JP5985724B2 - Electric car - Google Patents

Description

  The present invention relates to an electric vehicle to be an in-wheel motor vehicle such as a battery drive or a fuel cell drive equipped with a motor for driving wheels.

  In an electric vehicle, an IPM type motor (an embedded magnet type synchronous motor) is often used in order to improve a cruising distance under a limited battery capacity. The feature of this motor is that the regenerative brake can be easily applied. When the cruising distance is important, the regenerative brake should be used as much as possible.

JP 2010-32038 A

Since the regenerative brake directly brakes the wheel, the tire may slip when applied excessively compared to the friction brake, and an appropriate usage is a problem. In particular, in the in-wheel motor drive device, the braking torque is directly transmitted to each wheel, so that torque distribution between other wheels cannot be performed, and therefore it is necessary to avoid tire slip as much as possible.
It is possible to control the regenerative brake distribution between the mechanical brake and the regenerative brake from the detected values of the motor drive torque and wheel rotation speed in order to use the regenerative brake appropriately so that slip does not occur. is there. However, there are many cases where the wheels are momentarily floating with respect to the road surface during traveling, and the friction coefficient between the tire and the road surface changes depending on the road surface condition. For this reason, it is difficult to appropriately control the regenerative brake only by the detected values of the motor driving torque and the wheel rotational speed.

  An object of the present invention is to provide an electric vehicle that uses a regenerative brake as much as possible and prevents tire slip due to excessive application of the regenerative brake.

The electric vehicle of the reference proposal example includes a motor 6 that drives the wheel 2, a motor control unit 29 that controls the motor 6, and a regenerative braking force applied to the wheel 2 by power generation of the motor 6 provided in the motor control unit 29. In an electric vehicle provided with a regenerative brake 34 that gives a mechanical force and a mechanical brake 9 that mechanically gives a braking force to the wheel 2,
The wheel bearing 4 that supports the wheel 2 is provided with a load sensor 41 that detects a load in the vehicle traveling direction acting between the road surface and the tire, and when the output of the load sensor 41 reaches a set value, the regeneration is performed. A load corresponding regenerative brake limiting means 36 for reducing the braking torque of the brake 34 is provided.

  According to this configuration, the load corresponding regenerative brake limiting means 36 reduces the braking torque of the regenerative brake 34 when the load in the vehicle traveling direction acting between the road surface and the tire reaches a set value. As described above, since the braking torque of the regenerative brake 34 is reduced according to the load acting between the road surface and the tire, slipping of the tire due to excessive application of the regenerative brake 34 can be prevented. In particular, since the dominant of the regenerative brake 34 is limited in accordance with the load between the road surface and the tire that is actually acting, the difference in the road surface state is different from the case where the driving torque of the motor 6 or the detected value of the wheel rotation speed is limited. Appropriate control can be quickly performed on the lift of the tires from the road surface. Therefore, even if the regenerative brake 34 is used as much as possible, tire slip due to excessive application of the regenerative brake 34 can be prevented.

The load corresponding regenerative brake limiting means 36, after the output of the load sensor 41 reaches a set value and reduces the braking torque of the regenerative brake 34, the output value of the load sensor 41 is lower than the set value. When it becomes below, it is good to cancel the control which reduces the braking torque of the regenerative brake 34.
When the traveling load between the road surface and the tire decreases, it is not necessary to reduce the braking torque by the regenerative brake 34. By canceling the control to reduce the energy, the regenerative brake 34 can be used as much as possible to recover the energy.

The electric vehicle according to the present invention includes a motor 6 for driving the wheel 2, a motor control unit 29 for controlling the motor 6, and a regenerative braking force applied to the wheel 2 by the power generation of the motor 6 provided in the motor control unit 29. In an electric vehicle including a regenerative brake 34 to be applied and a mechanical brake 9 to mechanically apply a braking force to the wheel 2,
The motor control unit 29
Means 36 for reducing braking torque in the regenerative brake for preventing tire slip due to excessive application of the regenerative brake;
When a regenerative braking torque command is given from the brake operating means 17 to the motor control unit 29 via the ECU 21 which is an electric control unit for controlling the vehicle as a whole, the rotational speed of the wheel 2 and the battery are determined according to a predetermined rule. The maximum possible regenerative braking torque of the regenerative brake 34 is calculated from the state of charge 19 and if the maximum possible regenerative braking torque is less than the regenerative braking torque command, the braking of the regenerative brake 34 with respect to the regenerative braking torque command Maximum actuating means 35 for actuating the torque to the maximum,
Means 36 to reduce the braking torque in the regenerative braking, when a load acting between the road surface-tire has reached the set value, in preference to the control of pre-Symbol maximum operating means 35 reduces the braking torque of the regenerative brake 34 Create a function.
The regenerative brake 34 cannot perform braking effectively when the charge rate of the battery 19 is high or the remaining capacity is low, but the maximum operating means 35 calculates the maximum possible regenerative braking torque, The braking torque of the regenerative brake 34 is operated to the maximum within the range. For this reason, the regenerative brake 34 can be used as much as possible without causing the problem of insufficient braking torque due to the regenerative brake 34. In this way, while monitoring the charging state of the battery 19, the regenerative brake 34 is used as much as possible, and further, slip prevention due to excessive use of the regenerative brake 34 by means 36 for reducing the braking torque in the regenerative brake is performed. Therefore, the use of the regenerative brake 34 can be further enhanced while ensuring slip prevention.

In the present invention the regeneration, the motor control unit 29, reporting means 37 reports the value of the regenerative braking torque the regenerative brake 34 functions to the ECU 21 is set vignetting, the ECU 21, which has been reported from the reporting means 37 the value of the braking torque and the motor control unit 29 the braking torque as a differential mechanical braking force distribution means 38 which causes applied to the brake 9 of the regenerative braking torque command given to the good to be kicked set.
When the regenerative torque is reduced by the load corresponding regenerative brake limiting means 36, or when the regenerative brake 34 cannot obtain the regenerative braking torque of the regenerative torque command from the maximum possible regenerative braking torque calculated by the maximum operating means 35. Can appropriately perform various controls by the ECU 21 by reporting to the ECU 21 which is an electric control unit for controlling the entire vehicle. In particular, even if the regenerative braking torque is reduced by applying a braking torque that is a difference between the reduced regenerative braking torque value and the regenerative braking torque command to the mechanical brake 9 by the braking force distribution means 38, Total braking torque can be secured.

In the present invention, the load sensor 41 has a function of detecting the load in the vehicle width direction acting between the road surface and the tire in addition to the load in the vehicle traveling direction, and the load corresponding regenerative brake limiting means 36 is The braking torque of the regenerative brake 34 is reduced when the value calculated by the setting rule reaches the set value from the load in the vehicle traveling direction and the load in the vehicle width direction output from the load sensor 41. Also good.
When the vehicle travels on a curved road, the load between the road surface and the tire in the vehicle traveling direction on the left and right wheels 2 is different, and a load in the vehicle width direction acts between the road surface and the tire. For this reason, the regenerative brake 34 is more surely possible as much as possible by determining whether the regenerative braking torque can be reduced by the load corresponding regenerative brake limiting means 36 using both the load in the vehicle width direction and the load in the vehicle traveling direction. And slipping of the tire due to excessive application of the regenerative brake 34 can be prevented.

In the present invention, the motor 6 may be partly or wholly disposed in the wheel 2 to constitute the in-wheel motor drive device 8 including the motor 6 and the wheel bearing 4. The in-wheel motor drive device 8 may include a speed reducer 7 that decelerates the rotation of the motor 6 and transmits it to the wheels.
In the in-wheel motor drive device 8, since the braking torque of the regenerative brake 34 is directly transmitted to the wheels 2, torque distribution between the other wheels 2 and 3 cannot be performed, and therefore tire slip is avoided as much as possible. is necessary. Therefore, the effect of preventing slip according to the present invention is even more effective.

When the in-wheel motor driving device 8 is used, the inverter device 22 and the in-wheel motor driving device 8 constitute an in-wheel motor unit 30, and the inverter device 22 includes the motor control unit 29 and the motor control unit. The power control unit 29 may include a power circuit unit 28 that controls the motor 6 to pass a drive current, and the motor control unit 29 may be provided with the load corresponding regenerative brake limiting unit 36.
Thus, by providing the load corresponding regenerative brake limiting means 36 in the motor control unit 29 of the inverter device 22 provided in the in-wheel motor unit 30, the configuration and control of the ECU 21 that controls the entire vehicle can be simplified. For example, even when a design change or the like of the in-wheel motor drive device 8 is performed, the design change of the ECU 21 is not necessary or can be made small.

The electric vehicle according to the present invention includes a motor for driving a wheel, a motor control unit for controlling the motor, a regenerative brake that is provided in the motor control unit and applies a regenerative braking force to the wheel by power generation of the motor, and the wheel In the electric vehicle including a mechanical brake that mechanically applies a braking force to the motor, the motor control unit is configured to reduce braking torque in the regenerative brake for preventing tire slip due to excessive application of the regenerative brake; When the regenerative braking torque command is given from the brake operation means to the motor control unit via the ECU which is an electric control unit for controlling the entire vehicle, the wheel rotation speed and the battery charge are determined according to the defined rules. Calculate the maximum possible regenerative braking torque of the regenerative brake from the state If the large regenerative braking torque is less than the regenerative braking torque command, the regenerative braking torque command includes maximum operating means for maximizing the braking torque of the regenerative brake to reduce the braking torque in the regenerative brake. I mean, when a load acting between the road surface-tire has reached a set value, to produce a function to reduce the braking torque of the regenerative braking in preference to the control of pre-Symbol maximum operating means, regenerative whenever possible brake And slipping of the tire due to excessive application of the regenerative brake can be prevented.

1 is a block diagram of a conceptual configuration showing an electric vehicle according to an embodiment of the present invention in a plan view. It is a block diagram which shows the conceptual structure of the in-wheel motor unit of the same electric vehicle. It is a flowchart which shows the process of control of the braking force distribution of ECU in the same electric vehicle, and the control of the regenerative brake by an in-wheel motor unit. It is a graph which shows the relationship between the battery chargeable amount of the same electric vehicle, regenerative braking torque, and mechanical braking torque. It is a fracture front view of the in-wheel motor drive device in the electric vehicle. FIG. 6 is a sectional view taken along line VI-VI in FIG. It is a partial expanded sectional view of FIG. It is the figure which combined the side view of the outer member of the wheel bearing in the same electric vehicle, and the signal processing unit for load detection. It is an enlarged plan view of a sensor unit in the electric vehicle. It is sectional drawing of the sensor unit. It is sectional drawing of an example of the rotation detector in the same electric vehicle.

  An embodiment of the present invention will be described with reference to FIGS. This electric vehicle is a four-wheeled vehicle in which the wheels 2 that are the left and right rear wheels of the vehicle body 1 are driving wheels, and the wheels 3 that are the left and right front wheels are steering wheels of driven wheels. Each of the wheels 2 and 3 serving as the driving wheel and the driven wheel has a tire and is supported by the vehicle body 1 via wheel bearings 4 and 5, respectively. The wheel bearings 4 and 5 are given the abbreviation “H / B” of the hub bearing in FIG. The left and right wheels 2, 2 serving as driving wheels are driven by independent traveling motors 6, 6, respectively. The rotation of the motor 6 is transmitted to the wheel 2 via the speed reducer 7 and the wheel bearing 4. The motor 6, the speed reducer 7, and the wheel bearing 4 constitute an in-wheel motor driving device 8 that is one assembly part, and the in-wheel motor driving device 8 is partially or entirely inside the wheel 2. Placed in. The motor 6 may directly rotate and drive the wheels 2 without using the speed reducer 7. Each in-wheel motor drive device 8 constitutes an in-wheel motor unit 30 together with an inverter device 22 described later. Each wheel 2 and 3 is provided with mechanical brakes 9 and 10 which are friction brakes such as electric type.

  The wheels 3 and 3 that are the steering wheels that are the left and right front wheels can be steered via the steering mechanism 11 and are steered by the steering mechanism 12. The steering mechanism 11 is a mechanism that changes the angle of the left and right knuckle arms 11b that hold the wheel bearings 5 by moving the tie rods 11a to the left and right. The EPS (electric power steering) motor 13 converts rotational and linear motions. It can be moved left and right via a mechanism (not shown). The steering mechanism 12 detects a steering angle of a steering wheel 14 that is not mechanically connected to the tie rod 11a by a steering angle sensor 15, and a steering command that gives a driving command to the EPS motor 13 by a turning command that is the detected steering angle. It is a by-wire type.

  The control system will be described. A main ECU 21 that is an electric control unit that controls the entire vehicle, an inverter device 22 that controls the driving motor 6 in accordance with a command from the ECU 21, and a brake controller 23 are mounted on the vehicle body 1. The ECU 21 includes a computer, a program executed by the computer, various electronic circuits, and the like.

  The ECU 21 is roughly divided into a drive control unit 21a and a general control unit 21b when classified roughly by function. The drive control unit 21a gives the left and right wheel motors 6 and 6 the acceleration command output from the accelerator operation unit 16, the deceleration command output from the brake operation unit 17, and the turning command output from the steering angle sensor 15. The given acceleration / deceleration command is generated and output to the inverter device 22. In addition to the above, the drive control unit 21a outputs an acceleration / deceleration command to be output, information on the tire rotation speed obtained from the rotation sensor 24 provided on the wheel bearings 4 and 5 of the wheels 2 and 3, You may have the function to correct | amend using the information of each sensor. The accelerator operation unit 16 includes an accelerator pedal and a sensor 16a that detects the amount of depression and outputs the acceleration command. The brake operation unit 17 includes a brake pedal and a sensor 17a that detects the amount of depression and outputs the deceleration command.

  The general control unit 21b of the ECU 21 has a function of controlling various auxiliary machine systems 25, a function of processing input commands from the console operation panel 26, a function of displaying on the display means 27, and the like. The auxiliary machine system 25 is, for example, an air conditioner, a light, a wiper, a GPS, an airbag or the like, and is shown here as a representative block.

  The brake controller 23 is a means for giving a braking command to the mechanical brakes 9 and 10 of the wheels 2 and 3 in accordance with a braking command output from the ECU 21, and is constituted by an electronic circuit, a microcomputer, or the like serving as an ECU dedicated to braking. The The braking command output from the main ECU 21 includes a command generated by means for improving the safety of the ECU 21 in addition to a command generated by a deceleration command output from the brake operation unit 17. In addition, the brake controller 23 includes an antilock brake system.

The inverter device 22 includes a power circuit unit 28 provided for each motor 6 and a motor control unit 29 that controls the power circuit unit 28. The motor control unit 29 may be provided in common for each power circuit unit 28 or may be provided separately, but even if provided in common, each power circuit unit 28. For example, can be controlled independently so that the motor torque is different from each other. The motor control unit 29 has a function of outputting information (referred to as “IWM system information”) such as detection values and control values related to the in-wheel motor 8 of the motor control unit 29 to the ECU 21.
In this embodiment, the motor control unit 29 is provided separately for each power circuit unit 28, and includes an inverter device 22 composed of the power circuit unit 28 and the motor control unit 29, and the motor 6 to be controlled. The in-wheel motor drive device 8 constitutes the in-wheel motor unit 30 as described above.

  FIG. 2 is a block diagram showing a conceptual configuration of the in-wheel motor unit 30. The power circuit unit 28 of the inverter device 22 includes an inverter 31 that converts the DC power of the battery 19 into three-phase AC power used for driving the motor 6, and a PWM driver 32 that controls the inverter 31. The motor 6 is a three-phase synchronous motor, for example, an IPM type (embedded magnet type) synchronous motor or the like. The inverter 31 is composed of a plurality of semiconductor switching elements (not shown), and the PWM driver 32 performs pulse width modulation on the input current command and gives an on / off command to each of the semiconductor switching elements.

  The motor control unit 29 includes a computer, a program executed on the computer, and an electronic circuit, and includes a basic drive control unit 33 as a basic control unit. The basic drive control unit 33 is a unit that converts the current command into a current command in accordance with an acceleration / deceleration command by a torque command or the like given from the ECU 21 that is the host control unit, and gives the current command to the PWM driver 32 of the power circuit unit 28. The basic drive control unit 33 obtains a motor current value flowing from the inverter 31 to the motor 6 from the current detection means 39, and performs current feedback control. The motor drive control unit 33 obtains the rotation angle of the rotor of the motor 6 from the angle sensor 42 and performs control according to the rotation angle such as vector control.

  In this embodiment, the motor control unit 29 is provided with the next regenerative brake 34, the maximum operating means 35, the load corresponding regenerative brake limiting means 36, and the reporting means 37, and the ECU 21 is provided with the braking force distribution means 38.

  The regenerative brake 34 is a means for applying a regenerative braking force to the wheels 2 by the power generation of the motor 6. The regenerative brake 34 outputs a drive torque output by the basic drive control unit 33 in accordance with a regenerative braking torque command given from the braking force distribution means 38 of the ECU 21. Control to reduce. The regenerative brake 34 has a function of charging the battery 19 with the electric power generated by the motor 6 via the inverter 31.

  The maximum actuating means 35, when a regenerative braking torque command is given from the brake operating means 17 to the motor control section 29 via the braking force distributing means 38 of the ECU 21, follows the rules determined by mathematical formulas and the like. The maximum possible regenerative braking torque of the regenerative brake 34 is calculated from the rotational speed and the state of charge of the battery 19, and if the maximum possible regenerative braking torque is less than the regenerative braking torque command, the regenerative braking is performed with respect to the regenerative braking torque command. 34 is a means for operating the braking torque of 34 to the maximum. In the maximum actuating means 35, the rotation speed of the wheel 2 is recognized using, for example, the output of the rotation sensor 24 provided in the wheel bearing 4, and the state of charge of the battery 19 is the state of charge provided in the battery 19. Recognizing by the output of a detection means (not shown). The state of charge of the battery 19 here may be the charge rate or the remaining chargeable capacity.

Load corresponding regenerative brake limiting means 36, when it is detected by the load sensor 41, the value of the load F _x in the vehicle traveling direction acting between the road surface-tire reaches a set value for the limit, the braking of the regenerative brake 34 It is a means to reduce torque. The load corresponding regenerative brake limiting means 36 has a function of reducing the braking torque of the regenerative brake 34 in preference to the control of the maximum operating means 35. Further, the load corresponding regenerative brake limiting means 36 reaches the set value for return lower than the set value after the output of the load sensor 41 reaches the set value for limit and reduces the braking torque of the regenerative brake 34. When this is done, the control to reduce the braking torque of the regenerative brake 34 is released.
The set value and the extent to which the braking torque of the regenerative brake 34 is reduced are set by appropriately considering through simulation or the like. The load sensor 41 is provided in the wheel bearing 4 as will be described later with a specific example.

Load corresponding regenerative brake limiting means 36, in addition to the control corresponding to the load F _x of the vehicle traveling direction to the output of the load sensor 41, a load F of the load F _x in the vehicle width direction of the vehicle traveling direction to the output of the load sensor 41 _{From y} , when the value calculated by the setting rule reaches the set value, the braking torque of the regenerative brake may be reduced. In this case, the load sensor 41, in addition to the load F _x in the vehicle traveling direction, or to have a function of detecting a load F _y in the vehicle width direction acting between the road surface-tire or the load in the vehicle width direction, provide another load sensor (not shown) for detecting the F _y.

  The reporting unit 37 is a unit that reports the value of the regenerative braking torque at which the regenerative brake 34 functions to the ECU 21.

The braking force distribution means 38 of the ECU 21 distributes a total braking torque command given as a deceleration command from the brake operation means 17 into a regenerative braking torque command by the regenerative brake 34 and a braking torque command for the mechanical brakes 9 and 10. Means.
The braking force distribution means 38 gives the mechanical brakes 9 and 10 a braking torque that is a difference between the value of the regenerative braking torque reported from the reporting means 37 and the regenerative braking torque command given to the motor control unit 29. Control to add to braking torque. A braking torque command applied to the mechanical brakes 9 and 10 by the braking force distribution means 38 is applied to the mechanical brakes 9 and 10 via the brake controller 23.

Next, the braking operation by the above configuration and the details of the functions of the respective means 35 to 38 will be described.
3A shows the control of the braking force distribution means 38 of the ECU 21, and FIG. 3B shows the control of the maximum operating means 35 and the load corresponding regenerative brake limiting means 36.
In FIG. 3A, when the deceleration command of the brake operation means 17 is input to the ECU 21 as a braking torque command (step S1), the braking force distribution means 38 sends the braking torque command to the motors 6 of the motors 6 of each wheel 2. It distributes and outputs to the control part 9 (S2). At this time, the braking force distribution means 38 outputs all the braking torque commands of the brake operating means 17 as regenerative braking torque commands in the case of a braking torque within a predetermined normal range excluding sudden braking or the like, and the mechanical brake 9 , 10 is not given a braking torque command.
Thereafter, the braking force distribution means 38 waits for a report from the reporting means 37 of each regenerative brake 34 (S3).

  When the regenerative braking torque command from the braking force distribution means 38 is input to the maximum operating means 35 of the motor control unit 29 (step R1 in FIG. 3 (B)), from the rotation speed of the wheel 2 and the charged state of the battery 19, The maximum possible regenerative braking torque of the regenerative brake 34 is calculated (R2). This calculation is performed in accordance with rules defined by mathematical formulas.

As shown in FIG. 4, the maximum possible regenerative braking torque τ _BRM increases in proportion to the battery chargeable amount when the battery chargeable amount exceeds a certain level.
After this calculation, the maximum operating means 35 compares the maximum possible regenerative braking torque τ _BRM with the regenerative braking torque command τ _BRO (R3), and if the maximum possible regenerative braking torque τ _BRM is less than the regenerative braking torque command τ _BRO. For example, the braking torque of the regenerative brake 34 is operated to the maximum with respect to the regenerative braking torque command τ _BRO (R4). The shortage causes the mechanical brakes 2 and 3 to operate. That is, the necessary braking torque τ _BR is shared by the regenerative braking torque τ _BR and the braking torque τ _BRS of the mechanical brakes 2 and 3.
Possible if the maximum regenerative braking torque tau _BRM regenerative braking torque command tau _BRO above, to generate a regenerative braking torque of the regenerative braking torque command tau _BRO content by the regenerative brake 34 (R5).

Further, the load corresponding regenerative braking limiting means 36, the regenerative braking torque command to the motor control unit 29 is input, is detected by the load sensor 41, the value of the load F _x in the vehicle traveling direction acting between the road surface-tire comparing the set value for limiting a, when a load F _x in the vehicle traveling direction has reached the set value, it reduces the braking torque of the regenerative brake 34 (R6). The control for reducing the braking torque is performed with priority over the control of the maximum operating means 35.
Thereafter, the reporting means 37 reports the value of the regenerative braking torque at which the regenerative brake 34 functions to the ECU 21 (R7).

  The braking force distribution means 38 of the ECU 21 is mechanically connected via a brake controller 23 to a braking torque that is a difference between the value of the regenerative braking torque reported from the reporting means 37 and the regenerative braking torque command given to the motor control unit 29. The brakes 9 and 10 are given (S4). In principle, the brake controller 23 controls the mechanical brake 9 of the wheel 2 to which the regenerative braking torque has been reduced so as to apply the reduced braking torque to the mechanical brake 9 of the wheel 2. The braking torque corresponding to the reduced regenerative braking torque may be distributed.

  Although not shown in the flowchart of FIG. 3, the load corresponding regenerative brake limiting unit 36 reduces the braking torque of the regenerative brake 34 after the output of the load sensor 41 reaches the limit setting value. When the output of 41 becomes lower than the set value for return lower than the set value, the control for reducing the braking torque of the regenerative brake 34 is released.

According to the electric vehicle having this configuration, as described above, the braking torque of the regenerative brake 34 is reduced in accordance with the load acting between the road surface and the tire, so that tire slip due to excessive application of the regenerative brake 34 can be prevented. . In particular, since the dominant of the regenerative brake 34 is limited in accordance with the load between the road surface and the tire that is actually acting, the difference in the road surface state is different from the case where the driving torque of the motor 6 or the detected value of the wheel rotation speed is limited. Appropriate control can be quickly performed on the lift of the tires from the road surface. Therefore, even if the regenerative brake 34 is used as much as possible, tire slip due to excessive application of the regenerative brake 34 can be prevented.
In this embodiment, the present invention is applied to the in-wheel motor drive device 8. In the in-wheel motor drive device 8, since the braking torque is directly transmitted to each wheel 2, the torque between the other wheels 2 and 3. Distribution is not possible, so it is necessary to avoid tire slip as much as possible. For this reason, the slip prevention action by providing the load corresponding regenerative brake limiting means 36 is more effective.

  Further, the load corresponding regenerative brake limiting means 36, after the output of the load sensor 41 reaches the set value and reduces the braking torque of the regenerative brake 34, the set value for return whose output of the load sensor 41 is lower than the set value. When it becomes below, the control which reduces the braking torque of the said regenerative brake is cancelled | released. When the traveling load between the road surface and the tire decreases, it is not necessary to reduce the braking torque by the regenerative brake 34. By canceling the control to reduce the energy, the regenerative brake can be used as much as possible to recover the energy.

Further, the maximum effect means 35 provides the following effects. The regenerative brake 34 cannot perform braking effectively when the charge rate of the battery 19 is high or the remaining capacity is low, but the maximum operating means 35 calculates the maximum possible regenerative braking torque τ _BRM , The braking torque of the regenerative brake 34 is operated to the maximum within the range. For this reason, the regenerative brake 34 can be used as much as possible without causing the problem of insufficient braking torque due to the regenerative brake 34. As described above, the regenerative brake 34 is used as much as possible while monitoring the charging state of the battery, and further, slip prevention due to excessive use of the regenerative brake 36 by the load-compatible regenerative brake limiting means 36 is performed. The use of the regenerative brake can be further enhanced while ensuring the reliability.

  Next, a specific example of the in-wheel motor drive device 8 will be shown together with FIGS. The in-wheel motor drive device 8 includes a reduction gear 7 interposed between a wheel bearing 4 and a motor 6, and a hub of the wheel 2 that is a drive wheel supported by the wheel bearing 4 and a rotation output shaft of the motor 6. 74 are connected on the same axis. The speed reducer 7 is a cycloid speed reducer, in which eccentric portions 82a and 82b are formed on a rotational input shaft 82 that is coaxially connected to a rotational output shaft 74 of the motor 6, and bearings 85 are respectively provided on the eccentric portions 82a and 82b. The curved plates 84a and 84b are mounted, and the eccentric motion of the curved plates 84a and 84b is transmitted to the wheel bearing 4 as rotational motion. In this specification, the side closer to the outer side in the vehicle width direction of the vehicle when attached to the vehicle is referred to as the outboard side, and the side closer to the center of the vehicle is referred to as the inboard side.

  The wheel bearing 4 includes an outer member 51 in which a double row rolling surface 53 is formed on the inner periphery, an inner member 52 in which a rolling surface 54 facing each of the rolling surfaces 53 is formed on the outer periphery, and these The outer member 51 and the inner member 52 are composed of double-row rolling elements 55 interposed between the rolling surfaces 53 and 54 of the inner member 52. The inner member 52 also serves as a hub for attaching the drive wheels. The wheel bearing 4 is a double-row angular ball bearing, and the rolling elements 55 are made of balls and are held by a cage 56 for each row. The rolling surfaces 53 and 54 have a circular arc cross section, and the rolling surfaces 53 and 54 are formed so that the contact angles are aligned with the back surface. An end on the outboard side of the bearing space between the outer member 51 and the inner member 52 is sealed with a seal member 57.

  The outer member 51 is a stationary raceway, has a flange 51a attached to the housing 83b on the outboard side of the speed reducer 7, and is formed as an integral part. The flange 51a is provided with bolt insertion holes 64 at a plurality of locations in the circumferential direction. Further, the housing 83b is provided with a bolt screw hole 94 whose inner periphery is threaded at a position corresponding to the bolt insertion hole 64. The outer member 51 is attached to the housing 83b by screwing the mounting bolt 65 inserted into the bolt insertion hole 94 into the bolt screwing hole 94.

  The inner member 52 is a rotating raceway, and the outboard side member 59 having a hub flange 59a for wheel mounting and the outboard side member 59 are fitted to the inner periphery of the outboard side member 59. The inboard side material 60 is integrated with the outboard side material 59 by fastening. In each of the outboard side material 59 and the inboard side material 60, the rolling surface 54 of each row is formed. A through hole 61 is provided in the center of the inboard side member 60. The hub flange 59a is provided with press-fit holes 67 for hub bolts 66 at a plurality of locations in the circumferential direction. In the vicinity of the base portion of the hub flange 59a of the outboard side member 59, a cylindrical pilot portion 63 that guides driving wheels and braking components (not shown) protrudes toward the outboard side. A cap 68 that closes the outboard side end of the through hole 61 is attached to the inner periphery of the pilot portion 63.

  As described above, the speed reducer 7 is a cycloid speed reducer, and two curved plates 84a and 84b formed with a wavy trochoid curve having a gentle outer shape as shown in FIG. The shaft 82 is attached to each eccentric part 82a, 82b. A plurality of outer pins 86 for guiding the eccentric movements of the curved plates 84a and 84b on the outer peripheral side are provided across the housing 83b, and a plurality of inner pins 88 attached to the inboard side member 60 of the inner member 2 are provided. The curved plates 84a and 84b are engaged with a plurality of circular through holes 89 provided in the inserted state. The rotation input shaft 82 is spline-coupled with the rotation output shaft 74 of the motor 6 and rotates integrally. The rotary input shaft 82 is supported at both ends by two bearings 90 on the inboard side housing 83a and the inner diameter surface of the inboard side member 60 of the inner member 52.

  When the rotation output shaft 74 of the motor 6 rotates, the curved plates 84a and 84b attached to the rotation input shaft 82 that rotates integrally therewith perform an eccentric motion. The eccentric motions of the curved plates 84 a and 84 b are transmitted to the inner member 52 as rotational motion by the engagement of the inner pins 88 and the through holes 89. The rotation of the inner member 52 is decelerated with respect to the rotation of the rotation output shaft 74. For example, a reduction ratio of 1/10 or more can be obtained with a single-stage cycloid reducer.

  The two curved plates 84a and 84b are attached to the eccentric portions 82a and 82b of the rotary input shaft 82 so as to cancel out the eccentric motion with each other, and are mounted on both sides of the eccentric portions 82a and 82b. A counterweight 91 that is eccentric in the direction opposite to the eccentric direction of the eccentric portions 82a and 82b is mounted so as to cancel the vibration caused by the eccentric movement of the curved plates 84a and 84b.

  As shown in an enlarged view in FIG. 7, bearings 92 and 93 are mounted on the outer pins 86 and the inner pins 88, and outer rings 92a and 93a of the bearings 92 and 93 are respectively connected to the curved plates 84a and 84b. It comes into rolling contact with the outer periphery and the inner periphery of each through-hole 89. Therefore, the contact resistance between the outer pin 86 and the outer periphery of each curved plate 84a, 84b and the contact resistance between the inner pin 88 and the inner periphery of each through hole 89 are reduced, and the eccentric motion of each curved plate 84a, 84b is smooth. Can be transmitted to the inner member 52 as a rotational motion.

  In FIG. 5, the motor 6 is a radial gap type IPM motor in which a radial gap is provided between a motor stator 73 fixed to a cylindrical motor housing 72 and a motor rotor 75 attached to the rotation output shaft 74. The rotation output shaft 74 is cantilevered by two bearings 76 on the cylindrical portion of the housing 83 a on the inboard side of the speed reducer 7.

  The motor stator 73 includes a stator core portion 77 and a coil 78 made of a soft magnetic material. The stator core portion 77 is held by the motor housing 72 with its outer peripheral surface fitted into the inner peripheral surface of the motor housing 72. The motor rotor 75 includes a rotor core portion 79 that is fitted on the rotation output shaft 74 concentrically with the motor stator 73, and a plurality of permanent magnets 80 that are built in the rotor core portion 79.

The motor 6 is provided with an angle sensor 42 that detects a relative rotation angle between the motor stator 73 and the motor rotor 75. The angle sensor 42 detects and outputs a signal representing a relative rotation angle between the motor stator 73 and the motor rotor 75, and an angle calculation circuit 71 that calculates an angle from the signal output from the angle sensor body 70. And have. The angle sensor main body 70 includes a detected portion 70a provided on the outer peripheral surface of the rotation output shaft 74, and a detecting portion 70b provided in the motor housing 72 and disposed in close proximity to the detected portion 70a, for example, in the radial direction. Become. The detected portion 70a and the detecting portion 70b may be arranged close to each other in the axial direction. Here, a magnetic encoder or a resolver is used as each angle sensor 42. The rotation control of the motor 6 is performed by the motor control unit 29 (FIGS. 1 and 2). In this motor 6, in order to maximize the efficiency, each phase of each wave of alternating current flowing through the coil 78 of the motor stator 73 based on the relative rotation angle between the motor stator 73 and the motor rotor 75 detected by the angle sensor 42. Is controlled by the motor drive control unit 33 of the motor control unit 29.
Note that the motor current wiring of the in-wheel motor driving device 8 and various sensor system and command system wiring are collectively performed by a connector 99 provided in the motor housing 72 or the like.

  The load sensor 24 illustrated in FIG. 2 includes, for example, a plurality of sensor units 120 illustrated in FIG. 8 and a signal processing unit 130 that processes output signals of these sensor units 120. The sensor unit 120 is provided at four locations on the outer diameter surface of the outer member 51 that is a stationary raceway in the wheel bearing 4. FIG. 8 shows a front view of the outer member 1 viewed from the outboard side. Here, these sensor units 120 are provided on the upper surface portion, the lower surface portion, the right surface portion, and the left surface portion of the outer diameter surface of the outer member 51 that is in the vertical position and the horizontal position with respect to the tire ground contact surface. The signal processing unit 130 may be provided on the outer member 51, or may be provided on the motor control unit 29 of the inverter device 22.

The signal processing unit 130 compares the outputs of the four sensor units 120 described above, and acts on each load acting on the wheel bearing 4, specifically, between the road surface of the wheel 2 and the tire according to a predetermined arithmetic expression. A straight direction load F _{z as} a load, a vehicle traveling direction load F _x as a driving force or a braking force, and an axial load F _y are calculated and output. Four sensor units 120 are provided, and each sensor unit 120 is provided on the upper surface portion, the lower surface portion, the right surface portion, and the left surface portion of the outer diameter surface of the outer member 51 that is in the vertical position and the horizontal position with respect to the tire ground contact surface. Since they are equally arranged with a phase difference of 90 degrees in the circumferential direction, the vertical load F _z , the vehicle traveling direction load F _x , and the axial load F _y acting on the wheel bearing 4 can be accurately estimated. The vertical load F _z is obtained by comparing the outputs of the two upper and lower sensor units 120, and the vehicle traveling direction load F _x is obtained by comparing the outputs of the two front and rear sensor units 120. The axial load F _y is obtained by comparing the outputs of the four sensor units 120. The calculation of the loads F _x , F _y , and F _z by the signal processing unit 130 can be performed with high accuracy by setting arithmetic expressions and parameters based on values obtained by tests and simulations. . More specifically, various corrections are performed for the above calculation, but the description of the correction is omitted.

  Each of the sensor units 120 is, for example, as shown in an enlarged plan view and an enlarged cross-sectional view in FIGS. 9 and 10, and the distortion generating member 121 and attached to the distortion generating member 121 to detect the distortion of the distortion generating member 121. And the strain sensor 122. The strain generating member 121 is made of an elastically deformable metal plate having a thickness of 3 mm or less, such as a steel material, and has a planar shape of a strip having a uniform width over the entire length, and has notches 121b on both sides of the center. Further, the strain generating member 121 has two contact fixing portions 121 a that are fixed to the outer diameter surface of the outer ring 1 through spacers 123 at both ends. The strain sensor 122 is affixed to the strain generating member 121 at a location where the strain increases with respect to the load in each direction. Here, as the location, the central portion sandwiched between the notch portions 121b on both sides on the outer surface side of the strain generating member 121 is selected, and the strain sensor 122 measures the circumferential strain around the notch portion 121b. To detect.

  In the sensor unit 120, the two contact fixing portions 121a of the strain generating member 121 are positioned at the same size in the axial direction of the outer ring 1, and the two contact fixing portions 121a are located at positions separated from each other in the circumferential direction. These contact fixing portions 121a are fixed to the outer diameter surface of the outer ring 1 by bolts 124 through spacers 123, respectively. Each of the bolts 124 is inserted into a bolt insertion hole 126 of the spacer 123 from a bolt insertion hole 125 provided in the contact fixing portion 121a in the radial direction, and a screw hole 127 provided in an outer peripheral portion of the outer member 51. Screwed on. As described above, by fixing the contact fixing portion 121a to the outer diameter surface of the outer member 51 through the spacer 123, the central portion having the notch portion 121b in the thin plate-shaped strain generating member 121 is located outside the outer ring 1. It becomes a state away from the radial surface, and distortion deformation around the notch 121b becomes easy. As the axial position where the contact fixing portion 121a is arranged, an axial position that is the periphery of the rolling surface 53 of the outboard side row of the outer member 51 is selected here. Here, the periphery of the rolling surface 53 of the outboard side row is a range from the intermediate position of the rolling surface 53 of the inboard side row and the outboard side row to the formation portion of the rolling surface 53 of the outboard side row. It is. A flat portion 1b is formed at a location where the spacer 123 is contacted and fixed on the outer diameter surface of the outer member 51.

  Various strain sensors 122 can be used. For example, the strain sensor 122 can be composed of a metal foil strain gauge. In that case, the distortion generating member 121 is usually fixed by adhesion. Further, the strain sensor 122 can be formed on the strain generating member 121 with a thick film resistor.

  FIG. 11 shows an example of the rotation sensor 24 of FIGS. The rotation sensor 24 includes a magnetic encoder 24a provided on the outer periphery of the inner member 52 in the wheel bearing 4, and a magnetic sensor 24b provided on the outer member 51 so as to face the magnetic encoder 24a. The magnetic ender 24a is a ring-shaped member in which magnetic poles N and S are alternately magnetized in the circumferential direction. In this example, the rotation sensor 24 is disposed between both rows of rolling elements 55, 55, but may be installed at the end of the wheel bearing 4.

DESCRIPTION OF SYMBOLS 1 ... Vehicle body 2, 3 ... Wheel 4, 5 ... Wheel bearing 6 ... Motor 7 ... Reduction gear 8 ... In-wheel motor drive device 9, 10 ... Electric brake 11 ... Steering mechanism 12 ... Steering mechanism 19 ... Battery 21 ... ECU
DESCRIPTION OF SYMBOLS 22 ... Inverter device 24 ... Rotation sensor 28 ... Power circuit part 29 ... Motor control part 30 ... In-wheel motor unit 31 ... Inverter 32 ... PWM driver 33 ... Motor drive control part 34 ... Regenerative brake 35 ... Maximum operating means 36 ... Load correspondence Regenerative brake limiting means 37 ... reporting means 38 ... braking force distribution means 39 ... current detection means 41 ... load sensor 42 ... angle sensor

Claims (3)

A motor that drives the wheel; a motor control unit that controls the motor; a regenerative brake that is provided in the motor control unit and applies a regenerative braking force to the wheel by power generation of the motor; and a mechanical braking force to the wheel In an electric vehicle with a mechanical brake to give
The motor control unit is
Means for reducing braking torque in the regenerative brake for preventing tire slip due to excessive application of the regenerative brake;
When a regenerative braking torque command is given from the brake operation means to the motor control unit through an ECU that is an electric control unit for controlling the vehicle as a whole, the rotational speed of the wheel and the state of charge of the battery are determined according to a predetermined rule. The maximum possible regenerative braking torque of the regenerative brake is calculated from, and if the maximum possible regenerative braking torque is less than the regenerative braking torque command, the braking torque of the regenerative brake is operated to the maximum with respect to the regenerative braking torque command. Maximum actuation means, and
Means for reducing the braking torque in the regenerative braking, when a load acting between the road surface-tire has reached the set value, in preference to the control of pre-Symbol maximum operating means cause functions to reduce the braking torque of the regenerative brake An electric vehicle characterized in that And has it the electric vehicle according to claim 1, the motor control unit, said report means regenerative braking to report the value of the regenerative braking torque that acts on the ECU is set vignetting, the ECU, from the reporting means electric vehicle reported regenerative braking torque value and the braking force distribution means for creating added the braking torque as a difference between the regenerative braking torque command given to the motor control unit to the mechanical brake has been kicked set. And have you the electric vehicle according to claim 1 or claim 2, wherein the motor is an electric vehicle that partially or entirely disposed within the wheel constituting the in-wheel motor drive device including the motor and wheel bearing.

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