CN112770965B - Electric vehicle - Google Patents

Abstract

An electric vehicle (10) is provided with a motor housing part (98c) and a power supply line (134), wherein the motor housing part (98c) is arranged at the left side of a rear wheel (16) in a swing arm (18) and is used for housing a motor (20); the power supply line (134) is used for supplying power to the motor (20). A through hole (138) is formed at the front end of the swing arm (18) in a position in front of the rear wheel (16). The power supply line (134) extends forward from the motor (20) within the swing arm (18), curves inward in the vehicle width direction of the electric vehicle (10) at the front end portion of the swing arm (18), and extends forward of the swing arm (18) from the through hole (138).

Description

Electric vehicle

Technical Field

The present invention relates to an electric vehicle (electric vehicle) in which a motor is disposed in a swing arm (swing arm) rotatably supported by a pivot shaft (axle-supported to the pivot axis).

Background

In japanese patent laid-open publication No. 6200991, there is disclosed an electric vehicle having: a vehicle body frame; a pivot shaft provided on the vehicle body frame; a swing arm having one end rotatably supported by the pivot shaft; a rear wheel supported by the other end of the swing arm; and a motor, which is disposed inside the swing arm, for driving the rear wheel.

In this case, a motor housing portion for housing the motor is provided on the left side of the rear wheel in the swing arm. Further, a guide hole opened forward is formed near the motor housing portion at the upper portion of the swing arm. A wire harness (power supply line) that supplies electric power to the motor extends forward from the motor, extends to the outside via the guide hole, and extends forward along the upper wall of the swing arm.

Disclosure of Invention

In recent years, as the voltage of electric vehicles increases, the power supply line becomes thicker, and the rigidity of the power supply line increases. Therefore, when the power supply line extending from the guide hole to the outside is provided, the power supply line is less likely to bend along the upper wall of the swing arm, and therefore, there is room for improvement.

Accordingly, an object of the present invention is to provide an electric vehicle in which a power supply line extending from the inside to the outside of a swing arm can be arranged in a more linear shape.

The technical scheme of the invention is an electric vehicle, which is provided with a vehicle body frame, a pivot shaft, a swing arm and a motor, wherein the pivot shaft is arranged on the vehicle body frame; one end of the swing arm is rotatably supported on the pivot, and the other end of the swing arm supports a rear wheel; the electric vehicle further includes a motor housing portion provided at a position on one side of the rear wheel in the swing arm, the motor housing portion being configured to house the motor; the power supply line is configured to supply power to the motor, and a through hole is formed in a portion of one end portion of the swing arm located in front of the rear wheel so as to open forward, the power supply line extends forward from the motor in the swing arm, is bent inward in the vehicle width direction of the electric vehicle at the one end portion of the swing arm, extends from the through hole to the outside of the swing arm, is wired to the other side of the swing arm, and is connected to an electronic component, the electronic component is disposed behind a battery, and the battery is disposed in a space between a pair of right and left upright portions of the vehicle body frame.

According to the present invention, the power supply line extends from the motor to the outside via the inside of the swing arm from a through hole formed on one end portion of the swing arm. Accordingly, when the power supply line is arranged from the inside to the outside of the swing arm, the power supply line can be arranged in a more linear shape without bending the power supply line too much. Further, compared with japanese patent application laid-open No. 6200991, the degree of exposure of the power feed line to the outside is low, and therefore, the number of parts for protecting the power feed line with high rigidity from the outside and the appearance can be reduced. Further, since a space above or below the swing arm is secured, a space for mounting a battery can be secured above the pivot shaft, for example. As a result, the minimum height above the ground of the swing arm can be ensured.

Drawings

Fig. 1 is a left side view of the electric vehicle according to the present embodiment.

Fig. 2 is a perspective view of the electric vehicle of fig. 1 viewed from the left rear side around the rear wheel.

Fig. 3 is a left side view of the swing arm cover of fig. 1 and 2 in a state of being detached.

Fig. 4 is a left side view of the left rotor support portion of fig. 3 in a state where it is removed.

Fig. 5 is a sectional view taken along V-V of fig. 3.

Fig. 6 is a right side view showing the swing arm and the like broken.

Fig. 7 is a bottom view of the front end periphery of the swing arm.

Fig. 8 is a left side view illustrating the reducer housing portion.

Fig. 9 is a perspective view of a swing arm including a speed reducer housing portion, a brake mechanism, and a breather pipe (break pipe).

Fig. 10A is a sectional view taken along XA-XA of fig. 6, and fig. 10B is a sectional view taken along XB-XB of fig. 6.

Fig. 11 is a right side view showing a modification of the fixing portion of fig. 6.

Detailed Description

A preferred embodiment of an electric vehicle according to the present invention will be described below with reference to the drawings.

[1 ] schematic configuration of electric vehicle 10 according to the present embodiment ]

Fig. 1 is a left side view of an electric vehicle 10 according to the present embodiment. In the following description, the front-rear, left-right, and up-down directions are described in terms of directions viewed by an occupant seated on the seat 12 of the electric vehicle 10. In the electric vehicle 10, components arranged in a pair on the left and right sides are sometimes described with the letter "L" for the left-side component and the letter "R" for the right-side component.

The electric vehicle 10 is an electric motorcycle having a low step portion 14, and travels by driving the rear wheel 16 to rotate by the driving force of a motor 20, wherein the motor 20 is built in a swing arm 18, and the swing arm 18 rotatably supports the rear wheel 16. The electric vehicle 10 according to the present embodiment is not limited to the electric motorcycle (electric motorcycle) shown in fig. 1, and can be applied to various electric straddle-type vehicles driven by the motor 20. In the following description, the scooter-type electric vehicle 10 will be described.

The electric vehicle 10 includes a vehicle body frame 22 and a synthetic resin vehicle body cover 24 covering the vehicle body frame 22. The vehicle body frame 22 includes: a head pipe (head pipe)26 at the front end; a down pipe (down pipe)28 extending obliquely rearward and downward from the head pipe 26; a pair of left and right chassis portions (under frame sections) 30L, 30R extending rearward from the rear end of the lower tube 28; side frame sections (side frame sections) 32L and 32R extend obliquely rearward and upward from rear ends of the chassis sections 30L and 30R. The side frame portions 32L, 32R include: upright portions 34L, 34R extending obliquely rearward and upward from the pair of left and right chassis portions 30L, 30R; rear frames (rear frames) 36L and 36R extend rearward from the pair of left and right rising portions 34L and 34R. The rear ends of the pair of left and right rear frames 36L, 36R are connected together by a tail pipe section (tail pipe section) 38.

Front forks (front fork)40L and 40R are mounted to the head pipe 26 so as to be steerable. A handle 44 is attached to an upper portion of the front forks 40L and 40R via a steering column 42. A front wheel 46 is attached to the lower end of the front forks 40L, 40R. A front fender 48 that covers the front wheel 46 from above is attached to the front forks 40L, 40R.

A connection support portion 50 including a pivot bracket 50a is provided between the undercarriage portions 30L, 30R and the side frame portions 32L, 32R. The connection support portion 50 supports a pivot shaft 54 extending in the left-right direction (vehicle width direction) of the electric vehicle 10. The swing arm 18 has a front end (one end) rotatably supported by the pivot shaft 54. The swing arm 18 extends from the pivot shaft 54 toward the left side (one side) of the rear wheel 16 in the front-rear direction of the electric vehicle 10. The rear end (the other end) of the swing arm 18 supports the rear wheel 16.

The swing arm 18 incorporates a motor 20 such that the motor 20 is disposed on the left side of the rear wheel 16. Therefore, the swing arm 18 is configured as a swing type power unit. A rear shock absorber (rear shock) 56 is connected between the rear end portion of the swing arm 18 and the left rear frame 36L. Further, a rear fender 58 is attached to the rear frames 36L and 36R so as to cover the rear wheel 16 from above. Further, another fender 60 is attached to the swing arm 18, and the fender 60 is capable of swinging together with the swing arm 18 while directly covering the rear wheel 16 from above between the rear fender 58 and the rear wheel 16.

The rear frames 36L, 36R support the seat 12 on which the occupant sits from below. Between the seat 12 and the pivot shaft 54, a battery 62 of the electric vehicle 10 is disposed in a space between the pair of right and left rising portions 34L, 34R. The battery 62 is supported by the pair of right and left rising portions 34L, 34R, the rear frames 36L, 36R, and the pipe 64 connects the rising portions 34L, 34R to the front.

A PCU (power control unit)66 as an electronic component supported by the left and right standing portions 34L, 34R is supported at a position diagonally behind and below the battery 62 in front of the rear wheel 16. The PCU66 is configured to include an inverter and the like, and converts dc power supplied from the battery 62 into ac power, for example, and supplies the converted ac power to the motor 20. The PCU66 also converts ac power generated by the motor 20 during regeneration of the motor 20 into dc power to charge the battery 62. The positions of the battery 62 and the PCU66 shown in fig. 1 are examples, and may be arranged at other positions in the electric vehicle 10. For example, the battery 62 may be disposed in a space between the pair of right and left chassis portions 30L, 30R.

The body cover 24 is a cover that covers the body frame 22 and the like, and includes a front cover 68, a handlebar cover 70, leg shields (leg shields) 72, pedal-side covers 74L, 74R, a seat lower cover 76, rear side covers (rear side covers) 78L, 78R, and the like. The front cover 68 covers the front end portion of the body frame 22 such as the head pipe 26 from the front. The handlebar cover 70 is located above the front cover 68 and covers the right and left center portions of the handlebar 44. The leg shield 72 is attached to the front cover 68 and covers the head pipe 26 and the down pipe 28 from behind. The under seat cover 76 covers the space under the seat 12 from the front.

A pair of left and right step side covers 74L, 74R are connected to the leg shield 72 and the seat lower cover 76, and cover the pair of left and right undercarriage portions 30L, 30R from both left and right sides. The rear side covers 78L and 78R are connected to the rear edge portion of the seat undercover 76, and cover the PCU66 and the like from both the left and right sides.

A main stand (main stand)80 is disposed on a side of the swing arm 18. In this case, a shaft 82 of the main stand 80 is provided below the swing arm 18, and the main stand 80 is disposed such that a part of the main stand 80 is housed in a recess 84, the recess 84 being formed by recessing the left side portion of the swing arm 18. In addition, a sub-bracket 86 is disposed near the left standing portion 34L.

[2. characteristic Structure of the present embodiment ]

Next, a characteristic configuration (1 st to 4 th configurations) of the electric vehicle 10 according to the present embodiment will be described with reference to fig. 1 to 11.

< 2.1 Structure 1 >

The structure 1 is as follows: the motor 20 is configured as an assembly (unit) in which a stator 90 and a rotor 92, which are driving parts of the motor 20, are assembled in a motor housing 94, and the motor 20 is housed in the swing arm 18 to configure a swing type power unit. That is, the mounting work of the motor 20 with respect to the swing arm 18 can be completed only by housing the finished motor 20 in the swing arm 18, wherein the finished motor 20 houses the stator 90 and the rotor 92, and the motor shaft 96 is exposed from the motor housing 94. Here, the structure of the swing arm 18 accommodating the motor 20 will be described in more detail.

Swing arm 18 has a swing arm body 98. The swing arm main body 98 is a hollow member having: one end portion 98a extending in the vehicle width direction in a space near the pivot shaft 54 in front of the rear wheel 16; a connecting portion 98b extending rearward from the left side of the one end portion 98 a; a motor housing portion 98c provided in connection with the connecting portion 98b and disposed on the left side of the rear wheel 16; and the other end portion 98d provided rearward of the motor housing portion 98 c.

One end 98a of the swing arm main body 98 constitutes a front end of the swing arm 18 and is rotatably supported by the pivot shaft 54. As described above, the pivot shaft 54 is supported by the vehicle body frame 22 via the connecting support portion 50. As shown in fig. 1, 2, 6, and 7, the connection support portion 50 includes: a pipe 50b extending in the vehicle width direction and connecting the pair of left and right standing portions 34L, 34R; and 4 pivot holders 50a extending rearward from the pipe member 50b and supporting the pivot shafts 54. The 2 projections 98e extend forward from the left and right sides of the one end 98a of the swing arm main body 98 toward the pivot shaft 54. The 2 projecting portions 98e are rotatably supported by the pivot shaft 54 via 2 bearings 100 provided at both ends of the pivot shaft 54 in the vehicle width direction.

In the side views of fig. 1, 3, and 4, the connecting portion 98b of the swing arm main body 98 gradually expands from the front toward the rear. The motor housing portion 98c and the other end portion 98d of the swing arm main body 98 constitute a rear end portion of the swing arm 18. The motor housing portion 98c is formed in a substantially circular shape in the side views of fig. 1, 3, and 4, and the motor housing portion 98c is formed recessed inward in the vehicle width direction in the cross-sectional view of fig. 5. The rear damper 56 is connected to the other end 98d of the swing arm main body 98.

In the swing arm main body 98, a rear portion of the connecting portion 98b and the motor housing portion 98c are opened leftward. The opening of the opening portion is sized to accommodate the motor 20, and is covered by the swing arm cover 102 from the left side. A swing arm cover 102 is mounted to the swing arm body 98 by a plurality of bolts 104. Fig. 3 to 5 illustrate a state in which the swing arm cover 102 is detached from the swing arm main body 98.

The motor 20 housed in the motor housing portion 98c is, for example, a three-phase ac motor, and includes a stator 90, a rotor 92, and a motor housing 94, and the motor housing 94 houses the stator 90 and the rotor 92 therein. The motor housing 94 has: a stator support portion 94a which is an outer case of the motor housing 94 and is a cylindrical housing extending in the vehicle width direction; and left and right rotor support portions 94L, 94R as rotor covers that close the 2 openings at both ends of the stator support portion 94a in the vehicle width direction.

The stator 90 has a cylindrical stator core 90a formed of laminated steel plates. The stator core 90a has a plurality of slots 90b formed at predetermined angular intervals in the circumferential direction of the motor 20. A coil 90c is wound around the plurality of grooves 90 b. The stator support portion 94a is a stator holder that fixedly supports the outer peripheral surface of the stator core 90a, i.e., the outer surface of the stator 90 in the radial direction of the motor 20. Accordingly, the mechanical strength of the stator core 90a formed of laminated steel sheets is enhanced. The stator core 90a is fixed to the stator support 94a by shrink fitting, for example.

A rotor 92 is disposed radially inward of the stator 90. The rotor 92 has a cylindrical rotor core 92a formed of laminated steel plates. The rotor core 92a has a plurality of slots 92b formed at predetermined angular intervals in the circumferential direction of the motor 20. Magnets 92c are disposed in the plurality of grooves 92 b. The motor shaft 96 penetrates the center of the rotor core 92a in the vehicle width direction. Motor shaft 96 extends in the vehicle width direction through an opening formed in the center of each of 2 rotor support portions 94L and 94R. Motor shaft 96 is rotatably supported by 2 rotor support portions 94L, 94R via bearings 106L, 106R provided in 2 openings. That is, the rotor 92 is rotatably supported (rotatably supported) by the 2 rotor support portions 94L, 94R via the motor shaft 96 and the 2 bearings 106L, 106R.

A left end portion 96L of the motor shaft 96 protrudes outward (leftward) in the vehicle width direction from the left rotor support portion 94L. In the left rotor support portion 94L, a portion of the motor shaft 96 from which the left end portion 96L protrudes is formed as a recess 108 recessed inward in the vehicle width direction. The recess 108 is covered from the left by a cover member 110. Therefore, even if the swing arm cover 102 is detached from the swing arm main body 98, the left end portion 96L of the motor shaft 96 is not exposed (see fig. 3 and 5).

A rotation angle detecting portion 112 is disposed in an internal space formed by the recess 108 and the cover member 110, and the rotation angle detecting portion 112 detects the rotation angle of the rotor 92 and the motor shaft 96. The rotation angle detection unit 112 is a resolver (resolver), and includes: a resolver rotor 112a attached to a left end portion 96L of motor shaft 96; and a resolver stator 112b fixed to the left rotor support portion 94L so as to face the resolver rotor 112 a. Since the resolver is well known, a detailed description thereof will be omitted.

On the other hand, a right end portion (distal end portion) 96R of the motor shaft 96 projects from the right rotor support portion 94R toward the inside in the vehicle width direction (right direction) so as to be directed toward the motor housing portion 98c of the swing arm main body 98. Therefore, the right portions of the right rotor support portion 94R and the stator support portion 94a are opposed portions opposed to the motor housing portion 98 c. A speed reducer housing 116 for housing a speed reducer 114 to be described later is provided on the right side of the motor housing 98c of the swing arm main body 98.

The right end portion 96R of the motor shaft 96 is inserted into the reduction gear housing 116, and is axially supported (rotatably supported) by a bearing 118 provided in the reduction gear housing 116. Further, spline machining is performed on the right end portion 96R side of the motor shaft 96. A motor-side gear 120 (gear) for rotating an axle (output shaft) 16a of the rear wheel 16 is inserted into the splined portion. A spacer 122 for preventing the motor-side gear 120 from coming off is provided between the motor-side gear 120 and the bearing 118. In order to replace the motor 20 with the motor housing portion 98c, the spacer 122 is preferably pressed into the motor shaft 96 at a low pressure. The gasket 122 is pressed in by low pressure, so that the assembly is easy.

The reducer housing 116 is filled with a lubricating oil for lubricating the motor-side gear 120 and the like constituting the reducer 114. Therefore, an oil seal 121 is provided between the right rotor support portion 94R and the motor shaft 96, and this oil seal 121 prevents leakage of the lubricating oil from the speed reducer housing 116 to the motor housing 94. Further, an O-ring 123 is formed between the right rotor support portion 94R and the motor housing portion 98c on the side of the rotor support portion 94R, and the O-ring 123 prevents the lubricant oil from leaking from the reduction gear housing portion 116.

A plurality of screw holes (1 st through hole, 2 nd through hole) 124 extending in the vehicle width direction are formed in the 2 rotor support portions 94L, 94R and the stator support portion 94a at predetermined angular intervals in the circumferential direction of the motor 20. A plurality of bolts 126, 128 are screwed into the threaded holes 124. As shown in fig. 3 to 5, in the present embodiment, screw holes 124 are formed at 9 locations.

Among them, bolts 126 having a short length are screwed into the screw holes 124 at 3 positions. Shorter bolts 126 are used to fix the rotor support portions 94L, 94R and the stator support portion 94 a. As shown in fig. 5, a short bolt 126 is inserted into the screw hole 124 from the left side, whereby the rotor support portion 94L and the stator support portion 94a are fastened to the rotor support portion 94R.

On the other hand, long bolts (fixing means) 128 are screwed into the screw holes 124 in the other 6 locations. The long bolt 128 is used to fix the motor housing 94 including the 2 rotor support portions 94L, 94R and the stator support portion 94a to the motor housing portion 98 c. That is, long bolts 128 are inserted into the screw holes 124 from the left side and screwed into bolt holes 130 provided in the motor housing portion 98c, whereby the rotor support portion 94L, the stator support portion 94a, and the rotor support portion 94R are fastened to the motor housing portion 98 c.

The number and formation position of the screw holes 124, and the type and number of the bolts 126 and 128 screwed into the screw holes 124 are arbitrary, and it is needless to say that the design may be changed in accordance with the specifications of the swing arm 18 and the motor 20.

In the structure 1, the motor 20 is mounted on the motor housing portion 98c of the swing arm main body 98 when the electric vehicle 10 is manufactured. The motor 20 is used in the manufacturing process of the electric vehicle 10 in an assembled state (unit) in which the stator 90 and the rotor 92 are housed in the motor housing 94 and the right end portion 96R of the motor shaft 96 is projected from the right rotor support portion 94R. At this time, the short bolts 126 fix the rotor support portions 94L and 94R and the stator support portion 94a in a permanently fixed state, while the long bolts 128 may be temporarily fixed.

In this case, first, right end portion 96R of motor shaft 96 is inserted into reduction gear housing 116 and is axially supported (rotatably supported) by bearing 118. At this time, the right end portion 96R of the motor 20 can be axially supported by the bearing 118 in a state where the motor side gear 120 and the spacer 122 are fitted into the spline-processed portion on the right end portion 96R side of the motor shaft 96. Next, the 6 screw holes 124 to which the long bolts 128 are temporarily fixed and the 6 bolt holes 130 on the motor housing portion 98c side are positioned, and then the long bolts 128 are screwed into the screw holes 124 and the bolt holes 130, whereby the motor housing 94 is fixed to the motor housing portion 98 c. Accordingly, the motor 20 is housed in the motor housing portion 98c, and the operation of attaching the motor 20 to the swing arm 18 is completed.

< 2.2 Structure 2 >

The 2 nd structure is a structure for effectively cooling the motor 20 by exposing a part of the motor 20 housed in the motor housing portion 98c to the outside.

As shown in fig. 1 and 2, an exposed portion 132 is formed in the swing arm cover 102, and the exposed portion 132 serves as an opening portion through which a part of the motor housing 94 is exposed to the outside. Specifically, in the side view of fig. 1, the exposed portion 132 is formed as an arc-shaped opening from the front to the rear at a portion corresponding to the motor housing portion 98c of the swing arm cover 102 so that the rear portion of the motor housing 94 is exposed to the outside. As shown in fig. 2, exposed portion 132 is open to have a constant width in the vehicle width direction, and exposes motor housing 94 to the outside in the vehicle width direction. The arc-shaped exposed portion 132 is formed to be wider in the vertical direction from the front to the rear, and the exposed area is gradually increased.

Therefore, in the side view of fig. 1, the swing arm cover 102 has a circular portion 102a, and the circular portion 102a covers the central portion of the motor housing 94, that is, the motor shaft 96 and the rotation angle detection portion 112 (see fig. 5), from the left side. As shown in fig. 1 and 2, the circular portion 102a and the rear end portion 102b of the swing arm cover 102 are connected together by a connecting portion 102c extending in the front-rear direction. As shown in fig. 4, the exposed portion 132 is provided so as to correspond to the groove 90b of the wound coil 90 c. As shown in fig. 1, 2, and 4, the exposed portion 132 exposes a portion of the motor housing 94 to the outside so that the plurality of bolts 126 and 128 are covered by the swing arm cover 102.

As mentioned above, the motor 20 is a three-phase ac motor. As will be described later, the motor 20 is driven to rotate by supplying ac power from the PCU66 to the coil 90c via the power supply line 134 as a three-phase electric wire. In this case, the power supply line 134 is drawn forward from the motor 20. Therefore, the swing arm cover 102 and the swing arm main body 98 cover the power supply line 134 from the front and the side.

< 2.3 Structure 3 >

The 3 rd configuration relates to the wiring of the power supply line 134 from the motor 20 and the wiring of the communication line 136 from the rotation angle detecting unit 112.

As shown in fig. 6 and 7, a through hole 138 that opens forward is formed in a portion of one end 98a of the swing arm main body 98 that is located forward of the rear wheel 16. The through hole 138 is formed at a position between the 2 bearings 100 above the pivot shaft 54 at the one end portion 98a of the swing arm main body 98.

As shown in fig. 3, 4, 6, and 7, the power supply line 134 is a high-rigidity three-phase wire harness, and is routed inside the swing arm 18 along the internal shape of the swing arm 18. That is, the power supply line 134 extends forward from the motor 20 inside the swing arm 18, is bent inward in the vehicle width direction at the one end 98a of the swing arm main body 98, and extends forward of the swing arm 18 from the through hole 138. In this case, the power supply line 134 extends from between the 2 bearings 100 to the front of the swing arm 18 via the through hole 138 above the pivot shaft 54. Then, the power supply line 134 drawn out from the through hole 138 is routed upward of the pivot shaft 54 and connected to the PCU66 disposed diagonally rearward and downward of the battery 62. Therefore, the PCU66 and the motor 20 supply/receive ac power via the power supply line 134.

On the other hand, a communication line 136 is drawn from the rotation angle detecting unit 112. The communication line 136 is a wire harness having lower rigidity than the power supply line 134. Therefore, the communication line 136 is easier to route than the power supply line 134, and the communication line 136 extends forward from the rotation angle detecting unit 112 in the swing arm 18 so as to extend along the power supply line 134, bends inward in the vehicle width direction at the one end 98a of the swing arm main body 98, and extends forward of the swing arm 18 from the through hole 138. Therefore, the communication line 136 also extends from between the 2 bearings 100 to the front of the swing arm 18 via the through hole 138 above the pivot shaft 54. Then, communication line 136 drawn out from through hole 138 is routed upward of pivot shaft 54 and connected to PCU 66. Therefore, PCU66 and rotation angle detection unit 112 can transmit and receive the detection result of the rotation angle of rotor 92 and motor shaft 96 via communication line 136.

Further, inside the swing arm 18, specifically, at the one end 98a of the swing arm main body 98, the power feeding line 134 and the communication line 136 are fixed inside the one end 98a by a fixing portion 139 (see fig. 6 and 7).

Specifically, the fixing portion 139 includes: a binding member 140 such as a grommet for binding the power supply line 134 and the communication line 136; a clamping member 142 which is a ring-shaped holder that fastens the power supply line 134 and the communication line 136 together with the binding member 140; and a fixing member 143 such as a bolt for fixing the clamping member 142 in the one end portion 98 a.

In this case, as shown in fig. 10A, if the clamp member 142 is a 1-ring member, the power supply line 134 and the communication line 136 are fixed in the one end portion 98a by inserting the screw portions of the fixing member 143 into the holes formed in the both end portions thereof and screwing the screw portions into the screw holes formed in the one end portion 98 a.

Alternatively, as shown in fig. 10B, the clamp member 142 may be a detachable ring member formed in a ring shape by 2 plate-like members 142a and 142B having proximal end portions fixed to the fixing member 143 and distal end portions facing each other.

In this case, in the cross-sectional view of fig. 10B, one plate-like member 142a extends upward from the base end portion, the middle portion is formed into 2 arc-shaped portions covering the power feeding line 134 and the communication line 136 from above, and the tip end portion is directed downward. In the cross-sectional view of fig. 10B, the other plate-like member 142B is a substantially L-shaped member extending along the inner peripheral surface of the one end portion 98a, and the distal end portion thereof faces the distal end portion of the one plate-like member 142 a. Therefore, when the clamp member 142 is a detachable member, the power supply line 134 and the communication line 136 are fixed in the one end portion 98a by inserting the screw portion of the fixing member 143 into the holes formed in the base end portions of the 2 plate-like members 142a and 142b and screwing the screw portion into the screw hole formed in the one end portion 98 a.

As shown in fig. 11, a part of the clamp member 142 extends forward (is exposed) through the through hole 138. In this case, the fixing member 143 may fix the exposed portion of the clamping member 142 to the one end portion 98 a.

In fig. 6, 7, and 10A to 11, the case where the feed line 134 and the communication line 136 are fixed to the one end portion 98a is described. In the configuration 3, the power supply line 134 and the communication line 136 may be fixed to the swing arm 18 within the swing arm 18. Therefore, the power feeding line 134 and the communication line 136 may be fixed to the connection unit 98b in the connection unit 98 b.

In addition, in the 3 rd structure, the through hole 138 is formed so as to open forward. Therefore, when the electric vehicle 10 travels, liquid such as water may enter the swing arm 18 through the through hole 138 from the front. Therefore, a hole 144 for draining water is formed in the bottom of the swing arm main body 98. Fig. 6, 7, and 11 illustrate a case where a hole 144 is formed in a portion near the through hole 138 on the bottom of the swing arm main body 98, as an example.

Further, a plurality of ribs 146 for reinforcing the strength of the swing arm main body 98 are formed inside the swing arm main body 98 between the through hole 138 and the motor housing portion 98c, specifically, at a portion from the rear of the connecting portion 98b to the motor housing portion 98 c.

< 2.4 th Structure 4 >

The 4 th structure is related to the breather pipe 148, and the breather pipe 148 is used to discharge gas containing mist-like lubricating oil to the outside to reduce the internal pressure when the pressure (internal pressure) in the reduction gear housing 116 rises due to a temperature rise in the reduction gear housing 116 and the lubricating oil used in the reduction gear 114 volatilizes. Here, a structure around the reducer housing portion 116 will be described.

As shown in fig. 5, 8, and 9, the swing arm 18 is further provided with a speed reducer housing 116, and the speed reducer housing 116 is attached to the vehicle width direction inner side of the swing arm main body 98 and houses the speed reducer 114. A brake mechanism 150 is provided on the vehicle width direction inner side of the speed reducer housing portion 116 and on the inner side of the wheel portion 16b of the rear wheel 16. Therefore, the motor 20, the reduction gear 114, and the brake mechanism 150 are disposed in this order from the left side to the right side in the vehicle width direction around the rear wheel 16.

Further, a transmission cover 154 is fixed to the right side of the motor housing portion 98c of the swing arm main body 98 by a bolt 152. An inner space formed by the motor housing portion 98c and the transmission cover 154 constitutes a reduction gear housing portion 116.

The speed reducer 114 includes: a motor-side gear 120 mounted on the motor shaft 96; an intermediate shaft 156 disposed rearward of motor shaft 96 and extending in the vehicle width direction; an intermediate gear 158 as a reduction gear attached to the intermediate shaft 156 and meshing with the motor-side gear 120; and an output gear 162 that is attached to the axle 16a of the rear wheel 16 disposed rearward of the intermediate shaft 156 and meshes with a gear portion 160 formed on the left side in the vehicle width direction of the intermediate shaft 156.

The right end of the intermediate shaft 156 is supported by a bearing 164R, and the bearing 164R is disposed on the transmission cover 154. The left end portion of the intermediate shaft 156 is axially supported by a bearing 164L, and the bearing 164L is disposed on the right side of the motor housing portion 98 c. The left end portion of the axle 16a is supported by a bearing 166L, and the bearing 166L is disposed on the right side of the motor accommodating portion 98 c. The right end of the axle 16a is exposed to the outside through the transmission cover 154 and is connected to the wheel portion 16b of the rear wheel 16. The right end side of the axle 16a is supported by a bearing 166R, and the bearing 166R is disposed on the transmission cover 154.

Therefore, when motor 20 is driven and motor shaft 96 rotates, the driving force of motor 20 is transmitted to axle 16a via motor-side gear 120, intermediate gear 158, intermediate shaft 156, gear portion 160, and output gear 162, thereby enabling rotation of rear wheel 16 connected to axle 16 a. In this case, speed reducer 114 reduces the rotation speed of motor shaft 96 via intermediate gear 158, and drives axle 16a and rear wheel 16 to rotate.

The brake mechanism 150 is a drum brake, and includes: a brake drum 150a provided inside the wheel portion 16 b; 2 brake shoes 150b, these 2 brake shoes 150b are disposed on both sides across the axle 16 a; and a lining 150c disposed on the brake drum 150a side of the brake shoe 150 b. In this case, when the 2 brake shoes 150b are separated from each other against the tensile force of the spring member 150d provided between the 2 brake shoes 150b, the linings 150c of the 2 brake shoes 150b press the brake drum 150a, respectively, and therefore, the rotation of the wheel portion 16b (rear wheel 16) to which the brake drum 150a is attached can be braked. Further, since drum brakes are well known, detailed description thereof will be omitted.

In addition, in the 4 th configuration, the swing arm 18 is provided with a vent pipe 148 (see fig. 2 to 4, 8, and 9) extending from the reduction gear housing portion 116. The breather pipe 148 is disposed above the reduction gear housing portion 116. Therefore, the breather pipe 148 is disposed between the motor 20 and the rear wheel 16, as in the reducer housing portion 116.

One end 148a of the breather pipe 148 as an inlet communicates with the reduction gear housing 116 in a state of being fixed to the transmission cover 154. The other end 148b of the breather pipe 148, which is an outlet, is disposed on the fender 60, and the fender 60 is located above the swing arm 18 and is swingable together with the swing arm 18. In this case, the other end 148b of the breather pipe 148 is inserted into a cylindrical fixing portion 168 provided on the left side surface of the fender 60, whereby the other end 148b is fixed to the fender 60. Therefore, the breather pipe 148 is disposed in a state where one end 148a (inlet) is directed downward and the other end 148b (outlet) is directed upward.

As shown in fig. 8 and 9, an upper wall portion 170 extending in the front-rear direction is formed on the right side of the motor housing portion 98c above the reduction gear housing portion 116. The breather pipe 148 extends upward from the speed reducer housing portion 116, is bent forward along the upper wall portion 170, and is bent upward at the front end portion of the upper wall portion 170 and extends toward the fixing portion 168 of the fender 60. In this case, the upper wall portion 170 is inclined such that the other end 148b of the vent pipe 148 is higher than the one end 148 a. Therefore, the middle portion 148c of the vent pipe 148 disposed on the upper wall portion 170 is disposed on the upper wall portion 170 so as to be inclined so as to gradually increase in height as it moves forward. The upper wall portion 170 is provided with a fixing portion 172 such as a projection, and the fixing portion 172 such as a projection is used to fix the vent pipe 148 to the upper wall portion 170 and the right side portion of the motor housing portion 98c by projecting upward.

A plate member 174 extending in the up-down direction and the front-rear direction is integrally formed on the front side surface of the fender 60. The other end 148b (outlet) of the vent pipe 148 is disposed on the left side of the plate member 174. Thus, the plate member 174 is disposed between the vent tube 148 and the rear wheel 16.

On the other hand, as shown in fig. 8, one end 148a (inlet) of the breather pipe 148 is disposed between the motor shaft 96 and the axle 16a, more specifically, between the intermediate shaft 156 and the axle 16 a.

[3. effect of the present embodiment ]

The effects of the electrically powered vehicle 10 according to the present embodiment described above will be described in the order of the 1 st to 4 th configurations.

The electric vehicle 10 according to the present embodiment includes: a vehicle body frame 22; a pivot shaft 54 disposed on the vehicle body frame 22; a swing arm 18 having a front end (one end) rotatably supported by the pivot shaft 54 and a rear end (the other end) supporting the rear wheel 16; and a motor 20, which is disposed to the swing arm 18, for driving the rear wheel 16.

< 3.1 Effect of the 1 st Structure >

As the configuration 1, the electric vehicle 10 further includes a motor housing portion 98c, and the motor housing portion 98c is provided in the swing arm 18 and houses the motor 20. The motor 20 has: a stator 90; a rotor 92; and a motor housing 94 that houses the stator 90 in a fixed state, while rotatably housing the rotor 92 therein, and that fixes an opposing portion of the motor housing 94 that opposes the motor housing 98c to the motor housing 98 c.

Accordingly, in configuration 1, the motor 20 is disposed in the swing arm 18 only by fixing the motor housing 94 housing the stator 90 and the rotor 92 to the motor housing 98c, and therefore, the production efficiency of the electric vehicle 10 can be improved.

Further, a screw hole (1 st through hole) 124 directed toward the motor housing portion 98c is formed in the motor housing 94, and a bolt 128 is inserted into the screw hole 124, whereby an opposing portion of the motor housing 94 opposing the motor housing portion 98c is fixed to the motor housing portion 98 c. Accordingly, the motor housing 94 can be easily fixed to the motor housing 98 c.

The motor housing 94 also includes: rotor support portions 94L and 94R for rotatably supporting the rotor 92; and a stator support portion 94a that supports an outer side surface of the stator 90 in the radial direction of the motor 20. By causing stator support portion 94a and rotor support portions 94L and 94R to function as a part of motor housing 94, the number of parts of motor 20 can be reduced.

In addition, screw holes (2 nd through holes) 124 directed to the motor housing portion 98c are formed in the rotor support portions 94L and 94R and the stator support portion 94a, and the rotor support portion 94R and a part of the stator support portion 94a form opposing portions. In this case, the opposite portion is fixed to the motor housing portion 98c by inserting the bolt 128 into the screw hole 124. Accordingly, the motor housing 94 can be easily fixed to the motor housing 98c while reducing the number of parts of the motor 20.

Further, a motor shaft 96 is rotatably supported on the rotor 92, and the motor shaft 96 projects from the motor housing 94 such that a right end portion (tip end portion) 96R is directed toward the motor housing 98 c. Motor shaft 96 has right end 96R rotatably supported by bearing 118, and bearing 118 is provided on the motor housing portion 98c side. Accordingly, the motor shaft 96 can be suitably supported by the motor housing 98 c.

In this case, spline machining is performed on the right end portion 96R side of the motor shaft 96, and a motor-side gear (gear) 120 for driving the axle 16a of the rear wheel 16 is inserted into the spline-machined portion. Further, a spacer 122 for preventing separation is provided between the motor-side gear 120 and the bearing 118. Accordingly, the motor-side gear 120 can be prevented from being disengaged from the motor shaft 96.

< 3.2 Effect of the 2 nd Structure >

In the 2 nd structure, the electric vehicle 10 further has a motor housing portion 98c, which motor housing portion 98c is provided to the swing arm 18 for housing the motor 20. The motor 20 has a motor housing 94, and the motor housing 94 houses the stator 90 and the rotor 92 as a driving portion of the motor 20. The swing arm 18 has a swing arm cover 102, and an exposure portion 132 that exposes a part of the motor housing 94 to the outside is provided in the swing arm cover 102.

Accordingly, in the configuration 2, the heat of the motor 20 is radiated to the outside through the exposed portion 132 provided in the swing arm cover 102. As a result, the motor 20 housed in the motor housing portion 98c of the swing arm 18 can be efficiently cooled.

In addition, the electric vehicle 10 further includes a power supply line 134, and the power supply line 134 supplies power to the motor 20. The swing arm cover 102 covers the power supply line 134. Accordingly, the design of the electric vehicle 10 can be improved while protecting the power supply line 134.

In this case, the power supply line 134 is disposed in front of the motor 20, and the swing arm cover 102 covers the power supply line 134 from the front. Accordingly, the power supply line 134 can be protected from flying stones and the like from the front during traveling of the electric vehicle 10.

Motor 20 is a three-phase ac motor, and feeder 134 may be a three-phase wire for feeding power to the ac motor. This enables the electric vehicle 10 to travel satisfactorily.

The exposed portion 132 exposes the rear portion of the motor housing 94 to the outside. Accordingly, the motor 20 can be cooled while protecting the power feed line 134 from flying stones or the like from the front.

Further, exposed portion 132 exposes motor housing 94 to the outside in the vehicle width direction of electric vehicle 10. This can further improve the cooling efficiency of the motor 20.

The exposed portion 132 is formed to have a wider width toward the rear of the electric vehicle 10. Accordingly, the cooling efficiency of the motor 20 can be improved while protecting the interior of the swing arm 18 from flying stones and the like from the front.

The swing arm cover 102 covers a central portion of the motor housing 94 in a side view. This can protect the rotation angle detecting unit 112, the motor shaft 96, and the like.

The exposed portion 132 is formed in an arc shape in a side view. This enables the stator 90 constituting the motor 20 to be efficiently cooled.

The driving portion of the motor 20 is constituted by a stator 90 and a rotor 92, wherein the stator 90 is fixed inside a motor housing 94, and the rotor 92 is rotatably supported by a shaft inside the motor housing 94. Therefore, in configuration 2, the stator 90 and the rotor 92 can be cooled well.

The exposed portion 132 is provided to correspond to the slot 90b formed in the stator 90 and around which the coil 90c is wound, in a side view. This enables the stator 90 to be cooled more efficiently. That is, since the coil 90c is energized by the electric power supplied from the power supply line 134, the coil 90c is a component having the largest amount of heat generation in the motor 20. Therefore, by providing the exposed portion 132 corresponding to the coil 90c, the stator 90 can be cooled more efficiently.

Then, the motor housing 94 is fixed to the motor housing 98c via a bolt (fixing means) 128, whereby the motor 20 is housed in the motor housing 98 c. The exposure portion 132 exposes a part of the motor housing 94 to the outside so that the bolt 128 is covered by the swing arm cover 102. Accordingly, the bolt 128 can be concealed to improve the design of the electric vehicle 10 and cool the motor 20.

< 3.3 Effect of the 3 rd Structure >

In the 3 rd configuration, the electric vehicle 10 further includes: a motor housing portion 98c provided at a side of the rear wheel 16 in the swing arm 18 for housing the motor 20; and a power supply line 134 for supplying power to the motor 20. In this case, a through hole 138 is formed in a front end portion (one end portion 98a) of the swing arm 18 in a position forward of the rear wheel 16. The power supply line 134 extends forward from the motor 20 in the swing arm 18, is bent inward in the vehicle width direction of the electric vehicle 10 at one end 98a, and extends outward of the swing arm 18 from the through hole 138.

Accordingly, the power supply line 134 extends from the motor 20 to the outside through the through hole 138 formed in the one end portion 98a via the inside of the swing arm 18. As a result, when the feeder line 134 is disposed from the inside to the outside of the swing arm 18, the feeder line 134 can be disposed more linearly without bending the feeder line 134 too much. Further, since the degree of exposure of the power supply line 134 to the outside is low, the number of parts for protecting the power supply line 134 from the outside can be reduced and the appearance can be improved. Further, since a space above or below the swing arm 18 is secured, a space for mounting the battery 62 can be secured above the pivot shaft 54, for example. As a result, the minimum height above the ground of the swing arm 18 can be ensured.

Further, 2 bearings 100 are provided at both ends of the pivot shaft 54 in the vehicle width direction. One end portion 98a is rotatably supported on the pivot shaft 54 by 2 bearings 100. A through hole 138 is formed in the one end portion 98a at a position between the 2 bearings 100, and the power supply line 134 extends from between the 2 bearings 100 to the outside of the swing arm 18 via the through hole 138.

Thus, the power supply line 134 is not exposed to the outside at the outside in the vehicle width direction, but is exposed to the outside at the inside in the vehicle width direction. Accordingly, when the electric vehicle 10 is tilted during turning of the electric vehicle 10, the power feed line 134 is prevented from contacting the road surface, and therefore the tilt angle of the electric vehicle 10 can be secured.

Further, a through hole 138 is formed in a portion of the one end portion 98a located above the pivot shaft 54, and the power supply line 134 extends from above the pivot shaft 54 to the outside of the swing arm 18 through the through hole 138. Accordingly, the minimum height above the ground of the electric vehicle 10 including the swing arm 18 can be ensured.

Further, a rib 146 is provided between the through hole 138 in the swing arm 18 and the motor housing portion 98 c. Accordingly, the mechanical strength of the swing arm 18 can be enhanced.

In addition, the electric vehicle 10 further includes: a rotation angle detection unit 112 that is disposed on the motor 20 and detects a rotation angle of the motor 20; and a communication line 136 extending from the rotation angle detecting unit 112. In this case, the communication line 136 extends forward from the rotation angle detecting unit 112 in the swing arm 18 along the power supply line 134, is bent inward in the vehicle width direction at the one end 98a, and extends outward of the swing arm 18 from the through hole 138. Accordingly, communication line 136 reduces bending in swing arm 18 together with power feeding line 134, and can improve appearance while avoiding exposure to the outside.

In addition, the electric vehicle 10 further includes a fixing portion 139 that fixes the power supply line 134 to the swing arm 18 in the swing arm 18. Accordingly, the power supply line 134 arranged linearly can be held inside the swing arm 18.

In this case, the fixing portion 139 includes: an annular clamping member 142 that fastens the power supply line 134; and a fixing part 143 that fixes the clamping part 142 to the swing arm 18. Accordingly, the power supply line 134 can be reliably held inside the swing arm 18.

Specifically, the clamp member 142 may be 1 ring member or a detachable ring member formed by annularly forming 2 plate-like members 142a and 142b having proximal end portions fixed to the fixing member 143 and distal end portions facing each other. If the clamping member 142 is 1 annular member, the supply line 134 can be held with a smaller number of parts. On the other hand, if the clamp member 142 is a detachable member, the power supply line 134 can be taken out without detaching (detaching) the swing arm 18 when detaching the motor 20 from the swing arm 18. As a result, workability of the detaching operation of the motor 20 is improved.

In addition, when a part of the clamp member 142 extends to the outside through the through hole 138, the fixing member 143 may fix the exposed part of the clamp member 142 to the swing arm 18. Accordingly, the power supply line 134 can be taken out from the swing arm 18 only by detaching the fixing member 143 from the swing arm 18. As a result, the motor 20 can be removed more efficiently.

Further, a hole 144 for draining water is formed in the bottom of the swing arm 18. Accordingly, the liquid that has entered the swing arm 18 through the through hole 138 falls downward through the hole 144. As a result, the occurrence of short-circuiting or the like of the power feed line 134 due to liquid such as water can be avoided.

Further, the electric vehicle 10 includes a battery 62 and a PCU (electronic component) 66 supported by the vehicle body frame 22. The power supply line 134 is led out from the through hole 138 to the outside and connected to the PCU 66. The PCU66 supplies electric power supplied from the battery 62 to the motor 20 via the power supply line 134. Accordingly, the PCU66 can supply electric power to the motor 20 to drive the motor 20.

In this case, since the motor 20 is an ac motor and the power supply line 134 is a three-phase power supply line for supplying power to the ac motor, the electric vehicle 10 can be driven well.

< 3.4 Effect of the 4 th Structure >

In the 4 th configuration, the electric vehicle 10 includes a speed reducer 114 that transmits the driving force of the motor 20 to the rear wheels 16; a reducer housing unit 116 provided in the swing arm 18 and housing the reducer 114; and a vent pipe 148 extending from the reducer housing portion 116. One end 148a of the breather pipe 148 communicates with the reducer housing portion 116. The other end 148b of the breather pipe 148 is disposed on a fender 60 (a component of the electric vehicle 10) that is positioned above the swing arm 18 and is swingable together with the swing arm 18.

Accordingly, since the other end 148b of the breather pipe 148 is disposed upward, the lubricating oil liquefied in the breather pipe 148 returns to the reduction gear housing section 116 via the one end 148a of the breather pipe 148. As a result, the liquefied lubricant is not discharged to the outside, and therefore, contamination of the electric vehicle 10 and the like can be avoided.

The speed reducer housing section 116 and the breather pipe 148 are disposed between the motor 20 and the rear wheel 16. Accordingly, the space between the motor 20 and the rear wheel 16 can be effectively used.

The duct 148 is disposed along an upper wall portion 170, and the upper wall portion 170 is provided near the reducer housing portion 116 of the swing arm 18. Accordingly, the breather pipe 148 can be cooled by the traveling wind while protecting the breather pipe 148 from flying stones and the like during traveling of the electric vehicle 10. Further, by being disposed on the upper wall portion 170, even if the breather pipe 148 rattles due to vibrations or the like during traveling, the breather pipe 148 can be prevented from coming into contact with the rear wheel 16.

In this case, the upper wall portion 170 is inclined such that the other end 148b of the vent pipe 148 is higher than the one end 148 a. Accordingly, even when the gas is liquefied into the lubricating oil by cooling the breather pipe 148, the lubricating oil returns from the one end portion 148a of the breather pipe 148 to the reduction gear housing 116. As a result, the lubricating oil can be prevented from being discharged to the outside from the other end 148b of the breather pipe 148.

Further, the upper wall portion 170 is provided with a fixing portion 172 for fixing the air pipe 148 to the swing arm 18 and the upper wall portion 170. Accordingly, the breather pipe 148 can be prevented from being involved in the rear wheel 16.

The vent pipe 148 is disposed in a state in which the other end 148b as an outlet is directed upward. This can reliably prevent the lubricating oil from being discharged to the outside from the outlet of the breather pipe 148.

The vent pipe 148 is disposed in a state in which one end 148a as an inlet is directed downward. Accordingly, the lubricating oil liquefied in the breather pipe 148 can be reliably returned to the reduction gear housing 116.

Further, the other end 148b of the breather pipe 148, which is an outlet, is disposed on the side surface of the fender 60. Accordingly, the other end 148b of the breather pipe 148 can be easily fixed.

In this case, a plate member 174 is disposed between the breather pipe 148 and the rear wheel 16. Accordingly, it is possible to avoid the breather pipe 148 from being involved in the rear wheel 16 when the other end portion 148b of the breather pipe 148 is detached from the fender 60, and to avoid the lubricating oil discharged from the outlet from adhering to the rear wheel 16.

The plate member 174 is integrally formed with the fender 60. Accordingly, the plate member 174 can be easily provided.

One end 148a of the duct 148, which is an inlet, is provided between the motor shaft 96 of the motor 20 and an axle (output shaft) 16a, and the axle (output shaft) 16a transmits the driving force from the motor shaft 96 to the rear wheels 16. Accordingly, when the internal pressure rises due to the temperature rise in the reduction gear housing 116 and gas containing the atomized lubricating oil is generated, the gas can be efficiently discharged to the outside.

In this case, the inlet of the breather pipe 148 is provided between the intermediate shaft 156 of the speed reducer 114 and the axle 16a, wherein the speed reducer 114 transmits the driving force from the motor shaft 96 to the axle 16 a. Accordingly, the gas containing the mist of the lubricating oil can be discharged to the outside more efficiently.

The present invention has been described above with reference to preferred embodiments, but the technical scope of the present invention is not limited to the description of the above embodiments. It is obvious to those skilled in the art that various alterations and modifications can be added. It is obvious from the description of the embodiments that such additional modifications or improvements can be included in the technical scope of the present invention. In addition, the parenthesized reference numerals described in the claims are added to the reference numerals in the drawings for easy understanding of the present invention, and the present invention is not limited to the elements explained with the reference numerals.

Claims (11)

1. An electric vehicle (10) having a vehicle body frame (22), a pivot shaft (54), a swing arm (18), and a motor (20), wherein the pivot shaft (54) is provided to the vehicle body frame (22); one end of the swing arm (18) is rotatably supported by the pivot (54), and the other end supports a rear wheel (16); the motor (20) is arranged to the swing arm (18) for driving the rear wheel (16),

it is characterized in that the preparation method is characterized in that,

further comprising a motor housing section (98c) and a power supply line (134), wherein the motor housing section (98c) is provided at a position inside the swing arm (18) on the side of one side of the rear wheel (16) and houses the motor (20); the supply line (134) is used for supplying power to the motor (20),

a through hole (138) is formed in a position of one end of the swing arm (18) which is positioned in front of the rear wheel (16) and opens forward,

the power supply line (134) extends forward from the motor (20) in the swing arm (18), is bent inward in the vehicle width direction of the electric vehicle (10) at one end of the swing arm (18), extends to the outside of the swing arm (18) from the through hole (138), is routed to the other side of the rear wheel (16), and is connected to an electronic component (66), the electronic component (66) is disposed behind a battery (62), the battery (62) is disposed in a space between a pair of right and left upright portions (34L, 34R) of the vehicle body frame (22),

2 bearings (100) are provided at both ends of the pivot shaft (54) in the vehicle width direction,

one end of the swing arm (18) is rotatably supported on the pivot (54) through 2 bearings (100),

the through hole (138) is formed at a position between 2 bearings (100) at one end of the swing arm (18),

the power supply line (134) extends from between 2 of the bearings (100) to the outside of the swing arm (18) via the through hole (138).

2. The electric vehicle (10) of claim 1,

the through hole (138) is formed at a portion of one end portion of the swing arm (18) above the pivot shaft (54),

the power supply line (134) extends from above the pivot (54) to the outside of the swing arm (18) via the through hole (138).

3. The electric vehicle (10) of claim 1,

a rib (146) is provided at a position between the through hole (138) and the motor housing portion (98c) in the swing arm (18).

4. The electric vehicle (10) of claim 1,

the motor is further provided with a rotation angle detection unit (112) and a communication line (136), wherein the rotation angle detection unit (112) is arranged on the motor (20) and is used for detecting the rotation angle of the motor (20); the communication line (136) extends from the rotation angle detection unit (112),

the communication line (136) extends forward from the rotation angle detection unit (112) in the swing arm (18) along the power supply line (134), is bent inward in the vehicle width direction at one end of the swing arm (18), and extends from the through hole (138) to the outside of the swing arm (18).

5. The electric vehicle (10) of claim 1,

further comprising a fixing part (139) for fixing the power supply line (134) to the swing arm (18) within the swing arm (18).

6. The electric vehicle (10) of claim 5,

the fastening part (139) has an annular clamping part (142) and a fastening part (143), wherein the clamping part (142) serves to fasten the supply line (134); the fixing part (143) is used for fixing the clamping part (142) on the swing arm (18).

7. The electric vehicle (10) of claim 6,

the clamp member (142) is a ring-shaped member formed in a ring shape by 2 plate-shaped members (142 a, 142 b) having proximal end portions fixed to the fixing member (143) and distal end portions facing each other, or a detachable ring-shaped member.

8. The electric vehicle (10) according to claim 6 or 7,

a portion of the clamping member (142) extends to the outside through the through hole (138),

the fixing member (143) fixes the exposed portion of the clamp member (142) to the swing arm (18).

9. The electric vehicle (10) of claim 1,

a hole (144) for draining water is formed at the bottom of the swing arm (18).

10. The electric vehicle (10) of claim 1,

the battery (62) and the electronic component (66) are supported by the vehicle body frame (22),

the electronic component (66) supplies the electric power supplied from the battery (62) to the motor (20) through the power supply line (134).

11. The electric vehicle (10) of claim 1,

the motor (20) is an alternating current motor,

the power supply line (134) is a three-phase electric line for supplying power to the alternating current motor.

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