove of the second friction surface 55a pushes the mass body 21 in the axial direction, and the mass body 21 moves from the engaging position P3 to the disengaging position P4 and separates from the clutch hub 13. As a result, the auxiliary clutch C2 is disengaged, and the mass body 21 and the clutch hub 13 are separated from each other.

As described above, the distance between the fulcrum portion 81 and the action point portion 82 is longer than the distance between the fulcrum portion 81 and the force point portion 83. Therefore, in the axial direction, the distance L1 between the mass body 21 located at the release position P4 and the second friction surface 55a, and the distance between the mass body 21 located at the release position P4 and the action point portion 82. The sum of L2 and L2 is longer than the movement amount L3 of the pressure plate 15 that has moved from the engagement position P1 to the release position P2. In other words, the movable amount of the mass body 21 with respect to the moving amount L3 of the pressure plate 15 becomes large.

As shown in FIG. 2, when the driver releases the operation of the clutch release device 18, the diaphragm spring 16 returns to the pressurized state S1 and moves the pressure plate 15 to the engaging position P1. Along with this, the pressing plate 62 is separated from the pressing member 23, and the pressing member 23 returns to the pressurized state S3. The pressurizing member 23 that has returned to the pressurizing state S3 moves the mass body 21 to the engaging position P3. As a result, the clutch C1 and the auxiliary clutch C2 are engaged again.

In the power transmission mechanism 1 according to the first embodiment described above, the pressurizing member 23 includes a fulcrum portion 81 supported by the clutch cover 11, an action point portion 82 that presses the mass body 21 against the clutch hub 13, and an action point portion 82. It has a force point portion 83 that is pushed by the pressure plate 15 that moves from the engagement position P1 to the release position P2, and the force point portion 83 is pushed by the pressure plate 15 that moves from the engagement position P1 to the release position P2. The point of action 82 is separated from the mass 21. By adjusting the positions of the fulcrum portion 81, the action point portion 82, and the force point portion 83, the movement amount of the action point portion 82 with respect to the movement amount L3 of the pressure plate 15 in FIG. 4 (movable amount L1 + L2 of the mass body 21) , The load for making the mass body 21 movable, and the load can be adjusted. For example, by increasing the amount of movement of the point of action 82 with respect to the amount of pressure plate 15 pushing the pressure member 23, the mass body 21 can be more reliably separated from the clutch hub 13, and the mass body 21 and the clutch hub 13 can be separated from each other. The connection can be reliably cut off. Further, by reducing the load applied by the pressure plate 15 to the pressurizing member 23 in order to move the action point portion 82, the driver can cut off the connection between the mass body 21 and the clutch hub 13 with a lighter force. As described above, according to the power transmission mechanism 1 of the present embodiment, the degree of freedom in designing the mechanism for engaging and disengaging the mass body 21 and the clutch hub 13 is improved. Further, since the pressurizing member 23 independent of the diaphragm spring 16 pushes the mass body 21, the reduction of the force with which the diaphragm spring 16 pushes the pressure plate 15 can be suppressed, and the flywheel 4 slides against the clutch disc 12, so-called dragging. Is suppressed.

The distance between the fulcrum portion 81 and the action point portion 82 is longer than the distance between the fulcrum portion 81 and the force point portion 83. Thereby, according to the principle of leverage, the amount of the action point portion 82 separated from the mass body 21 can be increased as compared with the amount of the pressure plate 15 pushing the force point portion 83. Therefore, the mass body 21 can be reliably separated from the pressurizing member 23 and the clutch hub 13, and the connection between the mass body 21 and the clutch hub 13 can be reliably cut off.

The point of action 82 comes into contact with the ring 76, which is rotatably supported relative to the disc 75 via the bearing 77. As a result, when the clutch cover 11 on which the pressurizing member 23 is supported and the clutch hub 13 on which the disc 75 is pressed rotate relative to the central axis Ax, the pressurizing member 23 and the mass body 21 are brought into contact with each other. Friction between them is suppressed. Therefore, damage to the pressurizing member 23 due to friction is suppressed.

The resin bush 22 supports the mass body 21 and the clutch hub 13 so as to be relatively rotatable and axially movable around the central axis Ax. As a result, the mass body 21 can smoothly rotate in the circumferential direction and move in the axial direction with respect to the clutch hub 13.

The pressurizing member 23 is a disc spring. As a result, the mass body 21 can be pressed against the clutch hub 13 by the elastic force of the pressure member 23, and the pressure member 23 can push the mass body 21 substantially uniformly in the circumferential direction. As a result, an increase in the cost of the power transmission mechanism 1 is suppressed, and the mass body 21 is suppressed from being tilted with respect to the central axis Ax.

(Second Embodiment)
The second embodiment will be described below with reference to FIG. In the following description of the (plurality) embodiments, the components having the same functions as the components already described are designated by the same reference numerals as those described above, and the description is omitted. There is. Further, the plurality of components with the same reference numerals do not necessarily have all the functions and properties in common, and may have different functions and properties according to each embodiment.

FIG. 5 is a cross-sectional view showing an example of the power transmission mechanism 1 in the engaged state according to the second embodiment. As shown in FIG. 5, in the second embodiment, the emphasis point portion 83 is the inner peripheral portion of the pressurizing member 23. The force point portion 83 is closer to the mass body 21 than the fulcrum portion 81 in the axial direction. The force point portion 83 is separated from the mass body 21.

In the second embodiment, the action point portion 82 is provided between the fulcrum portion 81 and the force point portion 83 in the radial direction. The distance between the fulcrum portion 81 and the action point portion 82 is shorter than the distance between the fulcrum portion 81 and the force point portion 83.

The point of action 82 is closer to the mass 21 than the fulcrum 81 and closer to the mass 21 than the point 83 in the axial direction. The point of action 82 comes into contact with the contact surface 76a of the ring 76, as in the first embodiment.

The pressurizing member 23 is provided with a plurality of holes 91. The holes 91 are provided between the inner peripheral portion of the support member 32 and the outer peripheral portion of the mass body 21 in the radial direction. The plurality of holes 91 are provided at substantially equal intervals in the circumferential direction.

In the second embodiment, the pressing plate 62 of the pressure plate 15 has a mounting portion 62a, a plurality of insertion portions 62c, a plurality of extending portions 62d, and a plurality of tension portions 62e. The mounting portion 62a is mounted on the mounting surface 61b of the friction plate 61 by the bolt 63 as in the first embodiment.

The insertion portion 62c extends substantially in the axial direction from the mounting portion 62a. The plurality of insertion portions 62c are arranged at substantially equal intervals in the circumferential direction, and are passed through the plurality of holes 91 of the pressurizing member 23. The insertion portion 62c is separated from the edge of the pressurizing member 23 that defines the hole 91.

The extension portion 62d is located between the pressurizing member 23 and the diaphragm spring 16 in the axial direction. The extension portion 62d extends radially inward from the insertion portion 62c. According to another expression, the extension portion 62d extends toward the emphasis point portion 83.

The tension portion 62e is connected to the extension portion 62d. The tip of the tension portion 62e is located between the mass body 21 and the force point portion 83 in the axial direction. The tip of the tension portion 62e is located in the vicinity of the force point portion 83.

In the power transmission mechanism 1 of the second embodiment, when the pressure plate 15 moves from the engaging position P1 to the disengaging position P2, the pulling portion 62e of the pressing plate 62 pushes (pulls) the force point portion 83 of the pressurizing member 23. .. When the force point portion 83 is pushed, the pressure member 23 is elastically deformed and changes from the pressure state S3 shown by the solid line in FIG. 5 to the release state S4 shown by the alternate long and short dash line. That is, by being pushed by the pressure plate 15 that moves from the engaging position P1 to the releasing position P2, the action point portion 82 is separated from the ring 76 of the mass body 21. As a result, the mass body 21 moves from the engaging position P3 to the disengaging position P4 and separates from the clutch hub 13.

As described above, the distance between the fulcrum portion 81 and the action point portion 82 is shorter than the distance between the fulcrum portion 81 and the force point portion 83. Therefore, the load exerted by the pressure plate 15 on the pressurizing member 23 to move the action point portion 82 is smaller than the load exerted on the mass body 21 by the pressurizing member 23 in the pressurizing state S3.

In the power transmission mechanism 1 of the second embodiment described above, the distance between the fulcrum portion 81 and the action point portion 82 is shorter than the distance between the fulcrum portion 81 and the power point portion 83. As a result, the load applied by the pressure plate 15 to the force point portion 83 in order to separate the action point portion 82 from the mass body 21 can be made smaller. Therefore, the driver can cut off the connection between the mass body 21 and the clutch hub 13 with a lighter force.

Although the embodiments of the present invention have been illustrated above, the above-described embodiments and modifications are merely examples, and the scope of the invention is not intended to be limited. The above-described embodiment and modification can be implemented in various other forms, and various omissions, replacements, combinations, and changes can be made without departing from the gist of the invention. Further, the configuration and shape of each embodiment and each modification can be partially replaced.

1 ... Power transmission mechanism, 4 ... Flywheel, 11 ... Clutch cover, 12 ... Clutch disc, 13 ... Clutch hub, 14 ... Damper spring, 15 ... Pressure plate, 16 ... Diaphragm spring, 21 ... Mass body, 22 ... Resin bush , 23 ... Pressurizing member, 75 ... Disc, 76 ... Ring, 77 ... Bearing, 81 ... Support point, 82 ... Action point, 83 ... Power point, Ax ... Central axis, P1 ... Engagement position, P2 ... Release position ..

Claims (5)

A clutch cover that is attached to the flywheel and can rotate around the center of rotation,
A clutch disc that can rotate around the center of rotation and can move in the axial direction with respect to the clutch cover.
A clutch hub that can rotate around the center of rotation with respect to the clutch disc,
A spring located between the clutch disc and the clutch hub in the circumferential direction and compressed by the relative rotation of the clutch disc and the clutch hub.
A pressure plate that can be moved to a first position for pressing the clutch disc against the flywheel and a second position for separating the clutch disc from the flywheel.
A diaphragm spring that urges the pressure plate to the first position, and
A mass body that can rotate around the center of rotation and move in the axial direction with respect to the clutch hub.
It is pushed by the fulcrum portion supported by the clutch cover, the action point portion that presses the mass body so as to transmit rotation to the clutch hub, and the pressure plate that moves from the first position to the second position. A pressurizing member having a force point portion and having the force point portion separated from the mass body by being pushed by the pressure plate that moves from the first position to the second position. ,
A power transmission mechanism equipped with. The power transmission mechanism according to claim 1, wherein the distance between the fulcrum portion and the action point portion is longer than the distance between the fulcrum portion and the force point portion. The power transmission mechanism according to claim 1, wherein the distance between the fulcrum portion and the action point portion is shorter than the distance between the fulcrum portion and the force point portion. The mass body is formed between a first member pressed against the clutch hub, a second member in contact with the action point portion of the pressurizing member, and between the first member and the second member. A power transmission mechanism according to any one of claims 1 to 3, further comprising a bearing that rotatably supports the first member and the second member around the center of rotation. .. A resin bush, which is interposed between the mass body and the clutch hub, and supports the mass body and the clutch hub so as to be relatively rotatable around the center of rotation and relatively movable in the axial direction. The power transmission mechanism according to any one of claims 1 to 4, further comprising.

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