JP2009121666A - Clutch operation auxiliary device, vehicular power unit equipped with it, and saddle-riding type vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To downsize the power unit which has a built-in clutch operation auxiliary equipment to reduce the control force of a clutch lever. <P>SOLUTION: The clutch operation auxiliary equipment 70 includes the push shaft 39, the support plate 14c and the first turning plate 51 which the push shaft 39 is slid by turning and being connected with a clutch wire 43 while being supported in free turning to the support plate 14c. The first turning plate 51 is gear combined with the second turning plate 52. The second turning plate 52 is supported in free turning by the bearing member 90 fixed to the support plate 14c. The spring unit 54 which gives the assistant power in the direction to intercept a friction clutch is pin combined at the second turning plate 52. The spring unit 54 is installed so that the elastic direction S2 of the auxiliary spring 67 does not pass the rotation center 39a of a pressure plate 37 as viewed from an axis of the push shaft 39. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a clutch operation assisting device that reduces the operating force of a friction clutch when the transmission of torque by the friction clutch is interrupted, a power unit including the clutch operation assist device, and a saddle riding type vehicle.

  For example, as a power unit in a motorcycle or the like, a power unit having a friction clutch for intermittently transmitting torque from an engine to a transmission is known. The friction clutch has a clutch shaft, and a friction plate and a clutch plate that overlap in the axial direction of the clutch shaft (hereinafter referred to as the clutch shaft direction). The friction clutch includes a pressure plate that presses the friction plate and the clutch plate, and a clutch spring that urges the pressure plate. Usually, the clutch clutch that enables torque transmission by the clutch spring. Kept in a state.

  The friction clutch has a clutch release mechanism. The clutch release mechanism is for releasing the pressure of the pressure plate by the clutch spring, and is connected to the clutch lever via a clutch wire. Therefore, when the driver holds the clutch lever, the pressure plate slides against the urging force of the clutch spring, and transmission of torque from the friction plate to the clutch plate is interrupted.

  By the way, in a friction clutch used in a high-power / high-rotation type engine, it is desired to set a high clutch spring mounting load in order to increase the torque capacity. However, since the operation of the clutch lever is performed by a human hand, increasing the clutch spring mounting load increases the burden on the operation of the clutch lever.

  In order to improve this, conventionally, for example, a clutch operation assist device is known in which an assist mechanism for reducing the operation force of the clutch lever is attached to a clutch release mechanism to which a clutch wire is connected (for example, Patent Document 1 and Patent Document 1 below) 2).

  The clutch operation assistance device disclosed in Patent Document 1 is disposed outside the power unit. On the other hand, there is a need to arrange the clutch operation assisting device inside the power unit. Patent Document 2 below discloses a configuration in which a clutch operation assisting device is arranged inside a power unit.

  As shown in FIG. 9, the clutch operation assisting device disclosed in Patent Document 2 includes a pivotable push lever 525 connected to a clutch wire 528 and an auxiliary spring 529 that reduces the operating force of the clutch lever. ing. One end 529a of the auxiliary spring 529 is connected to the push lever 525, and the other end of the auxiliary spring 529 is connected to a connecting member 531 formed in a semicircular arc shape. The push lever 525 is fixed to a push screw 517 located on the same straight line as the clutch shaft (on a straight line extending in the front and back direction in FIG. 9), and rotates integrally with the push screw 517. On the other hand, the connecting member 531 is rotatably supported by the pin 530 and rotates around the pin 530.

  When the clutch lever is in a so-called play state (in other words, no load is applied even when the clutch lever is pulled), as shown by a solid line in FIG. 9, the auxiliary spring 529 is connected to the rotation center C0 of the push lever 525. It is located on a straight line M1 connecting the pin 530. In other words, the extension / contraction direction of the auxiliary spring 529 passes through the rotation center C0 of the push lever 525. Therefore, the urging force of the auxiliary spring 529 does not act as a force that rotates the push lever 525.

On the other hand, as shown by a two-dot chain line in FIG. 9, when the clutch lever is pulled, the push lever 525 is pulled and rotates counterclockwise. As a result, the posture of the auxiliary spring 529 changes, and the expansion / contraction direction M2 of the auxiliary spring 529 deviates from the rotation center C0 of the push lever 525. Thereby, a part of the urging force of the auxiliary spring 529 acts as a force for rotating the push lever 525 in the counterclockwise direction. Therefore, the biasing force of the auxiliary spring 529 acts as an assist force when pulling the clutch lever, and the operation force of the clutch lever is reduced.
Japanese Patent Laid-Open No. 7-132872 JP-A-55-94028

  As described above, in the clutch operation assisting device, the auxiliary spring 529 changes the posture from the initial position where the clutch lever is in the idle state to the disengagement position where the friction clutch is disengaged. In the initial position, the expansion / contraction direction M1 of the auxiliary spring 529 passes through the axis (= rotation center C0) of the push screw 517. Therefore, in the clutch operation assisting device, the auxiliary spring 529 has to be installed along the radial direction from the axial center of the push screw 517, and it is difficult to secure a sufficient installation space for the auxiliary spring 529. In addition, it is difficult to ensure a sufficient expansion / contraction length of the auxiliary spring 529. Therefore, in the above-described clutch operation assisting device, the power unit has to be enlarged in order to secure a sufficient installation space for the auxiliary spring 529.

  The present invention has been made in view of such points, and an object of the present invention is to reduce the size of a power unit incorporating a clutch operation assisting device.

  A clutch operation assisting device according to the present invention has a pressure plate and a clutch spring that urges the pressure plate, and is connected to a friction clutch disposed in a casing of a power unit via the transmission member. An operation element that is artificially operated against the urging force of the clutch spring when the transmission of torque by the friction clutch is interrupted, and is accommodated in the casing. A clutch operation assisting device that rotatably supports the pressure plate, is connected to the slide member that slides in a predetermined direction together with the pressure plate, and is connected to the transmission member, and rotates following the transmission member. A first rotating member that slides the slide member by the first rotating unit; When the operating element is operated in a direction to disengage the friction clutch, the friction clutch is disengaged from the disengagement start position where the operating element receives the reaction force of the clutch spring. An auxiliary elastic body that applies an urging force to rotate the first rotating member in a direction in which the friction clutch is disconnected while changing the expansion / contraction direction during a period until reaching the complete cutoff position; and the auxiliary elastic body And a second rotating member that is connected to the first rotating member and transmits the urging force of the auxiliary elastic body to the first rotating member by rotating, and is fixed to the support plate or A bearing member that is integrally formed with the support plate and rotatably supports the second rotation member, and the extension of the auxiliary elastic body is seen from the sliding direction of the slide member. In which direction does not pass through the rotation center of the pressure plate.

  According to the clutch operation assisting device, since the expansion / contraction direction of the auxiliary elastic body does not pass through the rotation center of the pressure plate when viewed from the sliding direction of the slide member, the auxiliary elastic body is positioned at the rotation center of the pressure plate when viewed from the sliding direction. It is not necessary to install along the radial direction. Therefore, the auxiliary elastic body can be installed without being restricted by the slide member. Therefore, a large installation space for the auxiliary elastic body can be secured without increasing the size of the power unit itself. Moreover, a large space for expansion and contraction of the auxiliary elastic body can be secured. As a result, the power unit can be reduced in size.

  Moreover, according to the said clutch operation assistance apparatus, the 2nd rotation member is supported by the bearing member fixed or integrated with the support plate. Therefore, the second rotating member is stably supported. Moreover, the positioning accuracy at the time of installing a 2nd rotation member improves. Therefore, transmission of force from the auxiliary elastic body to the first rotating member via the second rotating member becomes smooth, and as a result, operation of the operator by the operator becomes smooth.

  As described above, according to the present invention, it is possible to reduce the size of the power unit incorporating the clutch operation assisting device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  A motorcycle 1 shown in FIG. 1 includes a frame 2. The frame 2 includes a steering head pipe 3, a main frame member 4, and a down tube 5. The steering head pipe 3 supports the front fork 6. A steering handle 8 for steering the front wheel 7 is fixed to the upper end of the front fork 6. A clutch lever 9, which is an example of an operation element, is attached to the left end portion of the steering handle 8.

  The main frame member 4 extends rearward from the steering head pipe 3 and supports the fuel tank 10 and the seat 11. The down tube 5 includes a first portion 5a extending downward from the front end of the main frame member 4, and a second portion 5b extending rearward from the lower end of the first portion 5a.

  A power unit 13 is supported on the frame 2. The power unit 13 has a crankcase 14 and a cylinder 15. As will be described later, a friction clutch 30 (see FIG. 2) is accommodated in the crankcase 14. The clutch lever 9 and the friction clutch 30 are connected via a clutch wire 43. The clutch lever 9, the clutch wire 43, and the friction clutch 30 constitute a clutch operating device that artificially interrupts transmission and reception of torque in the power unit 13.

  As shown in FIG. 2, an engine 20 is provided inside the power unit 13. The engine 20 includes a piston 16, a crankshaft 18, and a connecting rod 17 that connects the piston 16 and the crankshaft 18. Inside the crankcase 14, a main shaft 21 and a drive shaft 22 are arranged in parallel with the crankshaft 18. A plurality of gears 23 are provided around the main shaft 21 and the drive shaft 22, and a transmission 25 is formed by the main shaft 21, the drive shaft 22 and the gear 23.

  A friction clutch 30 is provided at the left end of the main shaft 21. Hereinafter, for convenience, a portion of the main shaft 21 where the friction clutch 30 is provided is referred to as a clutch shaft 31. However, in this embodiment, the clutch shaft 31 is a part of the main shaft 21, and the clutch shaft 31 and the main shaft 21 are formed integrally.

  As shown in FIG. 3, the friction clutch 30 of the present embodiment is a wet multi-plate friction clutch. However, the friction clutch according to the present invention is not limited to the wet multi-plate friction clutch. The friction clutch 30 includes a clutch housing 32 and a clutch boss 34. The clutch housing 32 is rotatably supported on the clutch shaft 31. The clutch boss 34 is supported by the clutch shaft 31 so as to rotate integrally with the clutch shaft 31.

  The clutch housing 32 is provided with a plurality of friction plates 33, and the clutch boss 34 is provided with a plurality of clutch plates 35. The friction plates 33 and the clutch plates 35 are arranged alternately along the axial direction (left-right direction) of the clutch shaft 31.

  As shown in FIG. 2, a drive gear 19 is fixed to the left end of the crankshaft 18. A driven gear 36 is fixed to the clutch housing 32. The drive gear 19 and the driven gear 36 are engaged with each other, and the driven gear 36 rotates according to the drive gear 19. Therefore, the clutch housing 32 rotates according to the crankshaft 18. The drive gear 19 and the driven gear 36 constitute a speed reduction mechanism.

  As shown in FIG. 3, a pressure plate 37 is disposed on the left side of the clutch shaft 31. A clutch spring 38 made of a diaphragm spring is attached to the pressure plate 37. The type of the clutch spring 38 is not particularly limited. The pressure plate 37 is slidable in the axial direction of the clutch shaft 31 and is always urged toward the clutch boss 34 (the right side in FIG. 3) by a clutch spring 38. When the pressure plate 37 moves toward the clutch boss 34 and presses the friction plate 33, the friction plate 33 and the clutch plate 35 are pressure-bonded, and the friction clutch 30 is in a connected state (clutch-in state). On the other hand, when the pressure plate 37 is separated from the clutch boss 34, the pressure bonding between the friction plate 33 and the clutch plate 35 is released, and the friction clutch 30 is in a disconnected state (clutch out state).

  The crankcase 14 includes a case main body 14a having a support plate 14c and a clutch cover 14b. The support plate 14 c is disposed on the outer side (left side) of the pressure plate 37. The clutch cover 14b is disposed outside the support plate 14c. The clutch cover 14b covers the friction clutch 30 from the outside together with the support plate 14c. The clutch cover 14b also covers a clutch operation assisting device 70 described later.

  A push shaft 39 is supported on the support plate 14c. The push shaft 39 is disposed on the same straight line as the clutch shaft 31 and is disposed on the outer side (left side) of the clutch shaft 31. The pressure plate 37 is rotatably supported by the push shaft 39 via a bearing 40. Further, the pressure plate 37 cannot move in the axial direction with respect to the push shaft 39, and slides in the axial direction according to the push shaft 39. A virtual line 39a in FIG. 3 is a rotation center line of the push shaft 39. This imaginary line 39 a is also the rotation center line of the pressure plate 37.

  A cam plate 41 is attached to the left end of the push shaft 39. In the present embodiment, the push shaft 39 and the cam plate 41 are separate members, but the push shaft 39 and the cam plate 41 may be integrally formed. That is, a part of the push shaft 39 may form the cam plate 41. In the present embodiment, the cam plate 41 has a boss portion 41a, and the push shaft 39 is fitted into the boss portion 41a. A compression coil spring 42 is disposed between the left side of the cam plate 41 and the clutch cover 14b. The cam plate 41 is always urged rightward by the compression coil spring 42. Note that the compression coil spring 42 is not always necessary. As will be described later, the cam plate 41, the ball 60, and the first rotation plate 51 constitute a so-called ball cam type cam mechanism, and as long as the cam mechanism functions, the cam plate 41 is urged to the right. The compression coil spring 42 may not be provided.

  The boss portion 41 a of the cam plate 41 passes through the center hole of the first rotation plate 51. Note that the boss portion 41 a of the cam plate 41 is movable in the axial direction with respect to the first rotation plate 51. The first rotation plate 51 is rotatably supported by the support plate 14 c via the bearing 53.

  As shown in FIG. 4A, three cam grooves 61 are circumferentially arranged on the surface (left surface in FIG. 3) 51a of the first rotating plate 51. As shown in FIG. On the other hand, as shown in FIG. 4B, a similar cam groove 62 is also formed on the back surface 41b of the cam plate 41 (the right side surface in FIG. 3). These cam grooves 61 and 62 are grooves having a substantially V-shaped cross section. As shown in FIG. 3, a ball 60 is disposed between the cam groove 61 of the first rotation plate 51 and the cam groove 62 of the cam plate 41. Reference numeral 60a denotes a plate that prevents the ball 60 from falling off. The cam grooves 61 and 62 and the ball 60 form a so-called ball cam type cam mechanism. That is, when the first rotation plate 51 rotates, the ball 60 moves in the cam grooves 61 and 62, and the cam plate 41 is pushed out to the left by the ball 60. As a result, the pressure plate 37 slides to the left together with the push shaft 39, and the friction clutch 30 is disconnected.

  As shown in FIG. 5A, the clutch wire 43 includes a metal inner wire 43a and a synthetic resin outer tube 43b covering the inner wire 43a. The inner wire 43a is slidably inserted into the outer tube 43b, and is drawn from the end of the outer tube 43b.

  The clutch operation assisting device 70 includes a second rotating plate 52 and a spring unit 54 in addition to the first rotating plate 51 described above. The 1st rotation plate 51 is comprised by the sheet-metal press process component, for example. As shown in FIG. 4A, the first rotation plate 51 includes a substantially annular central portion 55, a wire connecting portion 56, and a gear portion 57. The wire connecting portion 56 and the gear portion 57 are located on the opposite sides with the center portion 55 interposed therebetween. Further, as shown in FIGS. 3 and 4A, the first rotation plate 51 is a portion 51b between the center portion 44 and the gear portion 57, and is located on the inner side in the clutch axial direction (right side in FIG. 3). Is bent to.

  A hole 58 through which the push shaft 39 is inserted is formed in the center portion 55. Further, the cam groove 61 described above is disposed around the hole 58 of the central portion 55. An engagement groove 59 and an engagement hole 63 are formed in the wire connecting portion 56. The engagement groove 59 is a portion around which the inner wire 43a of the clutch wire 43 is wound. The engagement groove 59 is curved so as to draw an arc centered on the center 58 c of the hole 58. The engagement groove 59 is formed in a substantially U-shaped cross section that opens upward. As shown in FIG. 5A, a cylindrical engagement element 64 fixed to the tip of the inner wire 43a is hooked in the engagement hole 63. With such a configuration, when the inner wire 43 a is pulled, the first rotation plate 51 rotates counterclockwise about the push shaft 39.

  As shown in FIG. 5B, a bearing member 90 is fixed to the support plate 14c. The method for fixing the bearing member 90 is not limited in any way, but in this embodiment, the bearing member 90 is fixed to the support plate 14c by bolts 91a and 91b. However, it goes without saying that a fixing tool other than the bolts 91a and 91b, for example, a screw or the like may be used. Further, the bearing member 90 may be fixed by joining to the support plate 14c. It is also possible to form the bearing member 90 integrally with the support plate 14c. That is, the bearing member 90 may be separate from the support plate 14c, but may be integrated. The bearing member 90 supports a second rotating plate 52, and the second rotating plate 52 is configured to rotate around a pivot shaft 65 that is the center of rotation of the bearing member 90. ing.

  As shown in FIG. 5A, teeth 52 a are formed on the second rotating plate 52. The teeth 52 a of the second rotating plate 52 are engaged with the teeth 57 a of the gear portion 57 of the first rotating plate 51. By these teeth 52a, 57a, the first rotating plate 51 and the second rotating plate 52 are connected so as to transmit torque to each other. Therefore, the 2nd rotation plate 52 rotates according to the 1st rotation plate 51 (refer Fig.5 (a)).

  The bearing member 90 includes a bearing 90a made of a ball bearing. However, the bearing 90a of the bearing member 90 may be a rolling bearing other than a ball bearing. Further, the shape and structure are not limited as long as the mechanism allows the rotation of the second rotation plate 52 with the pivot shaft 65 as the center of rotation.

  The distance from the rotation center of the first rotation plate 51 (axis 39a of the push shaft 39) to the teeth 57a is the distance from the rotation center of the second rotation plate 52 (axis of the pivot shaft 65) to the teeth 52a. It is longer than the distance. Therefore, the first rotation plate 51 and the second rotation plate 52 are connected so that the rotation angle of the second rotation plate 52 is larger than the rotation angle of the first rotation plate 51. Yes.

  The spring unit 54 includes a spring holder 66 and an auxiliary spring 67. The spring holder 66 includes an inner cylinder 66a and an outer cylinder 66b. The inner cylinder 66a and the outer cylinder 66b are fitted so as to be slidable in the axial direction, and the spring holder 66 can be expanded and contracted by the outer cylinder 66b sliding relative to the inner cylinder 66a.

  The inner cylinder 66 a has a spring receiver 68 and a support end 69. The spring receiver 68 projects in a flange shape from the outer peripheral surface of one end of the inner cylinder 66a. The support end portion 69 is formed at one end of the inner cylinder 66a and is rotatably supported by the mounting seat 14d of the support plate 14c.

  The outer cylinder 66 b has a spring receiver 71 and a connecting end 72. The spring receiver 71 projects in a flange shape from the outer peripheral surface of one end of the outer cylinder 66b. The connecting end portion 72 is formed at one end of the outer cylinder 66 b and is rotatably connected to one end of the second rotating plate 52 via a pin 73.

  The auxiliary spring 67 is a compression coil spring. The auxiliary spring 67 is interposed between the spring receiver 68 of the inner cylinder 66a and the spring receiver 71 of the outer cylinder 66b in a compressed state. For this reason, the spring holder 66 is always biased in the extending direction. In addition, the auxiliary spring 67 supports the end portion from the return position (see FIG. 5A), which will be described later, through the blocking start position (see FIG. 6A) to the blocking position (see FIG. 7A). The expansion / contraction direction S2 is changed using 69 as a fulcrum. However, at any position, when viewed from the axial direction of the push shaft 39, the expansion / contraction direction S2 of the auxiliary spring 67 and the axis 39a of the push shaft 39 do not intersect.

  A wire introduction port 74 is formed in the case main body 14a of the crankcase 14. The clutch wire 43 is inserted into the wire introduction port 74. The inner wire 43 a of the clutch wire 43 is drawn into the crankcase 14 through the wire introduction port 74 and connected to the wire connecting portion 56 of the first rotating plate 51.

  The support plate 14 c is formed with a first hole 47 and a second hole 48 in addition to the hole through which the push shaft 39 is inserted. The first hole 47 and the second hole 48 are located on opposite sides of the shaft center 39 a of the push shaft 39. A part of the wire connecting portion 56 of the first rotation plate 51 is inserted into the first hole 47 (see FIG. 3). A part of the second rotation plate 52 and the spring unit 54 enter the second hole 48 (see FIG. 3).

  The clutch lever 9 is rotatable between a return position where the friction clutch 30 keeps the clutch-in state and a disengagement position where the friction clutch 30 is clutch-off. Furthermore, a predetermined rotation range from the return position (for example, a rotation range in which the moving distance of the tip of the clutch lever 9 is 10 to 15 mm) is a so-called play area in which the clutch-off state is maintained even when the clutch lever 9 is gripped. It has become. In this play area, even if the clutch lever 9 is operated, the clutch wire 43 is only slightly pulled, and the urging force of the clutch spring 38 is not transmitted to the clutch lever 9. The end of the play of the clutch lever 9 is the cutoff start position. At this disconnection start position, the urging force of the clutch spring 38 acts on the clutch lever 9 via the clutch wire 43.

  5A and 5B show the state of the clutch operation assisting device 70 when the clutch lever 9 is in the return position. When the clutch lever 9 is in the return position, the pin 73 that connects the second rotation plate 52 and the spring unit 54 connects the support end 69 of the spring holder 66 and the pivot shaft 65 of the second rotation plate 52. It is shifted upward from the straight line S1.

  When the driver operates the clutch lever 9 from the return position to the disconnection start position, the first rotating plate 51 is pulled via the clutch wire 43, and the first rotating plate 51 rotates counterclockwise. Then, since the first rotation plate 51 and the second rotation plate 52 are gear-coupled, the second rotation plate 52 rotates in the clockwise direction. On the other hand, since the second rotation plate 52 and the spring unit 54 are pin-coupled, the spring unit 54 rotates counterclockwise with the support end 69 as a fulcrum.

  When the clutch lever 9 reaches the disengagement start position, as shown in FIG. 6A, a pin 73 is placed on a straight line S1 connecting the support end portion 69 of the spring holder 66 and the pivot shaft 65 of the second rotating plate 52. Is located. Therefore, the urging force of the auxiliary spring 67 does not act as a force for rotating the second rotating plate 52, and consequently does not act as a force for rotating the first rotating plate 51.

  When the clutch lever 9 is operated from the disconnection start position toward the disconnection position, the first rotation plate 51 further rotates counterclockwise. Then, as shown in FIG. 7 (b), the positions of the cam groove 61 of the first rotation plate 51 and the cam groove 62 of the cam plate 41 shift, and the ball 60 moves in both the cam grooves 61, 62. The cam plate 41 is pushed outward. Further, as shown in FIG. 7A, the rotation of the first rotation plate 51 further rotates the second rotation plate 52 in the clockwise direction, and the position of the pin 73 is below the straight line S1. Shift to the side. As a result, the spring holder 66 is extended by receiving the urging force of the auxiliary spring 67, and the urging force of the auxiliary spring 67 acts as a force for rotating the second rotating plate 52 in the clockwise direction. As a result, the biasing force of the auxiliary spring 67 functions as an assisting force that rotates the first rotating plate 51 in the counterclockwise direction.

  Accordingly, when the clutch lever 9 is operated in a direction that approaches the disconnection position beyond the disconnection start position, the first rotation plate 51 is forcibly rotated counterclockwise by the auxiliary spring 67. That is, the urging force of the auxiliary spring 67 is added to the operation force when the driver holds the clutch lever 9. Therefore, the burden on the driver when operating the clutch lever 9 is reduced.

  By the way, as described above, in the state where the clutch lever 9 is in the return position, as shown in FIG. 5A, the position of the pin 73 is shifted above the straight line S1. For this reason, the first rotating plate 51 is urged in the clockwise direction, that is, the direction opposite to the direction in which the friction clutch 30 is disconnected, by the urging force of the auxiliary spring 67.

  The force that urges the first rotation plate 51 in the clockwise direction is a reverse assist force that opposes the force that rotates the clutch lever 9 from the return position to the disconnection start position. Therefore, in this state, the initial input load when the clutch lever 9 is first gripped increases.

  For this reason, the clutch operation assisting device 70 of the present embodiment is provided with a canceling spring unit 80 for canceling the reverse assist force. In the present embodiment, the support plate 14 c is formed with a housing portion 81 that houses the canceling spring unit 80.

  As shown in FIG. 8, the canceling spring unit 80 includes a pressing pin 82 and a canceling spring 83. A flange-like stopper 84 is formed at the lower end of the pressing pin 82. The pressing pin 82 is inserted into the housing portion 81 from below.

  The support plate 14 c is provided with a spring receiver 85 that supports the lower end of the canceling spring 83. The canceling spring 83 is a compression coil spring, and is interposed between the upper end inner surface of the pressing pin 82 and the spring receiver 85 in a compressed state. The canceling spring 83 always urges the pressing pin 82 obliquely upward along the longitudinal direction of the housing portion 81. The biasing force of the canceling spring 83 is set slightly smaller than the reverse assisting force by the auxiliary spring 67.

  The pressing pin 82 has a first position where the upper end of the pressing pin largely protrudes from the housing portion 81 (see FIGS. 6A and 7A), and a first position where the upper end of the pressing pin 82 slightly protrudes from the housing portion 81. It is possible to move between two positions (see FIG. 5A). In the first position, the stopper 84 of the pressing pin 82 comes into contact with the lower end of the housing portion 81 and the position of the pressing pin 82 is regulated. In the second position, the stopper 84 of the pressing pin 82 comes into contact with the spring receiver 85 and the position of the pressing pin 82 is regulated.

  During the period from when the clutch lever 9 reaches the disconnection start position, the upper end of the pressing pin 82 abuts against the contact portion 76 of the first rotation plate 51 (see FIG. 5A). Therefore, the first rotating plate 51 receives the urging force of the canceling spring 83. As a result, when the clutch lever 9 is in the play area, the total urging force of the auxiliary spring 67 and the canceling spring 83 applied to the first rotating plate 51 becomes almost zero, and the clockwise direction of the first rotating plate 51 is clockwise. Rotation is limited.

  When the clutch lever 9 passes the disengagement start position and approaches the disengagement position, the contact portion 76 of the first rotation plate 51 is disengaged from the upper end of the pressing pin 82 (see FIG. 7A). As a result, the biasing force of the canceling spring 83 applied to the first rotating plate 51 becomes zero, and the first rotating plate 51 is forcibly rotated counterclockwise by the biasing force of the auxiliary spring 67.

  As described above, the clutch operation assisting device 70 according to the present embodiment includes the push shaft 39, the first rotation plate 51, and the auxiliary spring 67. Here, the push shaft 39 rotatably supports the pressure plate 37 and slides in the axial direction together with the pressure plate 37. The first rotation plate 51 is connected to the clutch wire 43 and rotates following the clutch wire 43 to slide the push shaft 39. When the clutch lever 9 is operated in a direction to disengage the friction clutch 30, the auxiliary spring 67 reaches the disengagement position where the disengagement of the friction clutch 30 is completed from the disengagement start position where the clutch lever 9 receives the reaction force of the clutch spring 38. During the period until, the urging force for rotating the first rotation plate 51 in the direction in which the friction clutch 30 is disconnected is applied while changing the expansion / contraction direction S2. In the clutch operation assisting device 70, when viewed from the axial direction (= sliding direction) of the push shaft 39, the expansion / contraction direction S <b> 2 of the auxiliary spring 67 passes through the axial center (= rotation center of the pressure plate 37) 39 a of the push shaft 39. (See FIG. 5 etc.).

  Therefore, according to the clutch operation assisting device 70 of the present embodiment, there is no need to install the auxiliary spring 67 along the radial direction from the axis 39a of the push shaft 39, and the auxiliary spring 67 is not restricted by the push shaft 39. Can be installed relatively freely. Therefore, a large installation space for the auxiliary spring 67 can be ensured without enlarging the crankcase 14 of the power unit 13. Therefore, the power unit 13 can be downsized.

  In addition, since a large expansion / contraction space for the auxiliary spring 67 can be secured, the expansion / contraction length of the auxiliary spring 67 can be increased. Therefore, a sufficient urging force can be obtained by ensuring a long expansion / contraction length without using an expensive spring. Accordingly, the cost of the clutch operation assisting device 70 can be reduced.

  Further, as shown in FIG. 5A and the like, the clutch operation assisting device 70 rotates around the pivot shaft 65 and transmits the urging force of the auxiliary spring 67 to the first rotating plate 51. 52. Then, when viewed from the axial direction of the push shaft 39, the position of the pivot shaft 65 and the position of the push shaft 39 are shifted.

  Thus, according to the present clutch operation assisting device 70, instead of directly connecting the spring unit 54 and the first rotating plate 51, the auxiliary spring 67 is interposed between the spring unit 54 and the first rotating plate 51. A second rotating plate 52 that applies the urging force to the first rotating plate 51 is interposed. Therefore, the restriction on the installation position of the auxiliary spring 67 is further reduced, and the size reduction of the power unit 13 can be promoted.

  Further, according to the clutch operation assisting device 70 according to the present embodiment, the bearing member 90 that rotatably supports the second rotation plate 52 is provided, and the bearing member 90 is fixed to the support plate 14c. Therefore, the second rotating plate 52 can be stably supported. Further, the second rotation plate 52 can be accurately positioned when the clutch operation assisting device 70 is installed. Therefore, the assist force is smoothly transmitted from the spring unit 54 to the first rotation plate 51 via the second rotation plate 52. As a result, transmission of a delicate frictional force or the like to the driver's hand holding the clutch lever 9 is suppressed, and the operation of the clutch lever 9 by the driver becomes smooth.

  Further, according to the clutch operation assisting device 70, since the second rotation plate 52 is not supported by the clutch cover 14b, the second rotation plate 52 can be moved even when the clutch cover 14b is removed. It can be rotatably supported. Therefore, adjustment of the clutch operation assisting device 70 (for example, adjustment of the cutoff start position) can be performed with the clutch cover 14b removed. Therefore, according to the present clutch operation assisting device 70, the maintainability can be improved.

  As shown in FIG. 3, according to the clutch operation assisting device 70, the bearing member 90 supports the second rotating plate 52 from the outside in the clutch axial direction (left side in FIG. 3). 51 is bent inward (right side in FIG. 3) in the clutch axial direction at a location 51b between the central portion 55 and the teeth 57a of the gear portion 57. Therefore, the 2nd rotation plate 52 can be arrange | positioned more inside. Therefore, although the bearing member 90 is disposed between the second rotation plate 52 and the clutch cover 14b, the second rotation plate 52 can be disposed more inside, so that the clutch cover 14b protrudes outward. This can be suppressed. In other words, interference between the clutch cover 14b and the bearing member 90 can be avoided without arranging the clutch cover 14b on the outer side.

  In the present embodiment, the bearing 90a of the bearing member 90 is a ball bearing. Therefore, the second rotation plate 52 can be supported more smoothly, and the operation of the clutch lever 9 by the driver becomes smoother.

  Further, in the clutch operation assisting device 70, the rotation angle of the second rotation plate 52 of the first rotation plate 51 and the second rotation plate 52 is larger than the rotation angle of the first rotation plate 51. So that they are connected.

  Therefore, when torque is transmitted from the second rotation plate 52 to the first rotation plate 51, the torque is amplified. Therefore, the urging force required for the auxiliary spring 67 can be kept small. As a result, a small-capacity spring can be used, and the auxiliary spring 67 can be reduced in size or cost.

  In the present embodiment, the first rotating plate 51 includes a wire connecting portion 56 connected to the clutch wire 43 and a gear portion 57 connected to the second rotating plate 52, and the shaft of the clutch shaft 31. When viewed from the direction, the wire connecting portion 56 and the gear portion 57 are located on the opposite sides of the push shaft 39.

  Therefore, according to the clutch operation assisting device 70, the wire connecting portion 56 and the gear portion 57 can be arranged in a compact manner, and the size reduction of the power unit 13 can be promoted.

  In the present embodiment, one end side of the auxiliary spring 67 (specifically, the support end portion 69 of the spring holder 66) is swingably supported by the support plate 14c.

  Therefore, the auxiliary spring 67 can be largely swung with the one end side of the auxiliary spring 67 as a fulcrum. Therefore, even if the auxiliary spring 67 is a relatively small spring, a sufficiently large urging force can be exhibited. The support plate 14c may directly support the auxiliary spring 67, or may indirectly support it through another member.

  Further, the clutch operation assisting device 70 according to the present embodiment includes a support plate 14c positioned between the friction clutch 30 and the first rotation plate 51, and holes 47 and 48 are formed in the support plate 14c. ing.

  Therefore, according to the clutch operation assisting device 70, the first rotating plate 51 can be firmly supported by the support plate 14c, and sufficient strength can be ensured. Further, the lubricating oil can be supplied from the friction clutch 30 side to the first rotating plate 51 side through the holes 47 and 48. Therefore, wear of the sliding portion of the clutch operation assisting device 70 can be suppressed.

  Further, according to the clutch operation assisting device 70, a part of the first rotating plate 51 (specifically, a part of the wire connecting portion 56) is inserted into the hole 47 of the support plate 14c. Further, the auxiliary spring 67 is inserted into the hole 48 of the support plate 14 c, and a part of the second rotating plate 52 is also inserted into the hole 48.

  As a result, it is possible to reduce the size of the power unit 13 in the width direction (the axial direction of the push shaft 39, in this embodiment, the left-right direction) by the amount of overlap between the first rotation plate 51 and the support plate 14c. Further, the power unit 13 can be reduced in size by the amount of overlap between the auxiliary spring 67 and the support plate 14c. Furthermore, the power unit 13 can be reduced in size by the amount of overlap between the second rotation plate 52 and the support plate 14c. In the present embodiment, the power unit 13 is so-called horizontal, and the width direction of the power unit 13 coincides with the vehicle width direction. Therefore, it is possible to promote slimming of the motorcycle 1.

  According to the present embodiment, when viewed from the axial direction of the push shaft 39, the first hole 47 and the second hole of the support plate 14 c are located on the opposite sides with the push shaft 39 interposed therebetween.

  Thereby, compared with the case where both the holes 47 and 48 are arrange | positioned intensively on one side, the rigidity of the support plate 14c can be improved.

  In addition, the clutch operation assisting device 70 of the present embodiment includes a ball cam type cam mechanism that slides the push shaft 39 according to the rotation of the first rotation plate 51. Specifically, the clutch operation assisting device 70 includes a cam plate 41 that slides in the axial direction together with the push shaft 39. The cam plate 41 extends in a direction perpendicular to the push shaft 39 and has a cam groove 62 formed therein. A cam surface 41b is formed. On the other hand, a cam groove 61 is formed in the first rotation plate 51, and a cam surface 51 a that faces the cam surface 41 b of the cam plate 41 is formed. The clutch operation assisting device 70 is disposed between the cam groove 62 of the cam plate 41 and the cam groove 61 of the first rotation plate 51. When the first rotation plate 51 rotates, the cam plate 41 is pushed to the push shaft. The ball 60 is slid in 39 axial directions.

  Therefore, according to the clutch operation assisting device 70 of the present embodiment, the first rotation plate 51 itself connected to the clutch wire 43 functions as a cam plate, and therefore, the pair of cam plates constituting the ball cam type cam mechanism are provided. There is no need to provide it separately. Therefore, also in this respect, the power unit 13 can be downsized in the width direction. Moreover, slimming of the vehicle can be promoted.

  In the present embodiment, the cam plate 41 is provided at the outer end of the push shaft 39, and the first rotation plate 51 is disposed inside the cam plate 41.

  Therefore, according to the present embodiment, the first rotation plate 51 is disposed inside the ball 60. Therefore, the 1st rotation plate 51 can be arrange | positioned more inside, and size reduction of the power unit 13 can be accelerated | stimulated. Further, since the first rotation plate 51 is arranged on the inner side, the second rotation plate 52 can be arranged on the inner side.

  According to the present embodiment, the first rotation plate 51 is formed with the first gear teeth 57a, and the second rotation plate 52 is engaged with the first gear teeth 57a in a plane orthogonal to the push shaft 39. Two gear teeth 52a are formed. That is, the first rotation plate 51 and the second rotation plate 52 are gear-coupled.

  Thereby, the 1st rotation plate 51 and the 2nd rotation plate 52 rotate in the same surface. Therefore, the overall axial length of the first rotation plate 51 and the second rotation plate 52 is shortened. Therefore, the size reduction of the power unit 13 in the width direction can be promoted.

  However, it is of course possible to connect the first rotation plate 51 and the second rotation plate 52 with a cam mechanism or the like. The connection aspect of the 1st rotation plate 51 and the 2nd rotation plate 52 is not necessarily limited to the thing of this embodiment.

  The bearing member 90 used for supporting the second rotating plate 52 of the present embodiment is supported by bolts 91a and 91b with respect to the support plate 14c, and is reduced in size by forming a bearing mechanism. . Further, since the rotation direction of the second rotation plate is maintained in a plane orthogonal to the axial direction of the bearing member 90 (pivot shaft 65), the torque from the first rotation plate is accurately transmitted.

  Further, the clutch operation assisting device 70 according to the present embodiment provides a canceling spring 83 that applies a biasing force that cancels the biasing force of the auxiliary spring 67 applied to the first rotating plate 51 when the clutch lever 9 is in the return position. It has.

  Thereby, the burden required for the initial operation of the clutch lever 9 can be reduced, and the operability of the clutch lever 9 can be improved.

(Other embodiments)
In the above embodiment, the clutch operation assisting device according to the present invention is applied to a motorcycle. However, the clutch operation assistance device according to the present invention is also applicable to a straddle-type vehicle other than a motorcycle.

  In the above-described embodiment, the part 51b of the first rotation plate 51 is bent so that the teeth 57a of the gear part 57 are located on the inner side of the center part 55. It suffices that the teeth 57a of the portion 57 are bent so as to be located on the inner side of the central portion 55, and the bending mode is not limited to bending but may be curved.

  In the present invention, the pressure plate is a member that press-fits the friction plate of the friction clutch and the clutch plate, and is not limited to a plate shape.

  The clutch spring is not limited to a diaphragm spring, and may be another type of spring such as a coil spring.

  In the embodiment, the push shaft 39 corresponds to the “slide member” of the present invention. However, the slide member is not limited to the push shaft 39. Any member that rotatably supports the pressure plate 37 and slides in a predetermined direction together with the pressure plate 37 may be used. Further, the slide member may be a single member or a combination of two or more members.

  In the embodiment, the rotation center of the first rotation member (first rotation plate 51) and the rotation center of the pressure plate 37 are the same when viewed from the slide direction of the slide member (= the axial direction of the push shaft 39). They may have been out of place. In that case, for example, a member such as a seesaw may be provided between the cam plate 41 and the push shaft 39. Thereby, the slide member can be slid by rotating the first rotation member following the transmission member. In addition, the mechanism for sliding the slide member may be of any type as long as the first rotation member is provided.

  The “transmission member” of the present invention is not limited to a wire shape but may be a rod shape.

  The “auxiliary elastic body” of the present invention is not limited to a coil spring but may be another elastic body such as a gas spring.

  In the embodiment, the first rotation plate 51 and the second rotation plate 52 are gear-coupled. However, the 1st rotation plate 51 and the 2nd rotation plate 52 may be connected by other coupling modes, such as link coupling.

  As described above, the present invention is useful for the clutch operation assist device that reduces the operation force of the friction clutch, the power unit including the clutch operation assist device, and the saddle riding type vehicle.

Fig. 3 is a left side view showing a part of the motorcycle. It is sectional drawing which notches and shows a part of power unit. It is sectional drawing of a clutch operation assistance apparatus. (A) is a front view of a 1st rotation plate, (b) is a front view of a cam plate. It is a figure showing a clutch operation auxiliary device when a clutch lever exists in a return position, (a) is a side view, (b) is a sectional view. It is a figure showing a clutch operation auxiliary device when a clutch lever exists in a interception start position, (a) is a side view and (b) is a sectional view. It is a figure showing a clutch operation auxiliary device when a clutch lever exists in a cutoff position, (a) is a side view, (b) is a sectional view. It is a side view of the cancellation | release spring unit in a clutch operation assistance apparatus when a clutch lever exists in a return position. It is a side view of the conventional clutch operation assistance apparatus.

Explanation of symbols

1 Motorcycle (saddle-ride type vehicle)
9 Clutch lever (operator)
13 Power unit 14 Crankcase (casing)
14c Support plate 30 Friction clutch 37 Pressure plate 38 Clutch spring 39 Push shaft (slide member)
39a Rotation center of pressure plate 43 Clutch wire (transmission member)
51 1st rotation plate (1st rotation member)
52 Second Rotating Plate (Second Rotating Member)
54 Spring unit (auxiliary elastic body)
55 Center (Rotation center)
57a Teeth (connection part)
65 Second rotation plate, center of rotation of bearing member 90 (pivot shaft)
67 Auxiliary spring 70 Clutch operation auxiliary device 90 Bearing member 90a Ball bearing

Claims (5)

A friction clutch having a pressure plate and a clutch spring for biasing the pressure plate, and disposed in a casing of the power unit;
An operator that is connected to the friction clutch via a transmission member and is artificially operated against the urging force of the clutch spring when the transmission of torque by the friction clutch is interrupted;
A clutch operation assisting device that is provided in the clutch operating device and is accommodated inside the casing,
A slide member that rotatably supports the pressure plate and slides in a predetermined direction together with the pressure plate;
A first rotation member coupled to the transmission member and configured to slide the slide member by rotating following the transmission member;
A support plate for rotatably supporting the first rotating member;
When operating the operating element in a direction to disengage the friction clutch, during a period from when the operating element receives a reaction force of the clutch spring to a disengagement position where the disengagement of the friction clutch is reached. An auxiliary elastic body that applies an urging force to rotate the first rotating member in a direction to disengage the friction clutch while changing an expansion / contraction direction;
A second rotating member connected to the auxiliary elastic body and connected to the first rotating member to transmit the urging force of the auxiliary elastic body to the first rotating member by rotating;
A bearing member fixed to the support plate or integrally formed with the support plate and rotatably supporting the second rotation member;
A clutch operation assisting device in which the expansion and contraction direction of the auxiliary elastic body does not pass through the rotation center of the pressure plate when viewed from the sliding direction of the slide member. In the clutch operation assistance device according to claim 1,
The casing has a cover that covers the first rotating member, the support plate, the auxiliary elastic body, and the bearing member from the outside,
The first rotation member includes a rotation center portion supported by the support plate, and a connection portion connected to the second rotation member,
A part of the first rotating member is bent so that the connecting portion is located inside the casing with respect to the rotating center portion,
The clutch operation assisting device, wherein the bearing member supports the second rotating member from the outside. In the clutch operation assistance device according to claim 1,
The clutch operation assisting device, wherein the bearing member has a ball bearing. A friction clutch that has a pressure plate and a clutch spring that biases the pressure plate, and is connected to an operator that is artificially operated against the biasing force of the clutch spring via a transmission member;
A slide member that rotatably supports the pressure plate and slides in a predetermined direction together with the pressure plate;
A first rotation member coupled to the transmission member and configured to slide the slide member by rotating following the transmission member;
A support plate for rotatably supporting the first rotating member;
When operating the operating element in a direction to disengage the friction clutch, during a period from when the operating element receives a reaction force of the clutch spring to a disengagement position where the disengagement of the friction clutch is reached. An auxiliary elastic body that applies an urging force to rotate the first rotating member in a direction to disengage the friction clutch while changing an expansion / contraction direction;
A second rotating member connected to the auxiliary elastic body and connected to the first rotating member to transmit the urging force of the auxiliary elastic body to the first rotating member by rotating;
A bearing member fixed to the support plate or integrally formed with the support plate and rotatably supporting the second rotation member;
A casing housing the friction clutch, the slide member, the first rotation member, the support plate, the auxiliary elastic body, the second rotation member, and the bearing member;
A power unit for a vehicle, wherein an extension / contraction direction of the auxiliary elastic body does not pass through a rotation center of the pressure plate when viewed from a sliding direction of the sliding member.   A straddle-type vehicle comprising the vehicle power unit according to claim 4.

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