JP4022358B2 - Clutch device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a clutch device, and more particularly to a clutch device capable of separately performing torque transmission / cut-off operation from an engine crankshaft to a first and second input shafts of a transmission.
[0002]
[Prior art]
The clutch device is a device for transmitting torque from the crankshaft of the engine to the transmission and interrupting the torque transmission as necessary. The clutch device is adapted for friction between the flywheel fixed to the crankshaft and the friction surface of the flywheel. The clutch disk assembly includes a coupling portion, and a clutch operation mechanism that is fixed to the flywheel and biases the friction coupling portion to the friction surface of the flywheel and releases the biasing as necessary.
[0003]
In the clutch device, there is a double clutch capable of separately transmitting torque or blocking torque transmission to two input shafts extending from the transmission. Such a double clutch has a friction coupling member to which torque is input from the crankshaft of the engine. A first friction surface is formed on the axial engine side of the friction coupling member, and a second friction surface is formed on the axial transmission side. Further, a first friction coupling portion of the first clutch disk assembly is disposed in the vicinity of the first friction surface. The first clutch disk assembly is connected to the first input shaft. A second friction coupling portion of the second clutch disk assembly is disposed in the vicinity of the second friction surface. The second clutch disk assembly is connected to the second input shaft. Further, a clutch operating mechanism is provided for operating connection / disconnection of both clutch disk assemblies. The clutch operation mechanism includes a cover member, a pressure plate, an elastic member that is supported by the cover member and urges the pressure plate toward the friction coupling portion.
[0004]
A damper mechanism for absorbing and attenuating torque fluctuations from the engine is disposed, for example, between the friction coupling member and the engine-side member. The damper mechanism generally has an input side member fixed to the engine side member, an output side member fixed to the clutch operation mechanism side, and an elastic member for elastically connecting the two members in the rotational direction. is doing.
[0005]
[Problems to be solved by the invention]
When the conventional clutch device is assembled, the damper mechanism is previously attached to one of the clutch device and the engine-side member. When the engine is assembled to the transmission in this state, the damper mechanism is fixed to the other of the clutch device and the engine-side member with bolts or rivets.
[0006]
Thus, since it is necessary to use fastening members, such as a volt | bolt and a rivet, at the time of the assembly | attachment of a clutch apparatus, the assembly workability | operativity falls.
An object of the present invention is to improve the assembly of the clutch device.
[0007]
[Means for Solving the Problems]
The clutch device according to claim 1 can perform torque transmission / cut-off operation separately from the crankshaft of the engine to the first and second input shafts of the transmission. A first clutch disk assembly, a second clutch disk assembly, a clutch operating mechanism, and a damper mechanism are provided. The friction coupling member has a first friction surface on the axial engine side and a second friction surface on the axial transmission side, and torque is input from the crankshaft. The first clutch disk assembly has a first friction coupling portion disposed in proximity to the first friction surface, and can transmit torque to the first input shaft. The second clutch disk assembly has a second friction coupling portion disposed in proximity to the second friction surface, and can transmit torque to the second input shaft. The clutch operating mechanism is attached to the friction coupling member, and can connect and disconnect the first friction coupling portion and the second friction coupling portion separately from the friction coupling member. The damper mechanism is a mechanism for elastically connecting the clutch operating mechanism directly to the crankshaft in the rotational direction. The clutch operating mechanism includes a first elastic member that generates an urging force for connecting the first friction connecting portion to the friction connecting member, and a first elastic member that generates an urging force for connecting the second friction connecting portion to the friction connecting member. And connecting the first friction connecting portion and the second friction connecting portion by applying a load obtained by hydraulic pressure to the first elastic member and the second elastic member on the same side in the axial direction. Are released separately.
[0008]
In this clutch device, the structure is simplified because the clutch cover is connected to the crankshaft via a damper mechanism.
According to a second aspect of the present invention, in the clutch device according to the first aspect, the damper mechanism includes an elastic member that is held by one of the crankshaft and the clutch operating mechanism and is detachably engaged with the other in the axial direction.
[0009]
In this clutch device, the clutch device can be assembled by approaching the crankshaft in the axial direction. That is, the assembling property is improved as compared with the conventional case.
According to a third aspect of the present invention, in the clutch device according to the second aspect, the damper mechanism includes a disk-shaped plate member disposed on the axial engine side at the tip of the crankshaft, both circumferential ends and the axial transmission by the plate member. And a drive member fixed to the crankshaft having an abutting portion detachable from the axial direction at both ends in the circumferential direction of the elastic member.
[0010]
In this clutch device, the elastic member is held in advance by the plate member, and when assembled, the contact portion of the drive member is engaged with both ends in the circumferential direction of the elastic member from the axial direction. Thus, the assembling property is improved.
According to a fourth aspect of the present invention, in the clutch device according to the third aspect, the plate member has a holding portion for holding the elastic member in the axial direction engine side.
[0011]
In this clutch device, the elastic member cannot be detached from the plate member by the holding portion.
According to a fifth aspect of the present invention, in the clutch device according to the third or fourth aspect, the clutch operating mechanism includes a pressure plate disposed on the engine side in the axial direction of the first clutch disk assembly, and a pressure plate supported by the plate member. An urging member for urging the disc side is provided.
[0012]
In this clutch device, since the plate member has a role of holding the elastic member and a role of supporting the urging member, the total number of parts is reduced.
In the clutch device according to a sixth aspect, in the fourth aspect, the elastic member is disposed on the inner peripheral side of the pressure plate.
In this clutch device, since the elastic member is disposed on the inner peripheral side of the pressure plate, the radial dimension can be reduced while suppressing the overall axial dimension.
[0013]
In the clutch device according to a seventh aspect, in any one of the third to sixth aspects, the plate member has an outer peripheral end fixed to the friction coupling member and an inner peripheral end rotatably supported by the crankshaft. In this clutch device, when bending vibration is transmitted from the engine side, the plate member can absorb vibration by bending in the bending direction .
[0014]
DETAILED DESCRIPTION OF THE INVENTION
1st Embodiment The longitudinal cross-sectional schematic of the clutch apparatus 1 as one Embodiment of this invention is shown in FIG.
The clutch device 1 is a device for transmitting and interrupting torque from the crankshaft 2 of the engine to the first and second input shafts 3 and 4 of the transmission. An engine (not shown) is arranged on the left side of FIG. 1, and a transmission (not shown) is arranged on the right side of FIG. The first input shaft 3 is a cylindrical shaft extending from the transmission side. The tip of the first input shaft 3 extends to the vicinity of the tip of the crankshaft 2. The second input shaft 4 is a substantially cylindrical shaft extending around the first input shaft 3 from the transmission side. The distal end of the second input shaft 4 is located closer to the axial transmission side than the first input shaft 3. A plurality of spline teeth extending in the axial direction are formed on the outer peripheral surfaces of both the input shafts 3 and 4.
[0015]
The clutch device 1 mainly includes a mass body 5, a friction coupling member 6, a first clutch disk assembly 7, a second clutch disk assembly 8, a first clutch operation mechanism 9, and a second clutch operation mechanism. 10.
The mass body 5 is fixed to the tip of the crankshaft 2. The mass body 5 is a member for securing a large moment of inertia on the crankshaft 2 side. The mass body 5 includes a disk-shaped member 12 and an annular member 13. The disc-like member 12 has an inner peripheral end fixed to the tip of the crankshaft 2 by a plurality of bolts 15. The bolt 15 is attached from the axial transmission side. The inner peripheral edge of the disk-shaped member 12 is in contact with the outer peripheral surface of the annular projecting portion 2 a formed on the tip surface of the crankshaft 2. The annular member 13 is fixed to the outer peripheral end axial transmission side of the disc-like member 12. The annular member 13 is an inertia member having a large axial thickness. The annular member 13 is fixed to the disc-like member 12 by a plurality of bolts 16 arranged in the circumferential direction. The bolt 16 is attached from the axial direction engine side. Further, an engine starting ring gear 17 is fixed to the outer peripheral edge of the disk-shaped member 12. In addition, the mass body may be comprised from the integral member.
[0016]
The frictional connection member 6 is a disk-like and annular member that is disposed on the transmission side of the mass body 5 at an interval. The outer diameter of the friction coupling member 6 is substantially equal to the outer diameter of the mass body 5. However, the inner diameter of the friction coupling member 6 is larger than the inner diameter of the mass body 5. The friction coupling member 6 has a first friction surface 6a on the axial engine side and a second friction surface 6b on the axial transmission side.
[0017]
A plurality of axial through-holes 19 are formed in the circumferential direction in the portion on the outer peripheral side of the friction surfaces 6 a and 6 b of the friction coupling member 6.
The second clutch cover 71 is a generally annular member made of sheet metal. The second clutch cover 71 is fixed so as to rotate integrally with the friction coupling member 6 and a first clutch cover 28 described later by a bolt (not shown). The second clutch cover 71 is composed of a first member 72 and a second member 73. The first member 72 includes an annular part 74 and a first extension part 75 and a second extension part 76 that extend from the annular part 74 toward the axial transmission side. The annular portion 74 is in contact with the outer peripheral portion axial transmission side of the friction coupling member 6. Further, the annular portion 74 is formed with a hole through which the aforementioned bolt passes. As shown in FIG.2 and FIG.4, the 1st extension part 75 and the 2nd extension part 76 are alternately formed in the rotation direction. The first extension 75 extends substantially straight in the axial direction. A second member 73 is fixed to the tip of the first extension portion 75. The second member 73 is a substantially annular member made of a sheet metal member, and has a generally cylindrical portion 77 extending from the first extension 75 to the axial transmission side, and a disk-shaped portion 78 extending from the tip to the inner peripheral side. have. The disc-shaped portion 78 is formed with an annular support portion 79 that protrudes toward the axial engine side. The second extension portion 76 extends to the inner peripheral side compared to the first extension portion 75. Accordingly, the second extension portion 76 is located on the axial direction engine side with respect to the second member 73. The second extension 76 is formed with a support portion 80 that protrudes toward the axial engine side.
[0018]
The first clutch disk assembly 7 is a mechanism for outputting torque to the first input shaft 3. The first clutch disk assembly 7 has a first friction coupling portion 21 on the outer peripheral side. The first friction coupling portion 21 is disposed in the vicinity of the first friction surface 6 a of the friction coupling member 6, that is, on the axial direction engine side of the friction coupling member 6. Further, the hub 23 of the first clutch disc assembly 7 is spline engaged with the first input shaft 3.
[0019]
Next, the first clutch operation mechanism 9 will be described. The first clutch operating mechanism 9 is a mechanism for biasing the first friction coupling portion 21 to the friction coupling member 6 and releasing the biasing force as necessary. The first clutch operation mechanism 9 includes a clutch cover assembly 27 and a release mechanism 51.
The clutch cover assembly 27 is attached to the axial engine side with respect to the friction coupling member 6, and mainly includes an outer peripheral side portion 29 of the first clutch cover 28, a first pressure plate 31, and a cone spring 32. Has been.
[0020]
The first clutch cover 28 is a disk-like and annular plate member that is disposed in the vicinity of the mass body 5 on the axial transmission side. The outer diameter of the first clutch cover 28 is substantially equal to the outer diameter of the annular member 13, but the inner diameter is smaller than the inner diameter of the disk-shaped member 12. The first clutch cover 28 is divided into an outer peripheral portion 29 and an inner peripheral portion 30 in the middle in the radial direction. The outer peripheral side portion 29 is bent so as to protrude toward the axial direction engine side, and a space is secured between the friction connecting member 6 and the axial direction. Further, the inner peripheral side portion 30 is bent so as to protrude toward the axial transmission side, and a space is secured between the disc-like member 12 and the axial direction. The outermost peripheral edge portion 34 of the outer peripheral side portion 29 is fixed to the outer peripheral portion of the friction coupling member 6 by a bolt or the like (not shown). The inner peripheral end of the inner peripheral portion 30 is composed of a cylindrical portion 35 and a flange 36 extending from the tip to the inner peripheral side. The outer peripheral surface of the cylindrical portion 35 is in contact with the inner peripheral surface of the annular projecting portion 2a of the crankshaft 2, and the flange 36 is connected to the axial end surface 2b of the crankshaft 2 on the inner peripheral side from the annular projecting portion 2a from the axial transmission side. It is in contact. Thus, the inner peripheral end of the first clutch cover 28 is positioned in the radial direction and the axial direction with respect to the crankshaft 2. Further, a bearing 38 is disposed between the cylindrical portion 35 and the input shaft 3. The bearing 38 is a radial bearing composed of an inner race, an outer race, and a plurality of rolling elements, and supports the input shaft 3 rotatably with respect to the crankshaft 2 and the first clutch cover 28.
[0021]
The first pressure plate 31 is an annular member disposed on the axial direction engine side of the first friction coupling portion 21. The first pressure plate 31 has an annular and flat pressing surface 31 a that faces the first friction coupling portion 21. The first pressure plate 31 is fixed to the first clutch cover 28 or the friction coupling member 6 so as to rotate integrally with the first clutch cover 28 or the friction coupling member 6 by a plate or the like not shown.
[0022]
The cone spring 32 is disposed between the outer peripheral side portion 29 and the first pressure plate 31 in the axial direction. An outer peripheral end of the cone spring 32 is supported by an annular support portion 31 c of the first pressure plate 31, and an inner peripheral end thereof is supported by an annular support portion 40 formed on the first clutch cover 28. In this state, the cone spring 32 is elastically deformed in the axial direction, thereby applying a force for urging the first pressure plate 31 toward the axial transmission side. Further, the inner peripheral surface of the cone spring 32 is supported by the outer peripheral surface of the cylindrical portion formed in the first clutch cover 28 and is positioned in the radial direction. The type of the urging member is not limited to the cone spring.
[0023]
The damper mechanism 41 is a mechanism for elastically connecting the first clutch operating mechanism 9 to the crankshaft 2 in the rotational direction. The damper mechanism 41 includes a drive member 43, an inner peripheral side portion 30 of the first clutch cover 28, and a plurality of elastic members 44.
The drive member 43 is an annular plate member, and is fixed to the tip of the crankshaft 2 by the plurality of bolts 15 described above. The drive member 43 includes an annular portion 43a that contacts the axial transmission side of the inner peripheral end of the disk-shaped member 12, and a plurality of contact portions 43b that extend from the outer periphery to the axial transmission side.
[0024]
A plurality of spring holding portions 45 extending in the circumferential direction are formed on the inner peripheral side portion 30 of the first clutch cover 28. The spring holding portion 45 is a protruding portion formed by drawing so as to protrude toward the axial transmission side as compared with other portions, and is recessed toward the axial engine side. Concave portions 46 that are shorter in the radial direction than the spring holding portions 45 are formed between the circumferential directions of the spring holding portions 45.
[0025]
Each elastic member 44 is a coil spring that extends long in the circumferential direction, and is accommodated in the spring holding portion 45. Spring seats 47 are disposed at both ends of the elastic member 44 in the circumferential direction. The spring seats 47 support both ends of the elastic members 44 in the circumferential direction and support surfaces 45a formed on both sides in the radial direction of the recesses 46. It is in contact. The spring seat 47 includes a support portion that supports the elastic member 44 and a protruding portion that extends from the support portion into the coil of the elastic member 44. Here, the contact portion 43 b of the drive member 43 described above extends into the recess 46, and both circumferential ends thereof are in contact with or close to the back surface of the support portion of the spring seat 47. In this way, the torque of the drive member 43 is transmitted to the first clutch cover 28 via the elastic member 44. Further, an arc-shaped or annular holding plate 48 is fixed to the outer peripheral side portion of the spring holding portion 45 by a plurality of rivets 49. The holding plate 48 supports the axial engine side on the radially outer side of the elastic member 44. As a result, the elastic member 44 is held by the first clutch cover 28 and does not fall off in the axial direction. Further, the contact portion 43b of the drive member 43 can be engaged or disengaged only by movement from the axial direction with respect to the held elastic member 44. The type of the elastic member is not limited to the coil spring, and the elastic member may be a bent plate spring or other spring or elastic body in which a plurality of spring elements are formed by bending a plate-like member.
[0026]
As described above, in the first clutch cover 28, the inner peripheral side portion 30 constitutes the output side member of the damper mechanism 41, and the outer peripheral side portion 29 constitutes the spring support portion of the first clutch operating mechanism 9. Yes. Thus, the number of parts as a whole is reduced by giving a plurality of functions to one member. Further, the first pressure plate 31 and the cone spring 32 are accommodated in a concave portion formed in the outer peripheral portion 29 facing the axial transmission side, and further in the concave portion formed in the inner peripheral portion 30 facing the axial engine side. Since the elastic member 44, the drive member 43, and the head of the bolt 15 are accommodated, the structure is compact in the radial direction and the axial direction. In particular, a structure in which the elastic member 44 is disposed on the inner peripheral side of the first pressure plate 31 is effective. Here, for example, if the elastic member 44 of the damper mechanism 41 is arranged on the axial engine side of the first pressure plate 31, the axial dimension of the entire apparatus becomes large, or the elastic member 44 has a radius of the first pressure plate 31. If it is arranged on the outer side in the direction, the radial dimension of the entire apparatus becomes large.
[0027]
The first clutch cover 28 is made of a thin metal plate in the axial direction, and can be elastically deformed in the axial direction. The first clutch cover 28 has an inner peripheral portion supported by the crankshaft 2, and the friction coupling member 6, the first clutch operating mechanism 9, and the second clutch operating mechanism 10 are mounted on the outer peripheral portion. When is input, it functions as a flexible plate that absorbs bending vibrations by bending in the bending direction as a whole.
[0028]
The release mechanism 51 is mainly composed of a release member 52 and a lever member 53. The release member 52 includes a drive member 54 and a support portion forming member 55. As shown in FIG. 3, the drive member 54 is a substantially cylindrical member extending in the axial direction, and includes an annular seat 58 and a plurality of axial extensions 59 extending from the seat 58 to the axial transmission side. It is configured. The axially engine side end of the seating portion 58 is in contact with a groove 31 b formed on the outer peripheral edge of the first pressure plate 31 on the axial transmission side. Further, the inner peripheral surface on the front end side of the seating portion 58 is in contact with the outer peripheral surface of the groove 31b and is positioned in the radial direction. By providing the annular seating portion 58 in this manner, the posture of the release member 52 with respect to the first pressure plate 31 is stabilized. As shown in FIGS. 1 and 2, the axially extending portion 59 penetrates through the axial through hole 19 of the frictional connection member 6 in the axial direction, and the tip is from the end of the frictional connection member 6 on the axial transmission side. It protrudes further. The tip of the axial extension 59 is a bent portion 60 that is bent inward in the radial direction and further extends in the axial direction. The support portion forming member 55 is a member for forming an annular support portion on the release member 52, and can be easily attached to and detached from the drive member 54 from the axial transmission. The support portion forming member 55 is a substantially annular sheet metal member, and includes a disc-shaped portion 61 and a cylindrical portion 62 that extends from the outer peripheral end to the axial transmission side. The disc-like portion 61 is formed with an annular support portion 64 that protrudes toward the axial transmission side. The tip of the cylindrical part 62 protrudes to the outer peripheral side of the bent part 60. In addition, the tubular portion 62 is formed with a bent portion 63 that is cut and bent to contact the inner peripheral side of the bent portion 60. The bent portion 63 is located in the middle of the rotation direction of the bent portion 60. In this way, the bent portion 60 is sandwiched between the radial direction of the tubular portion 62 and the bent portion 63, whereby the support portion forming member 55 is axially transmitted with respect to the tip of each axial extension portion 59. It is detachable on the side, but is engaged so as to be immovable in the radial direction and other directions.
[0029]
The lever member 53 is an annular and disk-shaped plate member. It is preferable that the lever member 53 has only an elastic function by a slit formed alternately from an inner peripheral edge and an outer peripheral edge in a disk-shaped plate, for example, and simply functions as a lever. The outer peripheral portion of the lever member 53 is in contact with the support portion 64 of the support portion forming member 55 from the axial transmission side, and the inner peripheral portion is in contact with the support portion 79 of the second clutch cover 71 from the axial engine side. ing. In the structure described above, when the inner peripheral end of the lever member 53 is moved to the axial transmission side, the outer peripheral end of the lever member 53 rotates to the axial engine side with the support portion 79 of the second clutch cover 71 as a fulcrum. The release member 52 is moved to the axial direction engine side. As a result, the first pressure plate 31 overcomes the urging force from the cone spring 32 and moves away from the first friction coupling portion 21.
[0030]
The first drive mechanism 84 is a mechanism for performing a clutch release operation with respect to the first clutch disk assembly 7 by driving the lever member 53 of the first clutch operation mechanism 9. The first drive mechanism 84 mainly includes a release bearing 85, a hydraulic cylinder 86, and a first hydraulic circuit 87. The release bearing 85 mainly includes an inner race, an outer race, and a plurality of rolling elements disposed therebetween, and can receive a radial load and a thrust load. A cylindrical retainer 88 is attached to the outer race of the release bearing 85. The retainer 88 includes a cylindrical portion that contacts the outer peripheral surface of the outer race, a first flange that extends radially inward from the axial engine side end of the cylindrical portion, and that contacts the axial transmission side surface of the outer race, and the cylindrical portion. And a second flange extending radially outward from the axial engine side end. The second flange is formed with an annular support portion that contacts the radially inner end of the lever member 53 from the axial engine side.
[0031]
The hydraulic cylinder 86 is mainly composed of a hydraulic chamber constituent member 89 and a piston 90. The hydraulic chamber constituting member 89 constitutes a hydraulic chamber between it and a cylindrical piston 90 arranged on the inner peripheral side thereof. Hydraulic pressure can be supplied from the first hydraulic circuit 87 into the hydraulic chamber. The piston 90 is a substantially cylindrical member, and the inner peripheral surface thereof is supported by a hydraulic cylinder 99 described later. Further, the piston 90 has a flange that comes into contact with the inner race of the release bearing 85 from the axial transmission side. In this state, when the hydraulic oil in the hydraulic chamber is drained from the first hydraulic circuit 87, the piston 90 moves the release bearing 85 to the axial transmission side.
[0032]
The second clutch disk assembly 8 is a mechanism for outputting torque to the second input shaft 4 of the transmission. The second clutch disk assembly 8 has a second friction coupling portion 22 on the outer periphery thereof. The second friction coupling portion 22 is disposed in the vicinity of the second friction surface 6 b of the friction coupling member 6, that is, on the axial transmission side of the friction coupling member 6. The hub 24 of the second clutch disk assembly 8 is splined to the second input shaft 4.
[0033]
Next, the second clutch operation mechanism 10 (clutch cover assembly) will be described. The second clutch operating mechanism 10 is a mechanism for urging the second friction coupling portion 22 of the second clutch disk assembly 8 with respect to the friction coupling member 6 and releasing the bias. The second clutch operation mechanism 10 mainly includes a second pressure plate 92 and a diaphragm spring 93. The second pressure plate 92 is an annular member disposed close to the axial transmission side of the second friction coupling portion 22 of the second clutch disk assembly 8. The second pressure plate 92 is fixed so as to rotate integrally with the second clutch cover 71 or the friction coupling member 6 by a plate or the like (not shown) and to be movable in the axial direction. The second pressure plate 92 has an annular and flat friction surface 92a on the second friction connecting portion 22 side. The diaphragm spring 93 is a substantially disc-shaped and annular plate member, and has an outer peripheral elastic portion 93a and a plurality of lever portions 93b extending from the inner peripheral end to the inner peripheral side. The elastic portion 93 a has an outer peripheral end supported by the support portion 80 of the second clutch cover 71 and an inner peripheral end supported by the support portion 92 b of the second pressure plate 92. The elastic portion 93a is compressed in the axial direction, thereby applying a biasing force toward the axial engine side to the second pressure plate 92. A biasing plate 96 is fixed to the axial transmission side of the second pressure plate 92 by a bolt 96a. The urging plate 96 extends between the plurality of lever portions 93b, and abuts against the inner peripheral end of the elastic portion 93a from the axial transmission side to urge the second pressure plate 92. As a result, when the inner peripheral end of the lever portion 93b is moved to the axial transmission side, the inner peripheral end of the elastic portion 93a is moved to the axial transmission side accordingly, and the urging force to the second pressure plate 92 is released. At the same time, the second pressure plate 92 is moved along the axial transmission side.
[0034]
The second drive mechanism 97 is a mechanism for performing a clutch release operation with respect to the second clutch disk assembly 8 by driving the diaphragm spring 93 of the second clutch operation mechanism 10. The second drive mechanism 97 mainly includes a release bearing 98, a hydraulic cylinder 99, and a second hydraulic circuit 100. The release bearing 98 is mainly composed of an inner race, an outer race, and a plurality of rolling elements disposed therebetween, and can receive a radial load and a thrust load. A cylindrical retainer 101 is attached to the outer race of the release bearing 98. The retainer 101 includes a cylindrical portion that contacts the outer periphery of the outer race, a first flange that extends radially outward from the axial engine side end of the cylindrical portion, and a radially inner side from the axial transmission side end of the cylindrical portion. And a second flange that contacts the surface of the outer race on the axial transmission side. The first flange is formed with an annular support portion that comes into contact with the radially inner end of the lever portion 93b from the axial engine side. The hydraulic cylinder 99 includes a piston 102 and a hydraulic chamber constituent member 103. The hydraulic chamber constituting member 103 constitutes a hydraulic chamber between the piston 102 arranged on the inner peripheral side thereof. Hydraulic pressure can be supplied from the second hydraulic circuit 100 into the hydraulic chamber. The piston 102 is a cylindrical member, and an inner peripheral surface thereof is supported by an outer peripheral surface of a member (not shown) extending from the transmission side. Further, the piston 102 has a flange that comes into contact with the inner race of the release bearing 98 from the axial transmission side. When the hydraulic oil in the hydraulic chamber is drained from the second hydraulic circuit 100 in this state, the piston 102 moves to the axial transmission side to move the release bearing 98.
[0035]
As described above, the first clutch operating mechanism 9 and the second clutch operating mechanism 10 are driven by the independent first and second drive mechanisms 84 and 97, respectively.
Further, in the clutch cover assembly 27 of the first clutch operating mechanism 9, the urging force to the first pressure plate 31 is given by the cone spring 32 which is a spring member, so that the friction coupling member 6 and the first clutch cover 28 are applied. There is no need to form an oil passage or a hydraulic oil chamber in the corresponding structure. Therefore, the entire structure of the clutch device 1 is simplified, the number of parts is reduced, and the overall size can be reduced.
[0036]
In particular, the second clutch cover 71 has a support portion 79 for the first clutch operation mechanism 9 and a support portion 80 for the second clutch operation mechanism 10 even though the second clutch cover 71 is an integral member as a whole. Therefore, the structure is simple and the increase in the number of parts can be suppressed, contributing to space saving.
Further, the annular member 13 described above is disposed further on the outer peripheral side of the outer peripheral side portion 29 of the first clutch cover 28, and ensures a sufficient moment of inertia without increasing the axial and radial dimensions of the clutch device 1. ing.
[0037]
As described above, most of the clutch device 1 is directly connected to the crankshaft 2 via the damper mechanism 41. For this reason, the structure of the damper mechanism 41 is simple and compact, and the assembly workability is improved. Here, “direct connection” means that the connection is made without any other member such as a flywheel.
[0038]
Next, the assembly operation of the clutch device 1 will be described. As shown in FIG. 6, as a configuration on the engine side, the mass body 5 and the drive member 43 are fixed in advance to the tip of the crankshaft 2 by bolts 15. An elastic member 44 is attached to the first clutch cover 28 in advance. This means that the elastic member 44 mainly constituting the damper mechanism 41 is mounted in advance on a part of the clutch device 1, that is, the first clutch cover 28 before the assembly operation. For this reason, transportation and storage of the clutch device 1 before assembly are convenient.
[0039]
From this state, for example, the engine and the crankshaft 2 are moved to the axial transmission side. Then, the contact portion 43b of the drive member 43 is inserted between the circumferential direction of each elastic member 44 from the axial transmission side, more specifically, between the spring seats 47. When the axial end surface 2b of the crankshaft 2 comes into contact with the flange 36 of the first clutch cover 28, the relative movement of both of them stops. As described above, the operation of assembling the clutch device 1 to the crankshaft 2 is completed only by moving the members on both sides in the axial direction, and does not require fastening members such as bolts and rivets. Thus, the work at the time of assembling the clutch device 1 is simplified, and the assembling work can be performed in a short time. In short, the assembling property of the clutch device 1 is improved.
Second embodiment Fig. 7 is a schematic longitudinal sectional view of a clutch device 1 as a second embodiment of the present invention. Since the basic structure of the clutch device 1 is the same as that of the above embodiment, only different points will be described here.
[0040]
An extension 88 a extending to the axial transmission side is further formed in the cylindrical portion of the retainer 88. Thus, the retainer 88 is formed with an outer peripheral surface 88b that is long in the axial direction.
The disc-shaped portion 78 of the second clutch cover 71 extends further to the inner peripheral side than the above embodiment, and forms an inner peripheral side portion 81. The inner diameter of the inner peripheral side portion 81 is substantially equal to the inner diameter of the lever member 53 and is located in the vicinity of the release bearing 85. A plurality of holes 81 a are formed in the inner peripheral side portion 81. Further, a cylindrical portion 82 extending toward the axial engine side is formed on the inner peripheral edge of the inner peripheral side portion 81. A tubular member 83 is fixed to the inner peripheral side of the tubular portion 82. The inner peripheral surface of the cylindrical member 83 is supported by the outer peripheral surface 88 b of the retainer 88. Here, the second clutch cover 71 is a member that is disposed closest to the transmission side in an integrated configuration including the first clutch cover 28, the friction coupling member 6, and the second clutch cover 71, and the member is the other member on the transmission side. It is supported by the member. As a result, the entire clutch device 1 is less likely to tilt due to bending vibration from the engine, and the resonance phenomenon that occurs due to bending vibration of the engine can be suppressed. Thereby, the plate | board thickness of the 1st clutch cover 28 can be made small, for example.
[0041]
Further, since the release bearing 85 is used as a member for supporting the inner peripheral end of the second clutch cover 71, a special part and a space for it are unnecessary. Furthermore, by attaching the cylindrical member 83 that is long in the axial direction to the inner peripheral side portion 81, the axial contact length between the inner peripheral surface of the second clutch cover 71 and another member can be increased. The clutch cover 71 is less inclined. Further, by using a material having a low coefficient of friction for the cylindrical member 83, the sliding resistance between the contact portions can be reduced when the release bearing 85 moves in the axial direction.
Third embodiment Fig. 8 is a schematic longitudinal sectional view of a clutch device 1 as a third embodiment of the present invention. Since the basic structure of the clutch device 1 of this embodiment is the same as that of the first embodiment, only different points will be described here.
[0042]
In both the embodiments, the first and second clutch operating mechanisms have a structure in which the drive mechanism performs a clutch release operation by pulling out a lever member or the like toward the axial transmission side, but in the present embodiment, the first and second clutch operating mechanisms are configured. The operation mechanism has a structure in which a clutch release operation is performed when the drive mechanism pushes a lever member or the like toward the axial direction engine.
[0043]
The second extension 76 ′ of the second clutch cover 71 ′ extends further to the inner peripheral side than the above-described embodiment, and its tip is bent so as to be wound on the axial engine side. The elastic part 93a ′ of the diaphragm spring 93 ′ is supported at the tip end of the second extension part 76 ′ via a wire ring so as to be swingable. The outer peripheral portion of the elastic portion 93a ′ is in contact with the support portion 92b of the second pressure plate 92.
[0044]
The retainer 101 ′ provided on the outer race of the release bearing 98 ′ has a cylindrical portion that contacts the outer peripheral surface of the outer race, and protrudes from the axial engine side end of the cylindrical portion to the inner peripheral side, and the axial engine side surface of the outer race. And a second flange extending from the cylindrical portion to the outer peripheral side. The second flange is in contact with the inner peripheral end of the diaphragm spring 93 'from the axial transmission side.
[0045]
The annular support portion 79 ′ in the second clutch cover 71 ′ is located on the outer peripheral side compared to the annular support portion 79 of the first embodiment. Further, the annular support portion 64 ′ of the support portion forming member 55 ′ is located on the inner peripheral side compared to the annular support portion 64 of the first embodiment. As a result, the outer peripheral end of the lever member 53 ′ abuts against the annular support portion 79 ′ from the axial engine side, and the inner peripheral portion abuts against the annular support portion 64 ′ from the axial transmission side. Yes.
[0046]
The retainer 88 ′ provided on the outer race of the release bearing 85 ′ has a cylindrical portion that abuts on the outer peripheral surface of the outer race, and protrudes from the axial engine side end of the cylindrical portion toward the inner peripheral side so that the axial side surface of the outer race. And a second flange extending from the cylindrical portion to the outer peripheral side. The second flange is in contact with the inner peripheral end of the lever member 53 'from the axial transmission side.
[0047]
Further, a friction facing 94 is bonded to the axially engine side of the flat annular portion in the outer peripheral side portion 29 of the first clutch cover 28. The friction facing 94 faces the flat surface of the disk-shaped member 12 in the axial direction. In the clutch engagement state shown in FIG. 8, a gap is secured between the axial direction of the friction facing 94 and the disc-like member 12. The friction facing 94 and the disk-like member 12 described above form a relative rotation suppression mechanism 95 for stopping or suppressing the operation of the damper mechanism 41 as necessary.
[0048]
When the hydraulic oil in the hydraulic chamber of the hydraulic cylinder 86 is supplied from the state shown in FIG. 8 by the first hydraulic circuit 87, the piston 90 moves to the axial engine side. Accordingly, the release bearing 85 ′ moves the inner peripheral end of the lever member 53 ′ to the axial direction engine side. The lever member 53 ′ rotates with the annular support portion 79 ′ of the second clutch cover 71 ′ as a fulcrum, and moves the release member 52 toward the axial engine side. As a result, the first pressure plate 31 overcomes the urging force of the cone spring 32 and moves away from the first friction coupling portion 21. When hydraulic oil is supplied into the hydraulic chamber of the hydraulic cylinder 99 by the second hydraulic circuit 100, the piston 102 moves to the axial engine side. Accordingly, the release bearing 98 ′ moves the inner peripheral end of the diaphragm spring 93 ′ to the axial direction engine side. The diaphragm spring 93 ′ rotates with the second extension portion 76 ′ of the second clutch cover 71 ′ as a fulcrum, and the elastic portion 93a ′ moves away from the second pressure plate 92 toward the axial transmission side. As a result, the second pressure plate 92 is separated from the second friction coupling portion 22 by the urging force of the strap plate.
[0049]
In any one or both of the clutch release operations described above, the outer peripheral portion 29 of the first clutch cover 28 in particular in the axial engine is affected by the load acting on the clutch operating mechanisms 9 and 10 from the release bearings on the axial engine side. Elastically deforms to the side. Thereby, in the relative rotation suppression mechanism 95, the friction facing 94 abuts on the disk-shaped member 12 and is frictionally engaged. That is, the first clutch cover 28 frictionally engages with the disk-shaped member 12 and rotates integrally. In other words, the first clutch cover 28 and the friction coupling member 6 are locked with respect to the crankshaft 2, and the damper mechanism 41 does not operate. Therefore, when the resonance point is passed in the low rotation speed region (for example, the rotation speed of 0 to 500 rpm) at the time of starting the engine, the damper mechanism 41 is less likely to be damaged and sound / vibration is not caused by the resonance by releasing the clutch.
[0050]
Here, the structure of the damper mechanism 41 is simplified because the lock of the damper mechanism 41 uses the load from the drive mechanisms 84 ′ and 97 ′ at the time of clutch release. In particular, since the relative rotation suppression mechanism 95 is made of members such as the disk-shaped member 12 and the first clutch cover 28, it is not necessary to provide a special structure.
Here, comparing this embodiment with the first embodiment, the clutch device of this embodiment is a push type that releases the clutch by pushing the inner peripheral end of the lever member 53 ′ toward the axial engine side. The clutch device of the first embodiment is a pull type that releases the clutch by pulling the inner peripheral end of the lever member 53 toward the axial transmission side. Here, the difference between them is only in the second clutch covers 71, 71 ′, release mechanisms 51, 51 ′, drive mechanisms 84, 84 ′, 97, 97 ′, and the first pressure plate 31 of the first clutch operating mechanism 9. It can be seen that the cone spring 32 is common. In other words, a pull-type clutch device and a push-type clutch device can be manufactured simply by changing the clutch cover, the support portion forming member, and the like for the common portion.
[0051]
【The invention's effect】
In the clutch device according to the present invention, since the clutch cover is connected to the crankshaft via the damper mechanism, the structure is simplified. Further, the clutch device can be assembled by approaching the crankshaft in the axial direction. That is, the assembling property is improved as compared with the conventional case.
[Brief description of the drawings]
FIG. 1 is a schematic longitudinal sectional view of a clutch device as a first embodiment of the present invention.
FIG. 2 is a plan view for explaining the relationship between a second clutch cover and a release mechanism.
FIG. 3 is a side view for explaining the relationship between a second clutch cover and a release mechanism.
FIG. 4 is a partial perspective view of a second clutch cover.
FIG. 5 is a partial rear view of the damper mechanism.
FIG. 6 is a schematic longitudinal sectional view for explaining the operation of assembling the clutch device.
FIG. 7 is a schematic longitudinal sectional view of a clutch device according to a second embodiment of the present invention.
FIG. 8 is a schematic vertical sectional view of a clutch device as a third embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Clutch apparatus 2 Crankshaft 3 1st input shaft 4 2nd input shaft 6 Friction connection member 9 1st clutch operation mechanism 10 2nd clutch operation mechanism 28 1st clutch cover 41 Damper mechanism

Claims (7)

A clutch device capable of operating torque transmission / disconnection separately from an engine crankshaft to a transmission first and second input shafts,
A friction coupling member having a first friction surface on the axial engine side and a second friction surface on the axial transmission side, to which torque is input from the crankshaft;
A first clutch disk assembly having a first friction coupling portion disposed close to the first friction surface and capable of transmitting torque to the first input shaft;
A second clutch disk assembly having a second friction coupling portion disposed in proximity to the second friction surface and capable of transmitting torque to the second input shaft;
A clutch operating mechanism that is mounted on the friction coupling member and is capable of separately coupling and uncoupling the first friction coupling portion and the second friction coupling portion to the friction coupling member;
A damper mechanism for elastically connecting the clutch operating mechanism directly to the crankshaft in the rotational direction,
The clutch operating mechanism includes a first elastic member that generates an urging force for connecting the first friction connecting portion to the friction connecting member, and an attachment for connecting the second friction connecting portion to the friction connecting member. A second elastic member that generates a force, and applying a load obtained by hydraulic pressure to the first elastic member and the second elastic member on the same side in the axial direction, and Separate the connection of the second frictional connection part separately,
Clutch device.   The clutch device according to claim 1, wherein the damper mechanism includes an elastic member that is held by one of the crankshaft and the clutch operation mechanism and is detachably engaged with the other in the axial direction.   The damper mechanism includes a disk-like plate member disposed on the axial engine side at the tip of the crankshaft, the elastic member held at both ends in the circumferential direction and the axial transmission side by the plate member, and the elastic member. The clutch device according to claim 2, further comprising: a drive member fixed to the crankshaft having contact portions that are detachable from the axial direction at both circumferential ends of the member.   The clutch device according to claim 3, wherein the plate member has a holding portion for holding the engine side of the elastic member in the axial direction.   The clutch operating mechanism includes a pressure plate disposed on the axial engine side of the first clutch disk assembly, and a biasing member supported by the plate member for biasing the pressure plate toward the clutch disk. The clutch device according to claim 3 or 4, wherein the clutch device is provided.   The clutch device according to claim 4, wherein the elastic member is disposed on an inner peripheral side of the pressure plate.   The clutch device according to any one of claims 3 to 6, wherein an outer peripheral end of the plate member is fixed to the friction coupling member, and an inner peripheral end is rotatably supported by the crankshaft.

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