JPH0984206A - Run controller of electric car - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a run controller of an electric car which has a brake device which brakes wheels and a regenerative brake device using a motor and with which the slope starting, a heel-and-toe operation for cornering, etc., can be performed excellently without a feeling of incongruity. SOLUTION: A brake operation value detecting means 22, a drive operation value detecting means 20, a motor control means 10 and a brake force control means 40 are provided. The motor control means 10 controls the regenerative brake force of a motor 1 in accordance with a brake operation value when the brake operation only is performed, controls the drive force of the motor 1 in accordance with the drive operation value when the drive operation only is performed and controls the drive force of the motor 1 with priority when both the brake operation and the drive operation are performed simultaneously. The brake force control means 40 calculates a requested brake power in accordance with the brake operation value and makes brake devices 30 and 31 generate a brake force equivalent to the difference between the requested brake force and the regenerative brake force.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a travel control device for an electric vehicle, and more particularly to a travel control device using a regenerative brake by a motor.

[0002]

2. Related Background Art In an electric vehicle, in addition to a mechanical brake such as a hydraulic brake, a regenerative brake by a rotational load resistance of a motor that drives the vehicle is effectively used for braking. In this case, the required braking force according to the depression amount of the brake pedal is calculated, and the required braking force is distributed to the mechanical braking force by the mechanical brake and the regenerative braking force by the regenerative brake, and based on this calculation result. I am trying to brake.

[0003]

By the way, in the electric vehicle as described above, as in the case of a vehicle driven by an engine, the driver operates the accelerator pedal together with the brake pedal at the time of heel and toe operation at the start of a slope or at the time of cornering. In some cases, you may step on. Thus, when the accelerator pedal and the brake pedal are stepped on at the same time, the motor generates a driving force obtained by subtracting the regenerative braking force according to the operation amount of the brake pedal from the required driving force according to the operation amount of the accelerator pedal. Controlled.

On the other hand, at this time, with respect to the braking by depressing the brake pedal, the braking force by the mechanical brake and the braking force by the regenerative brake are distributed and controlled as described above. However, the motor does not function as a regenerative brake when it is being driven. That is, when the brake pedal and the accelerator pedal are simultaneously depressed as described above, the regenerative braking force is not actually generated in the motor, and the vehicle is braked only by the mechanical braking force of the mechanical brake. Therefore, the actual braking force is insufficient because the regenerative braking force is not generated.

As described above, when the actual braking force becomes smaller than the required braking force, the desired braking cannot be performed even though the brake pedal is depressed, and the heel-and-toe operation is performed when starting a slope or when cornering. When doing so, good braking cannot be secured. In addition, even if you try to start or accelerate by depressing the accelerator pedal, if the brake pedal is depressed at the same time, the smooth driving is possible because the driving force of the motor is limited.
Accelerating driving becomes difficult and the driver feels uncomfortable.

The present invention has been made based on the above-mentioned circumstances, and an object thereof is to provide a traveling control device for an electric vehicle which can favorably perform a heel-and-toe operation at the time of starting a slope or cornering without feeling uncomfortable. Especially.

[0007]

In order to achieve the above-mentioned object, the invention of claim 1 provides a traveling control device for an electric vehicle, comprising a brake device for braking a vehicle wheel and a regenerative brake by a motor. , A brake operation amount detecting means for detecting an operation amount by the brake operating means, a driving force operation amount detecting means for detecting an operation amount by the driving force operating means, and the brake operation amount when only the brake operating means is operated. The regenerative braking force of the motor is controlled accordingly, and when only the drive force operating means is operated, the drive force of the motor is controlled according to the drive force operation amount,
When the brake operating means and the driving force operating means are operated at the same time, the motor controlling means for controlling the motor by prioritizing the operation by the driving force operating means, and the required braking force calculated based on the brake operating amount However, a braking force control unit that causes the braking device to generate a braking force that matches the difference between the required braking force and the regenerative braking force is provided.

Therefore, normally, when the brake operating means is operated, the vehicle is braked by the regenerative braking force of the motor according to the brake operation amount and the braking force that matches the difference between the required braking force and the regenerative braking force. However, when the brake operating means and the driving force operating means are operated at the same time, the operation by the driving force operating means is prioritized and the motor is drive-controlled, so that the braking force is applied by the braking device. Controlled.

Further, the invention of claim 2 is characterized in that the braking force control means controls the braking force by preferentially distributing the regenerative braking force. Therefore, normally, at the time of braking, the vehicle is brake-controlled by giving priority to the regenerative braking force, the regenerative braking is effectively used, and the regenerative energy is favorably recovered. Further, in the invention of claim 3, the braking force control means includes a target deceleration calculation means for calculating a target deceleration of the vehicle and a deceleration detection means for detecting an actual deceleration of the vehicle. The braking force is corrected and controlled so that the speed matches the target deceleration. Therefore, normally, when the actual deceleration is different from the target deceleration, the braking force by the braking device is appropriately corrected and controlled so that the actual deceleration and the target deceleration are matched, and good braking is always realized.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic configuration diagram of a traveling control device in an electric vehicle. As shown in the figure,
A power conversion circuit 4 is electrically connected to the high-power type motor 1 connected to wheels (not shown) via cables 2 and 3. This power conversion circuit 4 includes a cable 5,
A battery 8 such as a nickel hydrogen battery, which is a secondary battery, is electrically connected via 6.

Further, a motor torque control section (motor control means) 10 is electrically connected to the power conversion circuit 4. The motor torque controller 10 includes an accelerator pedal stroke sensor (driving force operation amount detecting means) 20 for detecting a stroke amount (operating amount) of an accelerator pedal (driving force operating means) 20 and a brake pedal (brake operating means). ) 23 is electrically connected to a brake pedal stroke sensor (brake operation amount detecting means) 22 for detecting a stroke amount (operation amount).

The motor torque control unit 10 includes a determination unit 12,
The storage unit 14, the calculation unit 16, and the instruction unit 18 are included. Signals corresponding to the stroke amounts of the pedals 20 and 23 from the accelerator pedal stroke sensor 20 and the brake pedal stroke sensor 22 are input to the determination unit 12, and the determination unit 12 outputs these signals. The input mode of is determined. That is,
Here, it is determined whether only the accelerator pedal 21 is operated, only the brake pedal 23 is operated, or both the accelerator pedal 21 and the brake pedal 23 are operated.

The storage unit 14 stores the case where only the accelerator pedal 21 is operated, the case where only the brake pedal 23 is operated, and the case where both the accelerator pedal 21 and the brake pedal 23 are operated. It has a map that stores the relationship between the pedal stroke amount and the torque gain in each mode. For example, FIG. 2 is a map showing the relationship between the accelerator pedal stroke and the driving torque gain, and FIG. 3 is a map showing the relationship between the brake pedal stroke and the regenerative torque gain.

Therefore, when the judging section 12 judges the mode, the map corresponding to the selected mode is selected.
In the calculation unit 16, the pedal 2 is calculated from each map stored in the storage unit 14 for each input mode determined by the determination unit 12.
The torque gain corresponding to each stroke amount of 1 and 23 is read, and the driving torque of the motor 1, that is, the output is calculated. Then, the output signal corresponding to the driving torque is output from the instruction unit 18 to the power conversion circuit 4. More specifically, when only the accelerator pedal 21 is operated, a drive torque signal for driving the motor 1 is output based on the map of FIG. 2, and when only the brake pedal 23 is operated, A regenerative torque signal for regenerating the motor 1 is output based on the map of FIG.

Here, the regenerative torque signal is a signal for adjusting the current value of the charging current when charging the battery 8 with the electric power generated by the motor 1, and the magnitude of this signal. Accordingly, the rotation resistance of the motor 1, that is, the regenerative braking force changes. On the other hand, an electromagnetic valve 34 for adjusting a braking force is connected to a brake caliper 31 of a hydraulic disc brake 30 which is a mechanical brake device via a hydraulic line 32, and the electromagnetic pressure supplied to the electromagnetic valve 34 is connected to the electromagnetic valve 34. A hydraulic brake control unit (braking force control means) 40 for controlling is electrically connected. The hydraulic brake control unit 40 includes the above-described brake pedal stroke sensor 22 and an acceleration (G) sensor (deceleration detection means) 50 that detects the longitudinal acceleration of the vehicle.
Are electrically connected.

The hydraulic brake control unit 40 includes a calculation unit 4
2 and an instruction unit 44. A signal corresponding to the stroke amount of the brake pedal 23 from the brake pedal stroke sensor 22 and a signal from the G sensor 50 are input to the calculation unit 42. In the calculation unit 42, the stroke of the brake pedal 23 is input. The required braking force according to the amount is calculated.

FIG. 4 is a map showing the relationship between the brake pedal stroke and the required braking force. The difference between the required braking force and the regenerative braking force is the hydraulic braking force. However,
Since the regenerative braking force is prioritized over the hydraulic braking force, once the required braking force is determined, the regenerative braking force becomes the maximum first, as shown by the broken line in the figure, and the remaining shortage is hydraulically braked. The value of the hydraulic braking force is determined so that the force supplements.

The calculation unit 42 calculates the target deceleration from the required braking force (target deceleration calculation means). Here, a negative deceleration based on the target deceleration and the information from the G sensor 50 is used. The acceleration, that is, the actual deceleration is compared. When the actual deceleration is different from the target deceleration, the hydraulic braking force of the calculated value of the required braking force is corrected and controlled so that the actual deceleration matches the target deceleration.

The calculation result of the calculation unit 42 is stored in the instruction unit 44.
Is converted into a drive signal and output to the electromagnetic valve 34, whereby the electromagnetic valve 34 is controlled and a desired supply hydraulic pressure is obtained. Hereinafter, the operation of the travel control device configured as described above when both the accelerator pedal 21 and the brake pedal 23 are operated will be described.

Accelerator pedal 21 and brake pedal 23
If both are operated, the determination unit 12 of the motor torque control unit 10 determines that the simultaneous stroke mode is performed when both the accelerator pedal 21 and the brake pedal 23 are operated. The corresponding map is selected. Here, accelerator pedal 2
The map of FIG. 2 similar to the case where only 1 is operated is selected.

That is, when both the accelerator pedal 21 and the brake pedal 23 are operated, even if the brake pedal 23 is depressed, the signal from the brake pedal stroke sensor 22 corresponding to the stroke amount of the brake pedal 23 is It is ignored, and the regenerative torque gain, that is, the regenerative braking force is regulated to the value 0. Therefore, in this case, only the signal from the accelerator pedal stroke sensor 20 corresponding to the stroke amount of the accelerator pedal 21 is adopted, and the motor 1 generates the driving torque according to the stroke amount of the accelerator pedal 21.

On the other hand, at this time, the hydraulic brake control unit 40
The calculation braking unit 42 calculates the required braking force, but here, as described above, since the regenerative braking force by the motor 1 is set to 0, the regenerative braking force is also the required braking force. Don't consider it.
FIG. 5 is a map showing the relationship between the brake pedal stroke and the required braking force when both the accelerator pedal 21 and the brake pedal 23 are operated. As shown in FIG. The braking force is the disc brake 30 depending on the brake pedal stroke.
It is the hydraulic braking force.

As described above, the accelerator pedal 2 is used.
1 and the brake pedal 23 are both operated, the regenerative braking force is restricted to the value 0 and the motor 1
Will produce a driving force according to the stroke amount of the accelerator pedal 21, and the disc brake 30 will produce a braking force according to the stroke amount of the brake pedal 23. That is, in this case, the drive system and the braking system are independently controlled on the motor 1 side and the disc brake 30 side, respectively.

Therefore, when performing a heel-and-toe operation at the start of a slope or at the time of cornering in which both the accelerator pedal 21 and the brake pedal 23 are operated, good braking is achieved as in the case of an engine-driven vehicle. While releasing the brake pedal 23, it is possible to quickly start and accelerate without discomfort.

[0025]

As described above, according to the running control device for an electric vehicle of claim 1, the running control device for an electric vehicle is provided with a brake device for braking the wheels of the vehicle and a regenerative brake by a motor. , A braking operation amount detecting means for detecting an operation amount by the brake operating means, a driving force operation amount detecting means for detecting an operation amount by the driving force operating means, and a braking operation amount when only the braking operation means is operated. Controls the regenerative braking force of the motor, controls the motor drive force according to the drive force operation amount when only the drive force operation means is operated, and drives when the brake operation means and the drive force operation means are operated at the same time. The motor control means for controlling the motor by giving priority to the operation by the force operation means, and calculating the required braking force based on the brake operation amount,
In the case where the braking operation means and the driving force operation means are operated at the same time, since the braking force control means for causing the braking device to generate the braking force that matches the difference between the required braking force and the regenerative braking force is provided. In that case, the drive force can be controlled by giving priority to the operation by the drive force operating means, while
Braking can be controlled by the braking force from the braking device,
The drive system and the braking system can be made independent to realize reliable braking and acceleration start. As a result, it is possible to favorably perform heel-and-toe operation and the like at the time of starting a slope or cornering.

According to the traveling control device of the electric vehicle of the second aspect, the braking force control means controls the braking force by preferentially distributing the regenerative braking force, so that the normal braking without operating the accelerator pedal is performed. At times, the braking control of the vehicle can be performed by giving priority to the regenerative braking force, and the regenerative brake can be effectively used, so that the regenerative energy can be efficiently collected. According to the traveling control device for an electric vehicle of claim 3, the braking force control means includes a target deceleration calculating means for calculating a target deceleration of the vehicle, and a deceleration detecting means for detecting an actual deceleration of the vehicle. Since the braking force is corrected and controlled so that the actual deceleration matches the target deceleration, normally, when the actual deceleration is different from the target deceleration, the braking force by the braking device is appropriately corrected and controlled, You can always achieve good braking.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a travel control device of the present invention.

FIG. 2 is a graph showing the relationship between accelerator pedal stroke and drive torque gain.

FIG. 3 is a graph showing a relationship between a brake pedal stroke and a regenerative torque gain.

FIG. 4 is a graph showing the relationship between the brake pedal stroke, the required braking force, and the distribution thereof when the accelerator pedal is not operated.

FIG. 5 is a graph showing a relationship between a brake pedal stroke at the time of operating an accelerator pedal, a required braking force, and its distribution.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 motor 8 battery 10 motor torque control unit (motor control means) 12 determination unit 14 storage unit 16 calculation unit 18 instruction unit 20 accelerator pedal stroke sensor (driving force operation amount detection unit) 21 accelerator pedal (driving force operation unit) 22 brake Pedal stroke sensor (brake operation amount detection means) 23 Brake pedal (brake operation means) 30 Hydraulic disc brake (brake device) 40 Hydraulic brake control unit (braking force control means) 42 Calculation unit 44 Indication unit 50 Acceleration sensor

Claims (3)

[Claims] 1. A travel control device for an electric vehicle, comprising: a brake device for braking a vehicle wheel; and a regenerative brake by a motor; and a brake operation amount detecting means for detecting an operation amount by a brake operating means; and a driving force operation. Driving force operation amount detection means for detecting an operation amount by means, and when only the brake operation means is operated, the regenerative braking force of the motor is controlled according to the brake operation amount, and only the driving force operation means is operated. The driving force of the motor is controlled according to the driving force operation amount, and when the brake operating means and the driving force operating means are simultaneously operated, the operation by the driving force operating means is prioritized. Of the required braking force and the regenerative braking force by calculating a required braking force based on the brake operation amount. Running controller for the electric vehicle, characterized in that it comprises a braking force control means for generating the braking device a braking force that matches. 2. The traveling control device for an electric vehicle according to claim 1, wherein the braking force control means preferentially distributes the regenerative braking force to control the braking force. 3. The braking force control means includes target deceleration calculation means for calculating a target deceleration of the vehicle and deceleration detection means for detecting an actual deceleration of the vehicle, wherein the actual deceleration is the target. The traveling control device for an electric vehicle according to claim 1, wherein the braking force is corrected and controlled so as to match the deceleration.