Electric Motorcycle, Vehicle Controller and Vehicle Control Method
An electric motorcycle includes a driving command detecting device, a state value detecting device, an electric motor driving a drive wheel, a control unit for executing a non-normal mode causing output of the electric motor in a non-normal mode to differ from the output of the electric motor in a normal mode, the control unit configured to shift the electric motorcycle from one of the normal or non-normal modes to the other normal or non-normal mode, when the state value satisfies a predetermined shift condition, in one of the normal and non-normal modes, and a cornering determiner unit for determining cornering status, wherein the control unit causes a change in the output of the electric motor to be less, when the electric motorcycle is cornering and the shift condition is satisfied than when the cornering determiner unit determines the electric motorcycle is not cornering and the shift condition is satisfied.
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The present invention relates to an electric motorcycle, a vehicle controller and a vehicle control method, in which a driving mode shifts based on a state value of the electric motorcycle or a vehicle.
BACKGROUND ARTIn an electric vehicle which generates driving power by actuating a motor using electric power supplied from a battery, a motor output is changed based on information different from a driving command, in some cases. For example, there is a technique which shifts the electric vehicle to an output limiting mode for limiting a motor output for a specified time to prevent a temperature of a motor and a temperature of an inverter from rising to excess, when these temperatures exceed their allowable ranges, a technique which shifts the electric vehicle to an output limiting mode for limiting a motor output by limiting a battery output for a specified time to protect the battery, when a temperature of the battery exceeds an allowable range or when a voltage or the like of the battery falls below an allowable range, or the like (e.g., see Patent Literature 1). After the electric vehicle shifts to the output limiting mode, it is controlled so as to return from the output limiting mode to a normal mode, when a state value such as the motor temperature, the inverter temperature, the battery temperature, or the battery voltage is restored to fall within its allowable range.
CITATION LIST Patent LiteraturePatent Literature 1: Japanese-Laid Open Patent Application Publication No. Hei 9-191582
SUMMARY OF INVENTION Technical ProblemHowever, when the state value falls outside of a predetermined range in the middle of cornering, and as a result, the electric vehicle automatically shifts from the normal mode to another output mode, driving power changes in the middle of the cornering, during which the driver is more likely to feel nervous, which may make the driver's driving feeling worse. Especially in the case of a motorcycle, its vehicle body is banked during the cornering, and therefore the change in the driving power significantly affects the driving feeling.
Accordingly, an object of the present invention is to improve driving feeling during cornering in a vehicle in which a driving mode shifts based on a state value different from a driving command.
Solution To ProblemThe present invention has been made in view of the above mentioned circumstances, and an electric motorcycle of the present invention comprises: a driving command detecting device for detecting a driving command input by a driver; a state value detecting device for detecting a state value different from the driving command; an electric motor for generating driving power transmitted to a drive wheel; a control unit capable of executing a normal mode for controlling an output of the electric motor in response to the driving command detected by the driving command detecting device and a non-normal mode for causing the output of the electric motor in the non-normal mode to be different from the output of the electric motor in the normal mode, the control unit being configured to shift the electric motorcycle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the state value detected by the state value detecting device satisfies a predetermined shift condition, in the one of the normal mode and the non-normal mode; and a cornering determiner unit for determining whether or not the electric motorcycle is cornering; wherein the control unit causes a change in the output of the electric motor to be less, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied than when the cornering determiner unit determines that the electric motorcycle is not cornering and the shift condition is satisfied.
In accordance with this configuration, when it is determined that the electric motorcycle is cornering and the shift condition is satisfied, the electric motor is controlled such that a change in the output is suppressed. This makes it possible to suppress a great change in driving power during the cornering. Therefore, in the electric motorcycle which shifts the driving mode based on the state value different from the driving command, driving feeling during the cornering can be improved. The phrase “a change in the motor output is caused to be less (suppressed)” means that a change in the motor output due to the mode shift is prevented by inhibiting the mode shift, and the mode shift is performed while keeping a state in which a change in the motor output due to the mode shift is lessened, than when the electric motorcycle is not cornering.
The control unit may inhibit the electric motorcycle from shifting from the one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied.
In accordance with this configuration, when it is determined that the electric motorcycle is cornering and the shift condition is satisfied, the mode shift is inhibited. This makes it possible to prevent a change in the output of the electric motor due to the mode shift. Therefore, driving feeling during the cornering can be improved easily and surely.
The control unit may control the output of the electric motor such that at least one of a change amount of the output of the electric motor and a change rate of the output of the electric motor which occurs with time in a case where the electric motorcycle shifts from the one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, is made less, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied than when the cornering determiner unit determines that the electric motorcycle is not cornering and the shift condition is satisfied.
In accordance with this configuration, when it is determined that the electric motorcycle is cornering and the shift condition is satisfied, at least one of the change amount and the change rate of the output of the electric motor, which occur at the time of the mode shift, is reduced. This makes it possible to suppress a change in the output of the electric motor due to the mode shift, during execution of the mode shift. As a result, it becomes possible to achieve advantages provided by the control for the mode shift and improve driving feeling during the cornering.
The electric motorcycle may further comprise a battery for supplying electric power to the electric motor; and an inverter interposed between the electric motor and the battery; wherein the state value detecting device may detect as the state value a state of at least one of driving system electric devices including the electric motor, the battery and the inverter; wherein the shift condition may include a non-normal mode shift condition for shifting the electric motorcycle from the normal mode to the non-normal mode, in which the state value is a predetermined non-normal value, and a normal mode shift condition for shifting the electric motorcycle from the non-normal mode to the normal mode, in which the state value is a predetermined normal value; and wherein the control unit may cause the output of the electric motorcycle in the non-normal mode to be less than the output of the electric motorcycle in the normal mode.
In accordance with this configuration, when the driving system electric device is placed in a non-normal state, in the normal mode, the electric motorcycle shifts to the non-normal mode for reducing the output of the electric motor. Thus, the driving system electric device can be protected.
The electric motorcycle may further comprise a battery for supplying electric power to the electric motor; and an inverter interposed between the electric motor and the battery; wherein the state value detecting device may include at least one of a temperature sensor for detecting as the state value a temperature of at least one of the battery, the inverter and the electric motor, a battery sensor for detecting a discharge ability of the battery as the state value, a rotational speed sensor for detecting a rotational speed of the electric motor as the state value, a vehicle speed sensor for detecting a vehicle speed as the state value, and an abnormality detecting device for detecting as the state value an abnormality of a sensor for detecting input information used to control the electric motor; wherein the shift condition may include an output limiting mode shift condition which is at least one of a condition in which the temperature detected by the temperature sensor exceeds a predetermined allowable value, a condition in which the discharge ability detected by the battery sensor is less than a predetermined allowable value, a condition in which the rotational speed detected by the rotational speed sensor is equal to or greater than a predetermined upper limit rotational speed, a condition in which the vehicle speed detected by the vehicle speed sensor is equal to or greater than a predetermined upper limit speed, and a condition in which the abnormality is detected by the abnormality detecting device; wherein the non-normal mode may include an output limiting mode for causing the output of the electric motor in the output limiting mode to be less than the output of the electric motor in the normal mode; and wherein the control unit may shift the electric motorcycle to the output limiting mode when the output limiting mode shift condition is satisfied, in the normal mode.
In accordance with this configuration, since the output of the electric motor is decreased in the output limiting mode, for example, the electric motor, the battery and/or the inverter are protected, or a driving speed is decreased or the rotational speed or the vehicle speed is limited, when the discharge ability of the battery is lowered, or the abnormality has occurred in the sensor.
The control unit may control the output of the electric motor such that a target value of the output of the electric motor gets gradually closer to a target value after the mode shift, when the cornering determiner unit determines that cornering has finished with the shift condition satisfied, from a state in which a change in the output of the electric motor is suppressed since the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied.
In accordance with this configuration, when the cornering finishes in a state in which a change in the motor output is suppressed during the cornering, a target value of the motor output is made to get gradually closer to a target value after the mode shift. Therefore, the mode shift can be completed while keeping a good driving feeling.
The shift condition may include a predetermined output rapid-increase mode shift condition; wherein the non-normal mode may include an output rapid-increase mode for causing the output of the electric motor in the output rapid-increase mode to be greater than the output of the electric motor in the normal mode for a specified time, when an increase rate of an accelerator displacement amount detected by the driving command detecting device is equal to or greater than a predetermined threshold; and wherein the control unit may shift the electric motorcycle to the output rapid-increase mode, when the output rapid-increase mode shift condition is satisfied in the normal mode.
In accordance with this configuration, the motor output is made greater for a specified time, when the accelerator displacement amount is rapidly increased in the output rapid-increase mode, than when the accelerator displacement amount is rapidly increased in the normal mode. This causes a greater acceleration than that in the normal mode for a moment. In this way, an acceleration response felt by the driver is improved.
The electric motorcycle may further comprise a cornering state determiner unit for determining whether or not a driving state is a final phase of cornering; wherein when the cornering state determiner unit determines that the driving state is the final phase of the cornering, in a state in which the cornering determiner unit determines that the electric motorcycle is cornering and the output rapid-increase mode shift condition is satisfied, the control unit does not suppress a change in the output of the electric motor.
In accordance with this configuration, when the electric motorcycle has reached the final phase of the cornering, an increase in the output of the electric motor is not suppressed, and a great acceleration is allowed. Therefore, accelerated driving is enabled to smoothly occur at the end of the cornering.
The electric motorcycle may further comprise a notification device for performing notification to the driver; wherein the control unit may cause the notification device to notify the driver that a change in the output of the electric motor is suppressed, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied.
In accordance with this configuration, the driver is notified that a change in the output of the electric motor is suppressed. In this way, the driver can know a controlled state of the electric motorcycle.
The control unit may vary a degree to which the change in the output of the electric motor is suppressed, according to a driving state during the cornering.
In accordance with this configuration, since the degree to which the change in the output of the electric motor is suppressed is varied according to a driving state during the cornering, it becomes possible to achieve advantages provided by the control for the mode shift and improve driving feeling during the cornering.
A vehicle controller of the present invention comprises a driving command reception section for receiving a driving command input by a driver; a state value reception section for receiving a state value different from the driving command; a normal mode executing section for controlling an output of a driving source in response to the driving command; a non-normal mode executing section for causing the output of the driving source in a non-normal mode to be different from the output of the driving source in a normal mode; a mode shift control section for shifting a vehicle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the state value received by the state value reception section satisfies a predetermined shift condition, in the one of the normal mode and the non-normal mode; and a cornering determiner section for determining whether or not the vehicle is cornering; wherein the mode shift control section causes a change in the output of the driving source to be less, when the cornering determiner section determines that the vehicle is cornering and the shift condition is satisfied than when the cornering determiner section determines that the vehicle is not cornering and the shift condition is satisfied.
A vehicle control method of the present invention comprises the steps of: receiving a driving command input by a driver; receiving a state value different from the driving command; controlling an output of a driving source in response to the driving command in a normal mode; causing the output of the driving source in a non-normal mode to be different from the output of the driving source in the normal mode; shifting a vehicle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the state value satisfies a predetermined shift condition, in the one of the normal mode and the non-normal mode; and determining whether or not the vehicle is cornering; wherein in the step of shifting the vehicle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, a change in the output of the driving source is caused to be less, when it is determined that the vehicle is cornering and the shift condition is satisfied than when it is determined that the vehicle is not cornering and the shift condition is satisfied.
Advantageous Effects Of InventionAs should be appreciated from the above, in accordance with the present invention, driving feeling during cornering can be improved in a vehicle in which a driving mode shifts based on a state value different from a driving command.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
A vehicle body frame of the electric motorcycle 1 includes a pair of main frames 9 extending in a substantially linear shape in a side view such that they extend rightward and leftward from the head pipe 5 in a rearward direction and are inclined in a slightly downward direction. A pair of right and left down frames 10 are coupled to front end portions of the main frames 9 such that the down frames 10 extend downward from the front end portions, respectively. Upper portions of a pivot frame 11 of a frame shape are provided at rear end portions of the main frames 9, respectively. A rear portion of a case 13 of a power plant 12 is fastened to the pivot frame 11. A front portion of the case 13 is fastened to lower end portions of the down frames 10. A front end portion of a swing arm 14 supporting the rear wheel 3 is mounted to the pivot frame 11 such that the swing arm 14 is vertically pivotable around the front end portion. A rear suspension 15 is interposed between an intermediate portion of the swing arm 14 and a rear end portion of the main frame 9. As indicated by a virtual line of
The case 13 of the power plant 12 accommodates an electric motor 18 for generating driving power, a transmission 19 for changing a speed of rotational power from the electric motor 18 and transmitting the resulting rotational power to the rear wheel 3, and a clutch 20 for permitting or inhibiting transmission of the driving power between the electric motor 18 and the transmission 19. A battery 21 is disposed above a front side of the case 13 of the power plant 12 to supply electric power to the electric motor 18. An inverter 22 is disposed above a rear side of the case 13 of the power plant 12 to convert DC power of the battery 21 into AC power and supply the AC power to the electric motor 18, or convert the AC power (regenerative electric power) generated by the electric motor 18 operative as a generator into the DC power to charge the battery 21 with the DC power. An ECU 23 (vehicle controller) as will be described in detail later is disposed between the pair of right and left main frames 9. In the present embodiment, the electric motor 18, the battery 21 and the inverter 22 will be referred to as driving system electric devices.
As the vehicle speed sensor 36, for example, a front wheel speed sensor for detecting a rotational speed of the front wheel 2 which is the driven wheel, is used. An accelerator displacement amount sensor 37 detects a displacement amount (opening degree) of the accelerator grip 7. A brake sensor 38 detects a displacement amount (braking amount) of the brake lever 8. A clutch switch 39 detects whether a clutch 20 is engaged or disengaged. A gear position sensor 40 detects a transmission gear position (reduction gear ratio) of the transmission 19. A bank angle sensor 41 detects a vehicle body bank angle formed when a vehicle body of the electric motorcycle 1 is banked laterally from its upright state.
The ECU 23 includes a sensor abnormality detecting section 45, a state value reception section 46, a shift condition determiner section 47, a driving command reception section 48, a cornering determiner section 49, a mode shift control section 50, a normal mode executing section 51, an output limiting mode executing section 52, a regenerative mode executing section 53, and an output rapid-increase mode executing section 54. The sensor abnormality detecting section 45 detects an abnormality in any of the sensors 30 to 41 for detecting input information used to control the electric motor 18. For example, the sensors 30 to 41 are provided in pairs. If values detected by each pair of sensors, among the sensors 30 to 41, are equal, the sensor abnormality detecting section 45 detects that these sensors are working normally, whereas if the detected values are different from each other, the sensor abnormality detecting section 45 detects that an abnormality has occurred in the sensor(s).
The state value reception section 46 receives a signal from the motor temperature sensor 30, the inverter temperature sensor 31, the battery temperature sensor 32, the battery voltage sensor 33, the SOC sensor 34, the rotational speed sensor 35, the vehicle speed sensor 36, the sensor abnormality detecting section 45, and other sensors, i.e., state value different from the driving command. That is, in the present embodiment, the motor temperature sensor 30, the inverter temperature sensor 31, the battery temperature sensor 32, the battery voltage sensor 33, the SOC sensor 34, the rotational speed sensor 35, the vehicle speed sensor 36, and the sensor abnormality detecting section 45, constitute a state value detecting device. The state value refers to a value relating to a state of a device built into the electric motorcycle 1, which is variable irrespective of the driving command input by the driver. The driving command refers to a command input by the driver to change the driving state of the electric motorcycle 1, such as a command of the accelerator displacement amount, a command of the brake displacement amount, a command for engaging/disengaging the clutch, a command of a transmission gear position, etc.
As will be described later, the shift condition determiner section 47 determines whether or not the state value received by the state value reception section 46 satisfies a predetermined shift condition used to execute a mode shift between a normal mode and a non-normal mode (output limiting mode, regenerative mode, output rapid-increase mode) different from the normal mode. The driving command reception section 48 receives the signal from the accelerator displacement amount sensor 37, the brake sensor 38, the clutch switch 39, the gear position sensor 40, and other sensors, i.e., the driving command input by the driver. That is, in the present embodiment, at least one of the accelerator displacement amount sensor 37, the brake sensor 38, the clutch switch 39, and the gear position sensor 40 constitutes a driving command detecting device. The cornering determiner section 49 determines whether or not the electric motorcycle 1 is cornering (in the middle of cornering). For example, when the bank angle of the vehicle body, from the upright state, which is detected by the bank angle sensor 41, is equal to or greater than a predetermined angle, the cornering determiner section 49 determines that the electric motorcycle 1 is cornering.
The mode shift control section 50 controls the mode shift among the driving modes (normal mode, output limiting mode, regenerative mode, output rapid-increase mode) based on a result of a determination performed by the shift condition determiner section 47 and a result of a determination performed by the cornering determiner section 49. The electric motorcycle 1 includes a notification device 55 for notifying the driver of information by the blinking of a lamp or the like, by emitting a sound using a speaker, etc. If the mode shift is inhibited even in a state in which the shift condition is satisfied as will be described later, the mode shift control section 50 causes the notification device 55 to notify the driver that the mode shift is inhibited. Or, the mode shift control section 50 is able to change control of the motor output in the middle of the mode shift, based on the signal from any of the rotational speed sensor 35, the vehicle speed sensor 36, and the gear position sensor 40.
The normal mode executing section 51 executes the normal mode for controlling the output (to be precise, torque) of the electric motor 18 in response to the driving command received by the driving command reception section 48. The output limiting mode executing section 52 executes the output limiting mode in which the output of the electric motor 18 is made less than the output of the electric motor 18 in the normal mode, to protect the electric motor 18, the inverter 22, the battery 21, etc. The regenerative mode executing section 53 executes the regenerative mode to generate regenerative electric power by using the electric motor 18 as the generator. The output rapid-increase mode executing section 54 executes the output rapid-increase mode to compensate the motor output corresponding to the accelerator displacement amount such that it is greater than the motor output in the normal mode for a specified time, when rapid acceleration is commanded, that is, an increase rate of the accelerator displacement amount detected by the accelerator displacement amount sensor 37 is equal to or greater than a predetermined value.
Then, the shift condition determiner section 47 determines whether or not the output limiting mode shift condition is satisfied (step S2). The output limiting mode shift condition includes a condition in which a state of the driving system electric device including the electric motor 18, the battery 21 and the inverter 22 has become a predetermined non-normal state different from the normal state, i.e., the state value received by the state value reception section 46 has become a predetermined non-normal value. More specifically, the output limiting mode shift condition includes a condition in which the temperature of the electric motor 18, the temperature of the battery 21 or the temperature of inverter 22 which is detected by any one of the temperature sensors 30 to 32, exceeds a predetermined allowable value, a condition in which the voltage detected by the battery voltage sensor 33 falls below a predetermined allowable value, a condition in which the SOC detected by the SOC sensor 34 falls below a predetermined allowable value, a condition in which the rotational speed detected by the rotational speed sensor 35 is equal to or higher than a predetermined upper limit rotational speed, a condition in which the vehicle speed detected by the vehicle speed sensor 36 is equal to or higher than a predetermined upper limit speed, and/or a condition in which an abnormality has been detected by the sensor abnormality detecting section 45.
When the shift condition determiner section 47 determines that the output limiting mode shift condition is not satisfied in step S2, the process moves to step S8. When the shift condition determiner section 47 determines that the output limiting mode shift condition is satisfied in step S2, the mode shift control section 50 determines whether or not the cornering determiner section 49 is determining that the electric motorcycle 1 is cornering (step S3). When the cornering determiner section 49 determines that the electric motorcycle 1 is not cornering (step S3: N), the electric motorcycle 1 automatically shifts to the output limiting mode such that a target value of the motor output gets gradually closer to a target value in the output limiting mode (step S4).
On the other hand, when the cornering determiner section 49 determines that the electric motorcycle 1 is cornering (step S3: Y), in the state in which the output limiting mode shift condition is satisfied (step S2: Y), the mode shift control section 50 inhibits the electric motorcycle 1 from shifting to the output limiting mode (step S5). As shown in
Then, when the cornering determiner section 49 determines that the cornering of the electric motorcycle 1 has finished (step S3: N), in the state in which the output limiting mode shift condition is satisfied (step S2: Y), the electric motorcycle 1 automatically shifts to the output limiting mode such that the target value of the motor output gets gradually closer to the target value in the output limiting mode (step S4). Since the target value of the motor output is made to get gradually closer to the target value after the mode shift, during execution of the mode shift, the mode shift can be completed while keeping a good driving feeling.
As shown in
As shown in
When the shift condition determiner section 47 determines that the regenerative mode shift condition is not satisfied in step S7, the process moves to step S12. When the shift condition determiner section 47 determines that the regenerative mode shift condition is satisfied in step S7, the mode shift control section 50 determines whether or not the cornering determiner section 49 is determining that the electric motorcycle 1 is cornering (step S8). When the cornering determiner section 49 determines that the electric motorcycle 1 is cornering in step S8, the mode shift control section 50 inhibits the electric motorcycle 1 from shifting to the regenerative mode (step S10). As a result, even when the regenerative mode shift condition is satisfied, the electric motor 18 does not shift to a power generation state but maintains an actuated state. This makes it possible to prevent a situation in which the electric motorcycle 1 shifts to the regenerative mode during the cornering, negative torque is generated in the electric motor 18 due to generation of electric power, and as a result, the motor output changes greatly. Concurrently with this, the mode shift control section 50 causes the notification device 55 to notify the driver that the mode shift is inhibited (step S11), and the process returns to step S7.
Then, when the cornering determiner section 49 determines that the cornering of the electric motorcycle 1 has finished (step S8: N), in the state in which the regenerative mode shift condition is satisfied (step S7: Y), the electric motorcycle 1 automatically shifts to the regenerative mode (step S9). As shown in
Then, the shift condition determiner section 47 determines whether or not the regenerative mode shift condition is satisfied (step S32). When the shift condition determiner section 47 determines that the regenerative mode shift condition is still satisfied, the process returns to step S31. When the shift condition determiner section 47 determines that the regenerative mode shift condition is not satisfied in step S32, the mode shift control section 50 determines whether or not the cornering determiner section 49 is determining that the electric motorcycle 1 is cornering (step S33). When the cornering determiner section 49 determines that the electric motorcycle 1 is cornering in step S33, the mode shift control section 50 inhibits the electric motorcycle 1 from returning (shifting) to the normal mode (step S34). Concurrently with this, the mode shift control section 50 causes the notification device 55 to notify the driver that the electric motorcycle 1 is inhibited from returning to the normal mode (step S35), and the process returns to step S32. Then, when the cornering determiner section 49 determines that the cornering of the electric motorcycle 1 has finished (step S33: N), in the state in which the regenerative mode shift condition is not satisfied (step S32: N), the mode shift control section 50 deactivates the regenerative mode, returns the electric motor 18 from the power generation state to the actuated state (step S36), and shifts the electric motorcycle 1 to the normal mode (step S1).
As shown in
When the shift condition determiner section 47 determines that the output rapid-increase mode shift condition is not satisfied in step S12, the process returns to step S2. When the shift condition determiner section 47 determines that the output rapid-increase mode shift condition is satisfied in step S12, the mode shift control section 50 determines whether or not the cornering determiner section 49 is determining that the electric motorcycle 1 is cornering (step S 13). When the cornering determiner section 49 determines that the electric motorcycle 1 is cornering in step S13, the mode shift control section 50 further determines whether or not the cornering determiner section 49 is determining that the electric motorcycle 1 has reached a final phase of the cornering (step S14). Specifically, the cornering determiner section 49 also acts as a corner end determiner section for determining whether or not the electric motorcycle 1 has reached a final phase of the cornering, i.e., the electric motor 1 is about to reach the end of the corner. For example, when an increase rate of the bank angle detected by the bank angle sensor 41 changes from a positive value to a negative value, and/or the accelerator displacement amount increases during the cornering, the cornering determiner section 49 determines that the electric motorcycle 1 has reached the final phase of the cornering.
When the cornering determiner section 49 determines that the electric motorcycle 1 has not reached the final phase of the cornering in step S16, the mode shift control section 50 inhibits the electric motorcycle 1 from shifting to the output rapid-increase mode (step S15). Therefore, as shown in
As shown in
Then, the shift condition determiner section 47 determines whether or not the output rapid-increase mode shift condition is satisfied (step S42). When the shift condition determiner section 47 determines that the output rapid-increase mode shift condition is still satisfied, the process returns to step S41. When the shift condition determiner section 47 determines that the output rapid-increase mode shift condition is not satisfied in step S42, the mode shift control section 50 determines whether or not the cornering determiner section 49 is determining that the electric motorcycle 1 is cornering (step S43). When the cornering determiner section 49 determines that the electric motorcycle 1 is cornering in step S43, the mode shift control section 50 inhibits the electric motorcycle 1 from returning (shifting) to the normal mode (step S44). Concurrently with this, the mode shift control section 50 causes the notification device 55 to notify the driver that the electric motorcycle 1 is inhibited from returning to the normal mode (step S45), and the process returns to step S42. Then, when the cornering determiner section 49 determines that the electric motorcycle 1 is not cornering (step S43: N), in the state in which the output rapid-increase mode shift condition is not satisfied (step S42: N), the mode shift control section 50 finishes rapidly increasing of the motor output (step S46), and shifts the electric motorcycle 1 to the normal mode (step S1).
As described above, in the present embodiment, during the cornering, by inhibiting the motor output from changing based on the information different from the driving command, the driving feeling during the cornering can be improved. Especially, in the motorcycle which is a vehicle performing cornering with the vehicle body banked by shifting the driver's weight, changing of the motor output based on the information different from the driving command is prevented, which significantly improves the driving feeling during the cornering. Specifically, even when it is determined that an abnormality has occurred in the electric device relating to driving of the vehicle, such as the electric motor, the battery or the inverter, during the cornering, the motor output is maintained until the cornering has finished, and occurrence of a change in the motor output is prevented during the cornering. Thus, a good driving feeling can be maintained during the cornering. In addition, after the cornering has finished, limiting of the motor output is executed to correspond to the abnormality occurring in the electric device. This makes it possible to protect the electric device, perform driving with the motor output suppressed as corresponding to the abnormality, etc., while lessening an influence on the driving feeling during limiting of the motor output. In the same manner, even when it is determined that the abnormal state of the electric device is obviated in the middle of the cornering, the output limiting mode is maintained until the cornering finishes to prevent a situation in which the motor output increases during the cornering. As a result, a good driving feeling can be maintained during the cornering.
It should be noted that limiting of the change in the motor output during the cornering is performed only based on the information different from the driving command. Therefore, even during the cornering, the output of the vehicle can be changed according to the driver's intention, and the driver can easily input the driving command, or the like, as desired. In addition, the change in the motor output due to starting/finishing of the regenerative operation and the change in the motor output due to starting/finishing of permitting the output to be rapidly increased are inhibited during the cornering, and thus, good driving feeling can be maintained as well. In exceptional cases, at the final phase of the cornering, the driving operation according to the driver's demand can be attained by permitting execution of an output rapid-increase permission mode in response to the driver's demand.
By suppressing the change in the motor output as in modified example 1 and in modified example 2, instead of inhibiting the change in the motor output, it become possible to achieve the advantages of the present invention that the driving feeling is prevented from getting worse. In the inventions of the modified examples, changing of the motor output is executed while mitigating the change in the motor output during the cornering. Thus, even during the cornering, the advantages provided by changing of the motor output can also be attained. For example, the electric device can be protected, kinetic energy can be converted into electric energy, etc., even though its changing magnitude or its change which occurs with time may be less during the cornering than during non-cornering.
As indicated by the one-dotted line B in
Although in the present embodiment, the cornering determiner section 49 determines whether or not the electric motorcycle 1 is cornering based on the information from the bank angle sensor 41, this may be performed by another method. For example, the cornering determiner section 49 may determine that the electric motorcycle 1 is cornering when a steering angle detected by a steering angle sensor is greater than a predetermined value, when a lateral acceleration detected by a lateral acceleration sensor is greater than a predetermined value, or a lateral vehicle body bank angle detected by a gyro sensor is greater.
Or, the cornering determiner section 49 may determine whether or not the electric motorcycle 1 is cornering based on a difference between a front wheel rotational speed and a rear wheel rotational speed. To be in more detail, in a case where a wheel width and a cross-sectional radius are different between the front wheel and the rear wheel, a speed difference between the front wheel and the rear wheel changes as the cornering of the vehicle body occurs. Therefore, the cornering determiner section 49 can determine whether or not the vehicle body is cornering based on a value relating to the speed difference between the front wheel and the rear wheel. For example, in the case where the rotational speed of the front wheel is greater than that of the rear wheel by a predetermined value or more, the cornering determiner section 49 may determine that the vehicle body is cornering.
Although in the present embodiment, the cornering determiner section 49 may determine that the electric motorcycle 1 is cornering when the bank angle of the vehicle body from the upright state is equal to or greater than the predetermined angle, the present invention is not limited to this. The cornering determiner section 49 may determine that the electric motorcycle 1 is cornering when the electric motorcycle 1 is slalom-driving in which the cornering occurs plural times in succession. In this case, when the cornering is the slalom-driving, the cornering determiner section 49 may determine that the cornering has finished when the slalom-driving has finished. For example, the cornering determiner section 49 may determine that the cornering has finished when specified time, for example, 1 second passes after the bank angle has become less than a predetermined value. This makes it possible to avoid misdetermination that the cornering has finished when the electric motorcycle 1 is placed in the upright state for a moment during the slalom-driving. Or, the cornering determiner section 49 may determine that the electric motorcycle 1 is slalom-driving in a case where time taken for the bank angle to change to a value less than a predetermined value is short. Or, the cornering determiner section 49 may determine whether or not the electric motorcycle 1 is slalom-driving, by another method. As a matter of course, a case where the slalom-driving is not included is within the scope of the present invention.
Although in the present invention, the change in the motor output during the cornering is suppressed in both the case where the motor output is reduced and the case where the motor output is increased, the present invention is not limited to this. The change in the motor output may be suppressed during the cornering in either one the case where the motor output is reduced and the case where the motor output is increased, which is also within the scope of the present invention. Although in the present embodiment, the change in the motor output is suppressed for the three output change modes, which are the output limiting mode, the regenerative mode, and the output rapid-increase mode, during the cornering, this need not be performed for all of the three output change modes, and may be performed for at least one of the three output change modes. Although in the present embodiment, the output limiting mode, the regenerative mode, and the output rapid-increase mode, occur in this order from starting of the control, these three modes may occur in a different order, which is also within the scope of the present invention. Furthermore, examples of the driving mode shift described in the present embodiment are merely exemplary. The present invention is applicable so long as the driving mode is varied based on the information different from the command input by the driver. That is, examples of mode shift to driving modes, which are other than those in the present embodiment, are also within the scope of the present invention. Examples of the driving mode shift may include driving mode shift associated with adjustment of regenerative force, limitation of the torque, limitation of the rotational speed, and limitation of the driving speed, according to the driving state.
Although in the example of
In the present embodiment, when the cornering finishes under the state the mode shift is inhibited because the electric motorcycle 1 is cornering, the motor output is made to get gradually closer to the target value after the mode shift. Alternatively, this may be performed quickly. Or, the output limiting mode may be deactivated according to the driver's intentions. For example, a switch for inputting a command for deactivating the output limiting mode may be provided, and the output limiting mode may be deactivated in response to the command input by the driver's operation of the switch. This can improve convenience. Or, setting for changing of limiting (suppressing) of the motor output, a threshold at which the electric motorcycle 1 enters the limiting mode, or the like, may be configured to be variable.
As a method of determining whether or not the electric motorcycle 1 has reached the final phase of the cornering, it may be determined that the electric motorcycle 1 has reached the final phase of the cornering, when the bank angle (steering angle) is reduced, a change in the bank angle (steering angle) is reduced, a change in the bank angle (steering angle) is reversed, gear change is performed, the clutch is operated, the accelerator is operated, etc., after it is determined that the electric motorcycle 1 is cornering. As the motor output to be controlled, a motor rotational speed may be used instead of the motor torque. Moreover, the present invention is not limited to the above described embodiment, and its configuration may be changed, added or deleted without departing from the spirit of the invention.
INDUSTRIAL APPLICABILITYAs described above, an electric motorcycle, a vehicle controller and a vehicle control method of the present invention have remarkable advantages that it is possible to improve the driving feeling during cornering in a vehicle in which a driving mode shifts based on a state value different from a driving command, and are effectively applicable to vehicles such as an electric motorcycle which can attain the advantages.
REFERENCE CHARACTERS LIST1 electric motorcycle (vehicle)
18 electric motor
21 battery
22 inverter
23 ECU (control device, vehicle controller)
30 temperature sensor (state value detecting device)
31 inerter temperature sensor (state value detecting device)
32 battery temperature sensor (state value detecting device)
33 battery voltage sensor (state value detecting device)
34 SOC sensor (state value detecting device)
35 rotational speed sensor (state value detecting device)
36 vehicle speed sensor (state value detecting device)
37 accelerator displacement amount sensor (driving command detecting device)
38 brake sensor (driving command detecting device)
39 clutch switch (driving command detecting device)
40 gear position sensor (driving command detecting device)
41 bank angle sensor
45 sensor abnormality detecting section (state value detecting device)
48 driving command reception section
46 state value reception section
49 cornering determiner section
50 mode shift control section
51 normal mode executing section
52 output limiting mode executing section (non-normal mode executing section)
53 regenerative mode executing section (non-normal mode executing section)
54 output rapid-increase mode executing section (non-normal mode executing section)
55 notification device
Claims
1. An electric motorcycle comprising:
- a driving command detecting device for detecting a driving command input by a driver;
- a state value detecting device for detecting a state value different from the driving command;
- an electric motor for generating driving power transmitted to a drive wheel;
- a control unit capable of executing a normal mode for controlling an output of the electric motor in response to the driving command detected by the driving command detecting device and a non-normal mode for causing the output of the electric motor in the non-normal mode to be different from the output of the electric motor in the normal mode, the control unit being configured to shift the electric motorcycle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the state value detected by the state value detecting device satisfies a predetermined shift condition, in the one of the normal mode and the non-normal mode; and
- a cornering determiner unit for determining whether or not the electric motorcycle is cornering;
- wherein the control unit causes a change in the output of the electric motor to be less, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied than when the cornering determiner unit determines that the electric motorcycle is not cornering and the shift condition is satisfied.
2. The electric motorcycle according to claim 1,
- wherein the control unit inhibits the electric motorcycle from shifting from the one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied.
3. The electric motorcycle according to claim 1,
- wherein the control unit controls the output of the electric motor such that at least one of a change amount of the output of the electric motor and a change rate of the output of the electric motor which occurs with time in a case where the electric motorcycle shifts from the one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, is made less, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied than when the cornering determiner unit determines that the electric motorcycle is not cornering and the shift condition is satisfied.
4. The electric motorcycle according to claim 1, further comprising:
- a battery for supplying electric power to the electric motor; and
- an inverter interposed between the electric motor and the battery;
- wherein the state value detecting device detects as the state value a state of at least one of driving system electric devices including the electric motor, the battery and the inverter;
- wherein the shift condition includes a non-normal mode shift condition for shifting the electric motorcycle from the normal mode to the non-normal mode, in which the state value is a predetermined non-normal value, and a normal mode shift condition for shifting the electric motorcycle from the non-normal mode to the normal mode, in which the state value is a predetermined normal value; and
- wherein the control unit causes the output of the electric motorcycle in the non-normal mode to be less than the output of the electric motorcycle in the normal mode.
5. The electric motorcycle according to claim 1, further comprising:
- a battery for supplying electric power to the electric motor; and
- an inverter interposed between the electric motor and the battery;
- wherein the state value detecting device includes at least one of a temperature sensor for detecting as the state value a temperature of at least one of the battery, the inverter and the electric motor, a battery sensor for detecting a discharge ability of the battery as the state value, a rotational speed sensor for detecting a rotational speed of the electric motor as the state value, a vehicle speed sensor for detecting a vehicle speed as the state value, and an abnormality detecting device for detecting as the state value an abnormality of a sensor for detecting input information used to control the electric motor;
- wherein the shift condition includes an output limiting mode shift condition which is at least one of a condition in which the temperature detected by the temperature sensor exceeds a predetermined allowable value, a condition in which the discharge ability detected by the battery sensor is less than a predetermined allowable value, a condition in which the rotational speed detected by the rotational speed sensor is equal to or greater than a predetermined upper limit rotational speed, a condition in which the vehicle speed detected by the vehicle speed sensor is equal to or greater than a predetermined upper limit speed, and a condition in which the abnormality is detected by the abnormality detecting device;
- wherein the non-normal mode includes an output limiting mode for causing the output of the electric motor in the output limiting mode to be less than the output of the electric motor in the normal mode; and
- wherein the control unit shifts the electric motorcycle to the output limiting mode when the output limiting mode shift condition is satisfied, in the normal mode.
6. The electric motorcycle according to claim 1,
- wherein the control unit controls the output of the electric motor such that a target value of the output of the electric motor gets gradually closer to a target value after the mode shift, when the cornering determiner unit determines that cornering has finished with the shift condition satisfied, from a state in which a change in the output of the electric motor is suppressed since the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied.
7. The electric motorcycle according to claim 1,
- wherein the shift condition includes a predetermined output rapid-increase mode shift condition;
- wherein the non-normal mode includes an output rapid-increase mode for causing the output of the electric motor in the output rapid-increase mode to be greater than the output of the electric motor in the normal mode for a specified time, when an increase rate of an accelerator displacement amount detected by the driving command detecting device is equal to or greater than a predetermined threshold; and
- wherein the control unit shifts the electric motorcycle to the output rapid-increase mode, when the output rapid-increase mode shift condition is satisfied in the normal mode.
8. The electric motorcycle according to claim 7, further comprising:
- a cornering state determiner unit for determining whether or not a driving state is a final phase of cornering;
- wherein when the cornering state determiner unit determines that the driving state is the final phase of the cornering, in a state in which the cornering determiner unit determines that the electric motorcycle is cornering and the output rapid-increase mode shift condition is satisfied, the control unit does not suppress a change in the output of the electric motor.
9. The electric motorcycle according to claim 1, further comprising:
- a notification device for performing notification to the driver;
- wherein the control unit causes the notification device to notify the driver that a change in the output of the electric motor is suppressed, when the cornering determiner unit determines that the electric motorcycle is cornering and the shift condition is satisfied.
10. The electric motorcycle according to claim 1,
- wherein the control unit varies a degree to which the change in the output of the electric motor is suppressed, according to a driving state during the cornering.
11. A vehicle controller comprising:
- a driving command reception section for receiving a driving command input by a driver;
- a state value reception section for receiving a state value different from the driving command;
- a normal mode executing section for controlling an output of a driving source in response to the driving command;
- a non-normal mode executing section for causing the output of the driving source in a non-normal mode to be different from the output of the driving source in a normal mode;
- a mode shift control section for shifting a vehicle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the state value received by the state value reception section satisfies a predetermined shift condition, in the one of the normal mode and the non-normal mode; and
- a cornering determiner section for determining whether or not the vehicle is cornering;
- wherein the mode shift control section causes a change in the output of the driving source to be less, when the cornering determiner section determines that the vehicle is cornering and the shift condition is satisfied than when the cornering determiner section determines that the vehicle is not cornering and the shift condition is satisfied.
12. A vehicle control method comprising the steps of:
- receiving a driving command input by a driver;
- receiving a state value different from the driving command;
- controlling an output of a driving source in response to the driving command in a normal mode;
- causing the output of the driving source in a non-normal mode to be different from the output of the driving source in the normal mode;
- shifting a vehicle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, when the state value satisfies a predetermined shift condition, in the one of the normal mode and the non-normal mode; and determining whether or not the vehicle is cornering;
- wherein in the step of shifting the vehicle from one of the normal mode and the non-normal mode to the other of the normal mode and the non-normal mode, a change in the output of the driving source is caused to be less, when it is determined that the vehicle is cornering and the shift condition is satisfied than when it is determined that the vehicle is not cornering and the shift condition is satisfied.
Type: Application
Filed: May 13, 2011
Publication Date: Feb 27, 2014
Applicant: KAWASAKI JUKOGYO KABUSHIKI KAISHA (Kobe-shi, Hyogo)
Inventor: Yoshimoto Matsuda (Kobe-shi)
Application Number: 14/117,364
International Classification: B60W 10/08 (20060101); B60W 10/10 (20060101);