JP2013129368A - Saddle-riding type electric motor vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a saddle-riding type electric motor vehicle with a compact charging receptacle, configured to reliably prevent generation of arc discharge when a charging plug is inserted to/removed from the charging receptacle.SOLUTION: An MCU 90 and a switch 42 change a state of a signal flowing in a communication wire 113 connected to a BMS 103 for controlling power supply between the receptacle 53 and a battery 6 immediately before or after a vehicle body frame moves. The BMS 103 cuts off or prevents power supply between the receptacle 53 and the battery 6 before releasing connection of a terminal of a plug 55 and a terminal of the receptacle 53, in response to a signal state of the communication wire 113.

Description

  The present invention relates to a straddle-type electric vehicle.

  An electric vehicle using an electric motor as a power source includes a receptacle for charging a battery. When charging the battery, a plug provided at the end of the cord extending from the charger is connected to the receptacle.

  As a connector used when charging an electric vehicle, a connector including a lock mechanism, a lock operation detection unit, and a lock control unit is known (for example, see Patent Document 1). In this connector, the lock mechanism locks and unlocks the charging side connector and the vehicle side connector in the mounted state, and the lock operation detecting means detects the operation state of the lock mechanism. Then, the lock control means switches the control switch for opening and closing the charging line from the charging power source to the battery between the open state and the closed state based on the detection result of the lock operation detecting means.

  In this connector, when the lock operation detecting means detects that the lock mechanism is attached to the vehicle-side connector and the lock mechanism is in the locked state, the control switch provided in the charging line is closed. Then, electric power is supplied from the charging power source to the battery via the charging line, and the two connectors are energized. Here, when a person who does not know the situation that the battery is being charged tries to remove both in the energized state, the lock operation detecting means detects that the lock mechanism is in the unlocked state. The Then, a control switch will be in an open state and between both connectors will be in a non-energized state. Thereby, when both connectors are removed, it is possible to prevent an arc from being generated between the contacts of the two, and the contact is reliably protected.

JP-A-10-262340

  However, in the above configuration, in order to prevent the arc discharge by switching the control switch provided in the charging line, the power cut-off mechanism including the lock mechanism, the lock operation detecting means, and the lock control means in the plug (charging connector) main body. Is built in. This leads to an increase in the size of the plug. Therefore, the receptacle (vehicle side connector) itself to which such a large plug is connected is inevitably increased in size.

  A straddle-type vehicle such as an electric two-wheeled vehicle has a limited space for mounting members compared to a four-wheeled vehicle, and therefore the receptacle is also arranged in a narrow space. Therefore, it is difficult to equip a straddle-type electric vehicle with a large receptacle to which a large plug as described above can be connected.

  Accordingly, an object of the present invention is to provide a straddle-type electric vehicle that can be equipped with a small receptacle and that can reliably prevent the occurrence of arc discharge when a plug is inserted into and removed from the receptacle.

One aspect that the present invention can take is a straddle-type electric vehicle,
A charging receptacle having an energizing terminal connected to the energizing terminal of the charging plug;
A battery connected to the energization terminal and energized;
An energization control unit for controlling energization between the energization terminal and the battery;
A signal line connected to the energization control unit;
A signal changing unit for changing a state of a signal flowing through the signal line;
A vehicle body frame that supports the charging receptacle, the battery, the signal line, and the signal changing unit;
The signal changing unit changes a state of a signal flowing through the signal line immediately before or after the body frame moves,
The energization control unit shuts off or suppresses energization between the charging receptacle and the battery before the connection state between the energizing terminal of the charging plug and the energizing terminal of the receptacle is released according to the signal state of the signal line. To do.

  According to such a configuration, even if a situation where the charging plug is forcibly pulled out from the charging receptacle due to the fact that the saddle riding type electric vehicle being charged has moved for some reason, the occurrence of arc discharge is surely prevented. be able to.

  The signal changing unit may employ a configuration that changes the state of the signal flowing through the signal line in accordance with the movement of the body frame.

  As the signal changing unit, a configuration is adopted in which the signal state is changed according to the movement of a part that is supported by the vehicle body frame and is relatively movable with respect to the vehicle body frame and capable of contacting the ground. can do.

As the signal changing unit, at least one of the following can be adopted.
An acceleration signal changing unit that changes a signal state according to the acceleration of the body frame. A wheel speed signal changing unit that changes a signal state according to a rotation state of a wheel supported by the body frame. In response to the state of the vehicle body tilt signal changing unit that changes the signal state according to the state of the side stand signal changing unit that changes the signal state according to the state of the side stand provided in the vehicle body frame A main stand signal changing unit for changing a signal state, a handle lock signal changing unit for changing a signal state according to a state of a handle lock provided on the body frame, and a load applied to a seat provided on the body frame. A seat load signal changing part for changing the signal state and a parking brake provided on the body frame. Parking brake signal changing unit for changing the signal state in response to state

  In this case, since the detection operation as a trigger for turning off the power uses existing sensors provided in each part of the saddle riding type electric vehicle, it is not necessary to provide a special detection mechanism in the charging receptacle or the charging plug. Therefore, it is possible to reduce the size of the charging receptacle and the charging plug. That is, even in a straddle-type electric vehicle in which the space for mounting components is limited compared to a four-wheeled vehicle, the degree of freedom of arrangement of the charging receptacle can be increased.

  From the viewpoint of preventing arc discharge, when the signal line is a communication line connecting the control unit of the charger for supplying power to the battery and the energization control unit, the signal line for performing control for cutting off charging. Therefore, it is possible to avoid an increase in the number of terminals of the charging receptacle, thereby contributing to cost reduction and improved connection reliability.

  The charging receptacle is formed such that the dimension in the first direction perpendicular to the insertion / extraction direction of the charging plug is larger than the dimension in the insertion / extraction direction and the second direction perpendicular to the first direction, and a plurality of terminals are provided. It is good also as a structure arrange | positioned in a line in the said 1st direction. In this case, the connection port of the charging receptacle can also be formed in a flat shape, and it is possible to ensure the degree of freedom of arrangement of the charging receptacle even in a saddle-type electric vehicle in which the mounting positions of the members are relatively limited. Further, the power supply terminals that are at a high temperature during charging can be arranged apart from each other.

1 is a left side view showing an electric motorcycle according to an embodiment of the present invention. FIG. 2 is a left side view showing a state where some parts are removed from the electric motorcycle of FIG. 1. FIG. 2 is a perspective view showing a housing space in a state where a seat of the electric motorcycle of FIG. 1 is opened. FIG. 4 is a perspective view showing a state in which a plug is connected to a receptacle provided in the accommodation space of FIG. 3. It is a perspective view which shows the external appearance of the receptacle of FIG. It is a perspective view which shows the external appearance of the plug of FIG. FIG. 2 is a configuration diagram of a charging system in the electric motorcycle of FIG. 1. It is a figure which shows typically the wiring between the electric motorcycle of FIG. 1, and a charger.

  The present invention will be described in detail below with reference to the accompanying drawings. In each drawing used in the following description, the scale is appropriately changed to make each member a recognizable size.

  FIG. 1 is a left side view showing an electric motorcycle according to an embodiment of the present invention. In the present embodiment, an electric motorcycle 1 including a scooter will be described as an example of a saddle riding type electric vehicle. The electric motorcycle 1 can travel with a load placed on the front part and the rear part, and is suitable for use as a cargo handling vehicle.

  In the following description, the front, rear, top and bottom, and left and right directions are in a reference posture corresponding to a state in which the electric motorcycle 1 is traveling straight on a horizontal plane, and the driver when the driver is facing forward. Based on this viewpoint. In addition, the configuration of the electric motorcycle 1 will be described with reference to the electric motorcycle 1 that stands upright, the front wheels 3 and the rear wheels 4 are in contact with the road surface A1, and the driver is not on the vehicle.

  The electric motorcycle 1 includes a body frame 2, a front wheel 3, a rear wheel 4, an electric motor 5, a battery 6, and a vehicle body cover 7. The electric motorcycle 1 drives the electric motor 5 with the electric power supplied from the battery 6, and drives the rear wheel 4 with the output of the electric motor 5. The electric motor 5 is accommodated in a power unit 47 disposed on the right side of the rear wheel 4. Hereinafter, the entire structure of the electric motorcycle 1 will be described in order from the front of the vehicle body.

  FIG. 2 is a left side view showing a state in which some components are removed from the electric motorcycle shown in FIG. The electric motorcycle 1 has a head pipe 8 disposed at the front upper portion of the electric motorcycle 1. A steering shaft 9 is rotatably inserted into the head pipe 8. A pair of left and right front forks 10 are attached to the lower end of the steering shaft 9. The front wheel 3 is attached to the front fork 10.

  A handle 11 is attached to the upper end portion of the steering shaft 9. The driver can turn the steering shaft 9, the front fork 10 and the front wheel 3 around the axis of the steering shaft 9 by operating the handle 11.

  A grip 12 is provided at each of the left and right ends of the handle 11 (only the left grip is shown). The right grip constitutes the throttle grip. The driver can adjust the output of the electric motor 5 by turning the throttle grip.

  As shown in FIG. 1, a meter 13 is provided near the center of the handle 11. A loading platform 14 is disposed below the meter 13. The loading platform 14 is fixed to the head pipe 8. The load of the load loaded on the loading platform 14 mainly acts on the front wheel 3 via the head pipe 8 and the steering shaft 9. A headlamp 15 is fixed to the lower part of the loading platform 14.

  As shown in FIG. 2, the electric motorcycle 1 includes a vehicle body frame 2 that extends rearward from the head pipe 8. The body frame 2 is formed using a steel pipe member or the like. The vehicle body frame 2 includes a down tube 19 and a frame main body 20 disposed behind the down tube 19. The down tube 19 extends obliquely downward and rearward from the lower portion of the head pipe 8. In the side view, the frame body 20 extends rearward from the lower end portion of the down tube 19, and an intermediate portion of the vehicle in the front-rear direction X <b> 1 is formed in an S shape.

  A pair of left and right frame bodies 20 are provided. The frame body 20 includes a first frame portion 21, a second frame portion 22, a third frame portion 23, and a fourth frame portion 24. The first frame portion 21 extends substantially straight rearward from the lower end portion of the down tube 19 and is slightly inclined rearward and upward.

  The second frame portion 22 is formed in an S shape in a side view. The second frame portion 222 includes a lower end portion 22a, an intermediate portion 22b, and an upper end portion 22c. The lower end portion 22 a of the second frame portion 22 is formed in a curved shape and is connected to the rear end portion of the first frame portion 21. The intermediate part 22b of the second frame part 22 extends straight from the lower end part 22a obliquely rearward and upward. In side view, the inclination angle of the intermediate portion 22b with respect to the first frame portion 21 is, for example, about 45 degrees. The upper end portion 22c of the second frame portion 22 is formed in a curved shape and is connected to the intermediate portion 22b.

  The third frame portion 23 extends linearly from the upper end portion 22c, and is slightly inclined rearward and upward. The fourth frame portion 24 extends rearward from the intermediate portion 22 b of the second frame portion 22, is bent obliquely rearward and upward in the middle, and is connected to the intermediate portion of the third frame portion 23.

  A main stand 7 is provided behind the intermediate portion 22b of the second frame portion 22 and below the fourth frame portion 24 so as to be rotatable in the front-rear direction of the vehicle body. When the electric motorcycle 1 travels, it is fixed at the rear end position of the rotation range so as not to hinder driving. When the electric motorcycle 1 is stopped for a long time, the main stand 7 is rotated forward by pulling the vehicle body backward while the passenger is stepping on the bar 7 a extending to the left and right sides of the main stand 7. The electric two-wheeled vehicle 1 is supported in a stopped state by being grounded and fixed at the front end position of the range.

  On the left side of the intermediate portion 22b of the second frame portion 22, a side stand 8 is provided so as to be rotatable in the front-rear direction of the vehicle body. When the electric motorcycle 1 travels, it is fixed at the rear end position of the rotation range so as not to hinder driving. When the electric motorcycle 1 is stopped for a short time, the passenger turns the side stand 8 forward with his / her foot. The side stand 8 is grounded and fixed at the front end position of the rotation range and supports the electric motorcycle 1 in a stopped state.

  The body frame 2 is provided with an acceleration sensor 91. The acceleration sensor 91 is a sensor that detects acceleration in the up / down / left / right / front / rear directions of the body frame 2 and is configured to output a signal corresponding to the acceleration.

  The body frame 2 is also provided with a handle lock sensor 92. During parking, so-called steering lock is performed to lock the steering shaft 8 so as not to rotate in order to prevent theft. The handle lock sensor 92 is a sensor that detects whether or not the steering shaft 8 is in the handle lock state, and is configured to output a signal when the handle lock state is released.

  A vehicle speed sensor 93 is provided on the front wheel 3. The vehicle speed sensor 93 is a sensor that outputs a signal corresponding to the amount of rotation of the front wheels, and is composed of a rotary encoder or the like. The output signal is used to specify the traveling speed of the electric motorcycle 1.

  The seat 29 is provided with a seating sensor 94. The seating sensor 94 is a sensor that outputs a signal corresponding to a load applied to itself, and is configured by a piezoelectric element or the like. When the passenger sits on the seat 29, a load is applied to the seating sensor 94 and a signal is output.

  The third frame portion 93 is provided with an inclination sensor 95. The tilt sensor 95 is a sensor that detects the tilt angle of the third frame portion 23 from the horizontal axis, and is configured to output a signal when the tilt angle exceeds a predetermined angle.

  A main stand sensor 96 is provided in the vicinity of the main stand 7. The main stand sensor 96 is a sensor that detects the position of the main stand 7 and is configured by a proximity sensor that detects metal. The main stand sensor 96 is configured to output a signal when it is detected that the main stand 7 is not at the front end position of the rotation range, that is, is not in a position to support the electric motorcycle 1 when the vehicle is stopped. The main stand sensor 96 is a switch that changes the signal state by pressing a button when the main stand 7 is at the front end position of the rotation range, and the signal state according to the rotation amount of the rotation shaft of the main stand 7. It can also be constituted by a rotary potentiometer that changes the angle.

  A side stand sensor 97 is provided in the vicinity of the side stand 8. The side stand sensor 97 is a sensor that detects the position of the side stand 8, and includes a proximity sensor that detects metal. The side stand sensor 97 is configured to output a signal when it is detected that the side stand 8 is not at the front end position of the rotation range, that is, is not in a position to support the electric motorcycle 1 when the vehicle is stopped. The side stand sensor 97 is a switch that changes the signal state by pressing a button when the side stand 8 is at the front end position of the rotation range, and the signal state changes according to the rotation amount of the rotation shaft of the main stand 8. It can also be constituted by a rotary potentiometer.

  A parking brake is provided on the handle 11 to lock the rear wheel 4 when the electric motorcycle 1 is parked. A parking brake sensor 98 is provided in the parking brake. The parking brake sensor 98 is a sensor that detects whether or not the parking brake is in a valid state, and is configured to output a signal when the parking brake is released.

  As shown in FIG. 1, the electric motorcycle 1 includes a vehicle body cover 7 attached to the vehicle body frame 2. The vehicle body cover 7 includes a front cover 25 that covers the head pipe 8, a lower cover 26 that extends rearward from the lower portion of the front cover 25, and a rear cover 27 that is disposed behind the front cover 25.

  The front cover 25 surrounds a part of the steering shaft 9 and the head pipe 8, and surrounds the down tube 19. The lower cover 26 extends rearward from the lower portion 25a of the front cover 25, and covers the first frame portion 21 and the lower end portion 22a of the second frame portion 22 from the lower side and the left and right sides. A footrest portion 28 is disposed at the upper end portion of the lower cover 26. The footrest portion 28 is provided for the driver to place his / her feet, and is formed substantially flat.

  The rear cover 27 as a whole is formed in a shape extending obliquely upward and rearward from the rear portion 26a of the lower cover 26. The rear cover 27 covers the area of the second frame portion 22 excluding the lower end portion 22a from the front and both left and right sides. The rear cover 27 covers the third frame portion 23 and the fourth frame portion 24 from both the front and left and right sides.

  A seat 29 is disposed above the rear cover 27. While the electric motorcycle 1 is traveling, the feet of the driver sitting on the seat 29 are placed on the footrest portion 28. In the front-rear direction X1, the footrest portion 28 is disposed between the rear surface 25b of the front cover 25 and the front end portion 29a of the seat 29. The seat 29 is disposed above the second frame portion 22, disposed above a portion of the third frame portion 23, and disposed above a portion of the fourth frame portion 24. . A space surrounded by the seat 29 and the rear cover 27 defines an accommodation space S1.

  As shown in FIG. 2, the seat 29 is supported by the first bracket 31 and the support bracket 37 to form a part of the outer surface of the vehicle body. The first bracket 31 is attached to the intermediate part 22 b of the second frame part 22. The first bracket 31 extends upward from the intermediate portion 22b. A hinge portion 38 is provided at the upper end portion of the first bracket 31. The seat 29 is supported by the first bracket 31 via the hinge portion 38. The first bracket 31 supports the seat 29 from below. The seat 29 can be rotated around the hinge portion 38. By rotating the seat 29 around the hinge portion 38, the accommodation space S1 can be opened upward. The hinge portion 38 may be omitted and the seat 29 may be directly fixed to the first bracket 31.

  The rear portion 29 b of the seat 29 is supported by a support bracket 37. The support bracket 37 is fixed to the third frame portion 23 of the vehicle body frame 2 and has a shape protruding upward from the third frame portion 23.

  A battery 6 as a power source for the electric motor 5 is disposed below the seat 29. The battery 6 is disposed between the pair of left and right second frame portions 22. The battery 6 is a rechargeable secondary battery. The battery 6 is formed in a substantially rectangular shape in a side view, and the length (height) in the vertical direction Z1 of the vehicle is longer than the length (width) in the front-rear direction X1. The battery 6 is disposed in a posture inclined rearward and obliquely upward, and is supported by the vehicle body frame 2. The upper part 6 a of the battery 6 is disposed between the first bracket 31 and the support bracket 37.

  As shown in FIG. 1, a loading platform 45 is disposed behind the seat 29. The loading platform 45 is disposed above the third frame portion 23 and is supported by the third frame portion 23. A load can be placed above the loading platform 45. The load of the load placed on the loading platform 45 is mainly received by the rear wheel 4.

  Thus, the loading platform 14, the battery 6 that is a heavy object, and the loading platform 45 are arranged side by side in the front-rear direction X1. Therefore, when a load is placed on the loading platform 14 and the loading platform 45, the load balance of the electric motorcycle 1 in the front-rear direction X1 can be made uniform. Therefore, even when a load is placed on the loading platform 14 and the loading platform 45, high maneuverability of the electric motorcycle 1 can be maintained.

  FIG. 3 is a perspective view showing the accommodation space S1 with the seat 29 opened. By rotating the seat 29 by the hinge portion 38, the opening portion 30 opened above the accommodation space S1 is opened. Further, the opening 30 is closed by rotating and closing the seat 29 at the hinge 38 in the opposite direction. Thus, the sheet 29 is a lid that can close the accommodation space S1. Since the sheet 29 closes the opening 30, rainwater, dust, and the like are prevented from entering the housing space S1.

  In the accommodation space S1, a connection box 51 is provided on the right side of the vehicle. The left side wall 52 of the connection box 51 is provided with a receptacle 53 as a charging receptacle of the present invention. The receptacle 53 is connected to the battery 6 so as to be energized. As shown in FIG. 4, a plug 55 as a charging plug provided on a charging cord 57 extending from a charger 58 described later is connected to charge the battery 6.

  The charging cord 57 is pulled out to the left side of the vehicle with the plug 55 connected to the receptacle 53. At the edge of the opening 30 of the accommodation space S1, a notch 63 is formed on the left front side. The charging cord 57 is passed through the notch 63 of the opening 30. Accordingly, the seat 29 can block the opening 30 of the accommodation space S1 in a state where the charging cord 57 that connects the plug 55 and the charger 58 is drawn into the accommodation space S1 from the outside.

  FIG. 5 shows the appearance of the receptacle 53. (A) shows the state where the connection port 54 is closed, and (b) shows the state where the connection port 54 is opened. The receptacle 53 includes a housing 71 made of synthetic resin or the like. A connection port 54 through which a connection portion 76 of a plug 55 described later can be inserted and removed is formed in the housing 71.

  The connection port 54 is formed in a flat shape as a whole. Specifically, the plug 55 has an opening formed such that the dimension in the horizontal direction D1 perpendicular to the insertion direction D0 is larger than the dimension in the insertion direction and the vertical direction D2 perpendicular to the horizontal direction. The housing 71 has a plurality of male terminals 72 inside an outer peripheral wall 73 that forms the connection port 54 (see FIG. 8).

  A flange portion 81 is formed on the housing 71 of the receptacle 53 so as to project around the outer peripheral wall 73. The flange portion 81 has mounting holes 82 formed on both sides. The housing 71 is fixed to the side wall 52 of the connection box 51 by screwing a screw member (not shown) inserted into the attachment hole 82 into a screw hole (not shown) provided in the side wall 52 of the connection box 51.

  The housing 71 has a pair of guide grooves 84 in a lower portion of the outer peripheral wall 73 that forms the connection port 54. These guide grooves 84 are formed on both the left and right sides in the width direction of the housing 71 of the receptacle 53. These guide grooves 84 are formed along the insertion direction of the plug 55. The receptacle 53 has a lid 85 that can close the connection port 54.

  The lid 85 is made of a synthetic resin or the like and has a flat plate portion 86. The lid 85 has a peripheral wall 87 on the connection port 54 side in the flat plate portion 86. The peripheral wall 87 extends along the outer peripheral wall 73 of the housing 71 of the receptacle 53 in a state where the lid 85 closes the connection port 54 of the receptacle 53.

  The lower end of the lid 85 is rotatably connected by a support shaft (not shown) provided along the longitudinal direction of the connection port 54 on the lower side of the connection port 54 in the housing 71 of the receptacle 53. Then, when the lid 85 is rotated by the support shaft, the connection port 54 of the receptacle 53 is opened and closed by the lid 85.

  FIG. 6 shows the appearance of the plug 55. (A) shows the appearance seen from above, and (b) shows the appearance seen from below. The plug 55 includes a housing 75 formed from a synthetic resin or the like. The housing 75 is provided with a connection portion 76 that can be inserted into the connection port 54 of the receptacle 53. The connecting portion 76 has a plurality of terminal accommodating portions 70 (see FIG. 8).

  Similarly to the connection port 54 of the receptacle 53, the connection portion 76 of the plug 55 is also flat. That is, the dimension of the first direction D1 perpendicular to the insertion direction D0 of the plug 55 is formed larger than the dimension of the insertion direction and the second direction D2 perpendicular to the first direction.

  By inserting the connection part 76 of the plug 55 into the connection port 54 of the receptacle 53, each male terminal 72 is inserted into each female terminal 78, and both are electrically connected.

  As shown in FIG. 6A, the housing 75 of the plug 55 has a grip portion 101. A connecting portion 76 is provided at the front end of the gripping portion 101, and the gripping portion 101 is formed to have a larger circumference than the connecting portion 76.

  Similar to the connecting portion 76, the grip portion 101 is also formed in a flat shape. That is, the dimension of the first direction D1 perpendicular to the insertion direction D0 of the plug 55 is formed larger than the dimension D2 of the insertion direction and the second direction perpendicular to the first direction.

  The rear end surface 101a of the grip portion 101 is gradually inclined rearward from the connecting portion 76 from the right side to the left side, and the left end of the rear end surface 101a is disposed behind the right end. As a result, the grip portion 101 has an asymmetric shape in the left-right direction in plan view, and has a shape that is easy for an operator to grip with the right hand.

  Note that the expressions of front and rear and left and right in the above description are merely used for convenience to show the positional relationship in the housing 75 and do not need to coincide with the front and rear and right and left directions of the vehicle body. The same applies to the following description.

  As shown in FIG. 6B, a pair of guide protrusions 104 are formed on the back surface of the plug 55. The guide protrusion 104 is formed over the entire length of the connection portion 76 including a part of the grip portion 101. The guide protrusions 104 are formed on both the left and right sides of the plug 55 in the width direction. The guide protrusion 104 is formed along the insertion direction with respect to the receptacle 53. The guide protrusion 104 is slightly bulged on the grip portion 101 side.

  As shown in FIG. 7, an acceleration sensor 91, a handle lock sensor 92, a vehicle speed sensor 93, a seating sensor 94, a tilt sensor 95, a main stand sensor 96, a side stand sensor 97, and a parking brake sensor 98 are an MCU (Machine Control Unit). 90 is communicably connected. The MCU 90 integrally controls each element of the electric motorcycle 1 and is disposed inside the power unit 47.

  On the other hand, the electric motorcycle 1 includes a BMS (Battery Management System) 103. The BMS 103 is connected to the battery 6 via the power line 105 and the communication line 111, and functions as an energization control unit that controls energization with the battery 6.

  The BMS 103 and the receptacle 53 are connected by a communication line 113 as a signal line of the present invention so that they can communicate with each other. A switch 42 that is communicably connected to the MCU 90 via the signal line 118 is provided in the middle of the communication line 113.

  The MCU 90 receives a predetermined signal from at least one of an acceleration sensor 91, a handle lock sensor 92, a vehicle speed sensor 93, a seating sensor 94, a tilt sensor 95, a main stand sensor 96, a side stand sensor 97, and a parking brake sensor 98. In this case, a signal for turning off the switch 42 is output.

  When the switch 42 is turned off, the signal flowing through the communication line 113 is blocked. As a result, communication between the receptacle 53 and the BMS 103 is disabled. On the other hand, when the switch 42 is turned on, a signal can be transmitted / received through the communication line 113. Thereby, communication between the receptacle 53 and the BMS 103 becomes possible. Normally, the switch 42 is turned on.

  That is, at least one of the MCU 90 and the switch 42, the acceleration sensor 91, the handle lock sensor 92, the vehicle speed sensor 93, the seating sensor 94, the tilt sensor 95, the main stand sensor 96, the side stand sensor 97, and the parking brake sensor 98 is included in the present invention. It functions as a signal changing unit and is configured to change the state of a signal flowing through the communication line 113 under a predetermined condition.

  More specifically, the acceleration sensor 91 functions as an acceleration signal changing unit that changes the signal state according to the acceleration of the body frame 2. The handle lock sensor 92 functions as a handle lock signal changing unit that changes the signal state according to the lock state of the handle 11 provided on the vehicle body frame 2. The vehicle speed sensor 93 functions as a wheel speed signal changing unit that changes the signal state according to the rotation state of the front wheel 3 supported by the body frame 2. The seating sensor 94 functions as a seat load signal changing unit that changes a signal state according to a load applied to the seat 29 provided in the vehicle body frame 2. The tilt sensor 95 functions as a vehicle body tilt signal changing unit that changes the signal state according to the tilt of the vehicle body frame 2. The main stand sensor 96 functions as a main stand signal changing unit that changes the signal state according to the state of the main stand 7 provided in the vehicle body frame 2. The side stand sensor 97 functions as a side stand signal changing unit that changes the signal state according to the state of the side stand 8 provided on the vehicle body frame 2. The parking brake sensor 98 functions as a parking brake signal changing unit that changes the signal state in accordance with the state of the parking brake provided on the vehicle body frame 2.

  The charging cord 57 connected to the plug 55 has a power line 115, a communication line 116, and a connection detection line 117, and is connected to the charger 58. A power cable 61 is connected to the charger 58, and a plug 60 that can be connected to a power source 62 described later is provided at the end of the power cable 61.

  When the plug 55 is connected to the receptacle 53, the power lines 106 and 115 are electrically connected to each other, and a charging path from the charger 58 to the battery 6 is formed. Further, the communication lines 113 and 116 are electrically connected to each other, and a communication path between the charger 58 and the BMS 103 is formed. Further, the connection detection lines 114 and 117 are electrically connected to each other, and a circuit capable of detecting the connection state of the plug 55 to the receptacle 53 is formed.

  The BMS 103 energizes between the receptacle 53 and the battery 6 when communication with the charger 58 becomes possible. That is, the BMS 103 switches off the energization between the battery 6 and the receptacle 53 unless communication with the charger 58 is possible.

  FIG. 8 schematically shows the wiring between the electric motorcycle 1 and the charger 58. The receptacle 53 is connected to the battery 6 via the wiring 56. The plug 55 connected to the receptacle 53 is connected to the charging cord 57. The charging cord 57 is connected to the charger 58. A power source 62 is connected to the charger 58 via an electric wire 61. Thus, with the plug 55 connected to the receptacle 53, the power from the power source 62 is supplied to the battery 6 via the charger 58, and the battery 6 is charged.

  A plurality of male terminals 72 provided in the receptacle 53 are supported by the housing 71 so as to extend from the base 71 a of the housing 71 toward the connection port 54. These male terminals 72 are arranged in a line at intervals in the flat longitudinal direction of the housing 71 (the first direction D1). A partition wall portion 74 is formed in the housing 71 and insulates each male terminal 72.

  Specifically, a positive terminal 72a, a first communication terminal 72b, a second communication terminal 72c, a connection detection terminal 72d, a ground terminal 72e, and a negative terminal 72f are arranged in this order from one end in the longitudinal direction of the housing 71. Yes. A first communication terminal 72b, a second communication terminal 72c, a connection detection terminal 72d, and a ground terminal 72e are disposed between the positive terminal 72a and the negative terminal 72f.

  The positive terminal 72 a and the negative terminal 72 f are connected to the power line 106 of the battery 6 mounted on the electric motorcycle 1. The first communication terminal 72 b and the second communication terminal 72 c are connected to a communication line 113 used for signal transmission between the BMS 103 as a control unit mounted on the electric motorcycle 1 and the charger 58. The connection detection terminal 72d is connected to a connection detection line 114 used for detecting the insertion state of the plug 55 into the connection port 54. The ground terminal 72 e is connected to the ground wire 121 of the electric motorcycle 1.

  The plurality of terminal accommodating portions 70 of the connection portion 76 are arranged along the longitudinal direction of the flat housing 75 (that is, the first direction D1). Between each terminal accommodating part 70, the slit 77 which can insert the partition part 74 formed in the housing 71 of the receptacle 53 is formed. Each terminal accommodating portion 70 accommodates a female terminal 78. That is, a plurality of female terminals 78 are arranged in a row in the longitudinal direction of the flat shape inside the connection portion 76.

  Specifically, a positive terminal 78a, a first communication terminal 78b, a second communication terminal 78c, a connection detection terminal 78d, a ground terminal 78e, and a negative terminal 78f are arranged sequentially from one end side in the longitudinal direction of the housing 75. Yes. A first communication terminal 78b, a second communication terminal 78c, a connection detection terminal 78d, and a ground terminal 78e are disposed between the positive terminal 78a and the negative terminal 78f.

  The positive terminal 78 a and the negative terminal 78 f are connected to the power line 115 of the charger 58. The first communication terminal 78b and the second communication terminal 78c are connected to a communication line 116 used for signal transmission between the BMS 103 as a control unit mounted on the electric motorcycle 1 and the charger 58. The connection detection terminal 78d is connected to a connection detection line 117 used for detecting the insertion state of the plug 55 into the connection port 54. The ground terminal 78 e is connected to the ground wire 122 of the charger 58.

  In order to charge the battery 6, as shown in FIG. 3, first, the seat 29 of the electric motorcycle 1 is unlocked, and the seat 29 is rotated to open the accommodation space S1. Next, in order to connect the plug 55 to the receptacle 53, the plug 55 at the end of the charging cord 57 extending from the charger 58 is gripped.

  The operator holding the plug 55 introduces the plug 55 into the accommodation space S1, rotates the lid 85 to open the connection port 54 of the receptacle 53, and inserts the connection portion 76 of the plug 55 into the connection port 54. Then, the guide protrusion 105 on the back surface of the plug 55 is fitted into the guide groove 84 of the housing 71 of the receptacle 53.

  Thereby, the power line 106 on the BMS 103 side and the power line 115 on the charger 58 side are connected, and the communication line 113 on the BMS 103 side and the communication line 116 on the charger 58 side are connected. Further, the connection detection line 114 on the BMS 103 side and the connection detection line 117 on the charger 58 side are connected, so that the BMS 103 detects that the plug 55 is connected to the receptacle 53. Since the switch 42 is turned on, the BMS 103 and the charger 58 can communicate with each other via the communication lines 113 and 116 connected to each other, and the BMS 103 energizes the receptacle 53 and the battery 6.

  When the connection of the plug 55 to the receptacle 53 is completed, as shown in FIG. 4, the charging cord 57 is disposed in the notch 63 formed in the opening 30 of the accommodation space S1, and the seat 29 is rotated to accommodate the accommodation space S1. The opening 30 is closed. When the operator operates the charger 58, charging of the battery 6 is started.

  In the present embodiment, when charging of the battery 6 is started by the charger 58, the BMS 103 notifies the MCU 90 via the signal line 119. In response to the notification, the MCU 90 shifts to an operation mode in which signal input from sensors arranged in each part of the electric motorcycle 1 is monitored.

  Although it is desirable to keep the electric motorcycle 1 being charged in a resting state, there are various factors that cause the vehicle to move. For example, in the case of the electric motorcycle 1 that is smaller and lighter than that of a four-wheeled vehicle, there is a possibility of attempting to move the vehicle while the charger 58 is connected to the electric two-wheeled vehicle 1. Moreover, the situation where the pedestrian puts the charging cable 57 on his / her foot and falls the electric motorcycle 1 is conceivable. Under such circumstances, the plug 55 connected to the receptacle 53 is forcibly pulled out, and there is a risk of leakage due to arc discharge, terminal damage, or the like.

  Before the above situation, the electric motorcycle 1 that is stationary under the charging process is always moved for some reason. Therefore, in the present embodiment, various situations involving the movement of the vehicle body frame 2 are detected by various sensors, and the MCU 90 monitors the output signals of the various sensors. When a movement of the vehicle body frame 2 that should not occur during charging is detected, the MCU 90 turns off the switch 42 and forcibly cuts off the energization between the receptacle 53 and the battery 6.

  For example, when the charging electric motorcycle 1 in a stationary state is moved, the acceleration sensor 91 detects the displacement of the body frame 2 and outputs a signal. If the movement involves the rotation of the front wheel 3, the vehicle speed sensor 93 outputs a signal corresponding to the rotation. Immediately after the body frame 2 is displaced, the MCU 90 that has received a signal input from at least one of the acceleration sensor 91 and the vehicle speed sensor 93 performs a process of turning off the switch 42. As a result, energization between the receptacle 53 and the battery 6 is cut off, and the possibility of arc discharge can be avoided in advance.

  For example, when the charged electric motorcycle 1 in a stationary state falls for some reason, the tilt sensor 95 detects the tilt state of the body frame 2 from the horizontal plane and outputs a signal. The MCU 90 that has received a signal input from the tilt sensor 95 immediately after the displacement of the body frame performs a process of turning off the switch 42. As a result, energization between the receptacle 53 and the battery 6 is cut off, and the possibility of arc discharge can be avoided in advance.

  In order to move the electric motorcycle 1 that is parked or stopped, some preliminary operations are required. The electric motorcycle 1 according to the present embodiment detects this preliminary operation, that is, a state immediately before the body frame 2 is displaced.

  As specific examples of the preliminary operation, operations such as releasing the handle lock, sitting on the seat 29, rotating the main stand 7 or the side stand 8 from the grounding position to the traveling position, and releasing the parking brake can be considered. . According to the configuration of the present embodiment, these operations are detected by the handle lock sensor 92, the seating sensor 93, the main stand sensor 96, the side stand sensor 97, and the parking brake sensor 98, and a signal corresponding to the state is output. .

  The MCU 90 that has received a signal input from at least one of these sensors performs processing for turning off the switch 42. As a result, energization between the receptacle 53 and the battery 6 is cut off, and the possibility of arc discharge can be avoided in advance.

  During charging, a large current flows through the positive terminal 78a and the negative terminal 78f connected to the power line, and heat generation increases. In the plug 55 of the present embodiment, a plurality of female terminals 78 are arranged in a line along the longitudinal direction of the flat connection portion 76. Further, the positive terminal 78a and the negative terminal 78f are sufficiently separated by other female terminals 78 disposed between them. Therefore, the heat generated in the positive terminal 78 a and the negative terminal 78 f can be radiated well at both ends of the housing 75. Therefore, it is possible to suppress the influence of heat generated during charging as much as possible.

  When charging is completed, the seat 29 is unlocked, and the seat 29 is rotated to open the accommodation space S1 as shown in FIG. Next, the plug 55 is pulled out from the receptacle 53 to release the connection, and the connection port 54 is closed with the lid 85. Thereby, the receptacle 53 is protected by the lid 85.

  Thereafter, the plug 55 is taken out from the accommodation space S1, and the seat 29 is rotated to close the opening 30 of the accommodation space S1. Since the accommodation space S1 is blocked by the seat 29, the intrusion of rainwater and dust into the accommodation space S1 is prevented, so that the receptacle 53 is double protected by the seat 29 and the lid 85.

  As described above, in the present embodiment, the MCU 90 changes the signal state of the communication line 113 immediately before or after the displacement of the vehicle body frame 2 to cut off the communication between the receptacle 53 and the BMS 103. The BMS 103 as the energization control unit disconnects the positive and negative terminals 78a and 78f as energization terminals in the plug 55 and the positive and negative terminals 72a and 72f as energization terminals in the receptacle 53 according to the state of the signal. Before, the energization between the receptacle 53 and the battery 6 is cut off.

  Therefore, even if the plug 55 is forcibly pulled out from the receptacle 53 due to the electric motorcycle 1 being charged being moved for some reason, the occurrence of arc discharge can be reliably prevented.

  In addition, since the detection operation as a trigger for turning off the power uses existing sensors provided in each part of the electric motorcycle 1, it is not necessary to provide a special detection mechanism for the receptacle 53 or the plug 55. Therefore, the receptacle 53 and the plug 55 can be reduced in size. That is, even in a saddle-type vehicle such as a two-wheeled vehicle in which the space for mounting components is limited as compared with a four-wheeled vehicle, the degree of freedom in arranging the receptacle 53 can be increased.

  The above embodiment is for facilitating understanding of the present invention, and does not limit the present invention. The present invention can be modified and improved without departing from the spirit of the present invention, and it is obvious that the present invention includes equivalents thereof.

  The energization control by the BMS 103 does not necessarily need to completely interrupt the energization between the receptacle 53 and the battery 6. A configuration may be adopted in which the voltage or current in the receptacle 53 is suppressed to such an extent that the occurrence of arc discharge associated with the plug 55 insertion / extraction operation can be prevented.

  The sensor for detecting the state immediately before and after the displacement of the body frame 2 or the state during the displacement is not limited to the one exemplified above. As long as the sensor can output a signal corresponding to the movement of the body frame 2, an appropriate arrangement and detection method can be employed.

  Parts for detecting the state immediately before the displacement of the body frame 2 (that is, the preliminary movement of the vehicle movement) are not limited to the main stand 7 and the side stand 8. As long as the component is supported by the vehicle body frame 2 and is relatively movable with respect to the vehicle body frame 2 and capable of contacting the ground surface A1, an appropriate arrangement and detection method can be employed.

  The function as an energization control unit that controls energization of the receptacle 53 and the battery 6 is not necessarily performed by the BMS 103 alone. At least one of the functions as the energization control unit can be assigned to at least one of a CCU (Cell Control Unit) or MCU (Machine Control Unit) that is mounted on the electric motorcycle 1 and has a control function.

  The combination of the on / off state of the switch 42 and the cutoff state of the communication line 113 is arbitrary. That is, the signal flowing through the communication line 113 may be blocked when the switch 42 is turned on.

  A signal line whose signal state is changed by an instruction from the MCU 90 is not limited to the communication line 113. From the viewpoint of preventing arc discharge, any power supply line or signal line that can cut off the AC power supply may be used, and the switch 42 may be provided in the middle of the power line 106 or the connection detection line 114.

  The disconnection of the communication line 113 is not necessarily performed directly by the switch 42. The communication line 113 may be blocked by an appropriate circuit element that operates according to a signal output from the switch 42. Moreover, it is good also as a structure which notifies the state of a vehicle from MCU90 to BMS103, and BMS103 interrupts | blocks or suppresses charging current based on the information.

  The number of wheels in the straddle-type electric vehicle to which the present invention is applied is not limited to two, but is determined as appropriate.

  1: Electric motorcycle, 2: Body frame, 6: Battery, 7: Main stand, 8: Side stand, 29: Seat, 42: Switch, 53: Receptacle, 55: Plug, 58: Charger, 72: Male terminal, 90 : MCU, 91: Acceleration sensor, 92: Handle lock sensor, 93: Vehicle speed sensor, 94: Seating sensor, 95: Tilt sensor, 96: Main stand sensor, 97: Side stand sensor, 98: Parking brake sensor, 113: Communication line , 103: BMS

Claims (8)

A charging receptacle having an energizing terminal connected to the energizing terminal of the charging plug;
A battery connected to the energization terminal and energized;
An energization control unit for controlling energization between the energization terminal and the battery;
A signal line connected to the energization control unit;
A signal changing unit for changing a state of a signal flowing through the signal line;
A vehicle body frame that supports the charging receptacle, the battery, the signal line, and the signal changing unit;
The signal changing unit changes a state of a signal flowing through the signal line immediately before or after the body frame moves,
The energization control unit shuts off or suppresses energization between the charging receptacle and the battery before the connection state between the energizing terminal of the charging plug and the energizing terminal of the receptacle is released according to the signal state of the signal line. A straddle-type electric vehicle.   The straddle-type electric vehicle according to claim 1, wherein the signal changing unit changes a state of a signal flowing through the signal line in accordance with a movement of the body frame.   The signal change unit changes the signal state according to the movement of a component that is supported by the body frame and that can move relative to the body frame and can contact the ground. The straddle-type electric vehicle described in 1. The signal changing unit is
An acceleration signal changing unit that changes a signal state according to the acceleration of the body frame;
A wheel speed signal changing unit that changes a signal state according to a rotation state of a wheel supported by the body frame;
A vehicle body inclination signal changing unit that changes a signal state according to the inclination of the vehicle body frame;
A side stand signal changing unit that changes the signal state according to the state of the side stand provided in the body frame;
A main stand signal changing unit that changes a signal state according to a state of a main stand provided in the vehicle body frame;
A handle lock signal changing unit that changes a signal state according to a lock state of a handle provided on the vehicle body frame;
A seat load signal changing unit that changes a signal state according to a load applied to a seat provided in the vehicle body frame;
The straddle-type electric vehicle according to claim 1, wherein the straddle-type electric vehicle is at least one of a parking brake signal changing unit that changes a signal state according to a state of a parking brake provided in the vehicle body frame. The signal changing unit is
An acceleration signal changing unit that changes a signal state according to the acceleration of the body frame;
A wheel speed signal changing unit that changes a signal state according to a rotation state of a wheel supported by the body frame;
The straddle-type electric vehicle according to claim 2, wherein the saddle type electric vehicle is at least one of a vehicle body inclination signal changing unit that changes a signal state according to the inclination of the vehicle body frame. The signal changing unit is
A side stand signal changing unit that changes the signal state according to the state of the side stand provided in the body frame;
A main stand signal changing unit that changes a signal state according to a state of a main stand provided in the vehicle body frame;
The straddle-type electric vehicle according to claim 3, wherein the straddle-type electric vehicle is at least one of a handle lock signal changing unit that changes a signal state according to a lock state of a handle provided on the vehicle body frame.   The straddle-type electric vehicle according to any one of claims 1 to 6, wherein the signal line is a communication line that connects a control unit of a charger that supplies power to the battery and the control unit.   The charging receptacle is formed such that the dimension in the first direction perpendicular to the insertion / extraction direction of the charging plug is larger than the dimension in the insertion / extraction direction and the second direction perpendicular to the first direction, and a plurality of terminals are provided. The straddle-type electric vehicle according to any one of claims 1 to 7, wherein the straddle-type electric vehicle is arranged in a row in the first direction.

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