JP2014069736A - Battery-loading structure of saddle-riding type electric vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a simple, compact and lightweight battery-loading structure of a saddle-riding type electric vehicle.SOLUTION: A vehicle body-rear side end part of a battery 22 is inserted in an electrode case 70 supported on a sub-frame 32. Further, movement of the battery 22 towards a vehicle body-front end side and upwards is restricted by a movement restriction member 88. Preferably, a first hinge part 94 and a second hinge part 96 are provided to the movement restriction member 88. Meanwhile, although movements of the battery 22 towards the left and right sides of the vehicle body are restricted by a vehicle body-side electrode 68, it is more preferable that a first rightward movement restriction piece and a second rightward movement restriction piece are provided to the movement restriction member 88 while a restriction part 86 is provided to a frame holder 74, and the movements are also restricted by these restriction means.

Description

  The present invention relates to a structure for mounting a battery in a clearance between a lower frame and an upper frame of a straddle-type electric vehicle, that is, a battery mounting structure for a straddle-type electric vehicle.

  A so-called saddle riding type electric vehicle in which a driver gets on a seat and rides on a seat and uses a motor as a travel drive source is equipped with a battery for energizing the motor. The present applicant has proposed a structure in which a battery is mounted in a space surrounded by a head pipe, a lower frame, an upper frame, and a pivot frame in Patent Document 1.

  In the technique described in Patent Document 1, a part of the vehicle body cover is a lid that can be opened and closed to cover the side of the battery box. The battery box is supported by a support frame.

JP 2010-83348 A

  Charging the battery is generally performed with the battery mounted on the vehicle body. For this reason, the vehicle body must be transported to the charging site. Moreover, a parking space is required at the charging place.

  Therefore, it is recalled that the battery is removed from the vehicle body and charged. This is because transportation with a battery alone is easy and there is an advantage that charging is possible even in a place where there is no parking space.

  By the way, in the technique of patent document 1, in order to remove a battery, after removing the said lid | cover, the complicated operation | work of rotating the said support frame below is required. Further, since the lid and the support frame are provided, the structure in the vicinity of the battery is increased in size and weight. Furthermore, a sufficient space is required to rotate the support frame, which also contributes to an increase in the size and weight of the structure in the vicinity of the battery.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a battery mounting structure for a straddle-type electric vehicle that is simple and downsized and can be reduced in weight.

In order to achieve the above object, the present invention provides an upper frame (30) extending from the head pipe (28) to the vehicle body rear side, and a vehicle body rear side from the head pipe (28) or the upper frame (30). A battery (22) supported by the lower frame (32) so as to be able to be taken in and out from the side of a vehicle body in a clearance between the lower frame (32) and the lower frame (32) positioned below the upper frame (30). In the battery mounting structure of the saddle riding type electric vehicle (10) mounting
The rear part of the battery (22) is connected to the vehicle body side electrode (68), and is removed from the vehicle body side electrode (68) by moving the battery (22) to the vehicle body front rear side along the lower frame (32). In addition, the forward and upward movement in the vehicle body direction is restricted by the movement restricting member (88).

  That is, in the present invention, the battery is removed from the vehicle body by simply removing the battery movement restriction by the movement restriction member and then removing the battery body rear side end from the vehicle body side electrode. Can do.

  In addition, since only the movement restricting member needs to be provided, the configuration in the vicinity of the battery can be simplified. That is, the battery mounting structure can be made compact (downsized), and as a result, the weight can be reduced.

  When charging, the battery can be removed from the vehicle body and transported, so that it is not necessary to transport the vehicle body. Moreover, it is easy to electrically connect the battery to a power source such as an outlet. For this reason, it becomes easy to carry out charging work including transportation and connection. In addition, it is possible to charge even where there is no parking space.

  In this configuration, the lower frame (32) is composed of a pair of left and right frames (34, 36), and an insertion opening (37) is formed between the pair of left and right frames (34, 36). The movement restricting member (88) can be rotated about the hinge portion (94), and the rotated movement restricting member (88) can be passed through the insertion opening (37). preferable.

  In this case, the movement restriction member with respect to the battery by the movement restriction member can be released by rotating the movement restriction member around the hinge portion. Therefore, since it is not necessary to remove the movement restricting member from the vehicle body, a complicated operation is unnecessary, and the time required for the battery removing operation can be shortened.

  In addition, it is easy to rotate the movement restricting member, and the amount of rotation can be increased.

  In addition, when the movement restricting member (88) is provided with a connecting portion (102) that is detachably connected to the vehicle body near the upper surface of the battery (22), the upper frame (30) is connected to the head pipe ( 28) configured to have a horizontal portion (38) extending substantially horizontally from the rear side of the vehicle body and a curved portion (40) curved from the horizontal portion (38) toward the lower frame (32). In addition, it is preferable that the connecting portion (102) is disposed below the bending portion (40).

  Since there is a horizontal portion, the curved portion that continues from the vehicle body rear side of the horizontal portion is curved so as to bypass the battery. Therefore, since a sufficient space is formed between the bending portion and the connecting portion, the work for connecting the vehicle body and the movement restricting member and the work for releasing the connection can be easily performed.

  Here, it is preferable that the movement restricting member (88) is made of a metal material, and a second hinge portion (96) is provided between the hinge portion (94) and the connecting portion (102). By using a metal material, the movement regulating member can be made excellent in durability. Further, since the movement restricting member can be folded around the second hinge part, the movement restricting member becomes compact, and it is easier to rotate around the hinge part. That is, workability is improved.

  In the above configuration, it is preferable to provide the movement restricting member (88) with restricting pieces (98, 100) for restricting the movement of the battery (22) in the vehicle body width direction. The restriction piece can restrict the movement of the battery in the vehicle body width direction. That is, the battery is prevented from coming off in the vehicle body width direction.

  Furthermore, it is preferable to provide an electrode case (70) that surrounds the vehicle body side electrode (68) and into which the vehicle body rear end of the battery (22) is inserted.

  By this insertion, it is possible to restrict the battery from moving in the vehicle body rear direction and the vehicle body width direction. When removing the battery from the vehicle body, the battery may be moved along the lower frame to the vehicle body front side, and the vehicle body rear side end portion of the battery may be exposed from the electrode case.

  Moreover, you may make it provide the control part (86) which controls the movement to the vehicle body width direction of the said battery (22) in a vehicle body. Even in this case, the movement of the battery in the vehicle body width direction can be restricted.

  According to the present invention, since the movement restricting member is provided to restrict the battery from moving to the front side and the upper side of the vehicle body, the movement restriction by the movement restricting member is released when the battery is removed from the vehicle body. Only need. For this reason, since the configuration in the vicinity of the battery is simplified, the battery mounting structure can be made smaller and lighter.

  When charging, since the battery can be removed from the vehicle body by releasing the movement restriction as described above, only the battery can be transported without transporting the vehicle body. In addition, since it is easy to electrically connect the battery to a power source such as an outlet, it is easy to perform a charging operation including transportation and connection. In addition, charging is possible even in places where there is no parking space.

1 is a schematic left side view of an essential part of a motorcycle (saddle-type electric vehicle) employing a battery mounting structure according to an embodiment of the present invention. FIG. 2 is a schematic left side view of the main part in a state in which a left side cover, an upper cover, and a seat are removed from FIG. 1. Fig. 2 is a schematic perspective view of a main part from a lower right front side of a vehicle body of the motorcycle. It is the partial cross section left side view which abbreviate | omitted illustration of the battery and showed the vehicle cross direction center cross section of the principal part. It is a VV arrow directional cross-sectional view of FIG. FIG. 6 is a cross-sectional view taken along line VI-VI in FIG. 1. FIG. 2 is a schematic left side view of the main part of the motorcycle with the left side cover removed from FIG. 1.

  Hereinafter, preferred embodiments of a battery mounting structure for a saddle riding type electric vehicle according to the present invention will be described in detail with reference to the accompanying drawings. In the following, the traveling side of the vehicle body is referred to as the front, the opposite direction is referred to as the rear, and the left hand side in a state where the driver gets in a normal posture is referred to as the vehicle body left side, and the right hand side is referred to as the vehicle body right side. In the drawings, the front side, the left side, and the upper side in the vertical direction are respectively indicated as Fr, L, and Up.

  FIG. 1 is a schematic left side view of a main part of a motorcycle 10 (saddle-type electric vehicle) in which the battery mounting structure according to the present embodiment is employed. The motorcycle 10 is an electric motorcycle that is provided in a wheel 20 of a rear wheel 18 and uses an in-wheel motor (not shown) energized by a battery 22 as a travel drive source.

  Here, FIG. 2 shows a schematic left side surface of the main part with the left side cover 12, the upper cover 14, and the seat 16 removed from FIG. The headlight and the like are also not shown.

  As shown in FIG. 2, the motorcycle 10 includes a head pipe 28 that supports a front fork 26 that supports a front wheel 24 so as to be steerable, and an upper frame 30 that extends from the head pipe 28 toward the rear side of the vehicle body (main Frame) and a lower frame 32 (subframe) extending from the head pipe 28 to the rear side of the vehicle body and positioned below the main frame 30. The battery 22 is disposed in a clearance between the upper frame 30 and the lower frame 32.

  The lower frame 32 is bifurcated from the head pipe 28. Therefore, as shown in FIG. 3, the lower frame 32 has a left frame 34 on the left side of the vehicle body and a right frame 36 on the right side of the vehicle body. In other words, the lower frame 32 is composed of a pair of left and right frames, and the left frame 34 and the right frame 36 are spaced apart by a predetermined interval. 37 is formed.

  As shown in FIG. 1, the left frame 34 and the right frame 36 extend substantially linearly while being inclined rearward and downward so as to approach the ground as going toward the rear of the vehicle body. The battery mounting structure according to the present embodiment is provided close to the lower frame 32 configured as described above, and this will be described in detail later.

  On the other hand, the upper frame 30 includes a horizontal portion 38 that extends substantially horizontally from the head pipe 28 toward the rear side of the vehicle body, and a curved portion 40 that curves from the horizontal portion 38 toward the lower frame 32. For this reason, the upper frame 30 is curved so as to bypass the battery 22. The curved portion 40 of the lower frame 32 and the upper frame 30 is connected via a pivot frame 42. A body stand 44 and a step 46 are supported on the pivot frame 42.

  The upper frame 30 is provided with a first stay 48 and a second stay 50, and a control device (power drive unit, PDU) 52 is held by the first stay 48 and the second stay 50.

  Further, a rear cushion 56 for supporting the rear arm 58 is provided on the vehicle body rear side of the second stay 50.

  In the upper frame 30, the seat rail 60 is connected to the vicinity of the starting end portion 40 a of the bending portion 40.

  Next, the battery mounting structure according to the present embodiment will be described.

  As shown in FIG. 3, an under cover 62 is attached below the lower frame 32 so as to straddle the left frame 34 and the right frame 36. That is, two support frames 64 extending along the width direction of the vehicle body are bridged between the left frame 34 and the right frame 36 (one of them is shown in FIG. 3). The under cover 62 is connected to these support frames 64 by bolts 66 and covers the vicinity of the connecting portion between the upper frame 30 and the rear arm 58 (see FIG. 1).

  A vehicle body side electrode 68 that is electrically connected to the battery 22 is disposed on the vehicle body rear side of the under cover 62, as shown in FIG. The vehicle body side electrode 68 is surrounded by the electrode case 70. The electrode case 70 is supported by the lower frame 32 and the pivot frame 42.

  The electrode case 70 is a hollow body, and an opening for inserting the battery 22 is formed on the front side of the vehicle body. Further, the both side walls have a shape that is inclined by cutting out a part of a rectangle from the lower side of the vehicle body to the upper side so as to avoid interference with the step 46 and the vehicle body stand 44.

  A recess 72 is formed in the ceiling wall of the electrode case 70 so as to be depressed toward the front side of the vehicle body. The bottom wall of the opening of the electrode case 70, that is, the vehicle body rear side wall of the electrode case 70 is provided slightly offset toward the vehicle body front side with respect to the recess 72. Further, an insertion port (not shown) through which the vehicle body side electrode 68 passes is formed through the vehicle body rear side wall.

  The vehicle body rear side end portion of the battery 22 is inserted into the electrode case 70 as described above. By this insertion, the vehicle body rear side end portion of the battery 22 is supported by the electrode case 70. That is, the movement of the rear end portion of the battery 22 in the vehicle body in the vehicle body rear side and in the vehicle body width direction (left and right side) is restricted by the electrode case 70.

  Here, a frame-like holder 74 for holding the battery 22 is connected to the support frame 64 via bolts 76 (see FIG. 3). The frame-shaped holder 74 forming a part of the vehicle body includes a front / rear frame portion 78 extending from the vehicle body front side to the vehicle body rear side along the under cover 62, and a vertical frame portion rising substantially vertically from the front / rear frame portion 78. 80 and a connecting frame portion 82 that is bent substantially perpendicularly to the vertical frame portion 80 and extends substantially parallel to the front and rear frame portions 78.

  Among these, the front side end portion of the front and rear frame portion 78 is bent substantially vertically from the support frame 64 toward the battery 22, and further extends along the front and rear direction of the vehicle body. The battery 22 is supported by the front and rear frame portions 78 when the upper end surface of the extending portion contacts the battery 22. In addition, since a predetermined clearance is formed between the battery 22 and the bolt 76, the bolt 76 does not interfere with the battery 22.

  The vertical frame portion 80 rises from the lower side of the electrode case 70 along the rear side wall of the vehicle body and passes through the recess 72 formed in the ceiling wall of the electrode case 70. The vertical frame portion 80 is connected to the vehicle body rear side wall of the electrode case 70 via a bolt (not shown). Of course, the insertion opening is formed at a position where it is not blocked by the vertical frame portion 80.

  As described above, the front and rear frame portions 78 are connected to the support frame 64 and the vertical frame portion 80 is connected to the electrode case 70, whereby the frame-shaped holder 74 is held by the vehicle body.

  The connecting frame portion 82 is set to be slightly thicker than the front and rear frame portions 78 and the vertical frame portion 80. And the socket 84 by which the thread part was engraved inside is provided in the vehicle body front side edge part.

  The frame-shaped holder 74 further has a restricting portion 86 bridged from the front and rear frame portion 78 to the connecting frame portion 82. Of course, the restricting portion 86 is bent so as to bypass the battery 22 so as not to prevent the battery 22 from being inserted into the electrode case 70.

  The frame-shaped holder 74 configured as described above is connected to a movement restricting member 88 that restricts the movement of the battery 22 toward the front side and the upper side of the vehicle body.

  The movement restricting member 88 is a front restricting portion 90 that restricts the movement of the battery 22 toward the front end surface of the vehicle body, and an upper restriction that is bent substantially vertically from the front restricting portion 90 and restricts the upward movement of the battery 22. Part 92. The front restricting portion 90 and the upper restricting portion 92 have a long and thin plate shape. That is, the front restricting portion 90 and the upper restricting portion 92 are provided in a band shape.

  Among these, the front restricting portion 90 is connected to the front and rear frame portions 78 of the frame-shaped holder 74 via the first hinge portion 94. That is, the front restricting portion 90 can be rotated about the first hinge portion 94 as a rotation center. As will be described later, the movement restricting member 88 can pass between the left frame 34 and the right frame 36 during this rotation.

  Further, the upper restricting portion 92 is connected to the front restricting portion 90 through the second hinge portion 96. For this reason, the upper restricting portion 92 can be turned around the second hinge portion 96 as a turning center.

  A first right movement restricting piece 98 that restricts the movement of the battery 22 to the right side of the vehicle body is provided in the vicinity of the first hinge portion 94 in the front restricting portion 90 and in the vicinity of the second hinge portion 96 in the upper restricting portion 92. The second rightward movement restricting piece 100 is formed to protrude. The first right movement restricting piece 98 extends from the front side of the vehicle body to the rear side and extends substantially parallel to the lower frame 32. On the other hand, the second rightward movement restricting piece 100 is directed from the upper side of the vehicle body to the lower side and protrudes in a direction substantially orthogonal to the extending direction of the lower frame 32.

  A bolt passage portion 102 erected substantially perpendicular to the extending direction of the upper restricting portion 92 is provided at the rear end portion of the upper restricting portion 92 in the vehicle body. The bolt 104 passed through the bolt passage portion 102 is screwed into a screw portion engraved inside the socket 84, thereby connecting the upper restriction portion 92 of the movement restriction member 88 and the frame holder 74. The frame part 82 is connected to each other. Since the socket 84 and the bolt passage portion 102 are below the bending portion 40, the connecting portion between the upper restricting portion 92 (movement restricting member 88) and the connecting frame portion 82 (frame-shaped holder 74) bypasses the battery 22. It is located below the curved portion 40 that is curved in the direction.

  The movement restricting member 88 configured as described above is made of a metal material such as stainless steel, for example.

  As shown in FIG. 3 and FIG. 5, which is a cross-sectional view taken along line VV in FIG. 1, a stepped portion 106 is formed on the vehicle body right side end surface of the battery 22 from the vehicle body front side end portion to the middle abdomen. Is done. The first right movement restriction piece 98 and the second right movement restriction piece 100 are in contact with the step portion 106. Further, due to the presence of the step portion 106, the right end surface of the vehicle body has a shape in which the grip portion 108 protrudes. Here, the cross section taken along line VV is a cross section orthogonal to the longitudinal direction of the battery 22.

  That is, the battery 22 is restricted from moving to the vehicle body rear side and the vehicle body side by inserting the vehicle body rear side end portion into the electrode case 70 (see FIGS. 1 and 2), and the frame-shaped holder. The front and rear frame portions 78 and the restricting portions 86 of 74 are restricted to move upward and to the left side of the vehicle body (see FIGS. 3 and 5). Further, the forward restricting portion 90 and the upward restricting portion 92 of the movement restricting member 88 restrict the movement toward the front and upper sides of the vehicle body, and the first rightward movement restricting piece 98 and the second rightward movement restricting piece 100 provide the vehicle body. Movement to the right is restricted. In short, the battery 22 is held in a state in which movement is restricted by the electrode case 70, the frame-shaped holder 74, and the movement restriction member 88.

  Next, the mounting structure of the control device 52 will be described. The control device 52 has a function of controlling the amount of power sent from the battery 22 to the motor. In this case, the control device 52 has a substantially rectangular shape.

  The first cable 110 (see FIG. 2) is electrically connected to the vehicle body side electrode 68. The first cable 110 is held along the upper frame 30 and extends to the connector 112 provided in the vicinity of the rear cushion 56.

  The connector 112 is electrically connected to a second cable 114 extending toward the control device 52 having a substantially rectangular shape. That is, the first cable 110 and the second cable 114 are electrically connected via the connector 112.

  A third cable 116 is further connected to the connector 112. The third cable 116 is for supplying power from the control device 52 to the motor.

  In this case, the cable connection portion of the control device 52 is provided on the upper end surface. For this reason, the second cable 114 is routed so as to be bent along the upper frame 30 and then bend from the vehicle body side to the vehicle body upper side.

  As shown in FIG. 1, the control device 52 is covered with a control device cover. That is, in this case, the control device cover includes the upper cover 14, the left side cover 12, and the right side cover 118 (all of which are side covers), and most of the upper end surface and both side surfaces of the control device 52 are the upper cover 14. The remaining portions of both side surfaces exposed from the exposed portion 117 of the upper cover 14 are covered with the left side cover 12 and the right side cover 118. Thereby, the control apparatus 52 is protected. The upper cover 14, the left side cover 12, and the right side cover 118 are all made of a resin material. The exposed portion 117 is a portion that exposes at least a part of the control device 52 to the side in a side view.

  As shown in FIG. 6 which is a cross-sectional view taken along the line VI-VI in FIG. 1, the upper cover 14 is located at a position where a fuel tank cover is provided in a motorcycle using gasoline as fuel and an internal combustion engine as a travel drive source. It is provided so as to straddle the vehicle body from the left side to the right side of the vehicle body.

  As shown in FIG. 7, the upper cover 14 is positioned and fixed to the horizontal portion 38 of the upper frame 30 and extends substantially parallel to the head pipe 28 to cover the front end surface of the control device 52, A top plate portion 122 that curves from the front portion 120 and extends toward the rear side of the vehicle body, and a left side portion that projects from the front portion 120 and the top plate portion 122 toward the width direction (left and right side) of the vehicle body 124 and the right side portion 126, and a rear portion 128 extending from each of the left side portion 124 and the right side portion 126 toward the vehicle body rear side. Most of the upper end surface and both side surfaces of the control device 52 are covered by the main body portion 129 of the upper cover 14 formed from the front portion 120, the top plate portion 122, the left side portion 124 and the right side portion 126.

  The left side portion 124 and the right side portion 126 are formed with a recess 130 that is recessed toward the control device 52 side at a position in front of the seat 16. The recess 130 is provided with a locking projection 132 for locking the left side cover 12 and the right side cover 118.

  The rear portion 128 is slightly biased toward the ground as compared with the main body portion 129. Due to this deviation, a stepped portion 133 is formed between the main body portion 129 and the rear portion 128. For this reason, the front end portion of the seat 16 comes into contact with the rear end portion of the main body portion 129. At this time, the upper end surface of the top plate portion 122 and the upper end surface of the front end portion of the sheet 16 are connected so as to be substantially continuous with each other. Further, the seat 16 is superimposed on the rear portion 128.

  As shown in FIG. 1, the left side cover 12 and the right side cover 118, which are also referred to as shrouds, have a substantially “←” shape, and are attached to the left side surface and the right side surface of the vehicle body, thereby Cover and protect the left and right sides respectively. The sharp tips of the left side cover 12 and the right side cover 118 reach the side of the head pipe 28. In addition, an annular recess 134 is formed on the surface facing the recess 130 at the upper end portion that jumps upward from the head pipe 28 so as to incline upward.

  The locking projection 132 is fitted into the annular recess 134. By this fitting, the left side cover 12 and the right side cover 118 are overlapped and connected to the upper cover 14 in the lower front part of the seat 16. That is, a part of the upper cover 14 is the overlapping part 136, and a part of the left side cover 12 and the right side cover 118 is the overlapping part 138. In the motorcycle 10, the overlapping portions 136 and 138 overlap each other.

  The lower ends of the left side cover 12 and the right side cover 118 extend in parallel along the lower frame 32 and face the vehicle body front side end surface of the battery 22.

  Next, the effect of the motorcycle 10 (saddle-type electric vehicle) configured as described above will be described.

  First, in the straddle-type electric vehicle according to the related art, the control device is supported by the seat rail 60. On the other hand, in the present embodiment, the control device 52 is arranged above the horizontal portion 38 of the upper frame 30 in front of the seat 16. For this reason, the vehicle body front side (front wheel 24 side) also bears a load. That is, the load distribution is good between the vehicle body front side and the vehicle body rear side (rear wheel 18 side).

  Further, since the control device 52 is mainly covered with the upper cover 14 and further covered with the left side cover 12 and the right side cover 118, the control device 52 is not removed when the covers 12, 14, 118 are not removed. It is no longer visible. Therefore, the external appearance does not change as the control device 52 is disposed on the front side of the vehicle body.

  Furthermore, in the present embodiment, the left side portion 124 of the upper cover 14 and the upper end portion of the left side cover 12 are overlapped, and the right side portion 126 of the upper cover 14 and a part of the upper end portion of the right side cover 118 are overlapped. In addition, the locking projection 132 is fitted into the annular recess 134. By this superposition, the rigidity of the upper cover 14, the left side cover 12, and the right side cover 118 is increased.

  Further, the seat 16 is superimposed on the rear portion 128 of the upper cover 14, and the main body portion 129 is provided with the step portion 133, so that the upper end surface of the front end surface of the seat 16 is substantially the upper end surface of the top plate portion 122. Connect in a continuous manner. This also contributes to increasing the rigidity of the upper cover 14.

  For the reasons described above, the rigidity of the upper cover 14, the left side cover 12, and the right side cover 118 is increased. As a result, for the driver of the motorcycle 10, an operation of tightening the left side cover 12 and the right side cover 118 with both knees ( Sufficient rigidity can be felt when performing so-called knee grip.

  Further, when the upper cover 14, the left side cover 12, and the right side cover 118 are integrally formed as the same member, the upper cover 14 is pulled out in the vertical direction at the time of molding, and in consideration of the slipping gradient, FIG. As shown by the line, the shape must be expanded along the width direction of the vehicle body as it goes downward. In other words, the vehicle body tends to be a cover member having a large widthwise dimension. In addition, a large-scale apparatus must be used as a molding apparatus for obtaining such a cover member.

  However, in the present embodiment, the upper cover 14, the left side cover 12, and the right side cover 118 are formed as separate members. For this reason, as can be seen from FIG. 6, the left side cover 12 and the right side cover 118 can have a shape that extends substantially linearly along the vertical direction of the vehicle body. Therefore, it can suppress that the dimension of the width direction of a vehicle body becomes large. Moreover, the molding apparatus for obtaining each of the upper cover 14, the left side cover 12, and the right side cover 118 can be made small.

  Further, since the side of the upper cover 14 is cut out as an exposed portion 117, the left side cover 12 and the right side cover 118 are secured while ensuring a sufficient clearance between the left side cover 12, the right side cover 118, and the upper cover 14. Can be arranged more inside the vehicle body. As a result, the vehicle width can be reduced.

  In addition, when the cable connection portion of the control device 52 is provided on the front end surface, the rear end surface, the left side surface, the right side surface, or the like, it is necessary to provide a sufficient space for the second cable 114 to be bent and connected. For this reason, although the longitudinal dimension or the width dimension of the vehicle body is increased, in this embodiment, the cable connection portion of the control device 52 having a substantially rectangular parallelepiped shape is provided on the upper end surface of the control device 52. The second cable 114 held along the upper frame 30 may be curved in an arc shape from the side of the vehicle body toward the upper side of the vehicle body. Thereby, the 2nd cable 114 can be bent gently. Therefore, the second cable 114 can be connected to the control device 52 without increasing the longitudinal dimension or the width dimension of the vehicle body.

  Moreover, until the upper cover 14 is attached, the upper end surface (cable connection portion) of the control device 52 is exposed upward, that is, toward the operator. For this reason, the arrangement | positioning of the 2nd cable 114 in the cable connection part vicinity, and the connection operation | work to the control apparatus 52 of the 2nd cable 114 become easy.

  In the motorcycle 10, electric power is supplied from the battery 22 to the motor via the control device 52, whereby the rear wheel 18 rotates following the energization of the motor. Accordingly, the motorcycle 10 travels. At this time, the amount of power supplied to the motor is controlled by the control device 52. This is particularly useful for a vehicle in which the position of the upper frame 30 is low and the control device 52 is disposed at a position of 1 m or less from the ground.

  As the motorcycle 10 travels (in other words, power is supplied from the battery 22), the amount of power stored in the battery 22 decreases. For this reason, it is necessary to charge the battery 22.

  As described above, since the battery 22 is held by the electrode case 70, the movement restricting member 88, and the frame-shaped holder 74, it cannot be detached from the vehicle body and transported as it is.

  Therefore, in order to remove the battery 22 from the vehicle body, first, the bolt 104 is loosened, and the bolt 104 is detached from the socket 84. As described above, since the curved portion 40 of the upper frame 30 is curved so as to bypass the battery 22, a sufficient space is formed between the curved portion 40 and the battery 22. For this reason, the operator easily performs an operation of loosening the bolt 104 by inserting a hand and a screwing tool between the bending portion 40 and the battery 22 (the connecting portion between the upper restricting portion 92 and the connecting frame portion 82). be able to.

  As a result of the bolt 104 being detached from the socket 84, the upper restricting portion 92 of the movement restricting member 88 is released from being restrained by the connecting frame portion 82 of the frame-shaped holder 74. Therefore, the first hinge portion 94 and the second hinge portion 96 can be rotated around the rotation center.

  Therefore, after slightly rotating the front restricting portion 90 and the upper restricting portion 92 with the first hinge portion 94 as the rotation center, the upper restricting portion 92 is moved toward the front restricting portion 90 with the second hinge portion 96 as the rotation center. If the angle between the front restricting portion 90 and the upper restricting portion 92 is an acute angle by turning, the movement restricting member 88 is folded in a compact manner. In addition, a sufficient clearance is provided between the battery 22 and the upper frame 30, and the connecting portion (socket 84 and the bolt passage portion 102) has the clearance without the movement restricting member 88 receiving interference from the upper frame 30 and the battery 22. It is necessary to set to pass. Therefore, when the height of the bolt passage portion 102 is a and the minimum gap between the battery 22 and the upper frame 30 is b, b> a is provided.

  Thereafter, the movement restricting member 88 is further rotated, so that the movement restricting member 88 is moved between the left frame 34 and the right frame 36 that are separated from each other, that is, the insertion opening 37 (see FIG. 1). 3) can be easily passed.

  Thus, according to the present embodiment, the movement restricting member 88 can be folded and rotated, so that the structure near the battery 22 can be reduced in size and weight.

  As a result of the rotation, the front end portion of the battery 22 on the vehicle body side is released from restraint by the movement restricting member 88. However, at this time, the battery 22 is still restrained by the frame-shaped holder 74 and the electrode case 70. Therefore, the battery 22 can only move to the front end portion of the vehicle body in parallel with the lower frame 32.

  Therefore, the worker grips the grip portion 108 (see FIG. 3) of the battery 22 and pulls the battery 22 along the lower frame 32 to the vehicle body front side end portion. That is, it is moved. As a result, the battery 22 is detached from the vehicle body side electrode 68, and the vehicle body rear side end portion of the battery 22 is exposed from the electrode case 70 to be released from restraint by the electrode case 70.

  The frame holder 74 is provided with a restricting portion 86 that restricts the movement of the battery 22 to the left side of the vehicle body. Further, the first right movement restriction piece 98 and the second right movement restriction piece 100 which are provided on the movement restriction member 88 and restrict the movement of the battery 22 to the right side of the vehicle body, which are the movement pieces, As the regulating member 88 is rotated, it is detached from the stepped portion 106 of the battery 22. Accordingly, the battery 22 whose rear end on the vehicle body is exposed from the electrode case 70 can be moved toward the right side of the vehicle.

  That is, the battery 22 can be taken out from the right side of the vehicle body by slightly moving along the lower frame 32 toward the front side of the vehicle body and exposing the rear end portion of the vehicle body from the electrode case 70. Eventually, the battery 22 can be easily removed from the vehicle body. In addition, since the restriction part 86 is provided in the frame-shaped holder 74, the battery 22 cannot be moved toward the left side of the vehicle body, in other words, cannot be taken out from the left side of the vehicle body.

  The battery 22 can be charged by transporting the battery 22 to a charging place and connecting the battery 22 to an appropriate power source such as a general household outlet.

  As understood from the above, according to the present embodiment, only the battery 22 needs to be transported when charging, and it is not necessary to transport the entire vehicle body. For this reason, transportation is easy. Further, charging is possible even in a place where there is no parking space.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention.

  For example, in the embodiment described above, the frame-shaped holder 74 and the movement restricting member 88 are connected by the first hinge portion 94 and the bolt 104, but a bolt is used instead of the first hinge portion 94. It may be. In this case, when removing the battery 22, the bolt 104 and the bolt may be loosened, and the movement restricting member 88 may be detached from the frame-shaped holder 74. In this case, it is not particularly necessary to provide the second hinge portion 96 or to configure the subframe 32 with the combination of the left frame 34 and the right frame 36.

  The straddle-type electric vehicle is not particularly limited to the motorcycle 10, and may be a three-wheeled vehicle or a four-wheeled buggy used in buggy competitions.

  Further, the sub frame 32 may extend backward from the vehicle body starting from the main frame 30 instead of from the head pipe 28.

  Furthermore, the control device 52 may be supported on the seat rail 60 in the same manner as in the saddle riding type electric vehicle according to the related art.

  The restriction portion 86 is provided on the left side, and the first right movement restriction piece 98 and the second right movement restriction piece 100 which are the restriction pieces 98 and 100 are provided on the right side. The portion 86 and the restriction pieces 98 and 100 may be provided in reverse. That is, it is sufficient that the restricting portion 86 is on one side and the restricting pieces 98 and 100 are on the other side.

DESCRIPTION OF SYMBOLS 10 ... Motorcycle 12 ... Left side cover 14 ... Upper cover 16 ... Seat 18 ... Rear wheel 22 ... Battery 24 ... Front wheel 28 ... Head pipe 30 ... Upper frame 32 ... Lower frame 34 ... Left frame 36 ... Right frame 37 ... Insertion Mouth 38 ... Horizontal part 40 ... Bending part 48 ... First stay 50 ... Second stay 52 ... Control device 58 ... Rear arm 60 ... Seat rail 64 ... Support frame 68 ... Car body side electrode 70 ... Electrode case 74 ... Frame-shaped holder 84 ... Socket 86 ... Restriction part 88 ... Movement restriction member 90 ... Front restriction part 92 ... Upper restriction part 94 ... First hinge part 96 ... Second hinge part 98 ... First right movement restriction piece 100 ... Second right movement restriction piece DESCRIPTION OF SYMBOLS 102 ... Bolt passage part 104 ... Bolt 106 ... Step part 108 ... Grasping part 110 ... 1st cable 112 ... Connector 114 ... 2nd cable 11 ... third cable 117 ... exposed portion 118 ... right side cover 120 ... front portion 122 ... top plate portion 124 ... left side portion 126 ... right side portion 128 ... rear portion 129 ... main body portion 130 ... dent 132 ... locking projection 133 ... Step part 134 ... Annular recess 136,138 ... Overlapping part

Claims (7)

An upper frame (30) extending from the head pipe (28) to the vehicle body rear side, and extending from the head pipe (28) or the upper frame (30) to the vehicle body rear side and below the upper frame (30) Of the straddle-type electric vehicle (10) in which a battery (22) supported by the lower frame (32) is mounted in the clearance between the lower frame (32) and the lower frame (32). In the battery mounting structure,
The rear part of the battery (22) is connected to the vehicle body side electrode (68), and is removed from the vehicle body side electrode (68) by moving the battery (22) to the vehicle body front rear side along the lower frame (32). A battery mounting structure for a saddle-ride type electric vehicle (10), characterized in that the forward and upward movement in the vehicle body direction is restricted by a movement restricting member (88). The battery mounting structure according to claim 1, wherein the lower frame (32) is composed of a pair of left and right frames (34, 36), and between the pair of left and right frames (34, 36). An insertion opening (37) is formed,
And the said movement control member (88) can be rotated centering | focusing on a hinge part (94),
The battery mounting structure of the straddle-type electric vehicle (10), wherein the moved movement restricting member (88) passes through the insertion port (37). The battery mounting structure according to claim 1 or 2, wherein the movement restricting member (88) has a connecting portion (102) detachably connected to the vehicle body side in the vicinity of the upper surface of the battery (22).
The upper frame (30) extends from the head pipe (28) substantially horizontally to the rear side of the vehicle body, and the lower frame (32) is curved from the horizontal portion (38). The battery mounting structure of the saddle riding type electric vehicle (10), characterized in that the connecting portion (102) is disposed below the bending portion (40).   The battery mounting structure according to claim 3, wherein the movement restricting member (88) is made of a metal material, and a second hinge portion (96) is provided between the hinge portion (94) and the connecting portion (102). A battery mounting structure for a saddle riding type electric vehicle (10), characterized in that:   The battery mounting structure according to any one of claims 1 to 4, wherein the movement restricting member (88) includes a restricting piece (98, 100) for restricting movement of the battery (22) in the vehicle body width direction. A battery mounting structure for a saddle riding type electric vehicle (10), comprising:   The battery mounting structure according to any one of claims 1 to 5, wherein the electrode case (70) surrounds the vehicle body side electrode (68) and into which a vehicle body rear side end portion of the battery (22) is inserted. A battery mounting structure for a saddle riding type electric vehicle (10), characterized in that   The battery mounting structure according to any one of claims 1 to 6, wherein the vehicle body is provided with a restriction portion (86) for restricting movement of the battery (22) in the vehicle body width direction. -Type electric vehicle (10) battery mounting structure.

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