JP5258486B2 - Shaft drive motorcycle - Google Patents

Description

  The present invention relates to a shaft drive type motorcycle including a drive shaft.

2. Description of the Related Art A shaft drive type motorcycle that includes a drive shaft on the side of a pivot shaft and transmits engine driving force to a rear wheel by this drive shaft is known (for example, see Patent Document 1).
JP 2008-87540 A (FIG. 3)

  In FIG. 3 of Patent Document 1, on the left side of the vehicle, a swing arm 12 (hereinafter referred to as “swing arm 12”) on which a rear wheel 2 (reference numeral is diverted from the same publication) is swingably suspended. ), A gear box 44 is provided at the rear of the swing arm 12, and a drive shaft 45 for transmitting engine power to the rear wheel 2 is provided inside the swing arm 12. A drive axle 56 (hereinafter referred to as “rear wheel axle 56” passes therethrough, and the rear wheel 2 is attached to the rear wheel axle 56.

  Although not disclosed in Patent Document 1, lubrication oil is put in the gear box 44, an oil seal is provided between the gear box 44 and the rear wheel axle 56, and oil leaks. In order to make it difficult, in addition to the oil seal, a labyrinth plate having a labyrinth structure is provided to improve oil sealability and prevent intrusion from outside such as mud and water.

  However, in the above structure, a labyrinth plate having a labyrinth structure or the like is required as a separate part, which increases the number of parts and increases the vehicle cost.

  An object of the present invention is to provide a technique for reducing the cost of a vehicle in a shaft drive type motorcycle having a labyrinth structure that makes it difficult for oil leakage from a gear box to occur.

According to the first aspect of the present invention, there is provided a vehicle body frame, a swing arm provided on the vehicle body frame for swingably supporting a rear wheel, and provided in or adjacent to the swing arm. A drive shaft for transmitting to a rear wheel axle provided on the rear wheel, a constant velocity joint interposed in the drive shaft, a pinion gear provided at one end of the drive shaft and meshing with a final gear provided on the rear wheel axle, and a swing In a shaft drive type motorcycle provided with a gear box provided at the rear part of the arm and accommodating a final gear, the gear box is provided with an opening through which the rear wheel axle is passed, and the rear wheel axle is provided with a rear A pulsar ring that measures the wheel speed of the wheel is provided, and inside this pulsar ring in the radial direction, there is an opening in the vehicle width direction. A labyrinth wall portion extending to the side is integrally provided, and the pinion gear is composed of a tooth portion and a cylindrical portion extending forward from the tooth portion, and a through hole is provided in the cylindrical portion, and the first half of the through hole The part is formed with a female spline that fits with a male spline provided on a shaft part that extends rearward at the rear part of the constant velocity joint, and a pinion shaft is inserted in the rear part.

The invention according to claim 2 is characterized in that an inner wall extending toward the center of the rear wheel axle is provided at the rear wheel side end of the opening.

  In the invention according to claim 1, the rear wheel axle is provided with a pulsar ring for measuring the wheel speed of the rear wheel, and a labyrinth wall portion extending in the vehicle width direction is integrally provided inside the pulsar ring in the radial direction.

  The gear box is filled with lubricating oil, and an oil seal is provided between the gear box and the rear axle, and a labyrinth member having a labyrinth structure is provided outside the oil seal to enhance the sealing effect. Etc. are provided.

Conventionally, in order to form a labyrinth structure, a labyrinth member has been required as a separate member. As a result, the number of parts increases, which may lead to an increase in the cost of the vehicle.
In this respect, in the present invention, since the labyrinth wall portion is integrally provided on the pulsar ring, an increase in the number of parts can be suppressed. If the increase in the number of parts can be suppressed, the cost of the vehicle can be reduced.

In the invention according to claim 2 , since the inner wall extending toward the center of the rear wheel axle is provided at the rear wheel side end of the opening, the gear box is further provided with an end on the rear wheel side, Labyrinth can be provided. Therefore, oil leakage from between the gear box and the rear wheel axle can be further suppressed.

  The best mode for carrying out the present invention will be described below with reference to the accompanying drawings. In the figure, “up”, “down”, “left”, “right”, “front”, and “rear” are directions viewed from the occupant seated in the vehicle. The drawings are viewed in the direction of the reference numerals.

FIG. 1 is a left side view of a vehicle according to the present invention. A motorcycle 10 as a vehicle is provided with a body frame 11.
The vehicle body frame 11 includes a head pipe 12, a main frame 14 that extends rearward from the head pipe 12 and supports the engine 13, and extends rearward from the upper rear end of the main frame 14 to support the occupant seat 15. And a rear frame 19 for attaching an electrical component such as 16 and supporting a vehicle body rear portion 18 including a rear fender 17.
The main frame 14 includes a pivot plate 22 provided at the rear end of the main frame 14 and supporting the swing arm 28.

  A pivot shaft 27 is provided on the pivot plate 22, and a rear swing arm 28 (swing arm 28) extends rearward from the pivot shaft 27, and a rear that absorbs an impact between the swing arm 28 and the main frame 14. A cushion unit 29 is provided, and a rear wheel 31 is attached to the tip of the swing arm 28. The rear wheel 31 is driven by a drive shaft 32 that connects between the engine 13 and the rear wheel 31 and transmits the driving force of the engine 13 to the rear wheel 31.

  The head pipe 12 is provided with a front fork 24, a front wheel 25 is attached to the lower end portion of the front fork 24, and a steering handle 26 for steering the front wheel 25 is provided at the upper end portion of the front fork 24.

  An engine 13 (V-type four-cylinder engine 13) is mounted on the main frame 14. The engine 13 is supported by the main frame 14 via first to fourth support points 30a to 30d. The first to fourth support points 30a to 30d are provided horizontally in the vehicle width direction and are arranged in this order from the front to the rear of the vehicle. Among these support points, the third to fourth support points 30 c to 30 d are provided on the pivot plate 22. That is, the engine 13 is suspended by the main frame 14 and the pivot plate 22.

  The V-type four-cylinder engine 13 includes a crankcase 37, a front cylinder 35 extending obliquely forward and upward with a crankshaft 34 provided in the crankcase 37 as a center, and extending obliquely rearward and upward with the crankshaft 34 as a center. After that, the cylinder 36 is arranged in a V shape. In the V-type four-cylinder engine 13, when the vehicle is viewed from the side, the main frame 14 overlaps the front cylinder 35 and the rear cylinder 36 that constitute the upper part of the engine 13, and the crankcase that constitutes the rear part of the engine 13. 37 is suspended so that a part of the pivot plate 22 overlaps.

The V-type four-cylinder engine 13 is provided with an exhaust device 33.
The exhaust device 33 includes exhaust pipes 41 a to 41 d extending from the cylinders 35, 35, 36, 36, a catalyst pipe 45 that collects the exhaust pipes 41 a to 41 d and purifies exhaust gas, and the catalyst pipe 45. And a muffler 47 connected to the general collecting pipe 46.

  In the figure, 51 is a radiator unit for cooling the engine 13, 52L, 52R (only the front side reference numeral 52L is shown, the same applies hereinafter), front disk brake caliper provided on the front fork, 53L, 53R (front side reference numeral 53L only) The same applies hereinafter.) Is provided on the front wheel 25 and is held between the front disc brake calipers 52L and 52R, 54 is a front master cylinder provided on the steering handle, 56 is a fuel tank attached to the main frame 14 and covers a fuel tank. The fuel tank covers 57L and 57R (only the front side reference numeral 57L are shown, the same applies hereinafter) also serving as the cowl portion 70 to be attached are shown to the driver steps 58L and 58R (only the front side reference numeral 58L attached to the main frame 14). The same shall apply hereinafter) for the rear frame 19. Steps for passengers, 59, headlights, 60, front fenders, 61L, 61R (only reference numeral 61L on the front side is shown), mirrors, 62, rear disc brake calipers, 63, rear wheels 31 A rear brake disc 65, which is clamped by the disc brake caliper 62, is a main stand.

Hereinafter, the cowl part 70 which mainly constitutes the exterior part of the motorcycle 10 will be described.
The cowl portion 70 includes a front cowl portion 72 that extends from the head pipe 12 and covers the front of the vehicle body frame 11 via a cowl stay 71 described later, and a side cowl portion that is provided continuously from the front cowl portion 72 and covers the side of the vehicle. 73 and an under cowl 74 provided below the engine 13 for the purpose of improving wind protection and the appearance of the vehicle.

  The front cowl 72 includes an upper center cowl 76 that covers the top of the headlight 59, a wind screen 77 that extends above the upper center cowl 76, and middle cowls 78L and 78R that cover the sides of the main frame 14 (see FIG. The front upper side cowl 79L and 79R (only the front side reference numeral 79L is shown. The same applies hereinafter) to which the left and right sides of the wind screen 77 are attached are shown. .

  The side cowl portion 73 covers the front upper side cowls 79L and 79R that support the left and right sides of the wind screen 77, the middle cowls 78L and 78R that cover the sides of the head pipe 12 and the main frame 14, and the lower part of the fuel tank cover 56. Knee covers 81L and 81R (only the reference numeral 81L on the front side of the figure is shown; the same applies hereinafter) sandwiched between the legs Rf of the driver R during driving, and components of the main frame 14 provided below these knee covers 81L and 81R Pivot plates 22L and 22R (only the reference numeral 22L on the front side of the figure is shown. The same applies hereinafter) pivot plate covers 82L and 82R that cover the outer surface.

  Supplementing the rear structure of the vehicle, a gear box 124 having a rear wheel axle 40 is provided inside the rear portion of the swing arm 28, and a tightening portion 125 for fastening the gear box 124 to the swing arm 28 is provided. The tightening portion 125 is provided with a gear box cover 126 that covers the outer surface of the gear box 124 from the side.

  The tightening portion 125 is provided with a flange portion 131 provided on the swing arm 28 side, and is attached to the flange portion 131 and screwed into the gear box 124 from the swing arm 28, and between the rear swing arm 28 and the gear box 124. Fastening members 132 to be fixed are provided.

FIG. 2 is a side view of the main part of the motorcycle according to the present invention, and FIG. 3 is a cross-sectional view of the main part of the motorcycle according to the present invention. Hereinafter, description will be given with reference to FIGS.
The motorcycle 10 according to the present invention can be called a shaft drive type motorcycle 10 because the drive shaft 32 is used as means for transmitting the driving force of the engine (reference numeral 13 in FIG. 1) to the rear wheel 31. .

The shaft drive type motorcycle 10 is rotated via a rear wheel axle 40 at a rear portion of the swing arm 28 and a swing arm 28 swingably provided on the pivot shaft 27. A rear wheel 31 that is pivotally supported, and a rear cushion 29 (rear cushion unit 29) interposed between the swing arm 28 and the vehicle body frame 11 are provided. A drive shaft 32 that transmits the driving force of the engine 13 to the rear wheel 31 is provided inside the swing arm 28.
In this embodiment, the drive shaft is provided in the swing arm, but may be provided adjacent to the swing arm.

  The drive shaft 32 is connected to the output shaft 111 from the engine (reference numeral 13 in FIG. 1) to transmit a driving force, and the drive shaft 32 is connected to the rear end 113b of the universal joint 113 to transmit the driving force of the engine 13. It comprises a drive shaft 112 for transmission, a constant velocity joint 115 that is attached to the rear end 112b of the drive shaft 112 and can change the axial length of the drive shaft 112, and a pinion gear 117 connected to the constant velocity joint 115. ing.

  The driving force of the engine 13 is transmitted to the rear wheel axle 40 by the pinion gear 117 and the final gear 118 that meshes with the pinion gear 117. In the figure, reference numerals 121 and 123 denote bearing portions that support the pinion gear 117. The details of the pinion gear 117 mounting structure will be described later.

Hereinafter, the configuration of the swing arm and the positional relationship between the swing arm and the drive shaft will be described.
The center axis 32J of the drive shaft is disposed below the line 28C connecting the pivot shaft 27 and the axle shaft 40 (rear wheel axle 40) of the rear wheel 31 when the vehicle body is viewed from the side. A line 28 </ b> C connecting 27 and the axle shaft 40 of the rear wheel 31 penetrates the swing arm 28 forward and backward, and the swing arm 28 is provided so as to surround the drive shaft 32.

  The swing arm 28 has a hollow portion 28e, and the front portion 28a has an upper space 28eu and a lower space 28eb partitioned by a partition member 134, and the drive shaft 32 is provided in the lower space 28eb. .

  Since the swing arm 28 is provided with the partition member 134 at the front portion 28a, the rigidity around the pivot shaft 27 can be increased. In addition, the torsion center of the swing arm 28 can be brought closer to the pivot shaft 27 in the height direction. If the torsion center of the swing arm 28 can be brought closer to the pivot shaft 27, the behavior characteristic of the rear wheel 31 during cornering can be brought closer to that of a general motorcycle, so that appropriate maneuverability is maintained during cornering. Can be made.

  The swing arm 28 is provided with a notch 133 at the lower part of the front end 28aa, and the notch 135 is closed by a cover member 137, and the cover member 137 covers the front part of the drive shaft 32. . Since the cover member 137 is made of resin, the weight can be reduced.

At the rear end of the swing arm 28, a gear box 124 that houses the rear wheel axle 40 and its surrounding drive system components is disposed.
The swing arm 28 is provided with a first arm member 142 extending from the vehicle body frame 11 via the first swing shaft 141 so as to be swingable, and a second swing shaft 143 from an intermediate portion 28 m of the swing arm 28. A second arm member 144 having a substantially triangular shape when viewed from the side and extending forward, and a rear cushion unit 29 (rear) between the front end 144a of the second arm member 144 and the vehicle body frame 11. A cushion 29) and a third swinging shaft 145 for swingably attaching the tip of the first arm member 142 to the intermediate portion 144 of the second arm member 144 are provided, and vibrations applied to the swing arm 28, etc. To absorb. Reference numeral 148 denotes a boot, and reference numerals 149 a and 149 b denote bolts for attaching the gear box cover 126 to the swing arm 28.

  The swing arm 28 is notched at the lower part of the front end 28aa, so that the rigidity of the swing arm 28 below the pivot shaft is lowered. By reducing the rigidity of the swing arm 28 on the lower side of the pivot shaft, the torsion center of the swing arm 28 can be made closer to the pivot shaft 27 in the height direction, and appropriate torsional characteristics can be set. Become.

A brake hose 139 connected to the rear brake caliper 62 is covered with a gear box cover 126.
Since the brake hose 139 is covered with the gear box cover 126 so that the brake hose 139 cannot be seen, the appearance around the rear brake caliper 62 can be further enhanced.

  4 is a cross-sectional view taken along line 4-4 of FIG. 2. The rear wheel drive mechanism 110 includes a drive shaft 32 and bearing portions 121 and 123 that rotatably support a pinion gear 117 that constitutes the rear portion of the drive shaft 32. A final gear 118 that meshes with a pinion gear 117 as a component of the drive shaft 32 and converts the direction of the driving force of the engine 13 by 90 °, and a sleeve 151 as a rear wheel axle 40 that is integrally attached to the final gear 118; The left bearing 152 and the right bearing 153 that rotatably support the sleeve 151 and the gear box 124 that supports the left bearing 152 and the right bearing 153 are main components.

  That is, the rear wheel drive mechanism 110 is accommodated in the swing arm 28 and a gear box 124 provided at the tip of the swing arm 28. The left and right bearings 152 and 153 are members that are provided between the gear box 124 and the rear wheel axle 40 and rotatably support the rear wheel axle 40.

The swing arm 28 is a member extending to the left side of the rear wheel 31, and the rear wheel 31 is supported in a cantilever manner.
In this embodiment, the swing arm 28 and the drive shaft 32 are disposed on the left side of the rear wheel 31, but may be disposed on the right side of the rear wheel 31.

A rear brake disk 63 and a rear wheel hub 31h included in the rear wheel 31 are integrally attached to a sleeve 151 as a rear wheel axle 40 rotatably provided in the gear box 124 via a fastening bolt 154. .
With the above configuration, the driving force applied to the final gear 118 as a driven gear is transmitted to the sleeve 151 and the rear wheel hub 31h to drive the rear wheel 31.
Details of the constant velocity joint 115 and the pinion gear 117 connected to the constant velocity joint 115 will be described below.

FIG. 5 is a cross-sectional view for explaining the internal structure of the gear box according to the present invention, which will be described with reference to FIG.
The constant velocity joint 115 has three sub-axes on the same plane and is connected to an input shaft 156 as a tripod portion for inputting the driving force of the engine 13 and to the input shaft 156 so as to be tiltable and slidable. And a boot 158 covering the front portion of the cup 157. Reference numeral 159 denotes a roller portion fitted to the sub shaft, and 161 denotes a groove fitted to the roller portion.
The front portion of the cup 157 is closed by a boot 158, and oil is injected into the cup 157.

The pinion gear 117 includes a tooth portion 162 and a cylindrical portion 163 extending forward from the tooth portion 162, and an inner peripheral portion 164 as a through hole is formed in the cylindrical portion 163, and the inner peripheral portion 164. A female spline 168 is formed in at least the front half of the inner peripheral portion 164, and a pinion shaft 166 that supports the rear end of the drive shaft 32 is inserted in the rear half of the inner peripheral portion 164.
In this embodiment, a female spline 168 is formed in the inner peripheral part 164 over the entire surface of the inner peripheral part 164 for convenience of processing, and a pinion shaft 166 is inserted into the rear half part of the inner peripheral part 164 having such a configuration. The pinion shaft 166 is attached to the pinion gear 117 through a circlip 185 so as not to move in the axial direction.
With such a configuration, the female spline 168 and the pinion shaft 166 can be easily provided on the pinion gear 117, and the cost of the pinion gear 117 is suppressed.
The outer peripheral portion 165 of the cylindrical portion 163 is supported by the bearing portion 121, and the outer peripheral portion 167 of the pinion shaft 166 is supported by the bearing portion 123.

A male spline 169 provided in the constant velocity joint 115 is provided with a first groove 174 in the circumferential direction. A circlip 173 is fitted in the first groove 174, and a circlip 173 is provided on the inner periphery of the pinion gear 117. Such a second groove 180 is provided.
By inserting the circlip 173 in the spline coupling portion 172, the spline coupling portion 172 can firmly attach the shaft portion 171 to the cylindrical portion 163, and can prevent the occurrence of axial vibration or the like. Become.

  A shaft portion 171 extends rearward from the cup 157 of the constant velocity joint, a male spline 169 is provided on the shaft portion 171, and a female spline that fits the male spline 169 on a cylindrical portion 163 extending forward from the pinion gear 117. 168 is provided to couple the male spline 169 and the female spline 168 together. That is, the spline coupling portion 172 is configured by the male spline 169 and the female spline 168.

The spline coupling portion 172 is disposed inside the bearing portion 121 that supports the cylindrical portion 163 as a pinion gear shaft as a shaft provided in the pinion gear 117. That is, since the spline coupling portion 172 is disposed so that a part thereof overlaps the bearing portion 121, the constant velocity joint 115 can be disposed closer to the bearing portion 121. Since the constant velocity joint 115 is disposed close to the bearing portion 121, the occurrence of vibration in the constant velocity joint 115 can be further suppressed.
In the present embodiment, the spline coupling portion is disposed inside the bearing portion. However, the spline coupling portion may be disposed outside the bearing portion.

  The gear box 124 is provided with a left bearing 152 that supports the left end of the rear wheel axle 40 and bearing portions 121 and 123 that support the pinion gear 117 and covers the left side of the vehicle, and a gear case 175 that is disposed to face the gear case 175 and that is opposed to the rear wheel axle. And a gear case cover 176 provided with a right bearing 153 for supporting the right end of 40.

  In such a gear box 124, a gear box front part 177 in which the pinion gear 117 is accommodated, a gear box left part 178 in which a left bearing 152 supporting the left side of the rear wheel axle 40 is accommodated, and a right side of the rear wheel axle 40 And a gear box right portion 179 in which a right bearing 153 for supporting the housing is accommodated.

The gear box front portion 177 includes a pinion gear 117, a bearing portion 121 that rotatably supports the outer periphery of a cylindrical portion 163 provided on the pinion gear 117, and a first inner race 121 c of the bearing portion 121 together with the cylindrical portion 163. A first lock nut 181, a second lock nut 182 that stops the outer race 121 a of the bearing 121 on a gear case 175 as a component of the gear box 124, and a first oil provided in front of the first and second lock nuts 181 and 182 A seal 183, a first retaining clip 184 provided in front of the first oil seal 183, a pinion shaft 166 inserted into the cylindrical portion 163 of the pinion gear 117 and supporting the rear portion of the pinion gear 117, and the pinion shaft 166 and the cylindrical portion Circlip 185 interposed between An O-ring 186 and a bearing portion 123 of the needle bearing for rotatably supporting the rear end of the pinion shaft 166, a stopper ring 188 provided on the outside of the bearing portion 123, and a.
Reference numeral 189 denotes a fastening hole into which the fastening member 132 is screwed.

The gear box left portion 178 includes a left bearing 152 that rotatably supports the left end of the rear wheel axle 40, a second shim ring 191 interposed between the inner race 152c of the left bearing 152 and the rear wheel axle 40, and a left A third lock nut 192 that stops the inner race 152c of the bearing 152 on the rear wheel axle 40, a fourth lock nut 193 that serves as a retainer that stops the outer race 152a of the left bearing 152 on the gear box 124, and for backlash measurement of the final gear 118. And a cap O-ring 195 as a seal member interposed between the cap 194 and the gear box 124.
The left bearing 152 includes an outer race 152a, a ball 152b, and an inner race 152c.

  The right portion 179 of the gear box is a right bearing 153 that rotatably supports the rear wheel axle 40 integrated with the final gear 118, and a position adjustment that is interposed between the inner race 153 c of the right bearing 153 and the rear wheel axle 40. A third shim ring 197, a pressing flange 211 for pressing the inner race 153c of the right bearing 153 in the axial direction of the rear wheel axle 40 from the outside of the vehicle to the inside through the screw member 198, and the pressing An axle oil seal 212 interposed between the flange 211 and the gear box 124, a retaining ring 214 for preventing the axle oil seal 212 from coming off, and a rear wheel provided on the holding flange 211 via bolts 215. The pulsar ring 216 that measures the wheel speed of 31 and the flat bolt 217 on the holding flange 211 (... Consists of the rear brake disc 63 which is provided through the same.). The following showing a plurality.

The holding flange 211 is attached to the holding flange 211 so that the cylindrical portion 219 is disposed between the axle oil seal 212 and the retaining ring 214 and the rear wheel axle 40.
The right bearing 153 is formed by arranging radial bearings composed of an outer race 153a, balls 153b, and an inner race 153c in two rows.

  The holding flange 211 is provided between the rear wheel axle 40 and the rear wheel hub 31h, and is provided in the radial direction of the rear wheel axle 40, to which the rear brake disk 63 as a brake disk is attached. A cylindrical portion 219 that is pressed in the axial direction of the wheel axle 40 is provided.

  In the figure, reference numeral 221 denotes a sensor provided on the swing arm 28 side to detect a wheel speed signal in combination with the pulsar ring 216, and 222 denotes a bolt for attaching the gear case cover 176 to the gear case 175.

FIG. 6 is a perspective view for explaining the holding flange attached to the rear wheel according to the present invention and its peripheral portion.
The rear wheel hub 31h is attached to a rear wheel axle (reference numeral 40 in FIG. 5) via five fastening bolts 154... And a flange portion 211 is attached to a pressing flange 211 that rotates integrally with the rear wheel hub 31h. The flange portion 211 includes five arm portions 256... That extend in the radial direction of the rear wheel axle 40, and a rear end portion of these arm portions 256. A brake disk 63 is attached.

  Returning to FIG. 5, a pressing flange 211 is provided between the rear wheel axle 40 and the rear wheel 31, and the rear brake disk 63 is attached to the pressing flange 211, so that the rear brake disk 63 is limited to a limited space. 63 can be arranged. In addition, a pulsar ring 216 is attached to the inside of the rear brake disk 63. Specifically, the pulsar ring 216 is attached to the inner side in the radial direction from the disk attaching portions 247... Provided on the flange portion 218. The holding flange 211 eliminates the need for the inner part of the rear brake disk 63, and the pulsar ring 216 can be mounted using the inner part of the rear brake disk 63, so that the structure around the rear brake disk can be made compact and thin. it can.

FIG. 7 is an exploded perspective view for explaining the periphery of the rear wheel axle according to the present invention.
First, components around the rear wheel axle will be described.
The rear wheel axle 40 fitted with the final gear 118 is inserted into the gear case 175 from the right side, the second shim ring 191 is inserted from the left side of the gear case 175, the left bearing 152 is inserted, and the left bearing 152 is connected to the third lock nut 192. And it stops with the 4th lock nut 193.

  From the right side of the gear case 175, the third shim ring 197 and the right bearing 153 are fitted to the rear wheel axle 40, the gear gear case cover 176 is attached to the right bearing 153, and the axle oil seal 212 and the retaining ring 214 are attached from the outside of the gear case cover 176. And presser flange 211 is attached. A rear brake disk 63 and a pulsar ring 216 are attached to the holding flange 211 in advance.

The periphery of the holding flange 211 will be described with reference to FIG.
Five arm portions 256... Extend radially outward from the cylindrical portion 219 to the holding flange 211, and a disk mounting portion 247 provided at the tip of these five arm portions 256. The rear brake disc 63 is attached to the arm portion 256, and the palsar ring 216 is attached to the ring attachment portions 237 provided inside the disk attachment portions 247 ... The cylindrical portion 219 of the holding flange 211 is inserted and attached to the rear wheel axle 40.
A seal 210 is interposed between the rear wheel axle 40 and the pressing flange 211.

Next, the configuration around the pinion gear will be described.
The pinion shaft 166 with the circlip 185 and the O-ring 186 attached is inserted into the inner periphery (reference numeral 164 in FIG. 5) of the pinion gear 117. Then, the bearing 123 (needle bearing) is fitted to the gear case 175 with the stopper ring 188 attached, and then the pinion gear assembly 223 into which the pinion shaft 166 is inserted is attached to the outer periphery of the cylindrical portion 163 extending from the pinion shaft 166. The first shim ring 224 and the bearing 121 are inserted in this order from the front of the gear case 175, the bearing 121 is held by the first lock nut 181 and the second lock nut 182, and then the first oil seal 183. And the first retaining clip 184 is attached.

FIG. 8 is a view for explaining the labyrinth structure provided in the gear box according to the present invention and its operation view.
The gear case cover 176 as a constituent member of the gear box 124 has an inner wall 227 extending toward an axis center of the rear wheel axle 40 in an opening 226 opened at an outer end portion thereof.

  Since the inner wall 227 extending toward the center of the rear wheel axle 40 is provided at the rear wheel side end of the opening 226, a labyrinth is further provided at the rear wheel side end of the gear box 124. Can do. Therefore, oil leakage from between the gear box 124 and the rear wheel axle 40 can be further suppressed.

The pulsar ring 216 serving as a member for detecting the wheel speed while serving as a constituent member of the labyrinth structure is a member having a donut shape. The pulsar ring 216 has an inner wall portion 231 provided in parallel to the axial direction of the pulsar ring 216 (the axial direction of the rear wheel axle) from the inner side to the outer side, the outer wall portion 231 outward, and the pulsar ring A seat portion 232 that extends perpendicularly to the axial direction and to which a bolt 215 is attached; an outer wall portion 233 that extends from the seat portion 232 inward of the vehicle and parallel to the axial direction of the pulsar ring 216; It is comprised from the standing wall part 233 and the to-be-detected part 235 which extended at right angles to the axial direction of the pulsar ring 216, and was formed with many small holes 234 ... opened for wheel speed detection. The inner wall portion 231 and the outer wall portion 233 are disposed to face each other.
The pulsar ring 216 is attached to a ring attachment portion 237 provided on the inner surface of the holding flange 211 via bolts 215.

Hereinafter, the labyrinth structure provided outside the axle oil seal 212 will be described.
A first labyrinth passage 241 is formed between a retaining ring 214 that stops the axle oil seal 212 and a front end portion 231a of the standing wall portion 231 provided in the pulsar ring 216, and an inner wall is formed outside the first labyrinth passage 241. A second labyrinth passage 242 is formed between the outer surface 231 c of the portion 231 and the inner wall 227 provided in the gear case cover 176.

That is, an inner wall portion 231 as a labyrinth wall portion extending in the vehicle width direction is integrally provided in the radial direction of the pulsar ring 216, and the inner wall portion 231 is disposed close to the retaining ring 214 and the inner wall 227. A labyrinth structure is formed.
By providing the labyrinth structure, the path in the case where oil leaks from the axle oil seal 212 becomes an arrow m, and oil leakage from the bearing 153 can be delayed.

The operation of the shaft drive type motorcycle described above will be described next.
FIG. 9 is a diagram for explaining the mounting structure of the pulsar ring according to the present invention and a comparative example, in which the gear box 124 is filled with lubricating oil, and between the gear box 124 and the rear axle 40, An axle oil seal 212 is provided, and a labyrinth structure is provided outside the axle oil seal 212 to enhance the sealing effect.

  In (a), an embodiment is shown, in which a sleeve 151 as a rear wheel axle 40 extends outward in a direction perpendicular to the axis of the rear wheel axle and a cylindrical portion 219 extending inward and parallel to the axis of the rear wheel axle. A holding flange 211 having a flange portion 218 is fitted to the sleeve 151 and attached via a screw member 198, and is attached to a ring attachment portion 237 as a component of the flange portion 218 via a bolt 215. A seat portion 232 of the pulsar ring 216 is attached, and a rear brake disc 63 is attached to a disc attachment portion 247 as a component of the flange via a flat bolt 217.

  A pulsar ring 216 for measuring the wheel speed of the rear wheel 31 is provided on the rear wheel axle 40, and an inner wall portion 231 and an outer wall portion 233 as labyrinth wall portions extending in the vehicle width direction are radially inward of the pulsar ring 216. It is provided integrally.

  In (b), a comparative example is shown, and a rear brake disc 63B is fastened together with a fastening bolt 154B that stops the rear wheel hub 31Bh on an outer surface 151Bc of a sleeve 151B as a rear wheel axle 40B. A labyrinth plate 252 is attached via a first bolt 253, and a pulsar ring 216B is attached outside the labyrinth plate 252 via a second bolt 254. That is, in order to form a labyrinth structure, a dedicated labyrinth plate 252 is attached separately from the pulsar ring 216B.

  In such a structure, the labyrinth plate 252 as the labyrinth member and the first bolts 253 to which the labyrinth plate 252 is attached are required as separate members, which increases the number of parts and may increase the cost of the vehicle. It was.

  Returning to (a), since the inner and outer standing wall portions 231 and 233 as the labyrinth wall portion are integrally provided on the pulsar ring 216, an increase in the number of parts can be suppressed and the cost of the vehicle can be reduced.

Hereinafter, the operation of the pressing flange will be described.
With reference to FIGS. 5 to 7, a pressing flange 211 is provided between the rear wheel axle 40 and the rear wheel 31. Since the holding flange 211 is provided with a flange portion 218 for attaching the rear brake disk 63 as a brake disk, it is not necessary to extend the rear brake disk 63 to the rear wheel axle 40.

  If it is not necessary to extend the rear brake disk 63, the rear brake disk 63 can be reduced in weight. In this case, since the plurality of arm portions 256 are extended to the pressing flange 211, an increase in weight due to the pressing flange 211 can be suppressed and wasteful meat can be reduced, thereby reducing the weight of the vehicle as a whole. be able to. In addition, by replacing the holding flange 211 with a member that is cheaper than the rear brake disk 63, the vehicle cost can be reduced.

  The holding flange 211 has a cylindrical portion 219 that holds the inner race 153 c in the axial direction of the rear wheel axle 40. In the rear wheel axle 40, the shaft diameter of the rear wheel axle 40 is increased by the cylindrical portion 219 of the holding flange 211 outside the right bearing 153, so that the rigidity of the rear wheel axle 40 can be easily ensured.

FIG. 10 is a flowchart for explaining the assembly procedure of the drive shaft according to the present invention and a comparative example, which will be described based on FIGS.
In (a), an embodiment is shown. In ST01, a constant velocity joint 115 including the input shaft 156, the cup 157, the boot 158, and the like is assembled, and oil is injected into the cup 157. In ST02, the input shaft 156 of the constant velocity joint 115 is coupled to the drive shaft 112 as a constituent member of the drive shaft 32. ST01 to ST02 can be performed in a subassembly line or the like, and the assembly workability of the constant velocity joint 115 can be improved.

  At ST11, the pinion gear 117 is assembled to the gear box 124 on the main line or the like, and at ST12, the constant velocity joint 115 is coupled to the pinion gear 117 to complete the operation.

  In (b), a comparative example is shown. In ST21, the drive shaft and the input shaft of the constant velocity joint are coupled with each other in the main line, etc., and in ST22, the pinion gear is assembled to the gear box. In step ST24, the constant velocity joint is assembled, and oil is injected into the cup to complete the assembly operation.

  In the constant velocity joint having such a structure, the constant velocity joint cannot be assembled in a small assembly (subassembly) before the drive shaft is assembled. There was room for improvement in terms of efficiency and efficiency. For example, in the comparative example, the assembly of the constant velocity joint is an operation in a narrow and limited space on the main line, and thus productivity has been an issue.

In this regard, in the present invention, the shaft portion 171 extends from the cup 157 of the constant velocity joint 115, and the cylindrical portion 163 of the pinion gear 117 is inserted into the shaft portion 171. Therefore, the constant velocity joint 115 is attached to the subassembly. After that, the cup 157 of the constant velocity joint 115 can be attached to the pinion gear 117, the degree of freedom of the work procedure can be increased, and the work can be speeded up and made efficient.
In addition, since the constant velocity joint 115 having a large size and weight is disposed close to the bearing portion 121 of the pinion gear 117, generation of vibration can be suppressed.

Hereinafter, it will be described that the rear brake disk 63 attached to the holding flange 211 according to the present invention is detachably provided.
In FIG. 9, the size relationship of the gap G between the pressing flange 211 and the pulsar ring 216 with respect to the plate thickness T of the rear brake disk 63 is configured such that T <G.
With such a configuration, when the flat bolts 217... Are removed, the rear brake disk 63 is lifted from the disk mounting portion 247 provided on the holding flange 211 to the left side in the vehicle width direction (downward in the figure). By rotating the rear brake disk 63 to the position of the imaginary line in the direction of the arrow, the rear brake disk 63 can be removed from the vehicle body.

A procedure for removing the rear brake disk will be described below with reference to FIGS. First, the fastening bolts 154 are removed, the rear wheel 31 is removed to the right in the vehicle width direction, and the rear disc brake caliper 62 is removed.
Next, the flat bolts 217 are removed, the rear brake disk 63 is removed from the holding flange 211, lifted from the disk mounting portion 247, and moved to the left in the vehicle width direction. Finally, the phase with the arm portion 256... Of the pressing flange 211 is shifted, and the rear brake disk 63 is tightened to a position where the tightening portion of the rear brake disk 63 and the arm portion 256. By rotating the attaching portion in the direction of the arrow in FIG. 6, the rear brake disk 63 can be removed to the right in the vehicle width direction.

  Although the present invention is applied to a motorcycle in the embodiment, it may be applied to a general saddle type vehicle.

  The present invention is suitable for a shaft drive type motorcycle having an oil seal between a gear box and a rear wheel axle and having a labyrinth structure outside the oil seal.

1 is a left side view of a vehicle according to the present invention. 1 is a side view of a main part of a motorcycle according to the present invention. 1 is a cross-sectional view of a main part of a motorcycle according to the present invention. FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. It is sectional drawing explaining the internal structure of the gear box which concerns on this invention. It is a perspective view explaining the pressing flange attached to the rear wheel concerning the present invention, and its peripheral part. It is a disassembled perspective view explaining the periphery of the rear-wheel axle which concerns on this invention. It is a figure explaining the labyrinth structure with which the gearbox concerning the present invention is equipped, and its operation figure. It is a figure explaining the attachment structure of the pulsar ring which concerns on this invention, and a comparative example figure. It is the flowchart and comparative example figure explaining the assembly procedure of the drive shaft which concerns on this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Motorcycle (shaft drive type motorcycle), 11 ... Body frame, 13 ... Engine, 28 ... Swing arm, 31 ... Rear wheel, 32 ... Drive shaft, 40 ... Rear wheel axle, 63 ... Brake disk (rear brake disk) 117 ... pinion gear, 118 ... final gear, 124 ... gear box, 153 ... bearing, 153a ... outer race of bearing, 211 ... pressing flange, 216 ... pulsar ring, 218 ... flange portion of pressing flange, 219 ... cylindrical portion, 231 ... Labyrinth wall (internal wall), 227 ... inner wall, 260 ... opening.

Claims (2)

A body frame (11), a swing arm (28) provided on the body frame (11) and swingably supporting the rear wheel (31), and in or adjacent to the swing arm (28). A drive shaft (32) for transmitting the driving force of the engine (13) to the rear wheel axle (40) provided on the rear wheel (31), and a constant velocity joint interposed in the drive shaft (32) (115), a pinion gear (117) provided at one end of the drive shaft (32) and meshing with a final gear (118) provided on the rear wheel axle (40), and provided at a rear portion of the swing arm (28). A shaft drive type motorcycle equipped with a gear box (124) for accommodating the final gear (118),
The gear box (124) is provided with an opening (260) through which the rear wheel axle (40) is passed,
The rear wheel axle (40) is provided with a pulsar ring (216) for measuring the wheel speed of the rear wheel (31),
On the radially inner side of the pulsar ring (216), a labyrinth wall portion (231) extending inward of the opening portion (260) in the vehicle width direction is integrally provided,
The pinion gear (117) includes a tooth portion (162) and a cylindrical portion (163) extending forward from the tooth portion (162), and a through hole (164) is provided in the cylindrical portion (163). A female spline (168) fitted into a male spline (169) provided on a shaft portion (171) extending rearwardly at the rear portion of the constant velocity joint (115) is formed in the front half portion of the through hole (164). ) And a pinion shaft (166) is inserted into the rear half of the shaft drive type motorcycle. The wheel side end portion after the opening (260), according to claim 1 Symbol mounting shaft, characterized in that the inner wall extending toward the center of the rear wheel axle (40) (227) is provided Drive type motorcycle.

Images