WO2014057537A1 - 車輪制御装置、車両、車輪制御方法 - Google Patents
車輪制御装置、車両、車輪制御方法 Download PDFInfo
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- WO2014057537A1 WO2014057537A1 PCT/JP2012/076191 JP2012076191W WO2014057537A1 WO 2014057537 A1 WO2014057537 A1 WO 2014057537A1 JP 2012076191 W JP2012076191 W JP 2012076191W WO 2014057537 A1 WO2014057537 A1 WO 2014057537A1
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L15/00—Methods, circuits, or devices for controlling the traction-motor speed of electrically-propelled vehicles
- B60L15/20—Methods, circuits, or devices for controlling the traction-motor speed of electrically-propelled vehicles for control of the vehicle or its driving motor to achieve a desired performance, e.g. speed, torque, programmed variation of speed
- B60L15/2045—Methods, circuits, or devices for controlling the traction-motor speed of electrically-propelled vehicles for control of the vehicle or its driving motor to achieve a desired performance, e.g. speed, torque, programmed variation of speed for optimising the use of energy
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L15/00—Methods, circuits, or devices for controlling the traction-motor speed of electrically-propelled vehicles
- B60L15/20—Methods, circuits, or devices for controlling the traction-motor speed of electrically-propelled vehicles for control of the vehicle or its driving motor to achieve a desired performance, e.g. speed, torque, programmed variation of speed
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2220/00—Electrical machine types; Structures or applications thereof
- B60L2220/40—Electrical machine applications
- B60L2220/42—Electrical machine applications with use of more than one motor
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2220/00—Electrical machine types; Structures or applications thereof
- B60L2220/40—Electrical machine applications
- B60L2220/44—Wheel Hub motors, i.e. integrated in the wheel hub
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2220/00—Electrical machine types; Structures or applications thereof
- B60L2220/40—Electrical machine applications
- B60L2220/46—Wheel motors, i.e. motor connected to only one wheel
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2240/00—Control parameters of input or output; Target parameters
- B60L2240/40—Drive Train control parameters
- B60L2240/42—Drive Train control parameters related to electric machines
- B60L2240/423—Torque
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2240/00—Control parameters of input or output; Target parameters
- B60L2240/60—Navigation input
- B60L2240/64—Road conditions
- B60L2240/645—Type of road
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2240/00—Control parameters of input or output; Target parameters
- B60L2240/60—Navigation input
- B60L2240/64—Road conditions
- B60L2240/647—Surface situation of road, e.g. type of paving
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2260/00—Operating Modes
- B60L2260/20—Drive modes; Transition between modes
- B60L2260/28—Four wheel or all wheel drive
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60L—PROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
- B60L2270/00—Problem solutions or means not otherwise provided for
- B60L2270/10—Emission reduction
- B60L2270/14—Emission reduction of noise
- B60L2270/145—Structure borne vibrations
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/64—Electric machine technologies in electromobility
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/72—Electric energy management in electromobility
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T90/00—Enabling technologies or technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02T90/10—Technologies relating to charging of electric vehicles
- Y02T90/16—Information or communication technologies improving the operation of electric vehicles
Definitions
- the present invention relates to a technique for controlling wheels provided in a vehicle.
- Patent Document 1 discloses feedback control that suppresses vibrations by adjusting a driving torque of a motor in a vehicle in which a motor (in-wheel motor) for driving the wheel is incorporated in a wheel. According to this feedback control, there is a possibility that the driving force of the motor is accurately controlled by making the current value of the motor follow the target current value.
- the present invention has been made in view of the above points, and one of the purposes thereof is a vehicle in which a motor for driving the wheel is incorporated in the wheel, in a predetermined high frequency band to the wheel. It is to provide an effective technique for appropriately controlling a motor with respect to road surface input.
- a wheel control device is a device that controls a plurality of wheels provided in a vehicle, and includes at least a control unit.
- This control unit fulfills the function of feedback-controlling the motor so that the driving torque of the motor provided on each wheel follows the target torque in order to drive each of the plurality of wheels.
- the control unit determines a feedback amount (also referred to as “feedback gain”) related to feedback control for a motor that drives a target wheel that has received a predetermined road surface input among a plurality of wheels before the target wheel receives a road surface input.
- the function to reduce more. In this case, as the predetermined road surface input, a disturbance in a high frequency band typically exceeding 10 Hz may be mentioned.
- the reduction of the feedback amount widely includes a mode in which the feedback amount is relatively low. Thereby, the effect of feedback control is suppressed. As a result, the electrical rigidity is reduced, so that the vibration transmission to the stator side member (for example, the motor housing) of the motor can be suppressed, thereby suppressing the vibration of the vehicle due to the kickback.
- the wheel control device preferably includes an information detection unit capable of detecting variation information when each of the plurality of wheels receives road surface input.
- typical examples of the variation information include unsprung acceleration acting on the unsprung region of the vehicle and rotation variation of the motor.
- the control unit identifies the target wheel from the variation information detected by the information detection unit, and when the target wheel receives road input, the feedback amount related to feedback control is reduced compared to before the target wheel receives road input. It is preferable to do this. Thereby, based on the fluctuation
- the information detection unit preferably includes an acceleration sensor provided on each of the plurality of wheels in order to detect unsprung acceleration acting on the unsprung region of the vehicle.
- a control part determines with the wheel from which the unsprung acceleration exceeding the threshold preset by the acceleration sensor was detected being a target wheel.
- the information detection unit includes a motor rotation sensor for detecting a rotation fluctuation of the motor.
- a control part determines with the wheel corresponding to the motor from which the rotation fluctuation
- the control unit reduces the feedback amount from the first gain to the first gain in order to reduce the feedback amount related to the feedback control from before the target wheel receives the road surface input. It is preferable to change to a lower second gain. Thereby, the feedback amount of the motor of the target wheel can be reduced from the first gain to the second gain.
- the proportional gain constituting the second gain is zero.
- the effect of reducing the feedback amount can be enhanced by setting the proportional gain, which has a great influence at the time of change, to zero among the feedback amount.
- the second gain is zero. Therefore, the feedback amount of the motor of the object wheel can be reduced by setting the second gain to zero.
- the control unit changes the feedback amount related to the feedback control from the first gain to the second gain, and then again from the second gain to the first gain after a predetermined time has elapsed. It is preferable to return to.
- the predetermined time relating to the reduction of the feedback amount is typically a short time (for example, 0.1%) that does not affect the vehicle motion (vehicle longitudinal acceleration, lateral acceleration, yaw rate, etc.). To 0.3 [s]). Thereby, it is possible to prevent the driving force of the wheels from fluctuating due to the reduction of the feedback amount and affecting the vehicle motion while suppressing the vibration of the vehicle due to the kickback.
- the control unit changes the feedback amount from the first gain to the second gain in the time required to return the feedback amount from the second gain to the first gain. It is preferable to perform motor control so as to exceed the time required for. That is, when the feedback amount of the feedback control is returned to the feedback amount before the reduction, this returning operation is executed gently. Thereby, while the effect of reducing the feedback amount can be obtained quickly, the generation of abnormal noise and vibration when the feedback amount is returned to before reduction can be suppressed.
- the control unit reduces the feedback amount of the predetermined high frequency band to the amplitude of the road surface input in order to reduce the feedback amount related to the feedback control than before the target wheel receives the road surface input. It is preferable to reduce it according to.
- the control unit reduces the feedback amount of the predetermined high frequency band to the amplitude of the road surface input in order to reduce the feedback amount related to the feedback control than before the target wheel receives the road surface input. It is preferable to reduce it according to.
- the control unit allocates the torque error (deviation) caused by the reduction of the feedback amount to the target torque of another motor other than the motor related to the reduction, and the target torque after the allocation. Accordingly, it is preferable to feedback-control another motor. That is, a predetermined motor torque error is compensated by another motor. For example, when the torque decreases due to a reduction in the feedback amount, this torque decrease can be added to the target torque of another motor, and when the torque increases due to a decrease in the feedback amount, this torque increase is It can be subtracted from the target torque.
- the drive torque error is an error related to torque accuracy (torque error ⁇ T) caused by reducing the feedback amount. Thereby, it can suppress that a change arises in a vehicle motion, and the discomfort given to a vehicle occupant can be reduced.
- the control unit performs the motor control so that the time required for allocating the torque error with respect to the target torque of another motor exceeds the time required for reducing the feedback amount.
- the reduction effect of the feedback amount can be quickly obtained in the motor of the target wheel, while the generation of abnormal noise and vibration caused by the sudden distribution of the torque error in another motor other than the motor of the target wheel. Can be suppressed.
- the torque error allocated to another motor is a predetermined low frequency component of the drive torque generated by the reduction of the feedback amount.
- the reduction effect of the feedback amount can be quickly obtained in the motor of the target wheel, while the generation of abnormal noise and vibration caused by the sudden distribution of the torque error in another motor other than the motor of the target wheel. Can be suppressed.
- the control unit before the control unit reduces the feedback amount related to the feedback control, the difference between the target torque and the torque zero region where the sign of the motor driving torque is reversed is large. It is preferable to offset so that Thereby, in the subsequent feedback amount reduction process, the control of the target wheel motor is performed following the target torque. Therefore, even when the actual driving torque varies due to the feedback amount reduction process, the possibility that the driving torque will be reversed (zero crossing) is reduced. As a result, in a wheel in which a speed reducer is interposed between the wheel and the motor, it is possible to suppress rattling noise and vibration from being generated in the speed reducer.
- the control unit allocates the torque change caused by the offset of the target torque to the target torque of another motor other than the motor related to the offset, and the different motor according to the allocated target torque.
- a predetermined motor torque change is supplemented by another motor.
- the target torque of a predetermined motor is offset in the upward direction (in the case of offset to the plus side)
- the torque change related to this offset can be subtracted from the target torque of another motor.
- the target torque is offset in the decreasing direction (in the case of offset to the minus side)
- the torque change related to this offset can be added to the target torque of another motor.
- the control unit holds the offset time from the time when the front wheel of the plurality of wheels passes through the traveling road surface according to the road surface input until the rear wheel passes. It is preferable to set to. Accordingly, it is possible to prevent excessive drive torque from being used (excess energy is consumed) by suppressing the time during which the offset state is maintained.
- the control unit In the wheel control device according to the present invention, the control unit generates a torque in the driving direction on one of the front wheel and the rear wheel among the plurality of wheels due to the offset, and is opposite to the driving direction on the other of the front wheel and the rear wheel.
- this equilibrium state is preferably maintained for a certain period of time.
- the control unit performs the motor control so that the time required for allocating the torque change for the target torque of another motor exceeds the time required for the offset. Therefore, it is possible to suppress the noise and vibration caused by the torque redistribution process being abruptly performed while reducing the noise and vibration due to the zero cross in the target wheel related to the road surface input.
- the control unit forms a control state in which another motor is feedback-controlled according to the target torque after allocation of the torque change after the offset from the initial state, and further returns to the initial state.
- the motor control is preferably performed so that the time required for shifting from the initial state to the control state exceeds the time required for shifting from the control state to the initial state.
- the vehicle according to the present invention includes a plurality of wheels, a motor provided on each wheel to drive each of the plurality of wheels, and a control device that controls the motor.
- the control device is constituted by the wheel control device.
- the wheel control method is a method for feedback-controlling a motor provided on each wheel to drive each of the plurality of wheels so that the driving torque of the motor follows the target torque. .
- a feedback amount related to feedback control is reduced for a motor that drives a target wheel that has received a road surface input among a plurality of wheels, before the target wheel receives a road surface input.
- the effect of feedback control is suppressed.
- the electrical rigidity is reduced, so that the vibration transmission to the stator side member (for example, the motor housing) of the motor can be suppressed, thereby suppressing the vibration of the vehicle due to kickback.
- the wheel control method when each of the plurality of wheels receives the road surface input, the fluctuation information is detected, the target wheel is identified from the detected fluctuation information, and the target wheel receives the road surface input. Further, it is preferable to reduce the feedback amount related to the feedback control than before the target wheel receives road surface input. Thereby, based on the fluctuation
- FIG. 1 is a diagram showing a schematic configuration of a drive mechanism of a vehicle 10 according to the present invention.
- FIG. 2 is a diagram showing a control system for controlling the motor 21 by the motor drive unit 111 in FIG.
- FIG. 3 is a diagram schematically showing how the unsprung vertical vibration of the vehicle 10 is attenuated during feedback control.
- FIG. 4 is a diagram illustrating a processing flow of feedback suppression control.
- FIG. 5 is a diagram illustrating a state of torque fluctuation during the feedback suppression control in FIG. 4.
- FIG. 6 is a modification of the feedback suppression control in FIG. 4 and is a diagram illustrating a processing flow of control including offset processing.
- FIG. 7 is a diagram showing a state of torque fluctuation in the offset state by the offset processing in FIG.
- FIG. 8 is a diagram showing a state of torque fluctuation when the offset release processing is executed in the offset state in FIG.
- FIG. 1 is referred to for the schematic configuration of the drive mechanism of the vehicle 10.
- An arrow F in FIG. 1 indicates the forward direction of the vehicle 10, and an arrow R indicates the reverse direction of the vehicle 10.
- the vehicle 10 corresponds to the “vehicle” of the present invention, and includes four wheels (the entire rotating portion including soft tires) 11 to 14, four motors (also referred to as “in-wheel motors”) 21 to 24, a controller 110, four motor drive units 111 to 114, an information detection unit 120, and an acceleration sensor 130.
- the controller 110, the four motor drive units 111 to 114, the information detection unit 120, and the acceleration sensor 130 are all components for controlling the four wheels 11 to 14 and the four motors 21 to 24. It constitutes the “wheel drive device” and “control unit” of the invention. In this case, four motors 21 to 24 can also be used as components.
- the first motor 21 is incorporated in the right front wheel 11 as a wheel, and rotationally drives the right front wheel 11 with the three-phase driving power supplied from the motor driving unit 111.
- the second motor 22 is incorporated in the left front wheel 12 as a wheel, and rotationally drives the left front wheel 12 by the three-phase driving power supplied from the motor driving unit 112.
- the third motor 23 is incorporated in the right rear wheel 13 as a wheel, and rotationally drives the right rear wheel 13 with three-phase driving power supplied from the motor driving unit 113.
- the fourth motor 24 is incorporated in the left rear wheel 14 as a wheel, and rotationally drives the left rear wheel 14 with the three-phase driving power supplied from the motor driving unit 114.
- Each of these four motors 21 to 24 is a rotor (typically a rotating shaft) that rotates with a corresponding wheel, and a stator (typically a motor) that is fixed to the vehicle body.
- a three-phase AC induction motor including a housing.
- a reduction gear (a reduction gear 31 described later) is interposed between each of the four motors 21 to 24 and a corresponding wheel, and the torque is increased or decreased via the reduction gear. (So-called “gear reduction method”) is employed.
- a structure in which each of the four motors 21 to 24 and the corresponding wheel is directly connected can be adopted.
- the controller 110 is connected to each of the motor drive units in order to control the motor drive units 111 to 114.
- the controller 110 is constituted by a microcomputer whose main components are a CPU, a ROM, a RAM, and the like.
- the information detection unit 120 is a known CAN (Controller (Area Network) communication is connected to the controller 110.
- the information detection unit 120 receives detection values (for example, accelerator opening, vehicle speed, etc.) detected by various sensors.
- the input detection value is transmitted to the controller 110 via CAN communication.
- This information detection unit 120 corresponds to the “information detection unit” of the present invention.
- the acceleration sensor 130 is connected to the controller 110.
- the acceleration sensor 130 is configured as a sensor that detects acceleration (typically, unsprung acceleration) acting on the unsprung portion of the vehicle 10.
- the acceleration sensor 130 is provided corresponding to each of the four wheels 11 to 14.
- the acceleration sensor 130 may be an element provided separately from the information detection unit 120 or may be included in the information detection unit 120.
- the acceleration sensor 130 corresponds to the “acceleration sensor” of the present invention.
- the controller 110 calculates the required torque Tr for the motor drive units 111 to 114 based on the detection value transmitted from the information detection unit 120, and sends the required torque Tr to each of the motor drive units 111 to 114. Output.
- the required torque Tr is preferably output as a current value for a motor driven by each motor drive unit.
- the controller 110 can perform feedforward control of each of the motors 11 to 14 via the motor driving units 111 to 114. As a result, an appropriate driving torque is distributed to each of the four wheels 11 to 14, and a desired vehicle motion of the vehicle 10 is formed.
- the controller 110 mainly controls the motor 21 by the motor driving unit 111 is described for convenience.
- the controller 110 is also connected to other motor drive units 112 to 114, and the motors 22 to 24 corresponding to the motor drive units can be appropriately controlled similarly to the motor 21.
- FIG. 2 is referred to for a control system for controlling the motor 21 by the motor drive unit 111.
- the motor drive unit 111 includes a torque control device 111a and a PWM inverter 111b.
- the current sensor 131 and the motor rotation sensor 132 are each electrically connected to the torque control device 111a.
- the current sensor 131 is configured as an information detection sensor for detecting a current value actually supplied to each phase of the motor 21, that is, an actual current value Ia (also simply referred to as “current value”) of the motor 21.
- the motor rotation sensor 132 is configured as an information detection sensor for detecting the rotation angle ⁇ and the rotation angular acceleration ⁇ of the motor 21.
- the torque control device 111 a acquires the required torque Tr from the controller 110 while transmitting the execution torque Ta corresponding to the actual current value Ia of the motor 21 to the controller 110.
- the motor drive unit 111 determines a voltage command value V (d-axis (magnetic flux component) voltage command value: Vd, based on the detected values by the current sensor 131 and the motor rotation sensor 132 and the required torque Tr from the controller 110.
- q-axis (torque component) voltage command value: Vq) is calculated, and the calculated voltage command value V is output to the PWM inverter 111b.
- the motor drive unit 111 includes voltage command calculation means for calculating the voltage command value V.
- the PWM inverter 111b is a known pulse width modulation type inverter that performs control to increase or decrease the time (pulse width) for outputting a pulse signal, and the voltage command value output from the torque control device 111a.
- V is modulated.
- a drive voltage is generated in each phase of the motor 21 and a drive current is supplied to each phase of the motor 21.
- the motor 21 is driven by this drive current, whereby the wheel 11 is rotationally driven via the speed reducer 31.
- the driving torque of the wheels 11 is adjusted by feedback control of the current supplied to the motor 21 by the controller 110 (hereinafter also referred to as “current feedback control”).
- current feedback control typically, control (PID control) is performed in which the actual current value Ia detected by the current sensor 131 follows the required torque Tr (required current value Ir) from the controller 110.
- the proportional component obtained by multiplying the deviation ⁇ I by the proportional gain Kp and the integral value of the deviation ⁇ I are obtained by multiplying the integral gain Ki.
- the voltage command value V is calculated by adding the integrated component and the differential component obtained by multiplying the differential value of the deviation ⁇ I by the differential gain Kd.
- the feedback amount (feedback gain) of this current feedback control is constituted by the proportional gain Kp, the integral gain Ki, and the differential gain Kd.
- the motor is controlled so that the drive current supplied to each phase of the motor 21 becomes the target current value, and the drive torque of the motor 21 can be controlled with high accuracy.
- a P control that calculates the voltage command value V based only on the proportional component and a PI control that calculates the voltage command value V based on the proportional component and the integral component can be used as needed. .
- the wheels 11 to 14 receive road surface input (disturbance) in a predetermined high frequency band (typically a frequency band exceeding 10 Hz) from the traveling road surface.
- a predetermined high frequency band typically a frequency band exceeding 10 Hz
- the rotor side member typically, the motor shaft
- the current of the motor 21 fluctuates.
- the rotational rigidity (also referred to as “electrical rigidity”) of the rotor-side member increases, and the reaction force acts on the stator-side member (typically the motor housing).
- the stator-side member typically the motor housing.
- FIG. 3 shows an example in which the unsprung acceleration Au [m / s 2 ] changes as time t [s] elapses.
- the attenuation rate at the time of driving is lower than that at the time of non-driving.
- the present invention is characterized in that the following feedback suppression control is additionally performed in order to cope with the road surface input in the high frequency band received by the wheel on the premise of the current feedback control described above.
- FIG. 4 shows a processing flow of feedback suppression control.
- This feedback suppression control is control for suppressing (reducing) an increase in electrical rigidity by suppressing the effect of the above-described current feedback control, and includes processing from step S101 to step S105.
- step S101 the controller 110 detects the unsprung acceleration Au [m / s 2 ] acting corresponding to each of the wheels 11 to 14 of the vehicle 10 continuously or at regular intervals. And remember. Thereby, the unsprung acceleration Au corresponding to each wheel is acquired.
- step S102 the controller 110 reads the unsprung acceleration Au detected in step S101 and compares it with a preset threshold value. As a result, if the controller 110 determines that the unsprung acceleration Au exceeds the threshold value (Yes in step S102), the controller 110 proceeds to step S103. In this case, it is determined that at least one of the four wheels 11 to 14 has received a road surface input exceeding a certain level from the road surface. On the other hand, if the controller 110 determines that the unsprung acceleration Au detected in step S101 has fallen below the threshold (No in step S102), the controller 110 proceeds to step S104. In this case, it is determined that none of the four wheels 11 to 14 has received a road surface input exceeding a certain level from the road surface.
- this acceleration sensor 130 it is possible to detect fluctuation information when the wheel receives road surface input.
- a motor rotation sensor 132 provided in each of the motors 21 to 24 may be employed. For example, it can be determined that the wheel corresponding to the motor in which the rotation fluctuation exceeding the preset threshold is detected by the motor rotation sensor 132 has received road surface input exceeding a certain level.
- the motor rotation sensor 132 in this case corresponds to the “motor rotation sensor” of the present invention.
- step S104 it is determined whether or not the process for canceling the feedback suppression control is in progress. If the condition of step S104 is satisfied, a process for ending the control is executed in step S105. If the condition of step S104 is not satisfied, the feedback suppression control is ended as it is.
- the controller 110 performs processing on the motor (for example, the motor 12 of the wheel 11) of the wheel (hereinafter also referred to as “target wheel”) that has received a road surface that exceeds a certain level among the four wheels 11 to 14.
- the feedback amount reduction process is performed.
- This feedback amount reduction process is a process for reducing the feedback amount of the current feedback control, and specifically, selectively selects one of the following three forms (first to third process forms). Can be adopted. Note that “reduction of the feedback amount” in the present specification includes a mode in which the feedback amount is zero, in addition to a mode in which the feedback amount is relatively small.
- the controller 110 sets the feedback amount of the motor of the target wheel to be relatively lower than that during the feedback control on condition that the condition of step S102 is satisfied. According to the first processing mode, the effect of reducing the feedback amount can be reliably obtained in the motor of the target wheel.
- the controller 110 can set the feedback amount (Kp, Ki, Kd) obtained by adding the proportional component, the integral component, and the derivative component to be lower than that during the PID control.
- the calculation means of the controller 110 stores a map M1 in which the feedback amount (Kp, Ki, Kd) of the PID control and the unsprung acceleration Au are associated, and a new feedback amount is obtained using this map M1.
- the feedback amount corresponding to the detected unsprung acceleration Au can be derived from the map M1, and the feedback amount during PID control can be changed to the feedback amount derived from the map M1.
- a feedback amount obtained by subtracting a predetermined value from a feedback amount at the time of PID control can be newly adopted.
- the controller 110 can set the feedback amount (Kp, Ki) obtained by adding the proportional component and the integral component to be lower than that during PI control.
- the calculation means of the controller 110 accumulates a map M2 in which the feedback amount (Kp, Ki) of PI control and the unsprung acceleration Au are associated, and a new feedback amount is set using this map M2. can do.
- the feedback amount corresponding to the detected unsprung acceleration Au can be derived from the map M2, and the feedback amount during PI control can be changed to the feedback amount derived from the map M2.
- a feedback amount obtained by subtracting a preset constant value from the feedback amount at the time of PI control can be newly adopted.
- the controller 110 can set the feedback amount (Kp) by the proportional component to be lower than that during P control.
- the calculation means of the controller 110 accumulates a map M3 in which the feedback amount (Kp) of P control and the unsprung acceleration Au are associated, and a new feedback amount is set using this map M3.
- the feedback amount corresponding to the detected unsprung acceleration Au can be derived from the map M3, and the feedback amount during P control can be changed to the feedback amount derived from the map M3.
- a feedback amount obtained by subtracting a preset constant value from the feedback amount during the P control can be newly adopted.
- the controller 110 configures the feedback amount of the motor of the target wheel on the condition that the condition of step S102 is established in any of the aforementioned PID control, PI control, and P control. Set the gain Kp to zero. According to this second processing mode, the effect of reducing the feedback amount can be enhanced by setting the proportional gain Kp, which has a large influence at the time of change in the feedback amount, to zero.
- the controller 110 controls the four motors 11 to 14 only by the feedforward control described above.
- the controller 110 can set the feedback amount of the motor of the target wheel to zero. For example, it can be set so that the actual current value Ia of each phase detected by the current sensor 131 is not transmitted to the calculation means of the controller 110. According to the third processing mode, an effect of reducing the feedback amount can be obtained by simple control. In this case, the controller 110 controls the four motors 11 to 14 only by the feedforward control described above.
- the controller 110 calculates the required torque Tr based on the detection value transmitted from the information detection unit 120, for example, and this request Torque Tr can be output to motor drive units 111-114.
- the feedback amount of the motor of the target wheel is reduced, so that the effect of feedback control is suppressed.
- the electrical rigidity decreases, so that vibration transmission to the stator side member (for example, motor housing) of the motor (for example, the motor 21) of the target wheel is suppressed, and thereby vibration of the vehicle 10 due to kickback is suppressed. Can be suppressed.
- the controller 110 performs the feedback amount reduction process in step S103 on the condition that the wheel actually receives a road surface input exceeding a certain level as in steps S101 and S102 in FIG. The case of executing is described.
- the controller 110 predicts the road surface input of the wheels received by the vehicle-mounted camera or the like mounted on the vehicle 10 with respect to road surface information (such as the presence or absence of unevenness, seams, steps, etc.) of the road surface of the vehicle 10.
- the feedback amount reduction process can be executed in advance.
- the controller 110 performs the target wheel (for example, In accordance with the amplitude (magnitude) of the road surface input received by the wheel 11), the feedback amount in the high frequency band is made smaller than that during feedback control. In this case, it is preferable to derive the amplitude of the high frequency band based on the frequency characteristics of the road surface input.
- the relationship between the amplitude of the road surface input in the high frequency band and the feedback amount is registered in advance, and the condition that the amplitude of the road surface input in the high frequency band has reached a certain level (for example, exceeds a predetermined threshold)
- the feedback amount in the high frequency band can be set based on this relationship.
- the feedback amount in the high frequency band can be set to zero by satisfying the above condition.
- a known low-pass filter that becomes effective when the above condition is satisfied in a region where the actual current value Ia of each phase detected by the current sensor 131 of the motor 21 is transmitted to the torque control device 111a. (Not shown) is preferably provided.
- the high frequency component of the actual current value Ia supplied to the motor 21 can be attenuated.
- vibration transmission to the stator side member (for example, motor housing) of the motor 21 is suppressed, and thereby vibration of the vehicle 10 due to kickback can be suppressed.
- a road surface input in a predetermined low frequency band (typically a frequency band lower than 10 Hz) can be dealt with by absorbing the road surface input by normal vehicle movement of the vehicle 10. it can. Therefore, it is possible to suppress the vibration of the vehicle 10 due to kickback, and to prevent the phenomenon that the driving force of the motor 21 is not transmitted to the wheels, so-called “driving force loss”.
- the controller 110 changes the feedback amount of the motor of the target wheel from the first gain to the second on the condition that the condition of step S102 is satisfied. Then, the feedback amount is returned from the second gain to the first gain on the condition that a predetermined time has been measured by a timer (not shown) or the like (feedback before reduction). Return to quantity). For example, a step of determining whether or not a predetermined time has elapsed after the processing of step S103 in FIG. 4 and a step of returning the feedback amount to the feedback amount before reduction on condition that the predetermined time has elapsed are provided. be able to.
- the predetermined time related to the reduction of the feedback amount is typically a short time (eg, 0. 0) that does not affect the vehicle motion (the longitudinal acceleration, lateral acceleration, yaw rate, etc. of the vehicle 10). 1 to 0.3 [s]) is preferable. Thereby, it is possible to prevent the driving force of the wheels from fluctuating due to the reduction of the feedback amount and affecting the vehicle motion while suppressing the vibration of the vehicle 10 due to the kickback.
- the controller 110 performs this return operation gently when returning the feedback amount of the motor of the target wheel to the feedback amount before the reduction.
- the feedback amount returning operation can be executed more slowly than the feedback amount reducing operation.
- the time t2 required for the return is measured by a timer (not shown) or the like.
- the controller 110 changes the feedback amount so that the relationship of t1 ⁇ t2 is established.
- a time t2 related to the feedback amount returning operation may be set in advance, and the feedback amount returning operation may be executed based on the set time t2. Furthermore, it is preferable that the time t2 or the sum of the time t1 and the time t2 is a preset short time (for example, 0.1 to 0.3 [s]). Thereby, it is possible to prevent the driving force of the wheels from fluctuating due to the reduction of the feedback amount and affecting the vehicle motion.
- the controller 110 calculates the error (deviation) of the drive torque generated by the feedback amount reduction process as the target wheel related to the feedback amount reduction process. Make up with the motors of the other wheels. That is, when the feedback amount is reduced in the wheel motor that has received the road surface input in the high frequency band, for example, the motor 21 of the wheel 11, the controller 110 causes the drive torque error (torque error ⁇ T) generated thereby to be other than the motor 21. Can be allocated (distributed) to the target torque of another motor.
- the controller 110 feedback-controls another motor according to the newly set target torque.
- the drive torque error is an error related to torque accuracy (torque error ⁇ T) caused by reducing the feedback amount.
- torque error ⁇ T an error related to torque accuracy
- the torque error ⁇ T of the motor 21 of the wheel 11 is assigned only to the motor 23 incorporated in the wheel 13 immediately behind the wheel 11 and assigned to the target torque of the motor 23. Thereby, it can suppress that a change arises in a vehicle motion, and the discomfort given to a vehicle occupant can be reduced.
- the controller 110 gently executes a control operation related to torque distribution by another motor other than the motor of the target wheel.
- the motor control can be performed so that the control operation related to torque distribution by another motor other than the motor 21 is slower than the operation of reducing the feedback amount in the motor 21.
- the controller 110 establishes a relationship of t3 ⁇ t4 with respect to the time t3 required to reduce the feedback amount in the motor 21 and the time t4 required to allocate the torque error ⁇ T with respect to the target torque of another motor.
- the motors 21 to 24 are controlled.
- a time t4 related to torque distribution by another motor can be set in advance.
- a known rate limit (not shown) that is effective in reducing the response speed may be provided in an area where the controller 110 and, for example, a motor drive unit of another motor other than the motor 21 are connected. it can.
- the controller 110 when the above-described torque error ⁇ T related to the motor of the target wheel (for example, the motor 21) is distributed to another motor in the above-described fifth or sixth embodiment, the controller 110 A predetermined low frequency component of the error ⁇ T is extracted, and this low frequency component is distributed to another motor. That is, a predetermined low frequency component of the torque error ⁇ T is assigned to the target torque of another motor.
- a known low-pass filter (not shown) that can extract a low-frequency component while attenuating a high-frequency component of the torque error ⁇ T can be used.
- the offset process of step S201 is provided between the process of step S102 and the process of step S103 of the feedback suppression control in FIG. Yes.
- the controller 110 detects a road surface input of a certain level or higher
- the controller 110 calculates a target torque related to the motor of the wheel (for example, the motor 21 of the wheel 11) that has received this road surface input. change.
- the controller 110 increases the command that makes it difficult for zero crossing of the drive torque to occur, that is, the target torque from T1 [N ⁇ m] to T2 [N ⁇ m].
- Such a torque setting command is output to the torque control device 111a.
- the motor 21 performs control that follows the target torque T2 [N ⁇ m]. Therefore, even when the actual drive torque varies due to the feedback amount reduction process, the possibility that the positive and negative of the drive torque is reversed (zero cross occurs) is reduced. Can be suppressed.
- any one of the following three processing forms (first to third processing forms) can be selectively employed.
- the controller 110 can change the offset amount of the target torque according to the magnitude of the road surface input received by the wheels, that is, according to the unsprung acceleration Au detected by the acceleration sensor 130. .
- the target torque T2 [N ⁇ m] is set so that the difference from the target torque T1 [N ⁇ m] increases as the unsprung acceleration Au increases.
- the road surface input received by the wheels is relatively large, and as a result of increasing the reduction amount of the feedback amount accordingly, even if the fluctuation of the driving torque becomes large, the above-mentioned zero cross is unlikely to occur.
- the controller 110 performs an offset process in advance in anticipation of road surface input received by the wheels. For example, the controller 110 obtains road surface information (such as the presence / absence and size of unevenness, seams, steps, etc.) of the traveling road surface of the vehicle 10 via road surface information acquisition means by an in-vehicle camera or a navigation device mounted on the vehicle 10. get. And the controller 110 determines whether the wheel 11 or the wheel 12 which is a front wheel may receive the road surface input more than a fixed level based on the information which this road surface information acquisition means acquired. In this case, the road surface information regarding the traveling road surface immediately before the vehicle 10 arrives can be acquired by the in-vehicle camera or the navigation device of the vehicle 10.
- road surface information such as the presence / absence and size of unevenness, seams, steps, etc.
- the road surface information registered based on the past travel history of the vehicle 10 and other vehicles can be acquired by the navigation device of the vehicle 10.
- the controller 110 determines that the wheel 11 or the wheel 12 may receive a road surface input of a certain level or more, the controller 110 before the wheel actually receives the road surface input,
- the above-described offset processing processing for increasing the target torque from T1 [N ⁇ m] to T2 [N ⁇ m]
- the motor of the front wheel can be appropriately controlled without delay.
- the road surface input received by the front wheels can be dealt with promptly.
- the controller 110 performs offset processing on the rear wheels. For example, when the acceleration sensor 130 detects that the wheel 11 or the wheel 12 that is the front wheel has received a road surface input of a certain level or higher, the controller 110 subsequently moves the wheel 13 or the wheel 14 that is the rear wheel to the road surface. Predict when to receive input. Specifically, for example, based on the vehicle speed and the wheel base (distance between the front wheel shaft and the rear wheel shaft) of the vehicle 10, the controller 110 passes the rear wheel after the traveling road surface related to the road surface input passes the front wheel. The time ⁇ t required until this time is calculated. In this case, it is preferable that the controller 110 acquires the vehicle speed of the vehicle 10 from the information detection unit 120 and stores the wheel base in advance.
- the controller 110 then applies the above-described offset processing (target torque from T1 [N ⁇ m] to T2 [N ⁇ m] to the motor 23 of the wheel 13 and the motor 24 of the wheel 14 until the calculated time ⁇ t elapses. ] Is applied.
- the acceleration sensor 130 functions as a predicting unit that predicts the timing of applying the above-described offset processing to the rear wheel motor.
- this prediction means can be omitted.
- the rear wheel motor can be appropriately controlled without delay.
- the offset processing described above may be executed by both the front wheel and rear wheel motors, or may be executed only by the rear wheel motor.
- the controller 110 executes the above-described offset processing in the motor of the target wheel, the vehicle motion (acceleration in the longitudinal direction of the vehicle 10, yaw rate, etc.)
- the motor can be controlled so that the driving torque of the four motors as a whole does not change.
- the controller 110 executes a torque redistribution process for redistributing the drive torque by allocating the torque change of the target torque of the target wheel motor to the target torque of another motor. That is, a predetermined motor torque change is supplemented by another motor.
- the torque change related to this offset can be subtracted from the target torque of another motor.
- the torque change related to this offset can be added to the target torque of another motor.
- the controller 110 performs feedback control according to the target torque after assigning another motor. Thereby, the fluctuation
- the target torque of the motor 21 can be reset to a value lower than T2 [N ⁇ m].
- T2 [N ⁇ m]
- the controller 110 sets a holding time (also referred to as “duration”) ⁇ t1 for holding the offset state in which the above-described offset processing is performed.
- This holding time ⁇ t1 is derived as the time until the rear wheel receives the road surface input after the front wheel receives a road surface input of a certain level or higher (the above-mentioned time ⁇ t).
- the controller 110 executes an offset release process for quickly releasing the offset state and returning to the state before the offset process on the condition that at least the holding time ⁇ t1 has elapsed.
- an offset release process for quickly releasing the offset state and returning to the state before the offset process on the condition that at least the holding time ⁇ t1 has elapsed.
- T2 [N ⁇ m] for example, after the target torque of the motor 21 is changed from T1 [N ⁇ m] to T2 [N ⁇ m], T2 [N ⁇ m] to T1 [T1 [ N ⁇ m]. Accordingly, it is possible to prevent excessive drive torque from being used (excess energy is consumed) by suppressing the time during which the offset state is maintained.
- the controller 110 causes the driving direction torque to be generated in one of the front wheels and the rear wheels by the offset processing described above, and the braking direction is applied to the other of the front wheels and the rear wheels.
- this equilibrium state is maintained for a certain period of time.
- the controller 110 preferably performs motor control so that the above-described equilibrium state is formed. Thereby, the delay of control can be prevented.
- the holding time ⁇ t ⁇ b> 2 described above may be a preset value or may be changed according to the vehicle speed of the vehicle 10.
- the holding time ⁇ t2 is set relatively long when the vehicle speed of the vehicle 10 is relatively low, and the holding time ⁇ t2 is set relatively when the vehicle speed of the vehicle 10 is relatively high. Can be set short. This is because the lower the vehicle speed, the longer it takes to pass the traveling road surface related to the road surface input at a certain level or higher, and accordingly it is necessary to lengthen the holding time ⁇ t2.
- the actually selected holding time ⁇ t2 may be calculated from a correlation equation between the vehicle speed of the vehicle 10 prepared in advance and the holding time ⁇ t2.
- the controller 110 can perform motor control so that the time ⁇ t3 required for the offset processing described above exceeds the time ⁇ t4 required for the torque redistribution processing.
- the time ⁇ t4 corresponds to the time required to allocate the torque change for the target torque of the other motor.
- the control state is canceled and returned to the initial state (also referred to as “normal state”).
- “Wheel control method according to claim 22 A wheel control method, wherein a wheel corresponding to a motor in which a rotation fluctuation exceeding a preset threshold is detected among the plurality of wheels is determined to be the target wheel.
- “ (Mode 2) can be adopted.
- “Wheel control method according to aspect 9 A wheel control method for performing motor control so that a time required for allocating the torque error with respect to a target torque of the another motor exceeds a time required for reducing the feedback amount.
- the embodiment (embodiment 10) can be adopted.
- “Wheel control method according to aspect 12” A wheel control method in which a torque change caused by the offset of the target torque is allocated to a target torque of another motor other than the motor related to the offset, and the other motor is feedback-controlled according to the allocated target torque.
- the mode (mode 13) may be taken.
- the wheel control method according to Aspect 13 wherein the offset causes a torque in the driving direction to be generated in one of the front wheels and the rear wheels among the plurality of wheels, and the driving direction in the other of the front wheels and the rear wheels.
- a wheel control method that maintains a balanced state for a certain period of time when a balanced state is generated in which a torque in the braking direction that is the opposite direction is generated. " The mode (mode 15) may be taken.
- “Wheel control method according to aspect 13 A wheel control method for performing motor control so that a time required for allocating the torque change with respect to a target torque of the another motor exceeds a time required for the offset. " The mode (mode 16) may be taken.
- “Wheel control method according to aspect 16 When a control state is formed in which the other motor is feedback-controlled according to the target torque after allocation of the torque change after the offset from the initial state, and when returning to the initial state, the control state is shifted from the initial state to the control state.
- the wheel control method of performing motor control so that the time required for shifting exceeds the time required for shifting from the control state to the initial state.
- (Aspect 17) can be adopted.
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Abstract
Description
また、ガタのある制御対象に、例えば引用文献(特開2005-020831号公報、特開2006-129542号公報)に開示の技術を適用しても、当該制御対象を適正に制御するのは困難である。
Area Network)通信によってコントローラ110に接続されている。この情報検出部120では、各種センサによって検出された検出値(例えば、アクセル開度、車速等)が入力される。入力された検出値は、CAN通信を経てコントローラ110に伝送される。この情報検出部120が本発明の「情報検出部」に相当する。
図4には、フィードバック抑制制御の処理フローが示されている。このフィードバック抑制制御は、上述の電流フィードバック制御の効果を抑制することで、電気的な剛性の増加を抑える(低減する)ための制御であり、ステップS101からステップS105までの処理を含む。
第2実施例では、4つの車輪11~14の少なくとも1つが所定の高周波数帯(典型的には、10Hzを上回る周波数帯)の路面入力を受けた場合、コントローラ110は、対象車輪(例えば、車輪11)が受けた路面入力の振幅(大きさ)に応じて、この高周波数帯のフィードバック量をフィードバック制御時よりも小さくする。この場合、この路面入力の周波数特性に基づいて高周波数帯の振幅を導出するのが好ましい。例えば、高周波数帯の路面入力の振幅とフィードバック量との関係を予め登録しておき、高周波数帯の路面入力の振幅が一定レベルに達した(例えば、所定の閾値を上回った)という条件の成立によって、この関係に基づいて高周波数帯のフィードバック量を設定することができる。或いは、前記の条件の成立によって、高周波数帯のフィードバック量をゼロに設定することができる。
第3実施例では、前述の第1実施例や第2実施例において、コントローラ110は、ステップS102の条件が成立したことを条件にして対象車輪のモータのフィードバック量を第1のゲインから第2のゲインに低減した後、更にタイマ(図示省略)等によって所定時間が経過したことが計測されたことを条件にしてこのフィードバック量を第2のゲインから第1のゲインに戻す(低減前のフィードバック量に戻す)。例えば、図4中のステップS103の処理後に、所定時間が経過したか否かを判定するステップと、この所定時間が経過したことを条件にしてフィードバック量を低減前のフィードバック量に戻すステップを設けることができる。この場合、フィードバック量の低減に係る所定時間は、典型的には車両運動(車両10の前後方向の加速度、左右方向の加速度、ヨーレート等)に影響を及ぼさない程度の短時間(例えば、0.1~0.3[s])であるのが好ましい。これにより、キックバックによる車両10の振動を抑制しつつ、フィードバック量の低減によって車輪の駆動力が変動して車両運動に影響が及ぶのを防止することができる。
第4実施例では、前述の第3実施例において、コントローラ110は、対象車輪のモータのフィードバック量を低減前のフィードバック量に戻す際に、この戻し動作を緩やかに実行する。
第5実施例では、前述の第1~第4実施例のいずれかにおいて、コントローラ110は、フィードバック量低減処理によって生じる駆動トルクの誤差分(偏差分)を、当該フィードバック量低減処理に係る対象車輪以外の車輪のモータによって補う。即ち、高周波数帯の路面入力を受けた車輪のモータ、例えば車輪11のモータ21においてフィードバック量を低減した場合、コントローラ110は、これにより生じる駆動トルクの誤差分(トルク誤差ΔT)をモータ21以外の別モータの目標トルクに割り振る(分配する)ことができる。例えば、フィードバック量の低減によってトルクが低下する場合はこのトルク低下分を別モータの目標トルクに加算することができ、またフィードバック量の低減によってトルクが上昇する場合はこのトルク上昇分を別モータの目標トルクから減算することができる。そして、コントローラ110は、新たに設定した目標トルクにしたがって別モータをフィードバック制御する。この場合、駆動トルクの誤差分は、フィードバック量を低減したことにより生じるトルク精度に関する誤差(トルク誤差ΔT)となり、例えばモータ21に対しては、3つのモータ22~24のうちの少なくとも1つを割り当てることができる。例えば車輪11のモータ21のトルク誤差ΔTを、この車輪11の真後ろの車輪13に組み込まれたモータ23のみに割り当てて、このモータ23の目標トルクに割り振るのが好ましい。これにより、車両運動に変化が生じるのを抑えることができ、車両乗員に与える違和感を低減することができる。
第6実施例では、前述の第5実施例において、コントローラ110は、対象車輪のモータ以外の別モータによるトルク分配に係る制御動作を緩やかに実行する。
第7実施例では、前述の第5実施例や第6実施例において、対象車輪のモータ(例えばモータ21)に係る前述のトルク誤差ΔT分を別モータに分配する場合、コントローラ110は、このトルク誤差ΔTの所定の低周波数成分を抽出してこの低周波数成分を別モータに分配する。即ち、トルク誤差ΔTの所定の低周波数成分を別モータの目標トルクに割り振る。この場合、物理的な手段として、トルク誤差ΔTの高周波数成分を減衰させる一方で、低周波数成分を抽出することが可能な公知のローパスフィルター(図示省略)を用いることができる。これにより、モータ21においてフィードバック量の低減効果を速やかに得ることができる一方で、モータ21以外の別モータにおいてトルク誤差ΔTが急激に分配されることで生じる異音や振動の発生を抑制することができる。この場合、車両運動の変化は低周波数帯の変動であるため、トルク誤差ΔTの高周波数成分を分配する必要がない。
第8実施例では、前述の第1~第7実施例のいずれかにおいて、図4中のフィードバック抑制制御のステップS102の処理とステップS103の処理との間に、ステップS201のオフセット処理を設けている。このオフセット処理では、コントローラ110は、図7に示すように、一定レベル以上の路面入力を検出した時点で、この路面入力を受けた車輪のモータ(例えば、車輪11のモータ21)に関する目標トルクを変更する。具体的には、図7が参照されるように、コントローラ110は、駆動トルクのゼロクロスが生じ難くなるような指令、即ち目標トルクをT1[N・m]からT2[N・m]まで上昇させるようなトルク設定指令をトルク制御装置111aに出力する。これにより、その後のフィードバック量低減処理(図6中のステップS103の処理)において、例えばモータ21では目標トルクT2[N・m]に追従した制御が実行される。従って、フィードバック量低減処理によって実駆動トルクが変動した場合であっても、駆動トルクの正負が逆転する(ゼロクロスが発生する)可能性が低くなり、これにより前述の減速機31においてガタ音や振動が発生するのを抑制することができる。
なお、前述のオフセット処理は、前輪及び後輪のモータの双方で実行されてもよいし、或いは後輪のモータのみで実行されてもよい。
第9実施例では、前述の第8実施例において、コントローラ110は、対象車輪のモータにおいて前述のオフセット処理を実行した場合、車両運動(車両10の前後方向の加速度、ヨーレート等)や走行速度の変動を抑えるべく、4つのモータ全体での駆動トルクが変化しないようにモータ制御することができる。具体的には、コントローラ110は、対象車輪のモータの目標トルクのトルク変更分を別モータの目標トルクに割り振ることによって駆動トルクを再分配するトルク再配分処理を実行する。即ち、所定のモータのトルク変更分を別モータによって補う。例えば、所定のモータの目標トルクを上昇方向にオフセットする場合(プラス側へのオフセットの場合)にはこのオフセットに係るトルク変更分を別モータの目標トルクから減算することができ、また所定のモータの目標トルクを低下方向にオフセットする場合(マイナス側へのオフセットの場合)にはこのオフセットに係るトルク変更分を別モータの目標トルクに加算することができる。例えば4つのモータ21~24で駆動トルクを再分配する場合には、モータ21の目標トルクの増加分(オフセット分)が3つのモータ22,23,24の各目標トルクの減少分(オフセット分)の加算値に合致するように設定する。そして、コントローラ110は、別モータを割り振り後の目標トルクにしたがってフィードバック制御する。これにより、車両10の車両運動や走行速度の変動を抑えることができる。
第10実施例では、前述の第8実施例又は前述の第9実施例において、コントローラ110は、前述のオフセット処理が実行されたオフセット状態を保持する保持時間(「継続時間」ともいう)Δt1を設定する。この保持時間Δt1は、前輪が一定レベル以上の路面入力を受けた後に後輪が当該路面入力を受けるまでの時間(前述の時間Δt)として導出される。これにより、当該路面入力に係る走行路面を前輪が通過してから後輪が通過するまでの間、オフセット状態が継続されるため、後輪の制御の遅れが防止される。この場合、コントローラ110は、少なくとも保持時間Δt1が経過したことを条件にして、速やかにオフセット状態を解除してオフセット処理前の状態に復帰させるオフセット解除処理を実行するのが好ましい。図8が参照されるように、例えばモータ21の目標トルクをT1[N・m]からT2[N・m]に変更した後、保持時間Δt1の経過後に再びT2[N・m]からT1[N・m]に戻すことができる。これにより、オフセット状態が維持される時間を抑えることによって、余分な駆動トルクが使用される(余分なエネルギーが消費される)のを防止することができる。
第11実施例では、前述の第9実施例において、コントローラ110は、前述のオフセット処理によって、前輪及び後輪のいずれか一方に駆動方向のトルクが生じ、且つ前輪及び後輪の他方に制動方向(駆動方向と反対方向)のトルクが生じた均衡状態が形成された場合、この均衡状態を一定時間保持する。この均衡状態を保持時間Δt2が経過するまで保持することで、トルクに関してプラス側とマイナス側にバランスがとれた安定的な状態での適正なオフセット処理が可能になる。なお、コントローラ110は、前輪に一定レベル以上の路面入力が入力されることが予測される場合には、前述の均衡状態が形成されるようにモータ制御するのが好ましい。これにより、制御の遅れを防止することができる。また、前述の保持時間Δt2は、予め設定された値であってもよいし、或いは車両10の車速に応じて変更されてもよい。
第12実施例では、前述の第9実施例において、コントローラ110は、前述のオフセット処理に要する時間Δt3を、前述のトルク再配分処理に要する時間Δt4が上回るようにモータ制御することができる。この場合、時間Δt4は、別モータの目標トルクに対するトルク変更分の割り振りに要する時間に相当する。この目的のため、応答速度を低下させるのに有効な公知のレートリミットやローパスフィルター等を用いるのが好ましい。これにより、路面入力に係る対象車輪においてゼロクロスによる異音や振動を低減しつつ、トルク再配分処理が急激に行われることにより生じる異音や振動を抑えることができる。この場合、車両運動の変化は低周波数帯の変動であるため、トルク再配分処理を急激に実行しなくても車両運動に影響を及ぼさない。
第13実施例では、前述の第12実施例において、前述のオフセット処理及びトルク再配分処理を実施した制御状態の後に、この制御状態を解除して初期状態(「通常状態」ともいう)に戻す。この場合、コントローラ110は、初期状態から制御状態に移行するのに要する時間Δt5(=Δt3+Δt4)を、制御状態から初期状態に戻すのに要する時間Δt6が上回るようにモータ制御するのが好ましい。これにより、制御状態から初期状態に復帰する際に生じる異音や振動を抑えることができる。
「請求項22に記載の車輪制御方法であって、
前記複数の車輪のうち予め設定された閾値を上回るばね下加速度が検出された車輪を前記対象車輪であると判定する、車輪制御方法。」
という態様(態様1)を採り得る。
「請求項22に記載の車輪制御方法であって、
前記複数の車輪のうち予め設定された閾値を上回る回転変動が検出されたモータに対応する車輪を前記対象車輪であると判定する、車輪制御方法。」
という態様(態様2)を採り得る。
「請求項21及び22、態様1のうちのいずれかに記載の車輪制御方法であって、
前記フィードバック制御に係るフィードバック量を前記対象車輪が前記路面入力を受ける前よりも低減するために、前記フィードバック量を第1のゲインから前記第1のゲインを下回る第2のゲインに変更する、車輪制御方法。」
という態様(態様3)を採り得る。
「態様3に記載の車輪制御方法であって、
前記第2のゲインを構成する比例ゲインがゼロに設定される、車輪制御方法。」
という態様(態様4)を採り得る。
「態様3に記載の車輪制御方法であって、
前記第2のゲインがゼロに設定される、車輪制御方法。」
という態様(態様5)を採り得る。
「態様3~5に記載の車輪制御方法であって、
前記フィードバック制御に係るフィードバック量を前記第1のゲインから前記第2のゲインに変更した後、所定時間経過後に再び前記第2のゲインから前記第1のゲインに戻す、車輪制御方法。」
という態様(態様6)を採り得る。
「態様6に記載の車輪制御方法であって、
前記フィードバック量を前記第2のゲインから前記第1のゲインに戻すのに要する時間が前記フィードバック量を前記第1のゲインから前記第2のゲインに変更するのに要する時間を上回るようにモータ制御を行う、車輪制御方法。」
という態様(態様7)を採り得る。
「請求項21及び22、態様1及び2のうちのいずれかに記載の車輪制御方法であって、
前記フィードバック制御に係るフィードバック量を前記対象車輪が前記路面入力を受ける前よりも低減するために、前記フィードバック量のうち所定の高周波数帯のフィードバック量を前記路面入力の振幅に応じて低減する、車輪制御方法。」
という態様(態様8)を採り得る。
「請求項21及び22、態様1~8のうちのいずれかに記載の車輪制御方法であって、
前記フィードバック量の低減によって生じるトルク誤差分を、当該低減に係るモータ以外の別モータの目標トルクに割り振り、割り振り後の目標トルクにしたがって前記別モータをフィードバック制御する、車輪制御方法。」
という態様(態様9)を採り得る。
「態様9に記載の車輪制御方法であって、
前記別モータの目標トルクに対する前記トルク誤差分の割り振りに要する時間が前記フィードバック量の低減に要する時間を上回るようにモータ制御を行う、車輪制御方法。」
という態様(態様10)を採り得る。
「態様9又は10に記載の車輪制御方法であって、
前記トルク誤差は、前記フィードバック量の低減によって生じる駆動トルクの所定の低周波数成分である、車輪制御方法。」
という態様(態様11)を採り得る。
「請求項22及び22、態様1から11のうちのいずれかに記載の車輪制御方法であって、
前記フィードバック制御に係るフィードバック量を低減する前に、前記目標トルクを当該目標トルクと前記モータの駆動トルクの正負が逆転するトルクゼロ領域との差が大きくなるようにオフセットする、車輪制御方法。」
という態様(態様12)を採り得る。
「態様12に記載の車輪制御方法であって、
前記目標トルクのオフセットによって生じるトルク変更分を、当該オフセットに係る前記モータ以外の別モータの目標トルクに割り振り、割り振り後の目標トルクにしたがって前記別モータをフィードバック制御する、車輪制御方法。」
という態様(態様13)を採り得る。
「態様12又は13に記載の車輪制御方法であって、
前記路面入力に係る走行路面を前記複数の車輪のうちの前輪が通過してから後輪が通過するまでの時間を、前記オフセットを保持する保持時間に設定する、車輪制御方法。」
という態様(態様14)を採り得る。
「態様13に記載の車輪制御方法であって
前記オフセットによって前記複数の車輪のうち前輪及び後輪のいずれか一方に駆動方向のトルクが生じ、且つ前記前輪及び前記後輪の他方に前記駆動方向と反対方向である制動方向のトルクが生じた均衡状態が形成された場合、この均衡状態を一定時間保持する、車輪制御方法。」
という態様(態様15)を採り得る。
「態様13に記載の車輪制御方法であって、
前記別モータの目標トルクに対する前記トルク変更分の割り振りに要する時間が前記オフセットに要する時間を上回るようにモータ制御を行う、車輪制御方法。」
という態様(態様16)を採り得る。
「態様16に記載の車輪制御方法であって、
初期状態から前記オフセットの後に前記トルク変更分の割り振り後の目標トルクにしたがって前記別モータをフィードバック制御する制御状態を形成し、更に前記初期状態に戻す場合、前記初期状態から前記制御状態に移行するのに要する時間を、前記制御状態から前記初期状態に移行するのに要する時間が上回るようにモータ制御を行う、車輪制御方法。」
という態様(態様17)を採り得る。
Claims (22)
- 車両に設けられた複数の車輪を制御する車輪制御装置であって、
前記複数の車輪のそれぞれを駆動するために各車輪に設けられたモータの駆動トルクが目標トルクに追従するように当該モータをフィードバック制御する制御部と、を備え、
前記制御部は、前記複数の車輪のうち所定の路面入力を受けた対象車輪を駆動するモータについて、前記フィードバック制御に係るフィードバック量を前記対象車輪が前記路面入力を受ける前よりも低減する、車輪制御装置。 - 請求項1に記載の車輪制御装置であって、
前記複数の車輪のそれぞれが前記路面入力を受けたときの変動情報を検出可能な情報検出部を備え、
前記制御部は、前記情報検出部が検出した変動情報から前記対象車輪を特定し、前記対象車輪が前記路面入力を受けたときに前記フィードバック制御に係るフィードバック量を当該対象車輪が前記路面入力を受ける前よりも低減する、車輪制御装置。 - 請求項2に記載の車輪制御装置であって、
前記情報検出部は、前記車両のばね下領域に作用するばね下加速度を検出するために前記複数の車輪のそれぞれに設けられた加速度センサを含み、
前記制御部は、前記加速度センサによって予め設定された閾値を上回るばね下加速度が検出された車輪を前記対象車輪であると判定する、車輪制御装置。 - 請求項2に記載の車輪制御装置であって、
前記情報検出部は、前記モータの回転変動を検出するためのモータ回転センサを含み、
前記制御部は、前記モータ回転センサによって予め設定された閾値を上回る回転変動が検出されたモータに対応する車輪を前記対象車輪であると判定する、車輪制御装置。 - 請求項1~4のうちのいずれか一項に記載の車輪制御装置であって、
前記制御部は、前記フィードバック制御に係るフィードバック量を前記対象車輪が前記路面入力を受ける前よりも低減するために、前記フィードバック量を第1のゲインから前記第1のゲインを下回る第2のゲインに変更する、車輪制御装置。 - 請求項5に記載の車輪制御装置であって、
前記第2のゲインを構成する比例ゲインがゼロである、車輪制御装置。 - 請求項5に記載の車輪制御装置であって、
前記第2のゲインがゼロである、車輪制御装置。 - 請求項5~7のうちのいずれか一項に記載の車輪制御装置であって、
前記制御部は、前記フィードバック制御に係るフィードバック量を前記第1のゲインから前記第2のゲインに変更した後、所定時間経過後に再び前記第2のゲインから前記第1のゲインに戻す、車輪制御装置。 - 請求項8に記載の車輪制御装置であって、
前記制御部は、前記フィードバック量を前記第2のゲインから前記第1のゲインに戻すのに要する時間が前記フィードバック量を前記第1のゲインから前記第2のゲインに変更するのに要する時間を上回るようにモータ制御を行う、車輪制御装置。 - 請求項1~4のうちのいずれか一項に記載の車輪制御装置であって、
前記制御部は、前記フィードバック制御に係るフィードバック量を前記対象車輪が前記路面入力を受ける前よりも低減するために、前記フィードバック量のうち所定の高周波数帯のフィードバック量を前記路面入力の振幅に応じて低減する、車輪制御装置。 - 請求項1~10のうちのいずれか一項に記載の車輪制御装置であって、
前記制御部は、前記フィードバック量の低減によって生じるトルク誤差分を、当該低減に係るモータ以外の別モータの目標トルクに割り振り、割り振り後の目標トルクにしたがって前記別モータをフィードバック制御する、車輪制御装置。 - 請求項11に記載の車輪制御装置であって、
前記制御部は、前記別モータの目標トルクに対する前記トルク誤差分の割り振りに要する時間が前記フィードバック量の低減に要する時間を上回るようにモータ制御を行う、車輪制御装置。 - 請求項11又は12に記載の車輪制御装置であって、
前記トルク誤差は、前記フィードバック量の低減によって生じる駆動トルクの所定の低周波数成分である、車輪制御装置。 - 請求項1~13のうちのいずれか一項に記載の車輪制御装置であって、
前記制御部は、前記フィードバック制御に係るフィードバック量を低減する前に、前記目標トルクを当該目標トルクと前記モータの駆動トルクの正負が逆転するトルクゼロ領域との差が大きくなるようにオフセットする、車輪制御装置。 - 請求項14に記載の車輪制御装置であって、
前記制御部は、前記目標トルクのオフセットによって生じるトルク変更分を、当該オフセットに係る前記モータ以外の別モータの目標トルクに割り振り、割り振り後の目標トルクにしたがって前記別モータをフィードバック制御する、車輪制御装置。 - 請求項14又は15に記載の車輪制御装置であって、
前記制御部は、前記路面入力に係る走行路面を前記複数の車輪のうちの前輪が通過してから後輪が通過するまでの時間を、前記オフセットを保持する保持時間に設定する、車輪制御装置。 - 請求項15に記載の車輪制御装置であって、
前記制御部は、前記オフセットによって前記複数の車輪のうち前輪及び後輪のいずれか一方に駆動方向のトルクが生じ、且つ前記前輪及び前記後輪の他方に前記駆動方向と反対方向である制動方向のトルクが生じた均衡状態が形成された場合、この均衡状態を一定時間保持する、車輪制御装置。 - 請求項15に記載の車輪制御装置であって、
前記制御部は、前記別モータの目標トルクに対する前記トルク変更分の割り振りに要する時間が前記オフセットに要する時間を上回るようにモータ制御を行う、車輪制御装置。 - 請求項18に記載の車輪制御装置であって、
前記制御部は、初期状態から前記オフセットの後に前記トルク変更分の割り振り後の目標トルクにしたがって前記別モータをフィードバック制御する制御状態を形成し、更に前記初期状態に戻す場合、前記初期状態から前記制御状態に移行するのに要する時間を、前記制御状態から前記初期状態に移行するのに要する時間が上回るようにモータ制御を行う、車輪制御装置。 - 複数の車輪と、
前記複数の車輪のそれぞれを駆動するために各車輪に設けられたモータと、
前記モータを制御する制御装置と、
を含み、
前記制御装置は、請求項1~19のうちのいずれか一項に記載の車輪制御装置によって構成されている車両。 - 車両に設けられた複数の車輪を制御する車輪制御方法であって、
前記複数の車輪のそれぞれを駆動するために各車輪に設けられたモータについて、当該モータの駆動トルクが目標トルクに追従するように当該モータをフィードバック制御する一方で、前記複数の車輪のうち所定の路面入力を受けた対象車輪を駆動するモータについて、前記フィードバック制御に係るフィードバック量を前記対象車輪が前記路面入力を受ける前よりも低減する、車輪制御方法。 - 請求項21に記載の車輪制御方法であって、
前記複数の車輪のそれぞれが前記路面入力を受けたときの変動情報を検出し、検出した前記変動情報から前記対象車輪を特定し、前記対象車輪が前記路面入力を受けたときに前記フィードバック制御に係るフィードバック量を当該対象車輪が前記路面入力を受ける前よりも低減する、車輪制御方法。
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US14/428,423 US9475404B2 (en) | 2012-10-10 | 2012-10-10 | Wheel control device, vehicle, wheel control method |
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PL3208380T3 (pl) * | 2016-02-17 | 2022-01-17 | Joseph Vögele AG | Sposób sterowania układarką z podwoziem kołowym i układarka z podwoziem kołowym |
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