CN112703307A - Power unit for saddle-ride type vehicle - Google Patents

Abstract

A power unit of a saddle-ride type vehicle is provided with an ACG cover (55), wherein the ACG cover (55) is connected with a crankcase, surrounds a rotor of an alternating current generator around a rotation axis (Rx), and forms a rotor accommodating space. The ACG cover (55) has a peripheral wall (81b) which is located axially outside the rotor and surrounds the rotor housing space around the rotation axis (Rx), and the peripheral wall (81b) is provided with an air guide opening (88) for radially introducing outside air. Thus, a power unit for a saddle-ride type vehicle is provided, which can prevent the foreign matter from flowing into the housing space of the cover coupled to the crankcase.

Description

Power unit for saddle-ride type vehicle

Technical Field

The present invention relates to a power unit for a saddle-ride type vehicle, the power unit comprising: a crankcase which rotatably supports a crankshaft; a rotating body provided on the crankshaft outside the crankcase and rotating around a rotation axis of the crankshaft; and a rotor cover coupled to the crankcase, surrounding the rotor around the rotation axis, and forming a rotor housing space.

Background

Patent document 1 discloses an ACG (alternator) starter that generates electric power in accordance with rotation of a crankshaft and causes rotation of the crankshaft in accordance with supply of electric current. The ACG starter includes a rotor (rotating body) that is fixed to the crankshaft on the outside of the crankcase and surrounds the stator around the rotation axis. An ACG cover (rotor cover) that surrounds the rotor around the rotation axis and forms a rotor housing space is coupled to the crankcase.

Documents of the prior art

Patent document

Patent document 1: japanese patent No. 6182099

Disclosure of Invention

Problems to be solved by the invention

In the crankcase, an annular wall is formed that receives the ACG cage and partially surrounds the rotor of the ACG starter. Notches are formed in the annular wall at the front and upper portions thereof. Since the outside air flows linearly from the notch toward the rotor of the ACG starter, the rotor is effectively cooled, but foreign matter is likely to be mixed into the outside air and enter the housing space.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a power unit for a saddle type vehicle capable of suppressing the flow of foreign matter into a housing space of a cover coupled to a crankcase.

Means for solving the problems

According to a first aspect of the present invention, a power unit for a saddle-ride type vehicle includes: a crankcase which rotatably supports a crankshaft; a rotating body provided on the crankshaft outside the crankcase and rotating around a rotation axis of the crankshaft; and a rotor cover that is coupled to the crankcase, surrounds the rotor around the rotation axis, and forms a housing space for the rotor, wherein the rotor cover has a peripheral wall that surrounds the housing space around the rotation axis and is located axially outside the rotor, and the peripheral wall is provided with an air guide opening through which outside air is guided in a radial direction.

According to a second aspect of the present invention, in the configuration of the first aspect, the rotor cover is formed in a cylindrical shape that is coaxial with the rotation axis and that draws a circle, and the air guide opening is disposed below a horizontal plane including the rotation axis.

According to a third aspect, based on the structure of the first or second aspect, the rotator cover has a wall body that is continuous around the rotation axis over the entire circumference.

According to a fourth aspect of the present invention, in any one of the first to third aspects, a rectifying plate is formed in the rotor cover, the rectifying plate being disposed at the air guide opening and extending radially with respect to the rotation axis.

According to a fifth aspect, in the structure of the fourth aspect, the current plates are arranged at equal intervals around the rotation axis.

According to a sixth aspect, in addition to any one of the first to fifth aspects, the rotor cover is made of resin.

According to a seventh aspect of the present invention, in any one of the first to sixth aspects, the rotor cover includes a first body surrounding the rotor around the rotation axis, and a second body coupled to the first body and having the peripheral wall, the first body is formed with a mesh-like spacer partitioning a space surrounded by the first body from a space surrounded by the peripheral wall, and the second body is formed with a protrusion protruding toward the spacer above a horizontal plane including the rotation axis.

Effects of the invention

According to the first aspect, the outside air flows into the housing space from the air guide opening of the rotor cover in the radial direction, and advances toward the rotor in the axial direction of the rotation axis. Since the flow path of the external air is nonlinear, the flow of foreign matter toward the rotating body can be suppressed.

According to the second aspect, since the air guide port opens downward with respect to the horizontal direction, the upward air guide port can be eliminated, and the release of the intake air sound to the occupant can be prevented.

According to the third aspect, since the wall body is continuous over the entire circumference, the strength of the rotation body cover with respect to the load increases in the axial direction of the rotation axis, and the opening area of the air guide opening increases with the increase in the strength.

According to the fourth aspect, the outside air can be rectified by the rectifying plate and introduced in the radial direction. The introduction of the outside air can be well rectified.

According to the fifth aspect, since the rectifying plates are arranged at equal intervals around the rotation axis, the outside air can flow into the rotation axis well.

According to the sixth aspect, since the rotor cover is made of resin, it is less likely to become hot. Can be lighter than metal.

According to the seventh aspect, even if water enters the housing space of the rotating body from the air guide opening when the saddle-ride type vehicle travels on a submerged road, the mesh-like spacers can be prevented from being clogged with foreign matter such as fallen leaves.

Drawings

Fig. 1 is a side view schematically showing an entire image of a motorcycle (saddle-ride type vehicle) according to an embodiment of the present invention. (first embodiment)

Fig. 2 is a front view of the motorcycle. (first embodiment)

Fig. 3 is a cross-sectional view of the power unit viewed in a cross-sectional plane including the cylinder axis, the rotation axis of the crankshaft, the shaft center of the main shaft, and the shaft center of the intermediate shaft. (first embodiment)

Fig. 4 is an enlarged left side view of the power unit. (first embodiment)

Fig. 5 is an enlarged vertical sectional view taken along line 5-5 of fig. 4. (first embodiment)

Fig. 6 is an enlarged left side view of the power unit as viewed when the outer member is removed from the inner member.

(first embodiment)

Fig. 7 is an enlarged sectional view taken along line 7-7 of fig. 6. (first embodiment)

Fig. 8 is an enlarged left side view of the power unit as viewed when the AC generator (ACG) cover is removed. (first embodiment)

Fig. 9 is an enlarged perspective view schematically showing an entire image of the inside member of the ACG cover from an obliquely upper viewpoint. (first embodiment)

Description of the reference numerals

11 saddle type vehicle (Motor bicycle)

32 power unit

38 crankcase

55 rotating body cover (ACG cover)

55a first body (inner part)

55b second body (outer part)

61 crankshaft

72 rotating body (rotor)

81b peripheral wall (outer peripheral wall)

82 wall body

88 air guide opening

88a fairing

89 separating element

92 projection

HP (including axis of rotation) horizontal plane

Rx (axis of rotation of crankshaft)

Detailed Description

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Here, the upper, lower, front, rear, left, and right of the vehicle body are defined based on the line of sight of the occupant seated in the motorcycle.

First embodiment

Fig. 1 is an overall image schematically showing a motorcycle as a saddle type vehicle according to an embodiment of the present invention. The motorcycle 11 includes a body frame 12 and a body cover 13 attached to the body frame 12. The vehicle body cover 13 has a box cover 16 that covers the fuel tank 14 and is connected to a passenger seat 15 behind the fuel tank 14. Fuel is stored in the fuel tank 14. When the motorcycle 11 is driven, the occupant gets over the occupant seat 15. The passenger seat 15 can be used for seating a passenger (hereinafter, referred to as a "rear-seat passenger") seated in a rear seat in addition to the driver.

The vehicle body frame 12 includes: a head pipe 17; a main frame 19 extending rearward and downward from the head pipe 17 and having a pivot frame 18 at a rear lower end; a lower frame 21 extending downward from the head pipe 19 at a position below the main frame 19; left and right seat frames 22 extending rearward in the horizontal direction from the curved region 19a of the main frame 19; a rear frame 23 extending rearward and upward from the pivot frame 18 below the seat frame 22 and joined to the seat frame 22 from below at a rear end. The rear frame 23 supports the seat frame 22 from below.

The front fork 24 is rotatably supported on the head pipe 14. A front wheel WF is rotatably supported around an axle 25 on the front fork 24. A steering handle 26 is coupled to an upper end of the front fork 24. As shown in fig. 2, the steering handle 26 extends in the vehicle width direction to the left and right in parallel with the ground. Handlebar grips 27 are fixed to both ends of the steering handlebar 26. The driver grips the handlebar 27 with the right and left hands when driving the motorcycle 11.

As shown in fig. 1, a swing arm 29 is coupled to the body frame 12 at the rear of the vehicle, and the swing arm 29 is vertically swingable about a pivot shaft 28. A rear wheel WR is rotatably supported around an axle 31 at the rear end of the swing arm 29. A power unit 32 for generating a driving force to be transmitted to the rear wheel WR is mounted on the vehicle body frame 12 between the front wheel WF and the rear wheel WR. The power of the power unit 32 is transmitted to the rear wheel WR via the power transmission device 33.

The motorcycle 11 includes a pair of pedals 34 disposed on both left and right sides of the power unit 32 in front of the pivot frame 18, and a pair of rear seat pedals 35 disposed behind the pedals 34 and disposed on both left and right sides of the rear wheel WR in front of the axle 31. As shown in fig. 2, the step plates 34 are fixed to both ends of a rod 36 that is attached to the engine 32 from below and extends in the vehicle width direction. The rear seat step plates 35 are fixed to brackets 37, respectively, and the brackets 37 extend rearward from the pivot shaft 28, are bent upward in the lateral direction of the rear wheel WR, and are coupled to the rear frame 23 at the upper ends thereof. The driver can place his feet on the step plate 34 across the passenger seat 15. The rear-seat occupant can place his or her feet on the rear-seat footboard 35 across the occupant seat 15 at the rear of the driver.

The power unit 32 includes: a crankcase 38 disposed between the lower frame 21 and the main frame 19, and connected to the lower frame 21 and the main frame 19, respectively; a cylinder block 39 extending upward from the front side of the crankcase 38 and having a cylinder axis C that inclines forward; a cylinder head 41 coupled to an upper end of the cylinder block 39 and supporting a valve train; and a head cover 42 coupled to an upper end of the cylinder head 41 and covering a valve train on the cylinder head 41. The crankcase 38 is formed with two upper and lower engine hangers 43a projecting from the front side to the front side, and two upper and lower engine hangers 43b, 43c projecting from the rear side to the rear side. The front engine hanger 43a is coupled to the lower frame 21 by a coupling 44a such as a bolt and a nut. The rear engine hangers 43b and 43c are coupled to the pivot frame 18 by coupling members 44b and 44c such as bolts and nuts. Power is generated in the crankcase 38 about the axis of rotation Rx. A left case cover 45 that houses an Alternator (ACG) starter and a sprocket described later is coupled to the crankcase 38.

As shown in fig. 3, a cylinder 48 is defined in the cylinder block 39, and the cylinder 48 guides the linear reciprocating motion of the piston 47 along the cylinder axis C. Here, a single cylinder 48 for receiving a single piston 47 is formed on the cylinder block 39. The combustion chamber 49 is divided between the piston 47 and the cylinder head 41. An ignition plug 51 facing the combustion chamber 49 is mounted on the cylinder head 41. The intake valve and the exhaust valve, which are opened and closed by the rotation of the camshaft 52, function to introduce the air-fuel mixture into the combustion chamber 49, and exhaust gas after combustion is discharged from the combustion chamber 49.

The crankcase 38 is divided into a first case half body 38a and a second case half body 38 b. The inner surfaces of the first case half 38a and the second case half 38b are opposed to each other. The first case half body 38a and the second case half body 38b are joined to each other in a liquid-tight manner at mating surfaces, and cooperate to define the crank chamber 53. The left case cover 45 is composed of an ACG cover (rotor cover) 55 and a sprocket cover 57, the ACG cover 55 is coupled to the outer surface of the first case half body 38a, the ACG actuator 54 is housed between the first case half body 38a, and the sprocket cover 57 is coupled to the outer surface of the first case half body 38a, and the sprocket 56 is housed between the first case half body 38 a. As shown in fig. 2, the ACG cover 55 and the sprocket cover 57 are disposed inside a virtual plane VP connecting the front end of the step plate 34, the front end of the handlebar 27, and the grounding point of the front wheel WF when the bicycle is tilted. As shown in fig. 3, a clutch cover 59 is coupled to an outer surface of the second case half body 38b, and a friction clutch 58, which will be described later, is accommodated between the clutch cover 59 and the second case half body 38 b.

The crankshaft 61 includes journals 64a and 64b connected to ball bearings 62 and 63 fitted into the first half case 38a and the second half case 38b, respectively, and a crankshaft 65 disposed between the journals 64a and 64b and housed in the crank chamber 53. The crank 65 has a crank arm 66 integrated with the journals 64a, 64b, and a crank pin 67 connecting the crank arms 66 to each other. The axes of the journals 64a, 64b coincide with the axis of rotation Rx. A large end of a connecting rod 68 extending from the piston 47 is rotatably connected to the crank pin 67. The connecting rod 68 converts the linear reciprocating motion of the piston 47 into the rotational motion of the crankshaft 61.

An ACG starter 54 is connected to one end of a crankshaft 61 projecting outward in one direction from the crankcase 38. The ACG starter 54 includes a stator 71 fixed to an outer surface of the crankcase 38, and a rotor (rotating body) 72 coupled to one end of the crankshaft 61 protruding from the crankcase 38 so as to be relatively non-rotatable. The stator 71 is arranged in the circumferential direction around the crankshaft 61, and has a plurality of coils 71a wound around a stator core. The rotor 72 includes a plurality of magnets 72a, and the plurality of magnets 72a are arranged in the circumferential direction along an annular track surrounding the stator 71. When the crankshaft 61 rotates, the magnet 72a is displaced relative to the coil 71a, and the ACG starter 54 generates electric power. Conversely, when an electric current flows in the coil 71a, a magnetic field is generated in the coil 71a, causing rotation of the crankshaft 61. The rotor 72 is provided with blades 72b, and the blades 72b suck air in the axial direction during rotation and generate an air flow in the centrifugal direction in the housing space.

The power unit 32 includes a dog clutch type transmission 73 combined with the crankshaft 61. The transmission 73 is housed in a transmission chamber 74 that is continuously divided from the crank chamber 53 in the crankcase 38. The transmission 73 includes a main shaft 75 having an axial center parallel to the axial center of the crankshaft 61 and an intermediate shaft (output shaft) 76. The main shaft 75 and the intermediate shaft 76 are rotatably supported by the crankcase 38 via rolling bearings.

A plurality of speed change gears 77 are supported by the main shaft 75 and the intermediate shaft 76. The transmission gear 77 is disposed between the rolling bearings and is accommodated in the transmission chamber 74. The speed change gear 77 includes: a rotary gear 77a supported coaxially with the main shaft 75 or the intermediate shaft 76 so as to be rotatable relative thereto; a fixed gear 77b fixed to the main shaft 75 so as not to be relatively rotatable, and meshing with the corresponding rotary gear 77 a; the shift gears 77c are supported by the main shaft 75 or the intermediate shaft 76 so as to be relatively non-rotatable and axially displaceable, and mesh with the corresponding rotary gears 77 a. The axial displacement of the rotating gear 77a and the fixed gear 77b is restricted. When the shift gear 77c is coupled to the rotary gear 77a by the axial displacement, the relative rotation of the rotary gear 77a and the main shaft 75 or the counter shaft 76 is restricted. When the shift gear 77c meshes with the fixed gear 77b of the other shaft, rotational power is transmitted between the main shaft 75 and the intermediate shaft 76. When the shift gear 77c is linked to the rotary gear 77a that meshes with the fixed gear 77b of the other shaft, rotary power is transmitted between the main shaft 75 and the intermediate shaft 76. In this way, the intermediate shaft 76 outputs the rotational force of the crankshaft 61 at an arbitrary reduction ratio via the transmission 73.

The main shaft 75 is connected to the crankshaft 61 via a primary reduction mechanism 78 that is housed between the crankcase 38 and the clutch cover 59 on the outside of the crankcase 38. The primary speed reduction mechanism 78 includes a power transmission gear 78a and a driven gear 78b supported rotatably relative to the main shaft 75. The power transmission gear 78a is fixed to the other end of the crankshaft 61 projecting outward from the crankcase 38. The driven gear 78b meshes with the power transmission gear 78 a.

The friction clutch 58 housed between the crankcase 38 and the clutch cover 52 is coupled to the main shaft 75. The friction clutch 58 includes a clutch outer 58a and a clutch hub 58 b. The driven gear 78b of the primary speed reduction mechanism 78 is coupled to the clutch outer 58 a. In the friction clutch 58, the clutch outer 58a and the clutch hub 58b are switched between being connected and disconnected according to the operation of the clutch lever.

Sprocket 56 is fixed to intermediate shaft 76. The power transmission device 33 includes a sprocket 56, a driven sprocket fixed to the axle 31 of the rear wheel WR, the sprocket 56, and a winding chain 79 wound around the driven sprocket. The sprocket 56 transmits the rotational force of the intermediate shaft 76 to the rear wheel WR via the winding chain 79.

The ACG cover 55 includes an inner peripheral wall 81a surrounding the rotor 72 of the ACG stator 54 around the rotation axis Rx, and an outer peripheral wall 81b located further outside than the rotor 72 of the ACG stator 54 in the axial direction of the rotation axis Rx and surrounding the housing space of the ACG stator 54 around the rotation axis Rx. As shown in fig. 4, the inner peripheral wall 81a and the outer peripheral wall 81b are formed in a cylindrical shape drawn in a circle coaxially with the rotation axis Rx. The outer peripheral wall 81b has a wall 82 continuous over the entire circumference around the rotation axis Rx.

The ACG cover 55 is formed with a mounting boss 84, and the mounting boss 84 is disposed radially outward of the inner peripheral wall 81a, overlaps the outer surface of the crankcase 38, and is fastened to the crankcase 38 by a bolt 83. The ACG cover 55 is coupled to the sprocket cover 57 by a box-shaped expanding body 85 extending rearward from the inner peripheral wall 81 a. A recess 87 is formed in the sprocket cover 57 at a position above and below the sprocket 56, and the recess 87 accommodates the screw 86 for fastening the sprocket cover 57 to the crankcase 38. The floor of the recess 87 overlaps the outer surface of the crankcase 38 and receives the heads of the screws 86 screwed into the crankcase 38.

The outer peripheral wall 81b is provided with a wind guide port 87 for radially introducing the outside air. The air guide opening 87 is disposed below a horizontal plane HP including the rotation axis Rx. A baffle plate 88a is formed on the outer peripheral wall 81b, and the baffle plate 88a is disposed on the air guide port 87 and extends radially with respect to the rotation axis Rx. The rectifying plates 88a are arranged at equal intervals around the rotation axis Rx.

As shown in fig. 5, the ACG cover 55 includes: an inner member (first body) 55a having a mounting boss 84 (see fig. 4) fixed to the crankcase 38 and forming an inner peripheral wall 81 a; and an outer member (second body) 55b coupled to the inner member 55a and having an outer peripheral wall 81 b. The outer member 55b covers the inner member 55a further outside than the rotor 72 in the axial direction of the rotation axis Rx.

The inner member 55a is formed with a mesh-like partition 89 that partitions the space surrounded by the inner member 55a from the space surrounded by the outer peripheral wall 81 b. As shown in fig. 6, the partition member 89 has a line-shaped body 89a extending in the radial direction from the outer edge of the opening 91 having a circular contour toward the rotation axis Rx, and a circular body 89b drawn concentrically with the circular shape of the opening 91 into a circle and connecting the line-shaped bodies 89 a. The size of the mesh can be set to about 1.5 to 3.0cm square, for example.

As shown in fig. 5, a plurality of projections 92 are formed on the inner surface of the outer member 55b, and the projections 92 project toward the partition 89 above the horizontal plane HP including the rotation axis Rx. The projection 92 is constituted by, for example, a rod having an axis parallel to the rotation axis Rx. The projections 92 are arranged along, for example, an arc drawn concentrically with the rotation axis Rx.

The inner member 55a is formed of a material having higher rigidity than the outer member 55 b. Here, the inner member 55a and the outer member 55b are each molded from a resin material. The inner member 55a is molded from polyamide 66(PA66 resin), for example. The outer member 55b is molded from polypropylene (PP resin), for example.

The inner member 55a has a connection end 93, and the connection end 93 is surrounded by the wall 82 of the outer peripheral wall 55b and radially narrows toward the front end. The connection end 93 has: a first wall 93a that is opposed to the outer peripheral wall 81b and that narrows in the radial direction toward the leading end; a second wall 93b expanding from a front end of the first wall 93a toward the rotation axis Rx; and a third wall 93c that expands from the inner side of the second wall 93b toward the crankcase 38 and forms a space with the first wall 93 a. An opening 91 is defined inside the third wall 93 c. The inner peripheral wall 81a, the first wall 93a, the second wall 93b, and the third wall 93c are continuous with a uniform wall thickness.

As shown in fig. 6, one or more engaging mechanisms 94 that engage with each other are disposed between the connection end 93 and the outer member 55 b. Referring also to fig. 7, the engagement mechanism 94 includes: two grooves 94a formed on the connection end 93 to extend on radial lines; two plates 94b, which are formed on the outer member 55b, extend on radial lines and enter the grooves 94a, respectively. Here, the grooves 94a are arranged at intervals of less than 120 degrees around the rotation axis Rx. The grooves 94a may be arranged at intervals other than equal intervals in the circumferential direction. If the grooves 94a are arranged at intervals other than equal intervals, the corresponding relationship between the grooves 94a and the plate pieces 94b is reliably determined, and therefore the outer member 55b can be overlapped with the inner member 55a at a predetermined angular position around the rotation axis Rx without fail. Grooves may be formed in the outer member 55b and a plate may be formed in the inner member 55 a.

As shown in fig. 5, a boss 96 into which a screw 95 penetrating the inner member 55a from the inside of the inner member 55a is screwed is formed on the outer member 55 b. Boss 96 enters recess 93d defined by connection end 93 from the axially outer side, and is received by the bottom plate of recess 93d at the tip. The screw 95 fastens the boss 96 to the bottom plate of the recess 93 d. The screw 95 has an axial center parallel to the rotation axis Rx. As shown in fig. 6, the bosses 96 are arranged at equal intervals of 120 degrees around the rotation axis Rx.

As shown in fig. 5, a gap is formed between the edge (end surface) of the wall 82 and the inner member 55 a. The head of the screw 95 faces a surface 72c of the rotor 72 that is continuous around the rotation axis Rx without interruption outside the cylindrical surface circumscribing the blade 72 b. The vane 72b is formed as a member having a smaller diameter than the surface 72c and fastened to the rotor 72 in a recess inside the surface 72 c.

A partition 97 is formed in the peripheral wall (inner peripheral wall 81a) of the inner member 55a, and the partition 97 vertically extends between the storage space of the ACG starter 54 and the space covered by the sprocket cover 57 to partition the storage space and the sprocket cover. An air outlet 98 is formed at the lower end of the partition 97. As shown in fig. 8, the inner peripheral wall 81a is radially distant from the outer periphery of the rotor 54 as it approaches the air outlet 98 in the rotation direction DR of the rotor 54.

The sprocket cover 57 defines a discharge passage 99 extending from the discharge port 98 by a predetermined length between the sprocket cover and the outer surface of the crankcase 38. Sprocket cover 57 has a partition wall 101, and partition wall 101 partitions discharge passage 99 from the space for housing sprocket 56. The air discharge passage 99 is divided between the partition wall 101 and the outer wall 102.

The discharge air passage 99 extends downstream in the rotational direction of the rotor 54 along the tangential direction of an imaginary cylindrical surface surrounding the rotor 54 coaxially with the rotor 54. The discharge passage 99 extends toward the rear of the vehicle body at a position below the sprocket 56. The exhaust passage 99 is inclined so as to be lowered toward the ground as it goes toward the rear of the vehicle body. The outlet 99a of the exhaust passage 99 faces the link 44c fixed to the engine hanger 43 c. In the outlet 99a of the air discharge passage 99, the outer wall of the sprocket cover 57 opposed to the partition wall 101 is folded back upward toward the partition wall 101. The turning back can prevent foreign matter from entering the exhaust passage 99 from below. In the air outlet 98, the outer wall of the ACG cover 55 overlaps the outer wall of the sprocket cover 57 from above. As shown in fig. 1, the outlet 99a of the exhaust passage 99 is disposed rearward of the step plate 34. The outlet 99a of the exhaust passage 99 is located at a position lower than a horizontal plane ZP that circumscribes the rear seat footboard 35 from below.

As shown in fig. 5, the inner member 55a of the ACG cover 55 contacts the crankcase 38 on a mating surface 103 formed on a plane orthogonal to the rotation axis Rx. On the inner member 55a, a water blocking wall 104 is formed, and the water blocking wall 104 protrudes from the outer periphery of the mating face 103 and covers the outer surface of the crankcase 38. As shown in fig. 9, the water blocking wall 104 is disposed forward and upward of the rotation axis Rx. The water blocking wall 104 is continuous from the upper end of the partition wall 97 forward along the mating surface 103, and is interrupted at a position lower than the horizontal plane HP including the rotation axis Rx (see fig. 6).

Next, the operation of the present embodiment will be described. When the air-fuel mixture is detonated in the combustion chamber 49, the reciprocating linear motion of the piston 47 is caused in the cylinder 48. The crankshaft 61 rotates in correspondence with the linear reciprocation of the piston 47. As a result, the rotor 72 of the ACG starter 54 is displaced relative to the stator 71. The ACG starter 54 generates electricity.

The blades 72b generate an air flow in a centrifugal direction corresponding to the rotation of the rotor 72. When the airflow is generated, the outside air flows into the housing space of the ACG starter 54 along the second wall 93b of the connection end 93 in the radial direction from the air guide port 87 of the outer member 55 b. The outside air advances toward the rotor 72 in the axial direction of the rotation axis Rx within the housing space. Since the flow path of the outside air is nonlinear, the flow of foreign matter toward the rotor 72 can be suppressed. The outside air flows into the inner space of the inner member 55a from the opening 91. The outside air cools the ACG starter 54 in the housing space of the ACG starter 54.

The cooling air guided in the centrifugal direction by the rotation of the blades 72b flows out from the air outlet 98 to the outside, and is guided to the rear of the step plate 34 along the air outlet passage 99. The path of the exhaust air may bypass the feet of the driver. The feet of the driver may not be exposed to the influence of the exhaust.

When the power unit 32 is started, if a current is supplied to the coil 71a of the ACG starter 54, a relative displacement is generated between the coil 71a and the magnet 72 a. Thus, in the ACG starter 54, the rotor 72 rotates. Rotation of rotor 72 causes rotation of crankshaft 61. The blades 72b generate an air flow in a centrifugal direction corresponding to the rotation of the rotor 72. The outside air flows into the inner space of the inner member 55a from the opening 91. The outside air cools the ACG starter 54 in the housing space of the ACG starter 54. Warm air is generated due to heat generation of the ACG starter 54. The warm air is guided to the rear of the step 34 along the discharge passage 99. Since the path of the exhaust air avoids the driver's feet, the driver's feet may not be exposed to the warm air from the ACG starter 54.

In the present embodiment, the ACG cover 55 is formed in a cylindrical shape that draws a circle coaxially with the rotation axis Rx. The air guide opening 88 is disposed below a horizontal plane HP including the rotation axis Rx. In this way, since the air guide port 88 opens downward with respect to the horizontal direction, the upward air guide port is eliminated, and the intake sound is prevented from being emitted toward the occupant.

The outer part 55b of the ACG cage 55 has a wall 82 that is continuous over the entire circumference around the rotation axis Rx. Since the wall body 82 is continuous over the entire circumference, the strength of the outer member 55b against the load in the axial direction of the rotation axis Rx increases, and the opening area of the air guide port 88 increases with the increase in strength.

The ACG cover 55 is formed with a baffle plate 88a, and the baffle plate 88a is disposed in the air inlet 88 and extends radially with respect to the rotation axis Rx. The outside air is rectified by the rectifying plate 88a and introduced in the radial direction. The introduction of the outside air can be well rectified. In addition, since the rectifying plates 88a are disposed at equal intervals around the rotation axis Rx, the outside air can flow into the rotation axis Rx satisfactorily.

In the power unit 32 of the present embodiment, the ACG cover 55 is made of resin. Since the ACG cover 55 is made of resin, it is not easily heated. The ACG cover 55 can be lighter than a metal cover.

In the present embodiment, the ACG cover 55 includes: an inner part (first body) 55a that surrounds the rotor 72 of the ACG starter 54 about the rotation axis Rx; and an outer member (second body) 55b coupled to the inner member 55a and having an outer peripheral wall 81 b. At this time, a mesh-like partition 89 is formed in the inner member 55a to partition the space surrounded by the inner member 55a from the space surrounded by the outer peripheral wall 81 b. A plurality of projections 92 are formed on the outer member 55b, and the projections 92 project toward the partition 89 above a horizontal plane HP including the rotation axis Rx. When the motorcycle 11 travels on a submerged road, even if water enters the storage space of the ACG starter 54 through the air guide port 88, the mesh-like spacer 89 can be prevented from being clogged with foreign matter such as fallen leaves.

In the power unit 32, instead of the four-stroke single-cylinder engine, a multi-cylinder engine having a plurality of cylinders arranged in parallel or arranged horizontally or in a V-shape may be used, or a similar two-stroke engine may be used.

Claims (7)

1. A power unit (32) for a saddle-ride type vehicle, comprising: a crankcase (38) which rotatably supports a crankshaft (61);

a rotating body (72) that is provided on the crankshaft (61) outside the crankcase (38) and that rotates around a rotation axis (Rx) of the crankshaft (61);

a rotor cover (55) that is coupled to the crankcase (38), surrounds the rotor (72) around the rotation axis (Rx), and forms a housing space for the rotor (72);

the power unit (32) of the saddle-ride type vehicle is characterized in that,

the rotor cover (55) has a peripheral wall (81b) that is located axially outside the rotor (72) and surrounds the storage space around the rotation axis (Rx), and the peripheral wall (81b) is provided with an air guide opening (88) through which outside air is radially introduced.

2. The power unit for a saddle-ride type vehicle according to claim 1, wherein said rotor cover (55) is formed in a cylindrical shape that is drawn coaxially with said rotation axis (Rx), and said air guide opening (88) is disposed below a Horizontal Plane (HP) that includes said rotation axis (Rx).

3. The power unit for a saddle-ride type vehicle according to claim 1 or 2, wherein the rotor cover (55) has a wall body (82) that is continuous around the entire circumference of the rotation axis (Rx).

4. The power unit for a saddle-ride type vehicle according to any one of claims 1 to 3, wherein a rectifying plate (88a) is formed on the rotor cover (55), and the rectifying plate (88a) is disposed in the air guide opening (88) and extends radially with respect to the rotation axis (Rx).

5. The power unit for a saddle-ride type vehicle according to claim 4, wherein said rectifying plates (88a) are disposed at equal intervals around said rotation axis (Rx).

6. The power unit for a saddle-ride type vehicle according to any one of claims 1 to 5, wherein said rotor cover (55) is made of resin.

7. The power unit for a saddle-ride type vehicle according to any one of claims 1 to 6, wherein said rotor cover (55) includes a first body (55a) that surrounds said rotor (72) around said rotation axis (Rx) and a second body (55b) that is joined to said first body (55a) and has said peripheral wall (82), wherein a mesh-like partition (89) that partitions a space surrounded by said peripheral wall (82) from the space surrounded by said first body (55a) is formed on said first body (55a), and wherein a protrusion (92) that protrudes toward said partition (89) above a Horizontal Plane (HP) including said rotation axis (Rx) is formed on said second body (55 b).

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