JP6713501B2 - Gearbox - Google Patents

Description

The present invention relates to a transmission device for a vehicle engine in which a shift operation is performed by rotating a shift drum.

As a conventional technique, one end of a shift drum is rotatably supported by a bearing member between the shift drum and a case body that houses the transmission, and a shaft portion that extends from a head of a bolt that fixes the shift drum and the drum center. Is fitted to the shifter body (see Patent Document 1).

With such a structure, when the shift drum rotates, the shaft portion is also stressed by the rotation of the shifter main body, which increases friction during the rotation of the shift drum and increases resistance during a shift change. Is possible.

JP, 2008-82520, A

According to the present invention, one end of the shift drum is rotatably supported by a bearing member between the shift drum and a case body that houses the transmission, and a shaft portion extending from a head of a bolt that fixes the shift drum and the drum center is provided. An object of the present invention is to reduce resistance during a shift change in a transmission fitted to a shifter main body, to perform a smooth shift change, and to thin a shaft portion to contribute to downsizing.

In order to achieve the above-mentioned object, the present invention provides a transmission having a shift drum supported by a case body, wherein one end of the shift drum is arranged between the end and the case body. Rotatably supported by the first bearing member, a shaft portion having a diameter smaller than that of the shift drum is provided coaxially with the shift drum at the end portion of the shift drum, and the end portion of the shaft portion is The transmission is characterized in that it is rotatably held by a support member that is separate from the case body.

According to the above configuration, the shift drum is held by the bearing member and the end portion of the shaft portion is also supported by the supporting member, so that the amount of deflection of the shaft portion during rotation of the shift drum is reduced and the rotation of the shift drum becomes smooth. The shift change can be performed smoothly. Further, the shaft portion of the shift drum can be made thin to contribute to downsizing.

In the above configuration, the support member is fixed to the case body provided with the first bearing member, and a second bearing member is provided between the end portion of the shaft portion and the support member. The end portion may be rotatably supported by the support member via the second bearing member.

According to the above configuration, the shaft portion of the shift drum, which is a rotating body, can be easily held on the case body side via the support member.

In the above configuration, a pole ratchet mechanism that intermittently feeds the shift drum is provided, the support member has a guide plate in the pole ratchet mechanism, and a holding portion attached to the guide plate, and the guide plate is It may be attached to the case body.

According to the above configuration, the holding portion can be easily fixed by providing the holding portion on the guide plate which is an existing component.

In the above configuration, the pole ratchet mechanism includes a shifter body rotatably supported by the shaft portion of the shift drum, and a projection provided on the shifter body and engaged with a master arm is provided to the shaft portion. It may be provided on the shift spindle side, and the shaft portion may pass through the shifter main body and be held by the holding portion on the axially outer side.

According to the above configuration, the master arm can be shortened and interference with the shaft portion can be prevented.

In the above configuration, the movement of the shifter body in the axial direction may be restricted by a collar member provided between the second bearing member and the shifter body.

According to the above configuration, it is possible to reduce the friction between the shifter body and the guide plate due to the axial movement of the shifter body.

In the above configuration, a case cover member may be attached to the case body at an axially outer side of the shaft portion, and the functional component may be arranged between the shaft portion and the case cover member.

According to the above configuration, since the holding portion is fixed to the guide plate, a space can be secured outside the end portion of the shaft portion in the axial direction, so that the functional component can be arranged.

In the above configuration, the shift drum is configured by a cylindrical main body having an opening at least one of which is opened on the outer side in the axial direction, and a lid that closes the opening, and the shaft includes the lid. You may make it comprised integrally.

According to the above configuration, the inside of the main body of the shift drum can be processed, and the weight can be reduced.

According to the transmission device of the present invention, the shift drum is held by the bearing member and the end portion of the shaft portion is also supported by the supporting member, so that the amount of deflection of the shaft portion during rotation of the shift drum is reduced and the shift drum rotates. Becomes smooth, and shift changes can be made smoothly. Further, the shaft portion of the shift drum can be made thin to contribute to downsizing.

1 is a right side view of a motorcycle equipped with a power unit according to an embodiment of the present invention. It is a right side view of a power unit. It is a left side view which removed the unit case cover of a power unit. FIG. 4 is a sectional view taken along the line IV-IV in FIG. 2. FIG. 5 is a sectional view taken along line V-V of FIG. 3. FIG. 3 is a cross-sectional view around a variable speed drive device. FIG. 3 is a cross-sectional view of the periphery of a gear change mechanism. FIG. 3 is a cross-sectional view of the periphery of a gear change mechanism. It is the schematic which showed the state which aims at the synchronization of a synchronizing mechanism in time series. It is a schematic diagram of a transmission. FIG. 3 is a diagram showing a relationship between switching of a shift speed of a transmission and a ratio. It is a right side view which removed the unit case cover of a power unit. FIG. 3 is an enlarged view of a main part around a shaft portion of a shift drum and a gear shift operation mechanism. It is a principal part enlarged view of a shift operation mechanism. FIG. 6 is a cross-sectional view of the detent mechanism cut in the pole operation portion of the shifter body perpendicularly to the axial direction of the shaft portion and viewed from the right side. It is a perspective view of a support member. It is a front view of a guide plate. FIG. 11 is an enlarged view of a main part around a shaft portion and a gear shift operation mechanism of a shift drum showing another embodiment.

A transmission device T of a power unit P according to an embodiment of the present invention will be described with reference to the drawings.

In the present specification and claims, the front-rear, left-right, and up-down directions follow the direction of the vehicle in which the power unit according to the present invention is mounted on a vehicle, particularly a motorcycle. In the figure, arrow FR indicates forward, RE indicates rearward, RH indicates rightward, LH indicates leftward, UP indicates upward, and DW indicates downward.

As shown in FIG. 1, a vehicle body frame 2 of a motorcycle 1 has a head pipe 3 arranged in a front portion, a head pipe 3 extending rearward and obliquely downward, and a curved middle portion extending rearward. The main frame member 4, the center frame member 5 extending downward from the rear end of the main frame member 4, the seat stay 6 extending rearward from the upper portion of the center frame member 5, and the center frame member 5 It includes a midstay 7 that is bridged between the rear portion and the rear portion of the seat stay 6, and a down frame 8 that extends downward from the head pipe 3.

A front fork 9 that rotatably supports a front wheel 10 at its lower end is rotatably supported on the head pipe 3. A steering handle 11 is connected to the upper end of the front fork 9. A swing arm 13 is swingably supported by the center frame member 5 via a pivot shaft 12. A rear wheel 15 is rotatably supported at the rear end of the swing arm 13 via a rear wheel shaft 14.

An occupant seat 16 is attached above the seat stay 6, and a fuel tank 17 is mounted in front of the occupant seat 16 and above the main frame member 4.

A power unit P that drives the rear wheels 15 is mounted on the motorcycle 1 with the rotation axis of the crankshaft 23 oriented in the left-right direction. An endless chain 18 is bridged between a drive sprocket 33a fitted to the output shaft 33 of the power unit P and a driven sprocket 14a fitted to the rear wheel shaft 14.

The power unit P is supported by a plurality of engine hangers 2a provided on the vehicle body frame 2 at the front portion, the upper center portion, the upper rear portion, and the lower rear portion of the power unit P. The engine hanger 2a that supports the lower rear portion of the power unit P is located below an even-numbered stage shaft 32, which will be described later.

As shown in FIG. 2, the power unit P includes a water-cooled two-cylinder four-stroke cycle internal combustion engine (hereinafter referred to as internal combustion engine) E and a transmission device T connected to the rear of the internal combustion engine E, which are integrated. Is. The speed change operation of the speed change device T is controlled by the speed change control device 100 mounted on the motorcycle 1. The internal combustion engine E is provided with an engine speed detector 101 that detects the engine speed, and the detected engine speed Ne is sent to the shift control device 100.
The power unit P includes a crankcase 21 that rotatably supports a crankshaft 23, and a transmission case 22 that houses the transmission mechanism 30 of the transmission T, with the crankcase 21 as the first half and the transmission case 22 as the second half. A unit case 20 integrally formed in the front and rear is provided. The unit case 20 includes an upper unit case half 20U in which an upper crankcase half 21U and an upper transmission case half 22U are integrally formed, a lower crankcase half 21D, and a lower transmission case half. The lower unit case half body portion 20D integrally formed with the body portion 22D is divided into upper and lower parts.

A cylinder block 24, a cylinder head 25, and a head cover 26 are sequentially stacked on the upper portion of the upper crankcase half portion 21U toward the front and obliquely upward, and are provided so as to be inclined forward.
The lower side of the lower unit case half 20D is closed by an oil pan 27.
The right side of the unit case 20 is covered with a right unit case cover 28R, and the left side of the unit case 20 is covered with a left unit case cover 28L (see FIG. 3).

The crankshaft 23 is sandwiched between an upper crankcase half portion 21U and a lower crankcase half portion 21D via a bearing (not shown), and is rotatably supported by the crankcase 21.

As shown in FIG. 4 to FIG. 6, a transmission device T that shifts the driving force of the internal combustion engine E to a predetermined shift speed includes a constantly meshing shift mechanism 30 and a shift mechanism that operates the shift speed of the shift mechanism 30. An operation mechanism 70 and a so-called twin type clutch device 47 including two clutches, a first clutch 47A and a second clutch 47B, are provided. The transmission T has eight forward gears.

As shown in FIGS. 4 and 5, the speed change mechanism 30 of the speed change device T includes an odd number stage shaft 31 which is an input shaft and is provided with odd number drive gears m1, m3, m5 and m7, and an odd number stage gear 31. Rotational driving force is transmitted from the shaft 31 and even-numbered stage shaft 32 in which even-numbered-stage driving gears m2, m4, m6, m8 are arranged, and driven gears c1-c4 in which odd-numbered and even-numbered stage driving gears m1-m8 mesh And an output shaft 33 including a gear, and a gear group G including even-numbered and odd-numbered drive gears and driven gears. The odd-numbered stage shaft 31, the even-numbered stage shaft 32, the output shaft 33, the shift drum 110 and the shift fork shaft 90 described later are arranged parallel to the crank shaft 23 and oriented in the left-right direction.

As shown in FIG. 3, the crankshaft 23, the odd-numbered stage shaft 31, the even-staged stage shaft 32, and the shift drum 110 are arranged such that the output shaft 33 is arranged behind the crankshaft 23 in the side view of the vehicle. The 31 and even-numbered shafts 32 are arranged rearward of the crank shaft 23. Further, the odd stage shaft 31 is provided on the opposite side of the even stage shaft 32 with respect to the line L1 connecting the crank shaft 23 and the output shaft 33. The shift drum 110 is arranged on the opposite side of the output shaft 33 with respect to the line L2 connecting the odd-numbered shaft 31 and the even-stage shaft 32. Further, at least one of the odd-stage shaft 31 and the even-stage shaft 32 is arranged between the crank shaft 23 and the output shaft 33 in the vehicle front-rear direction, but in the present embodiment, the odd-stage shaft 31 is It is arranged between the crankshaft 23 and the output shaft 33. Regarding the three shafts of the odd stage shaft 31, the even stage shaft 32 and the output shaft 33, the inter-axis length D1 between the odd stage shaft 31 and the output shaft 33 is longer than the inter-axis length D2 between the even stage shaft 32 and the output shaft 33. It is arranged so that.

As shown in FIG. 3, the odd-numbered-stage shaft 31 is arranged in the upper transmission case half portion 22U and obliquely above and rearward of the crankshaft 23. As shown in FIG. 4, the odd-numbered stage shaft 31 rotates relatively to the odd-numbered stage main shaft 31a to which the rotational driving force from the crankshaft 23 is transmitted via the first clutch 47A and substantially the center of the odd-numbered stage main shaft 31a. The power transmission outer shaft 31b, which is disposed so as to be covered so that the rotational driving force is transmitted to the even-numbered stages via the second clutch 47B, and the relative rotation adjacent to the power transmission outer shaft 31b near the right end of the odd-numbered stage main shaft 31a. It consists of a clutch outer shaft 31c which is supported so as to be possible. The odd-numbered shaft shaft 31 is provided with an odd-numbered-shaft rotational speed sensor 104 that detects the rotational speed of the odd-numbered shaft 31.

The odd-numbered stage main shaft 31a is rotatably supported at its left end by the upper transmission case half 22U via a ball bearing 34 and at its right end by a right unit case cover 28R via a ball bearing 35. The odd-numbered drive gears m1, m3, m7, and m5 are attached to the odd-numbered main shaft 31a from the left side via a needle bearing 56 so as to be relatively rotatable.

A power transmission outer shaft 31b is supported by a needle bearing 41 so as to be relatively rotatable from the center of the odd-numbered stage main shaft 31a toward the right end. The inner clutch 47B ₂ of the second clutch 47B is attached to the right end of the power transmission outer shaft 31b so as not to rotate relative to it, and the transmission gear 51 for transmitting power to the even-numbered shaft 32 is integrally formed at the left end. Has been done.

Further, a clutch outer shaft 31c is supported by the odd-numbered stage main shaft 31a so as to be rotatable relative to the power transmission outer shaft 21b in the right direction via a needle bearing 42. At the center of the clutch outer shaft 31c, a primary driven gear 46 that meshes with a primary drive gear 45 that is fitted to the crankshaft 23 is fitted so that it cannot rotate relatively. A first clutch 47A is arranged on the right side of the primary driven gear 46, and a second clutch 47B is arranged on the left side.

The outer clutch 47A ₁ of the _first clutch 47A and the outer clutch 47B ₁ of the second clutch 47B are attached to the clutch outer shaft 31c so as to rotate integrally. The inner clutch 47A ₂ of the first clutch 47A is spline-fitted to the odd-numbered stage main shaft 31a, and the inner clutch 47B ₂ of the second clutch 47B is spline-fitted to the power transmission outer shaft 31b.

The rotational driving force supplied from the crankshaft 23 is reduced at a predetermined reduction ratio by the primary drive gear 45 and the primary driven gear 46, and is transmitted to the clutch outer shaft 31c. The rotational driving force transmitted to the clutch outer shaft 31c is selectively connected to the first clutch 47A and the second clutch 47B by a hydraulic circuit (not shown), so that the odd-numbered stage main shaft 31a or the power transmission outer shaft 31b is connected. And power is transmitted.

The output shaft 33 from which power is output from the transmission T is disposed behind the crankshaft 23 and sandwiched between the upper and lower transmission case halves 22U and 22D. The output shaft 33 is sandwiched between the upper and lower transmission case halves 22U and 22D through the ball bearing 39 at the left end, the ball bearing 39 at the left end and the needle bearing 40 at the right end, and the transmission case It is rotatably supported by 22. A drive sprocket 33a is fitted to the left end of the output shaft 33.

The power transmission outer shaft 31b of the odd-numbered stage shaft 31 is rotatably supported by the odd-numbered stage main shaft 31a by a needle bearing 41. A transmission gear 51 for transmitting power from the odd-numbered stage shaft 31 to the even-numbered stage shaft 32 is integrally formed on the power transmission outer shaft 31b adjacent to the left side of the ball bearing 36. The right end of the power transmission outer shaft 31b is spline-fitted to the inner clutch 47B ₂ of the second clutch 47B, the power from the crankshaft 23 is disconnectably by the second clutch 47B.

A transmitted gear 52 that rotates integrally with the even-numbered shaft 32 is provided on the right end side of the even-numbered shaft 32. At the right end of the output shaft 33, an idle gear 53 that meshes with the transmission gear 51 and the transmission gear 52 is supported by a needle bearing 58 so as to be relatively rotatable.

As shown in FIG. 4, on the left side of the idle gear 53, a first ceramic gear 54 having a diameter substantially the same as the outer diameter of the idle gear 53 is relatively rotatably fitted. The first ceaseless gear 54 meshes with the transmission gear 51 and is biased by the spring 54a in the direction opposite to the rotation direction of the transmission gear 51.
Further, on the right side of the idle gear, a second ceramic gear 55 having a diameter substantially the same as the outer diameter of the idle gear 53 is relatively rotatably fitted. The second ceram gear 55 meshes with the transmitted gear 52 and is biased by the spring 55a toward the rotation direction of the idle gear 53.

The idle gear 53 of the output shaft 33 always meshes with the transmission gear 51 of the power transmission outer shaft 31b of the odd-numbered stage shaft 31 and the transmitted gear 52 of the even-numbered stage shaft 32. When the second clutch 47B is connected, the rotational driving force of the crankshaft 23 is transmitted through the second clutch 47B, the transmission gear 51 of the power transmission outer shaft 31b, the idle gear 53, and the transmitted gear 52 to the even-numbered stage shaft 32. Be transmitted to. At this time, since the first cerease gear 54 and the second cerease gear 55 are provided on both left and right sides of the idle gear 53, backlash between the transmission gear 51 and the idle gear 53 and between the idle gear 53 and the transmitted gear 52 is prevented. Therefore, the rattling noise between the gears when shifting to an even number of gears can be reduced.

The gear group G provided in the transmission device T is configured as follows.
On the odd-numbered stage main shaft 31a of the odd-numbered-stage shaft 31, four odd-numbered-stage drive gears m1, m3, m7, and m5 having gear ratios of 1st speed, 3rd speed, 7th speed, and 5th speed are arranged from the left side in order of needle bearing It is rotatably supported via 56.

Four even-numbered drive gears m2, m4, m8, and m6 having gear ratios of 2nd, 4th, 8th, and 6th gears are sequentially arranged on the even-numbered stage shaft 32 from the left via a needle bearing 57. It is rotatably supported.

The output shaft 33 is provided with four driven gears c1, c2, c3 and c4 from the left side. These driven gears c1 to c4 are spline-fitted to the output shaft 33 and rotate integrally with the output shaft 33.

The drive gear m1 of the odd-numbered stage shaft 31 and the drive gear m2 of the even-numbered stage shaft 32 are paired, and both are always meshed with the driven gear c1 of the output shaft 33. Similarly, the drive gear m3 of the odd-numbered stage shaft 31 and the drive gear m4 of the even-numbered stage shaft 32, the drive gear m7 of the odd-numbered stage shaft 31 and the drive gear m8 of the even-numbered stage shaft 32, the drive gear m5 of the odd-numbered stage shaft 31 and the even-numbered stage The drive gears m6 of the shaft 32 are paired, and the paired drive gears are always in mesh with the driven gears c2, c3, c4.

As shown in FIG. 4, the odd-numbered stage main shaft 31a of the odd-numbered stage shaft 31 is provided between the first-speed drive gear m1 and the third-speed drive gear m3 and between the seventh-speed drive gear m7 and the fifth-speed drive gear m5. And a sleeve 61 as a gear change mechanism 60 is provided. The sleeve 61 is slidable on the odd-numbered shaft 31 in the axial direction, and is selectively connected to the adjacent drive gears m1, m3, m5, m7 via the synchro mechanism S.

The even-numbered stage shaft 32 is located between the second speed drive gear m2 and the fourth speed drive gear m4 and between the eighth speed drive gear m8 and the sixth speed drive gear m6, and serves as a gear shift switching mechanism 60. Is provided. The sleeve 61 is slidable in the axial direction on the even-numbered shaft 32, and is selectively connected to the adjacent drive gears m2, m3, m6, and m8 via the synchronizing mechanism S.
As shown in FIGS. 7 and 8, each of the sleeves 61 is provided with a fork engaging groove 61a, and the shift fork 91 engaging with the fork engaging groove 61a allows the sleeve 61 to move in the axial direction. Can be moved to.

The gear shift mechanism 60 is provided with a synchro mechanism S that establishes the gears in synchronization with each other between the sleeves 61 and the drive gears that are coupled to each other.
7 and 8 show the speed change mechanism 60 and the synchro mechanism S provided between the first speed drive gear m1 that establishes the first speed stage and the third speed drive gear m3 that establishes the third speed stage. It will be explained based on.
The other gear change mechanism 60 and the synchronizing mechanism S are also similar mechanisms.

As shown in FIG. 4, a speed change gear 65 typified by the first speed drive gear m1 and a speed change gear 66 typified by the third speed drive gear m3 include a needle bearing 56 on a rotary shaft (odd stage shaft 31) 67. It is rotatably supported through the shaft.
The speed change gear 65 has speed change gear teeth 65a (first speed drive gear teeth) on the outer circumference, and gear dog teeth 65t are formed on the outer circumference of a cylindrical portion 65s protruding toward the speed change gear 66 (third speed drive gear m3). .. Further, a protruding cylindrical portion 65ss having an inner peripheral portion further protruding from a cylindrical portion 65s having gear dog teeth 65t on the outer periphery is formed.
The transmission gear 66 has transmission gear teeth 66a (third-speed drive gear teeth) on the outer periphery, and gear dog teeth 66t are formed on the outer periphery of a cylindrical portion 66s protruding toward the transmission gear 65 (first-speed drive gear m1). .. Further, a protruding cylindrical portion 66ss having an inner peripheral portion further protruding from a cylindrical portion 66s having gear dog teeth 66t on the outer periphery is formed.

The sleeve 61 is spline-fitted to the outer peripheral surface of the hub 62, which is spline-fitted by being restricted from moving in the axial direction by the odd-numbered stage main shaft 31a, and is slidably fitted in the axial direction. The sleeve teeth 61t formed on the inner peripheral surface of the sleeve 61 are fitted to the spline teeth 62s formed on the outer peripheral surface of the hub 62.
In addition, a large number of spline teeth 62s formed on the outer peripheral surface of the hub 62 are broken at portions at intervals of 120 degrees in the circumferential direction, and cutout grooves 62b are formed at three locations.

Both ends of the sleeve teeth 61t annularly arranged on the inner peripheral surface of the sleeve 61 are tapered.
A fork engaging groove 61a with which the shift fork 91 is engaged is formed on the outer periphery of the sleeve 61.

A blocking ring 63 and a synchro spring 64 are arranged between the protruding cylindrical portion 65ss (66ss) of the transmission gear 65 (66) and the hub 62. The blocking ring 63 has ring teeth 63t having substantially the same diameter as the dog gear 65t (66t) of the transmission gear 65 (66).

In order to establish the shift speed, the sleeve 61 engaged with the shift fork 91 is slid toward the shift gear 65 by the shift operating mechanism 70 from the neutral state as shown in FIG. The sleeve 61 and the blocking ring 63 come into contact with each other and start synchronization with the sleeve 61.

The synchronizing operation of the synchronizing mechanism S will be described with reference to FIG.

The state shown in FIG. 9(1) is the neutral state before starting the gear shift, the sleeve 61 is in the neutral position, the sleeve teeth 61t are not in contact with the front and rear synchro springs 64, and the synchronous operation occurs. Absent.

When shifting is started and the sleeve 61 moves to the right, as shown in FIG. 9(2), the sleeve teeth 61t of the sleeve 61 come into contact with the synchro spring 64, and the blocking ring 63 is moved to the shifting gear via the synchro spring 64. It can be pressed to the 66 side.

Further, when the sleeve 61 moves to the right, the blocking ring 63 is pressed against the transmission gear 66 side, as shown in FIG. 9C, and the inner peripheral surface 63a of the blocking ring 63 and the projecting cylindrical portion 66ss of the transmission gear 66. A frictional force is also generated between the sleeve tooth 61t and the ring tooth 63t, and the chamfer surfaces 61c and 63c of the sleeve tooth 61t are brought into contact with each other so that synchronization is started (balk stage).

Further, when the sleeve 61 moves to the right, as shown in FIG. 9(4), the sleeve tooth 61t meshes with the ring tooth 63t so as to separate the ring tooth 63t, and the sleeve 61 and the blocking ring 63 are integrated. Rotate (ring tooth scraping stage).

Further, when the sleeve 61 moves to the right, as shown in FIG. 9(5), the sleeve teeth 61t come into contact with the gear dog teeth 66t of the transmission gear 66 at their apexes, and further, the chamfer surfaces 61c, 66c are contacted with each other. Contact (gear dog tooth contact stage).

Further, when the sleeve 61 moves to the right, as shown in FIG. 9(6), the sleeve tooth 61t meshes with the gear dog tooth 66t so as to separate the gear dog tooth 66t, and the synchronization ends (the gear dog tooth separating step). ).

By moving the sleeve 61 further to the right, as shown in FIG. 9(7), the sleeve tooth 61t completely meshes with the gear dog tooth 66t so that the sleeve 61 (and the odd-numbered stage shaft 31) and the transmission gear 66 are separated from each other. Rotate together (in gear stage).

The synchro mechanism S operates as described above, and connects the sleeve 61 and the transmission gear 66 while synchronizing them.

Next, the gear shift operation mechanism 70 that moves the sleeve 61 of the gear shift mechanism 60 will be described.

As shown in FIG. 6, the speed change operation mechanism 70 includes a shift motor 71, a reduction gear mechanism 72, a shift spindle 73, a master arm 74, a pole ratchet mechanism 75 that is an intermittent feed mechanism, a shift drum 110, a shift fork shaft 90, and It has a shift fork 91. The rotation driving force of the shift motor 71 is reduced by the reduction gear mechanism 72 to rotate the shift spindle 73, and the pole ratchet mechanism 75 intermittently moves the shift drum 110 via a master arm 74 that rotates integrally with the shift spindle 73. The shift fork 91 is moved by rotating the shift fork 91, and each sleeve 61 of the speed change mechanism 30 is moved in the axial direction to switch the shift speed of the speed change mechanism 30.

As shown in FIGS. 3 and 5, the shift drum 110 of the speed change operation mechanism 70 is arranged below the odd-numbered stage shaft 31 so as to be parallel to the rotation axis of the crankshaft 23.
As shown in FIG. 6, the shift drum 110 includes a cylindrical main body portion 111 having an opening portion 111b on one side (on the right side) and a bottom portion 111c on the other side (on the left side), and an opening portion 111b. It is configured by a lid portion 112 that closes the inside, and is configured in a hollow cylindrical shape inside.
The body portion 111 of the shift drum 110 is provided with a shaft portion 114 that extends leftward coaxially with the body portion 111 and has a smaller diameter than the body portion 111 of the shift drum 110. The lid portion 112 of the shift drum 110 is provided with a shaft portion 113 that extends coaxially with the main body portion 111 of the shift drum 110 to the right and has a diameter smaller than that of the main body portion 111.
Four lead grooves 111a are provided on the outer circumferential surface of the main body 111 in the radial direction.

The right end 110a, which is one end of the shift drum 110, is rotatably supported by the lower transmission case half 22D via a ball bearing 88 serving as a first bearing member. On the left side of the shift drum 110, a shaft portion 114 extending from the main body portion 111 of the shift drum 110 is rotatably supported by the lower transmission case half body portion 22D via a needle bearing 89.

An intermittent feed mechanism 68 for intermittently rotating the shift drum 110 is provided at the right end of the shift drum 110. The intermittent feeding mechanism 68 includes a guide plate 121 for restricting the movement of a pole ratchet 77 of a pole ratchet mechanism 75 described later.

The shift motor 71 is attached to the left unit case cover 28L on the left side of the lower transmission case half body 22D. The reduction gear mechanism 72 is provided between the lower transmission case half portion 22D and the left unit case cover 28L, and is composed of a drive gear 72a formed integrally with the motor shaft 71a of the shift motor 71, and a large and small gear. The first and second gears 72b and 72c and the driven gear 72d fitted to the shift spindle 73 are included.

Shift spindle 73 is rotatably supported via a bearing in the lower left of the lower transmission casing halves 22D and the left unit case cover 28L. A master arm 74 is welded to the right end portion of the shift spindle 73 so that the shift spindle 73 and the master arm 74 can rotate integrally. The rotation of the shift spindle 73 causes the master arm 74 to swing. ..

As shown in FIGS. 6 and 14, a pin 79p penetrating the restriction hole 74b formed in the master arm 74 is provided so as to project from the lower transmission case half body portion 22D, and the coil portion is wound around the shift spindle 73. The supported torsion coil spring 79 is attached such that both ends extending in the same direction sandwich the locking piece 74a formed on the master arm 74 and the pin 79p from both outsides.
Therefore, when the master arm 74 swings, an urging force acts to return the master arm 74 to the neutral position by the torsion spring force of the torsion coil spring 79.

The swing of the master arm 74 rotates the shift drum 110 via the pole ratchet mechanism 75.
As shown in FIGS. 6 and 13 to 15, the pole ratchet mechanism 75 has a projection 76d slidably fitted in a long hole 74h formed at the swinging tip of the master arm 74. A shifter body 76 as a ratchet input member, a drum center 78 as a ratchet output member that rotates integrally with the shift drum 110, and a pair of built-in units between the outer periphery of the shifter body 76 and the inner periphery of the drum center 78. It has a pole ratchet 77 and a guide plate 121 for restricting the movement of the pole 77a of the pole ratchet 77.

As shown in FIG. 13, the drum center 78 includes a base portion 78a having a shaft insertion hole 78b and a recess 78c, through which the shaft portion 113 of the shift drum 110 is inserted, and a base portion 78a in the axial direction from the base portion 78a. The detent cam 78e projects outward and the cam portion 78d has a pole contact cam 78f formed on the inner peripheral surface.
The drum center 78 is inserted through the shaft insertion hole 78b into the shaft portion 113 of the shift drum 110 and the nut 116 is fastened, and the detent pin 115 between the lid portion 112 of the shift drum 110 and the drum center 78 allows the shift drum 110 to move. It is designed to rotate together with.

As shown in FIG. 13, the shifter main body 76 is housed inside the cam portion 78d of the drum center 78 and the base portion 76a that rotates in the opening 121c of the guide plate 121, and the pole operation portion that operates the pole 77a. It has 76b and an arm portion 76c provided with a protrusion 76d that engages with the master arm 74. The shifter body 76 is formed with an insertion hole 76e into which the shaft portion 113 of the shift drum 110 is inserted, and the shifter body 76 is rotatably supported axially outward from a drum center 78 of the shaft portion 113. There is.

As shown in FIG. 15, the pole ratchet 77 includes a pole 77a, a pressing member 77b that contacts the pole 77a, and a spring member 77c.
According to the shape of the inner edge of the opening 121c of the guide plate 121, the pole 77a stands up only in a predetermined range.
When the shifter body 76 is rotated in one direction by being guided by the projection 76d that slides in the long hole 74h by the swing of the master arm 74, the tip of one pole 77a stands up and the inner circumference of the drum center 78 is increased. The drum center 78 is intermittently rotated in association with the rotation of the shifter main body 76 by being locked by the pole abutment cam 78f, and shifts gears by intermittently rotating the shift drum 110.

For intermittent rotation of the shift drum 110, a detent mechanism 80 that guides and positions the shift drum 110 to a predetermined rotation position is provided.
On the outer peripheral end surface of the detent cam 78e, which is provided on the outer peripheral portion of the drum center 78 that rotates integrally with the shift drum 110, curved concave portions corresponding to the shift speed are alternately arranged with convex portions that are tapered in the circumferential direction. Is formed on the concavo-convex cam surface 78e ₁ .

With reference to FIG. 14, a roller 85 is rotatably supported at the tip of a detent arm 84 pivotally supported by a support shaft 83.
The detent arm 84 is urged to swing by a torsion coil spring 86 and presses the roller 85 against the uneven cam surface 78e ₁ of the detent cam 78e.
The detent mechanism 80 is configured as described above, and the roller 85 pressed by the concave-convex cam surface 78e ₁ on the outer peripheral end surface of the detent cam 78e settles in the required concave portion to position the shift drum 110 at the required rotational position. can do.

As shown in FIGS. 6 and 13, the end portion 113a of the shaft portion 113 of the shift drum 110 is rotatably held by the support member 120 as shown in FIG. The support member 120 includes a guide plate 121 of the intermittent feeding mechanism 68 and a holding portion 122 attached by a nut 123.

As shown in FIG. 17, the guide plate 121 that constitutes the support member 120 has a plate-like shape, and includes a base 121a having an opening 121c, and a pair of flanges 121b extending from both sides of the base 121a. Have. The opening 121c restricts the movement of the pole 77a of the pole ratchet 77. At the end of the flange 121b, a bolt insertion hole 121d through which the bolt 126 is inserted is provided. A pair of pin mounting holes 121e is formed near the base portion 121a of the flange portion 121b. As shown in FIG. 16, a fixing pin 121f for fixing the holding portion 122 is caulked into the pin mounting hole 121e. As shown in FIG. 13, the guide plate 121 is fixed to the lower transmission case half body portion 22D by bolts 126.

As shown in FIGS. 13 and 16, the holding portion 122 attached to the guide plate 121 includes a base 122a having a cylindrical shape and a circular recess 122c provided on the guide plate 121 side, and a pair of bases 122a extending from both sides of the base 122a. Has a flange portion 122b. The center of the base portion 122a is an opening portion 122d that opens in a circular shape.

As shown in FIG. 13, a ball bearing 125 as a second bearing member is fitted in the recess 122c of the base 122a. The ball bearing 125 rotatably supports the end 113a of the shaft 113 of the shift drum 110. A columnar leg portion 122e protruding toward the guide plate 121 side is formed from the end portion of each flange portion 122b. The leg portion 122e is provided with a pin through hole 122f through which the fixed pin 121f of the guide plate 121 is passed.

After the shifter main body is inserted into the holding portion 122, the collar member 124 is fitted to the shaft portion 113 of the shift drum 110, inserted into the inner peripheral surface of the ball bearing 125, and the pin 122 of the leg portion 122e of the holding portion 122 is inserted. The fixing pins 121f of the guide plate 121 are inserted into the holes 122f and the nuts 123 are fastened to the fixing pins 121f, so that the guide plate 121 and the holding portion 122 are integrated.
When viewed from the axial direction, the base portion 76a of the shifter main body 76 is smaller than the opening 121c of the guide plate 121, but the collar member 124 provided between the ball bearing 125 and the shifter main body 76 allows the shifter main body 76 to be axially outside. There are restrictions on movement to.

The right unit case cover 28R is attached to the lower transmission case half body 22D at an axially outer side of the shaft portion 113 of the shift drum 110, and a functional component is provided between the shaft portion 113 and the right unit case cover 28R. A hydraulic control valve 130 is installed. The hydraulic control valve 130 is a linear solenoid and controls connection/disconnection of the first clutch 47A and the second clutch 47B.

As shown in FIGS. 3 and 5, above and behind the shift drum 110, a shift fork shaft 90 is fitted at both ends to the lower transmission case half body 22D and supported in parallel with the shift drum 110. Has been done. Four shift forks 91 are supported on the shift fork shaft 90 so as to be movable in the axial direction.

As shown in FIG. 5, the shift fork 91 includes a base 91a having a shaft insertion hole 91b through which the shift fork shaft 90 is inserted, and a two-pronged direction from the base 91a in a direction orthogonal to the shift fork shaft 90. It has an extending fork portion 91c and a pin portion 91d provided on the opposite side of the fork portion 91c with the base portion 91a interposed therebetween.
The fork portion 91c is engaged with a fork engaging groove 61a formed in the sleeve 61. The pin portion 91d is engaged with each lead groove 111a formed on the outer peripheral surface of the shift drum 110.

When the shift drum 110 is rotated by driving the shift motor 71 of the speed change operation mechanism 70, the corresponding shift forks 91 are axially moved by being guided by the lead grooves 111a formed on the outer peripheral surface of the shift drum 110. As a result, each sleeve 61 is moved in the axial direction, and the shift speed is switched.

In the present embodiment, the sleeve 61 without the transmission gear is used as the transmission switching mechanism 60, but a shifter gear provided with the transmission gear integrally with the sleeve may be used.

In the transmission T, as shown in FIG. 3, the diameter d3 of the idle gear 53 is set to be larger than the diameter d1 of the transmission gear 51 and the diameter d2 of the transmitted gear 52. That is, the diameters of the two gears, the transmission gear 51 and the transmitted gear 52, are reduced, and only one of the idle gears 53 has a large diameter. With this configuration, the size of the power unit P in a side view can be made smaller than that of the idle gear having a small diameter and the two gears of the transmission gear and the transmitted gear having a large diameter.

On the other hand, since the diameter d1 of the transmission gear 51 and the diameter d2 of the transmitted gear 52 are smaller than the diameter d3 of the idle gear 53, both the number of the transmission gear 51 and the number of the transmitted gear 52 are small. Will end up. In this way, it becomes difficult to finely adjust the ratio between the transmission gear 51 and the transmission gear 52 having a small number of gears.

FIG. 10 is a schematic diagram of the transmission T in which the first-speed drive gear m1 and the second-speed drive gear m2 of the drive gears are taken as an example. FIG. 11 shows the ratio of each shift stage. The thin broken line is the target ratio, the thick broken line is the ratio only by shifting the transmission gears (m1 to m8, c1 to c4), and the black arrow is the transmission gear 51 and the transmitted gear. The solid line indicates the speed increase amount due to the gear 52, and the total ratio is the total ratio of the ratio due to the transmission gear 51 and the speed increase amount due to the transmitted gear 52.

As shown in FIGS. 3 and 10, the odd-stage shaft 31, the even-stage shaft 32, and the output shaft 33 have an inter-axis length D1 between the odd-stage shaft 31 and the output shaft 33, and the even-stage shaft 32 and the output shaft 33. It is arranged so as to be longer than the inter-axis length D2. That is, since the diameter d1 of the transmission gear 51 is made larger than the diameter d2 of the transmitted gear 52, the ratio transmitted from the transmission gear 51 to the transmitted gear 52 is greatly increased. The ratio of the transmission gears 51 and the transmission gears 52 having a diameter larger than that of the transmission gears 52 (m1 to m8, c1 to c4) can be adjusted more easily, so that even-numbered stages can be finely adjusted to lower ratios than odd-numbered stages. The target ratio is achieved by decelerating.

The power unit P for the saddle riding type vehicle of the present embodiment is configured as described above. The power unit P stores the power of the internal combustion engine E, the odd-stage shaft 31 and the even-stage shaft 32 to which the power from the crank shaft 23 is transmitted, and the power of the crank shaft 23 and the odd-stage shaft 31 housed inside the unit case 20. A twin clutch type clutch device 47 in which a first clutch and 37A which are connected/disconnected and a second clutch 37B which is connected/disconnected to and from the crankshaft 23 and the even-numbered shaft 32 are selectively connected to transmit power, and an odd-numbered-stage shaft 31 or the even-numbered stage shaft 32 selectively transmits the power, the odd-numbered stage drive gears m1, m3, m5, m7 provided on the odd-numbered stage shaft 31, and the even-numbered stage shaft 32. Drive gears m2, m4, m6, m8 at even stages and a plurality of drive gears m1, m3, m5, m7 at even stages provided on the output shaft 33 and drive gears m2 at even stages. A plurality of driven gears c1, c2, c3, c4 meshing with m4, m6, m8, respectively, and a drive gear m1, m3, m5, m7 from the odd-numbered stage shaft 31 provided on the odd-numbered stage shaft 31. The force is applied to the even-stage shaft 32 and the sleeve 61 as the gear changeover mechanism 60 that connects and disconnects the force by axial movement and the even-stage shaft 32 to the even-stage drive gears m2, m4, m6 and m8. An odd-numbered stage shaft 31, which includes a sleeve 61 as a speed change mechanism 60 that connects and disconnects due to movement in the axial direction, a shift fork 91 that moves the sleeve 61 in the axial direction, and a shift drum 110 that drives the shift fork 91. The even-numbered shaft 32, the output shaft 33, and the shift drum 110 are arranged in parallel, and as shown in FIG. 3, the output shaft 33 is arranged rearward of the crank shaft 23 in the side view of the motorcycle 1, and the odd-stage shaft is arranged. 31 and the even-stage shaft 32 are arranged rearward of the crankshaft 23, and the odd-stage shaft 31 is provided on the opposite side of the even-stage shaft 32 with respect to the line L1 connecting the crankshaft 23 and the output shaft 33. 110 is arranged on the opposite side of the output shaft 33 with respect to the line L2 connecting the odd-stage shaft 31 and the even-stage shaft 32.

The transmission T of the present embodiment is configured as described above, and therefore has the following effects.

The shift drum 110 is supported by the lower transmission case half 22D, and the right end 110a of the shift drum 110 is formed by a ball bearing 88 arranged between the end 110a and the lower transmission case half 22D. A shaft 113, which is rotatably supported and has a diameter reduced from that of the shift drum 110, is provided coaxially with the shift drum 110 at an end 110a of the shift drum 110. The end 113a of the shaft 113 is a lower transmission case half. Since it is rotatably held by the support member 120 that is separate from the body portion 22D, the shift drum 110 is held by the ball bearing 88 and the end 113a of the shaft 113 is also supported by the support member 120. The amount of deflection of the shaft portion when the shift drum 110 rotates can be reduced, and the rotation of the shift drum 110 can be made smooth. Further, the shaft portion 113 of the shift drum 110 can be made thin, which contributes to downsizing of the transmission T.

Further, the support member 120 is fixed to the lower transmission case half body 22D provided with the ball bearing 88, and the ball bearing 125 is provided between the end 113a of the shaft portion 113 and the support member 120. Since the end portion 113a is rotatably supported by the support member 120 via the ball bearing 125, the shaft portion 113, which is a rotating body, is connected to the lower transmission case half body portion 22D side via the support member 120. It can be easily held by.

The transmission T includes a pole ratchet mechanism 75 that intermittently feeds the shift drum 110, and the support member 95 includes a guide plate 121 of the pole ratchet mechanism 75 and a holding portion 122 attached to the guide plate 121. Since the guide plate 121 is attached to the lower transmission case half portion 22D, the holding portion can be easily fixed by providing the holding portion 122 on the guide plate 121 of the existing component.

Furthermore, the pole ratchet mechanism 75 includes a shifter main body 76 rotatably supported by the shaft portion 113 of the shift drum 110, and the protrusion 76d provided on the shifter main body 76 and engaged with the master arm 74 is provided on the shift drum 110. The shaft portion 113 is provided on the shift spindle 73 side with respect to the shaft portion 113, the shaft portion 113 penetrates the shifter main body 76, and is held by the holding portion 122 on the outer side in the axial direction. The interference with 113 can be prevented.

Further, since the shift of the shifter main body 76 in the axial direction is restricted by the collar member 124 provided between the ball bearing 125 and the shifter main body 76, the shifter main body 76 moves in the axial direction with the guide plate 121. The friction between them can be reduced.

Furthermore, since the right unit case cover 28R is attached to the lower transmission case half body portion 22D, which is located on the axially outer side of the shaft portion 113, the shaft portion 113 is fixed by fixing the holding portion 122 to the guide plate 121. Since a space can be secured outside the end portion 113a in the axial direction, functional components such as the hydraulic control valve 130 can be arranged between the shaft portion 113 and the right unit case cover 28R.

Furthermore, the shift drum 110 is composed of a cylindrical main body portion 111 having an opening portion 111b that is open at least on one side in the axial direction, and a lid portion 112 that closes the opening portion, and the shaft portion 113 is a lid portion 112. Since it is integrally formed, the inside of the main body 111 can be processed, and the weight can be reduced. On the other hand, since the inside of the main body 111 can be cut by machining after the main body 111 is manufactured by casting, the accuracy can be improved and the main body 111 can be thinly processed to reduce the weight.

In the present embodiment, the holding portion 122 is attached to the guide plate 121 with the nut 123, but as shown in FIG. 18, it may be fixed with the circlip 127 to the fixing pin 121f through which the holding portion 122 is inserted. .. Further, the functional component arranged between the shaft portion 113 and the right unit case cover 28R may be an oil chamber for storing oil.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and various design changes can be made without departing from the scope of the invention. Of course, straddle-type vehicles, power units, and the like include those implemented in various modes.
For convenience of explanation, the left and right arrangements of the illustrated embodiment have been described, but even if the left and right arrangements are different, the present invention is included within the scope of the gist of the invention.

T... transmission,
22... transmission case, 28R... right unit case cover, 73... shift spindle, 74... master arm, 75... pole ratchet mechanism, 76... shifter body, 76a... base, 88... ball bearing,
110... Shift drum, 110a... End part, 111... Main body part, 111b... Opening part, 112... Lid part, 113... Shaft part, 113a... End part
120... Support member, 121... Guide plate, 121c... Opening part, 122... Holding part, 124... Collar member, 125... Ball bearing, 130... Oil chamber.

Claims (7)

In the transmission (T) having the shift drum (110) supported by the case body (22),
One end portion (110a) of the shift drum (110) is rotatably supported by a first bearing member (88) arranged between the end portion (110a) and the case body (22). ,
A shaft to which a force for rotating the shift drum (110) is applied to the end portion (110a) of the shift drum (110) coaxially with the shift drum (110) and having a diameter smaller than that of the shift drum (110). Part (113) is provided,
Located on the outside in the axial direction of the shaft portion (113), a case cover member (28R) is attached to the case body (22),
An end portion (113a) of the shaft portion (113) is disposed between the case body (22) and the case cover member (28R) and is fixed to the case body (22 ). Therefore, the transmission is characterized by being rotatably held. Between the end portion of the front Kijiku portion (113) (113a) and said supporting member (120), a second bearing member (125) is provided,
The transmission according to claim 1, wherein the end portion (113a) is rotatably supported by the support member (120) via the second bearing member (125). A pole ratchet mechanism (75) for intermittently sending the shift drum (110) is provided,
The pole ratchet mechanism (75) includes a pole ratchet (77) and a guide plate (120) for restricting the movement of the pole ratchet (77),
The support member (120) includes a guide plate (121) in the pole ratchet mechanism (75) and a holding portion (122) attached to the guide plate (121 ) and holding the second bearing member (125). Have,
The transmission according to claim 2, wherein the guide plate (121) is attached to the case body (22). The pole ratchet mechanism (75) includes a shifter body (76) rotatably supported by the shaft portion (113) of the shift drum (110),
A protrusion (76d) provided on the shifter body (76) and engaged with the master arm (74) is provided on the shift spindle (73) side with respect to the shaft portion (113),
The shaft portion (113), the transmission device according to claim 3, wherein through the shifter body (76), characterized in that it is held by the holding portion in the axially outer (122). A collar member (124) provided between the second bearing member (125) and the shifter body (76) is used to restrict the movement of the shifter body (76) outward in the axial direction. Item 5. The transmission according to Item 4. Transmission according to any one of claims 1 to 5, characterized in that are arranged functional parts (130) between the front Kijiku portion (113) and the case cover member (28R). The shift drum (110) is composed of a cylindrical main body portion (111) having an opening portion (111b) that is open at least on one side in the axial direction, and a lid portion (112) that closes the opening portion (111b). The transmission according to any one of claims 1 to 6, wherein the shaft portion (113) is formed integrally with the lid portion (112).

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