阅读说明：本技术 一种电动汽车停车方法及装置 (Electric automobile parking method and device ) 是由 侯伟 刘信奎 尹良 战东红 夏新艳 于 2020-12-24 设计创作，主要内容包括：本发明提供一种电动汽车停车方法及装置,通过实时检测刹车踏板的开度和电动汽车的车速；当检测到刹车踏板的开度小于预设的刹车踏板开度,以及电动汽车的车速小于第一预设车速且大于第二预设车速时,根据电动汽车的车速、刹车踏板的开度和第二预设车速,确定需求制动扭矩；将电动汽车的制动扭矩调节至需求制动扭矩,其中,需求制动扭矩用于降低电动汽车的车速；当检测到电动汽车的车速小于第二预设车速时,将调节至需求制动扭矩的制动扭矩设置为0；控制电机控制器切换至转速控制模式,使电机控制器基于预设的需求转速控制电动汽车停车,其中,预设的需求转速为0。基于本发明,能够在保证停车舒适性的基础上,提高制动能量的利用率。(The invention provides a method and a device for parking an electric automobile, which are characterized in that the opening of a brake pedal and the speed of the electric automobile are detected in real time; when the opening degree of a brake pedal is detected to be smaller than a preset opening degree of the brake pedal, and the speed of the electric automobile is detected to be smaller than a first preset speed and larger than a second preset speed, determining a required braking torque according to the speed of the electric automobile, the opening degree of the brake pedal and the second preset speed; adjusting the braking torque of the electric automobile to a required braking torque, wherein the required braking torque is used for reducing the speed of the electric automobile; when the speed of the electric automobile is detected to be less than a second preset speed, setting the braking torque adjusted to the required braking torque to be 0; and controlling the motor controller to switch to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0. Based on the invention, the utilization rate of the braking energy can be improved on the basis of ensuring the parking comfort.)

1. An electric vehicle parking method, characterized in that the method comprises:

detecting the opening degree of a brake pedal and the speed of the electric automobile in real time;

when the opening degree of a brake pedal is detected to be smaller than a preset opening degree of the brake pedal, and the speed of the electric automobile is detected to be smaller than a first preset speed and larger than a second preset speed, determining a required braking torque according to the speed of the electric automobile, the opening degree of the brake pedal and the second preset speed;

adjusting a braking torque of the electric vehicle to the required braking torque, wherein the required braking torque is used for reducing the speed of the electric vehicle;

when the speed of the electric automobile is detected to be less than the second preset speed, setting the braking torque adjusted to the required braking torque to be 0;

and controlling the motor controller to switch to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0.

2. The method of claim 1, further comprising:

when the opening degree of a brake pedal is detected to be smaller than a preset opening degree of the brake pedal, and the speed of the electric automobile is detected to be not smaller than the first preset speed, a preset first brake torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal is obtained;

and adjusting the braking torque of the electric automobile to the first braking torque, and returning to the step of detecting the opening degree of a brake pedal and the speed of the electric automobile in real time, wherein the first braking torque is used for reducing the speed of the electric automobile.

3. The method according to claim 1, wherein the determining a required braking torque according to the vehicle speed of the electric vehicle, the opening degree of the brake pedal, and the second preset vehicle speed comprises:

acquiring a preset second braking torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal;

calculating to obtain a third braking torque by using a PID (proportion integration differentiation) regulation method by taking the speed of the electric automobile as an independent variable and the second preset speed as a target value;

and taking the larger of the second braking torque and the third braking torque as the required braking torque.

4. The method of claim 1, wherein after controlling the electric vehicle to stop, the method further comprises:

detecting the opening degree of an accelerator pedal in real time;

when the detected opening degree of the accelerator pedal is larger than a preset opening degree of the accelerator pedal, acquiring a first opening degree of the accelerator pedal and the current speed of the electric automobile;

acquiring a preset first driving torque corresponding to the current speed of the electric automobile under the first opening degree of the accelerator pedal and an absolute value of an actual driving torque of the motor controller at the current moment;

and if the first driving torque is larger than the absolute value of the actual driving torque at the current moment, controlling the motor controller to switch to a torque control mode, so that the motor controller controls the electric automobile to start based on the first driving torque.

5. The method of claim 4, further comprising:

if the detected opening degree of the accelerator pedal is not larger than the preset opening degree of the accelerator pedal, detecting the hand brake state of the hand brake in real time;

when the hand brake state of the hand brake is detected to be a pull-up state, acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile;

acquiring a preset second driving torque corresponding to the current speed of the electric automobile at a second opening of the accelerator pedal, wherein the second driving torque is 0;

and controlling the motor controller to switch to a torque control mode, so that the motor controller controls the electric automobile to enter a starting state based on the second driving torque.

6. The method of claim 5, further comprising:

when the hand brake state of the hand brake is detected to be a release state, judging whether the absolute value of the actual driving torque at the current moment is greater than a preset first driving torque threshold value;

if the absolute value of the actual driving torque at the current moment is larger than a preset first driving torque threshold value, clearing a preset first timer, and judging whether the difference value between the absolute value of the actual driving torque at the current moment and the absolute value of the actual driving torque at the previous moment is smaller than a preset second driving torque threshold value or not;

if the difference value is not smaller than a preset second driving torque threshold value, returning to the step of detecting the accelerator pedal in real time;

if the difference value is smaller than a preset second driving torque threshold value, starting a preset second timer;

the acquiring the second opening degree of the accelerator pedal and the current speed of the electric automobile comprises the following steps:

when the accumulated timing time of the second timer is greater than a first time threshold value, acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile;

if the absolute value of the actual driving torque at the current moment is not greater than a preset first driving torque threshold value, clearing the second timer, and starting the first timer;

the acquiring the second opening degree of the accelerator pedal and the current speed of the electric automobile comprises the following steps: and when the accumulated timing time of the first timer is greater than a second time threshold value, acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile.

7. An electric vehicle parking apparatus, comprising:

the first detection unit is used for detecting the opening of a brake pedal and the speed of the electric automobile in real time;

the device comprises a required braking torque determining unit, a braking torque determining unit and a braking torque determining unit, wherein the required braking torque determining unit is used for determining a required braking torque according to the speed of the electric vehicle, the opening degree of a brake pedal and a second preset speed when the condition that the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal and the speed of the electric vehicle is smaller than a first preset speed and larger than the second preset speed is detected;

a first adjusting unit for adjusting a braking torque of the electric vehicle to the required braking torque, wherein the required braking torque is used for reducing a vehicle speed of the electric vehicle;

a setting unit configured to set the braking torque adjusted to the required braking torque to 0 when it is detected that the vehicle speed of the electric vehicle is less than the second preset vehicle speed;

the first control unit is used for controlling the motor controller to be switched to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0.

8. The apparatus of claim 7, further comprising:

the first obtaining unit is used for obtaining a preset first brake torque corresponding to the speed of the electric automobile under the opening degree of a brake pedal when the opening degree of the brake pedal is detected to be smaller than a preset opening degree of the brake pedal and the speed of the electric automobile is detected to be not smaller than a first preset speed;

and the second adjusting unit is used for adjusting the braking torque of the electric automobile to the first braking torque and returning to the step of detecting the opening degree of a brake pedal and the speed of the electric automobile in real time, wherein the first braking torque is used for reducing the speed of the electric automobile.

9. The apparatus according to claim 7, wherein the required braking torque determination unit includes:

the second acquisition unit is used for acquiring a preset second braking torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal;

the calculating unit is used for calculating to obtain a third braking torque by using a PID (proportion integration differentiation) adjusting method by taking the speed of the electric automobile as an independent variable and the second preset speed as a target value;

and a required braking torque determination subunit configured to take the larger of the second braking torque and the third braking torque as a required braking torque.

10. The apparatus of claim 7, further comprising:

the second detection unit is used for detecting the opening degree of the accelerator pedal in real time;

the third obtaining unit is used for obtaining the first opening degree of the accelerator pedal and the current speed of the electric automobile when the opening degree of the accelerator pedal is detected to be larger than the preset opening degree of the accelerator pedal;

the fourth acquisition unit is used for acquiring a preset first driving torque corresponding to the current speed of the electric automobile under the first opening degree of the accelerator pedal and an absolute value of an actual driving torque of the motor controller at the current moment;

and the second control unit is used for controlling the motor controller to switch to a torque control mode if the first driving torque is larger than the absolute value of the actual driving torque at the current moment, so that the motor controller controls the electric automobile to start based on the first driving torque.

Technical Field

The invention relates to the technical field of intelligent driving, in particular to a method and a device for controlling an electric automobile to stop.

Background

In the process of normal running of the electric automobile, when a driver wants to stop the electric automobile, the driver is required to press a brake pedal of the electric automobile to stop the electric automobile. The brake pedal of the electric automobile consists of a front half part and a rear half part, wherein the front half part is an idle stroke, and the rear half part is a stroke control pneumatic brake.

In the prior art, after a driver steps on a brake pedal of an electric automobile, a motor is controlled by the front half part of the brake pedal to apply a reverse preset fixed brake torque for brake recovery, so that the automobile speed is reduced, the motor recovery brake is cancelled after the automobile speed is reduced to a preset automobile speed threshold value, and the driver further steps on the brake pedal to stop the electric automobile through a stroke control air brake. In order to prevent the vehicle from shaking, the preset vehicle speed threshold value is large, so that when the vehicle speed is lower than the preset vehicle speed threshold value, the motor recovery braking is directly cancelled, a large amount of braking energy is not utilized, and the utilization rate of the braking energy is low. And, impact is stronger when the pneumatic brake is braked, leads to the travelling comfort relatively poor when parkking.

Disclosure of Invention

In view of this, the present invention provides a method and an apparatus for controlling parking of an electric vehicle, so as to improve the utilization rate of braking energy on the basis of ensuring the parking comfort.

The invention discloses a parking method of an electric automobile in a first aspect, which comprises the following steps:

detecting the opening degree of a brake pedal and the speed of the electric automobile in real time;

when the opening degree of a brake pedal is detected to be smaller than a preset opening degree of the brake pedal, and the speed of the electric automobile is detected to be smaller than a first preset speed and larger than a second preset speed, determining a required braking torque according to the speed of the electric automobile, the opening degree of the brake pedal and the second preset speed;

adjusting a braking torque of the electric vehicle to the required braking torque, wherein the required braking torque is used for reducing the speed of the electric vehicle;

when the speed of the electric automobile is detected to be less than the second preset speed, setting the braking torque adjusted to the required braking torque to be 0;

and controlling the motor controller to switch to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0.

Optionally, the method further includes:

when the opening degree of a brake pedal is detected to be smaller than a preset opening degree of the brake pedal, and the speed of the electric automobile is detected to be not smaller than the first preset speed, a preset first brake torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal is obtained;

and adjusting the braking torque of the electric automobile to the first braking torque, and returning to the step of detecting the opening degree of a brake pedal and the speed of the electric automobile in real time, wherein the first braking torque is used for reducing the speed of the electric automobile.

Optionally, the determining the required braking torque according to the vehicle speed of the electric vehicle, the opening degree of the brake pedal and the second preset vehicle speed includes:

acquiring a preset second braking torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal;

calculating to obtain a third braking torque by using a PID (proportion integration differentiation) regulation method by taking the speed of the electric automobile as an independent variable and the second preset speed as a target value;

and taking the larger of the second braking torque and the third braking torque as the required braking torque.

Optionally, after controlling the electric vehicle to stop, the method further includes:

detecting the opening degree of an accelerator pedal in real time;

when the detected opening degree of the accelerator pedal is larger than a preset opening degree of the accelerator pedal, acquiring a first opening degree of the accelerator pedal and the current speed of the electric automobile;

acquiring a preset first driving torque corresponding to the current speed of the electric automobile under the first opening degree of the accelerator pedal and an absolute value of an actual driving torque of the motor controller at the current moment;

and if the first driving torque is larger than the absolute value of the actual driving torque at the current moment, controlling the motor controller to switch to a torque control mode, so that the motor controller controls the electric automobile to start based on the first driving torque.

Optionally, the method further includes:

if the detected opening degree of the accelerator pedal is not larger than the preset opening degree of the accelerator pedal, detecting the hand brake state of the hand brake in real time;

when the hand brake state of the hand brake is detected to be a pull-up state, acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile;

acquiring a preset second driving torque corresponding to the current speed of the electric automobile at a second opening of the accelerator pedal, wherein the second driving torque is 0;

and controlling the motor controller to switch to a torque control mode, so that the motor controller controls the electric automobile to enter a starting state based on the second driving torque.

Optionally, the method further includes:

when the hand brake state of the hand brake is detected to be a release state, judging whether the absolute value of the actual driving torque at the current moment is greater than a preset first driving torque threshold value;

if the absolute value of the actual driving torque at the current moment is larger than a preset first driving torque threshold value, clearing a preset first timer, and judging whether the difference value between the absolute value of the actual driving torque at the current moment and the absolute value of the actual driving torque at the previous moment is smaller than a preset second driving torque threshold value or not;

if the difference value is not smaller than a preset second driving torque threshold value, returning to the step of detecting the accelerator pedal in real time;

if the difference value is smaller than a preset second driving torque threshold value, starting a preset second timer;

the acquiring the second opening degree of the accelerator pedal and the current speed of the electric automobile comprises the following steps:

when the accumulated timing time of the second timer is greater than a first time threshold value, acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile;

if the absolute value of the actual driving torque at the current moment is not greater than a preset first driving torque threshold value, clearing the second timer, and starting the first timer;

the acquiring the second opening degree of the accelerator pedal and the current speed of the electric automobile comprises the following steps: and when the accumulated timing time of the first timer is greater than a second time threshold value, acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile.

A second aspect of the present invention provides an electric vehicle parking apparatus, including:

the first detection unit is used for detecting the opening of a brake pedal and the speed of the electric automobile in real time;

the device comprises a required braking torque determining unit, a braking torque determining unit and a braking torque determining unit, wherein the required braking torque determining unit is used for determining a required braking torque according to the speed of the electric vehicle, the opening degree of a brake pedal and a second preset speed when the condition that the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal and the speed of the electric vehicle is smaller than a first preset speed and larger than the second preset speed is detected;

a first adjusting unit for adjusting a braking torque of the electric vehicle to the required braking torque, wherein the required braking torque is used for reducing a vehicle speed of the electric vehicle;

a setting unit configured to set the braking torque adjusted to the required braking torque to 0 when it is detected that the vehicle speed of the electric vehicle is less than the second preset vehicle speed;

the first control unit is used for controlling the motor controller to be switched to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0.

Optionally, the apparatus further comprises:

the first obtaining unit is used for obtaining a preset first brake torque corresponding to the speed of the electric automobile under the opening degree of a brake pedal when the opening degree of the brake pedal is detected to be smaller than a preset opening degree of the brake pedal and the speed of the electric automobile is detected to be not smaller than a first preset speed;

and the second adjusting unit is used for adjusting the braking torque of the electric automobile to the first braking torque and returning to the step of detecting the opening degree of a brake pedal and the speed of the electric automobile in real time, wherein the first braking torque is used for reducing the speed of the electric automobile.

Optionally, the required braking torque determination unit includes:

the second acquisition unit is used for acquiring a preset second braking torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal;

the calculating unit is used for calculating to obtain a third braking torque by using a PID (proportion integration differentiation) adjusting method by taking the speed of the electric automobile as an independent variable and the second preset speed as a target value;

and a required braking torque determination subunit configured to take the larger of the second braking torque and the third braking torque as a required braking torque.

Optionally, the apparatus further comprises:

the second detection unit is used for detecting the opening degree of the accelerator pedal in real time;

the third obtaining unit is used for obtaining the first opening degree of the accelerator pedal and the current speed of the electric automobile when the opening degree of the accelerator pedal is detected to be larger than the preset opening degree of the accelerator pedal;

the fourth acquisition unit is used for acquiring a preset first driving torque corresponding to the current speed of the electric automobile under the first opening degree of the accelerator pedal and an absolute value of an actual driving torque of the motor controller at the current moment;

and the second control unit is used for controlling the motor controller to switch to a torque control mode if the first driving torque is larger than the absolute value of the actual driving torque at the current moment, so that the motor controller controls the electric automobile to start based on the first driving torque.

The invention provides a method and a device for parking an electric automobile, which are characterized in that when the opening degree of a brake pedal is detected to be smaller than the preset opening degree of the brake pedal and the speed of the electric automobile is in a certain range, the required braking torque is determined according to the detected opening degree of the brake pedal and the preset minimum speed (second preset speed), so as to further reduce the speed of the electric automobile according to the determined required braking torque, when the speed of the electric automobile is reduced to the preset minimum speed, the braking torque adjusted to the required braking torque is set to be 0, and a motor controller is controlled to be switched to a rotating speed control mode, so that the motor controller controls the electric automobile to park based on the preset required rotating speed (0rpm), the motor recovery braking is not cancelled, and the utilization rate of braking energy is improved, and the invention can realize parking without utilizing air braking, thereby improving comfort.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic flow chart of a parking method for an electric vehicle according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart illustrating another method for parking an electric vehicle according to an embodiment of the present invention;

fig. 3 is a schematic flow chart of a starting method of an electric vehicle according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of an electric vehicle parking apparatus according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In this application, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Referring to fig. 1, a schematic flow chart of an electric vehicle parking method provided by an embodiment of the present invention is shown, where the electric vehicle parking method is applied to a vehicle control unit, and the electric vehicle parking method specifically includes the following steps:

s101: and detecting the opening of the brake pedal and the speed of the electric automobile in real time.

In the specific process of executing step S101, in the process of normally driving the electric vehicle, if the driver wants to stop the vehicle, the driver needs to depress the brake pedal, when the driver depresses the brake pedal, the opening degree of the brake pedal changes, and when the driver wants to stop the vehicle, the vehicle speed is also reduced, so that it can be seen that whether the driver needs to enter the parking link can be determined by detecting the opening degree of the brake pedal and the vehicle speed of the electric vehicle in real time.

S102: and when the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal and the speed of the electric automobile is smaller than the first preset speed and larger than the second preset speed, determining the required braking torque according to the speed of the electric automobile, the opening degree of the brake pedal and the second preset speed.

In step S102, a brake pedal opening is preset, when the opening of the brake pedal is detected to be smaller than a preset brake pedal opening, it is indicated that the driver steps on the brake pedal, and when the opening of the brake pedal is detected to be larger than the preset brake pedal opening, it is indicated that the driver steps on the brake pedal too much, which may be in a latter half formed by the brake pedal, and may have an air brake engaged, and at this time, the driver does not enter a parking link.

A certain vehicle speed range is preset (for convenience of distinction, the maximum vehicle speed in the preset vehicle speed range is referred to as a first preset vehicle speed, and the minimum vehicle speed is referred to as a second preset vehicle speed), and when the vehicle speed of the electric vehicle is within the preset vehicle speed range, it can be determined that the current vehicle speed of the electric vehicle is already at a relatively low vehicle speed.

The method comprises the steps of presetting a corresponding relation between the speed of the electric automobile and the braking torque under a certain opening degree of a brake pedal, namely, when the opening degree of the brake pedal and the speed of the electric automobile are determined, obtaining the braking torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal according to the corresponding relation between the speed of the electric automobile and the braking torque.

In the specific implementation process of step S102, when it is detected that the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal, and when it is detected that the vehicle speed of the electric vehicle is smaller than the first preset vehicle speed and greater than the second preset vehicle speed, the current opening degree of the brake pedal and the current vehicle speed of the electric vehicle may be obtained, and under the opening degree of the brake pedal, according to the corresponding relationship between the vehicle speed of the electric vehicle and the brake torque, a brake torque corresponding to the current vehicle speed of the electric vehicle is obtained (for convenience of distinguishing, the brake torque obtained at this time is referred to as a second brake torque); and determining a third braking torque according to the current speed of the electric automobile and a second preset speed, and further taking the larger one of the second braking torque and the third braking torque as a required braking torque so as to adjust the braking torque of the electric automobile to the required braking torque, thereby reducing the current speed of the electric automobile.

It should be noted that, after the braking torque corresponding to the current vehicle speed of the electric vehicle is acquired according to the corresponding relationship between the vehicle speed of the electric vehicle and the braking torque at the acquired opening degree of the brake pedal, the acquired braking torque may be further corrected according to the current state of the current power battery and the current state of the motor to obtain a corrected braking torque, and the obtained corrected braking torque is used as the second braking torque.

Optionally, the mode of determining the second braking torque according to the current vehicle speed of the electric vehicle and the second preset vehicle speed may be: and calculating a third braking torque by using a basic regulation method (PID) by taking the current speed of the electric automobile as an independent variable and the second preset speed as a target value.

S103: and adjusting the braking torque of the electric automobile to the required braking torque, wherein the required braking torque is used for reducing the speed of the electric automobile.

In the specific execution process of step S103, after determining the required braking torque according to the current vehicle speed of the electric vehicle, the opening degree of the brake pedal, and the second preset vehicle speed, the braking torque of the electric vehicle is adjusted to the required braking torque, so as to reduce the vehicle speed of the electric vehicle.

S104: and when the vehicle speed of the electric vehicle is detected to be less than the second preset vehicle speed, setting the braking torque adjusted to the required braking torque to be 0.

In the specific process of executing step S104, after the braking torque of the electric vehicle is adjusted to the required braking torque and the speed of the electric vehicle is reduced, it is detected whether the current speed of the electric vehicle is less than a second preset speed, if it is detected that the current speed of the electric vehicle is not less than the second preset speed, it is indicated that the current speed of the electric vehicle is not yet low, the speed of the electric vehicle is continuously reduced, until it is detected that the current speed of the electric vehicle is less than the second preset speed, the motor is torque-cleared, that is, the braking torque adjusted to the required braking torque is set to 0.

S105: and controlling the motor controller to switch to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0.

In the specific implementation process of step S105, during the normal driving process of the electric vehicle, the motor controller is in the torque control mode, and after the motor is cleared, a rotation speed control mode command and a preset required rotation speed may be sent to the motor controller, so that the motor controller switches from the torque control mode to the rotation speed control mode based on the received rotation speed mode control command, and maintains the rotation speed of the motor at the preset required rotation speed, thereby achieving the parking of the electric vehicle.

The preset required rotating speed is 0rpm, when the motor controller is switched from the torque control mode to the rotating speed control mode based on the received rotating speed control mode instruction, the rotating speed of the motor is maintained at 0rpm, ramp smoothing processing can be performed when a torque path is switched, and the electric vehicle is prevented from being bumped when the electric vehicle is parked, so that the comfort level is improved.

The invention provides an electric automobile parking method, when detecting that the opening degree of a brake pedal is smaller than a preset brake pedal opening degree and the speed of an electric automobile is in a certain range, determining a required braking torque according to the detected opening degree of the brake pedal and a preset minimum speed (a second preset speed) so as to further reduce the speed of the electric automobile according to the determined required braking torque, setting the braking torque adjusted to the required braking torque to be 0 when the speed of the electric automobile is reduced to the preset minimum speed, controlling a motor controller to switch to a rotating speed control mode, enabling the motor controller to control the electric automobile to park based on the preset required rotating speed (0rpm), and not canceling motor recovery braking so as to improve the utilization rate of braking energy, and the invention can realize parking without utilizing air braking, thereby improved the comfort level, reduced simultaneously and used the air brake, corresponding can reduce the pump work duration of inflating, can reduce the vehicle power consumption to a certain extent.

Referring to fig. 2, a schematic flow chart of another electric vehicle parking method provided by the embodiment of the invention is shown, and the method specifically includes the following steps:

s201: and detecting the opening of the brake pedal and the speed of the electric automobile in real time.

S202: judging whether the opening degree of a brake pedal is smaller than a preset opening degree of the brake pedal; if the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal, executing step S203; if the opening of the brake pedal is not smaller than the preset opening of the brake pedal, step S201 is executed.

In step S202, a brake pedal opening is preset, when the brake pedal opening is smaller than a preset brake pedal opening, it is indicated that the driver steps on the brake pedal, and when it is detected that the brake pedal opening is larger than the preset brake pedal opening, it is indicated that the driver steps on the brake pedal too much, which may be in a latter half formed by the brake pedal, and an air brake may be engaged, and at this time, the vehicle does not enter a parking link.

In the specific execution process of the step S202, whether to enter a parking link is determined according to the opening degree of the brake pedal, specifically, whether the opening degree of the brake pedal is smaller than a preset opening degree of the brake pedal is judged, if the opening degree of the brake pedal is not smaller than the preset opening degree of the brake pedal, which indicates that the driver has pressed the brake pedal too much, the driver does not enter the parking link, and the driver continues to return to execute the real-time detection of the opening degree of the brake pedal and the speed of the electric vehicle; and if the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal, determining that the driver steps on the brake pedal, entering a parking link, and executing the step S203.

S203: judging whether the speed of the electric automobile is less than a first preset speed or not; if the speed of the electric automobile is not less than the first preset speed, executing step S204; if the speed of the electric vehicle is less than the first preset speed, step S206 is executed.

In step S203, a certain vehicle speed range is preset (for convenience of distinction, the maximum vehicle speed in the preset vehicle speed range is referred to as a first preset vehicle speed, and the minimum vehicle speed is referred to as a second preset vehicle speed), and when the vehicle speed of the electric vehicle is within the preset vehicle speed range, it may be determined that the current vehicle speed of the electric vehicle is already at a relatively low vehicle speed.

In the specific execution process of step S203, when the opening degree of the brake pedal is smaller than the preset opening degree of the brake pedal, which indicates that the driver steps on the brake pedal, a parking link is entered, and it is further determined whether the speed of the electric vehicle is smaller than a first preset speed; if the speed of the electric vehicle is not less than the first preset speed, it is described that the speed of the electric vehicle is still relatively high, and it is necessary to further reduce the speed of the electric vehicle, that is, to execute step S204.

In the case that the vehicle speed of the electric vehicle is less than the first preset vehicle speed, in order to further determine the vehicle speed section of the current vehicle speed of the electric vehicle, it is required to further determine whether the current vehicle speed of the electric vehicle is less than the second preset vehicle speed, that is, to execute step S206.

S204: the method comprises the steps of obtaining a preset first braking torque corresponding to the speed of the electric automobile under the opening degree of a brake pedal.

In step S204, a correspondence relationship between the vehicle speed of the electric vehicle and the braking torque at a certain opening degree of the brake pedal, that is, when the opening degree of the brake pedal and the vehicle speed of the electric vehicle are determined, the braking torque corresponding to the vehicle speed of the electric vehicle at the opening degree of the brake pedal is acquired based on the correspondence relationship between the vehicle speed of the electric vehicle and the braking torque.

In the specific execution of step S204, when the vehicle speed of the electric vehicle is not less than the first preset vehicle speed, the current opening degree of the brake pedal is obtained, and under the current opening degree of the brake pedal, according to the preset corresponding relationship between the vehicle speed of the electric vehicle and the brake torque, the brake torque corresponding to the vehicle speed of the electric vehicle is obtained (for convenience of distinguishing, the brake torque is referred to as the first brake torque), so as to adjust the brake torque of the electric vehicle to the first brake torque, thereby reducing the vehicle speed of the electric vehicle.

S205: the braking torque of the electric vehicle is adjusted to a first braking torque.

In the specific execution of step S205, after the preset first braking torque corresponding to the vehicle speed of the electric vehicle at the opening degree of the brake pedal is acquired, the braking torque of the electric vehicle is adjusted to the first braking torque, so as to reduce the vehicle speed of the electric vehicle.

In the embodiment of the present application, after step S205 is executed, step S201 is returned to be executed.

S206: and determining the required braking torque according to the speed of the electric automobile and the second preset speed.

S207: and adjusting the braking torque of the electric automobile to the required braking torque, wherein the required braking torque is used for reducing the speed of the electric automobile.

S208: and when the vehicle speed of the electric vehicle is detected to be less than the second preset vehicle speed, setting the braking torque adjusted to the required braking torque to be 0.

S209: and controlling the motor controller to switch to a rotating speed control mode, so that the motor controller controls the electric automobile to stop based on a preset required rotating speed, wherein the preset required rotating speed is 0.

In the process of specifically executing step S206 to step S209, the implementation principle and the execution process of step S206 to step S209 are the same as those of step S102 to step S105 in fig. 1 disclosed in the present invention, and reference may be made to corresponding parts in fig. 1 disclosed in the present invention, which is not described herein again.

In the embodiment of the application, when the opening degree of the brake pedal is detected to be not less than the preset opening degree of the brake pedal, or the speed of the electric vehicle is detected to be greater than the preset maximum speed (first preset speed), determining the required first braking torque according to the detected opening degree of the brake pedal and the current speed of the electric vehicle, so as to further reduce the speed of the electric vehicle according to the determined first braking torque until the opening degree of the brake pedal is detected to be less than the preset opening degree of the brake pedal, and the speed of the electric vehicle is less than the preset maximum speed (first preset speed) and greater than the preset minimum speed (second preset speed), determining the required braking torque according to the detected opening degree of the brake pedal and the preset minimum speed, so as to further reduce the speed of the electric vehicle according to the determined braking torque, when the speed of the electric automobile is reduced to the preset lowest speed, the braking torque adjusted to the required braking torque is set to be 0 so as to control the motor controller to be switched to a rotating speed control mode, and the motor controller controls the electric automobile to stop based on the preset required rotating speed (0rpm), so that the utilization rate of braking energy is improved.

Further, after the electric vehicle is stopped, the invention further provides a starting method of the electric vehicle to control the starting of the electric vehicle, as shown in fig. 3, which is a schematic flow diagram of the starting method of the electric vehicle provided by the embodiment of the invention, and the method specifically includes the following steps:

s301: and detecting the opening degree of the accelerator pedal in real time.

In the specific execution process of step S301, if the driver wants to control the start of the electric vehicle during the stop of the electric vehicle, the start of the electric vehicle may be realized by stepping on the accelerator pedal. When a driver steps on the accelerator pedal, the opening degree of the accelerator pedal changes, so that whether the electric automobile needs to be stopped or not is determined by detecting the opening degree of the accelerator pedal, and the electric automobile enters a starting link.

S302: judging whether the opening degree of an accelerator pedal is larger than a preset opening degree of the accelerator pedal; if the opening degree of the accelerator pedal is larger than the preset opening degree of the accelerator pedal, executing step S303; if the opening degree of the accelerator pedal is not greater than the preset opening degree of the accelerator pedal, step S307 is executed.

In step S302, an accelerator pedal opening is preset, and the preset accelerator pedal opening may be an initial accelerator pedal opening, that is, an opening when the accelerator pedal is not depressed, and when it is detected that the accelerator pedal opening is greater than the preset accelerator pedal opening, it is described that the driver depresses the accelerator pedal.

In the specific execution process of step S302, whether to exit from the parking is determined according to the opening degree of the accelerator pedal, and a step S303 is executed if it is determined that the opening degree of the accelerator pedal is greater than a preset opening degree of the accelerator pedal, and the opening degree of the accelerator pedal is greater than the preset opening degree of the accelerator pedal, and the driver steps on the accelerator pedal.

If the opening degree of the accelerator pedal is not larger than the preset opening degree of the accelerator pedal, the driver is determined not to step on the accelerator pedal, and whether the electric automobile needs to be quit from the parking process or not can be further determined by judging whether the hand brake is pulled up or not, so that the electric automobile enters a state to be started.

S303: the method comprises the steps of obtaining a first opening degree of an accelerator pedal and the current speed of the electric automobile.

In the specific execution of step S303, when it is determined that the opening degree of the accelerator pedal is greater than the preset accelerator pedal opening degree, it may be determined that the driver depresses the accelerator pedal, and the current opening degree of the accelerator pedal (for convenience of distinction, the opening degree of the accelerator pedal obtained here is referred to as a first opening degree of the accelerator pedal) and the current vehicle speed of the electric vehicle are obtained.

S304: the method comprises the steps of obtaining a preset first driving torque corresponding to the current speed of the electric automobile under the first opening degree of an accelerator pedal and an absolute value of an actual driving torque of a motor controller at the current moment.

In step S304, a correspondence relationship between the vehicle speed of the electric vehicle and the drive torque at a certain opening degree of the accelerator pedal, that is, a correspondence relationship between the vehicle speed of the electric vehicle and the drive torque at the certain opening degree of the accelerator pedal, is set in advance, and the drive torque corresponding to the vehicle speed of the electric vehicle at the certain opening degree of the accelerator pedal is acquired from the correspondence relationship between the vehicle speed of the electric vehicle and the drive torque at the certain opening degree of the accelerator pedal.

In the specific execution of step S304, when the first opening degree of the accelerator pedal and the current vehicle speed of the electric vehicle are acquired, the driving torque corresponding to the vehicle speed of the electric vehicle at the first opening degree of the accelerator pedal (for convenience of distinction, the driving torque acquired here is referred to as the first driving torque) and the absolute value of the actual driving torque of the motor controller at the current time are acquired from the correspondence relationship between the vehicle speed of the electric vehicle and the driving torque at the first opening degree of the accelerator pedal.

S305: judging whether the first driving torque is larger than the absolute value of the actual driving torque at the current moment; the first driving torque is larger than the absolute value of the actual driving torque at the current moment, and step S306 is executed; if the first driving torque is not greater than the absolute value of the actual driving torque at the current time, step S301 is executed.

In the specific process of executing step S305, after obtaining the first driving torque and the absolute value of the actual driving torque of the motor controller at the current time, determining whether the first driving torque is greater than the absolute value of the actual driving torque at the current time, and if the first driving torque is not greater than the absolute value of the actual driving torque at the current time, returning to execute step S301; and if the first driving torque is larger than the absolute value of the actual driving torque at the current moment, the motor controller can be controlled to be switched to a torque control mode, so that the motor controller controls the electric automobile to start based on the first driving torque.

S306: and controlling the motor controller to switch to a torque control mode, so that the motor controller controls the electric automobile to start based on the first driving torque.

In the specific implementation of step S306, the motor controller is in the rotation speed control mode during the parking of the electric vehicle, and before controlling the electric vehicle to start, a torque control mode command may be sent to the motor controller, so that the motor controller switches from the rotation speed control mode to the torque control mode based on the received torque control mode command, so that the motor controller controls the electric vehicle to start smoothly based on the first driving torque in the torque control mode, and there is no back slip or back slip during the starting.

S307: and detecting the hand brake state of the hand brake in real time.

In the specific process of executing step S307, during the parking process of the electric vehicle, the driver may also pull the hand brake to enable the electric vehicle to enter the starting state. When the opening degree of the accelerator pedal is not larger than the preset opening degree of the accelerator pedal, the driver is determined not to step on the accelerator pedal, the hand brake state can be further detected, and when the driver pulls up the hand brake, the hand brake state can be changed, so that the driver can determine whether to quit the parking of the electric automobile or not and enter the state to be started by detecting the hand brake state.

S308: judging whether the hand brake state of the hand brake is a pull-up state or not; if the hand brake state of the hand brake is not the pull-up state, executing step S309; if the handbrake state is the pull-up state, step S315 is executed.

In step S308, when the handbrake state is the pull-up state, it indicates that the driver pulls up the handbrake, and when the handbrake state is the release state, it indicates that the driver does not pull up the handbrake.

In the specific process of executing the step S308, judging whether the current hand brake state of the hand brake is the pull-up state, if the hand brake state of the hand brake is not the pull-up state, determining that the driver does not pull up the hand brake, and executing a step S309; and if the hand brake state of the hand brake is the pull-up state, determining that the driver pulls up the hand brake, and executing the step S315.

In the specific implementation of step S308, the motor controller is in the rotation speed control mode during the parking of the electric vehicle, and before controlling the electric vehicle to start, a torque control mode command may be sent to the motor controller, so that the motor controller switches from the rotation speed control mode to the torque control mode based on the received torque control mode command, so that the motor controller controls the electric vehicle to start smoothly based on the second driving torque in the torque control mode, and there is no back slip or back slip during the starting.

S309: judging whether the absolute value of the actual driving torque at the current moment is greater than a preset first driving torque threshold value or not; if the absolute value of the actual driving torque at the current moment is greater than the preset first driving torque threshold, executing step S310; if the absolute value of the actual driving torque at the current time is not greater than the preset first driving torque threshold, step S313 is executed.

In the specific process of executing step S309, a first driving torque threshold is preset, when the handbrake state of the handbrake is not the pull-up state, it may be determined that the current handbrake state is the release state, it is determined that the driver does not pull up the handbrake, it is further determined whether the absolute value of the actual driving torque of the motor controller at the current time is greater than the preset first driving torque threshold, and in the case that the actual driving torque of the motor controller is greater than the preset first driving torque threshold, the preset first timer is cleared, that is, the preset first timer is turned off, and step S310 is executed; in the case where the absolute value of the actual driving torque of the motor controller at the present time is not greater than the preset first driving torque threshold value, step S313 is executed.

S310: clearing a preset first timer, and judging whether the difference value between the absolute value of the actual driving torque at the current moment and the absolute value of the actual driving torque at the previous moment is smaller than a preset second driving torque threshold value or not; if the torque is not less than the preset second driving torque threshold value, returning to execute the step S301; if the second driving torque is smaller than the preset second driving torque threshold, step S311 is executed.

In the specific process of executing step S310, when the absolute value of the actual driving torque of the motor controller at the current time is greater than the preset first driving torque threshold, the preset first timer is cleared, and it is further determined whether the difference between the absolute value of the actual driving torque at the current time and the absolute value of the actual driving torque at the previous time is smaller than the preset second driving threshold, and when the difference between the absolute value of the actual driving torque at the current time and the absolute value of the actual driving torque at the previous time is not smaller than the preset second driving torque threshold, the process returns to execute step S301. And starting a preset second timer under the condition that the difference value between the absolute value of the actual driving torque at the current moment and the absolute value of the actual driving torque at the previous moment is smaller than a preset second driving torque threshold value.

S311: a preset second timer is started.

In the specific execution process of step S311, when a difference between an absolute value of an actual driving torque at a current time and an absolute value of an actual driving torque at a previous time is smaller than a preset second driving torque threshold, starting a preset second timer, so that when a timing time of an accumulated second timer is greater than a first time threshold, a second opening of a current accelerator pedal and a current vehicle speed of the electric vehicle are obtained, and a second driving torque is determined according to the obtained second opening of the accelerator pedal and the current vehicle speed of the electric vehicle, and then the motor controller is controlled to switch to the torque control mode, so that the motor controller controls the electric vehicle to enter a to-be-started state based on the second driving torque, where the second driving torque is 0.

S312: when the cumulative time counted by the second timer is greater than the first time threshold, step S315 is executed.

In the specific execution process of step S312, after the preset second timer is started, the timing time of the second timer is accumulated, and when the timing time of the accumulated second timer is greater than the first time threshold, the second opening of the current accelerator pedal and the current vehicle speed of the electric vehicle are obtained, so as to determine a second driving torque according to the obtained second opening of the accelerator pedal and the current vehicle speed of the electric vehicle, and further control the motor controller to switch to the torque control mode, so that the motor controller controls the electric vehicle to enter a to-be-started state based on the second driving torque.

In the embodiment of the application, in the process of accumulating the second timer, when the situation that the actual driving torque absolute value of the motor controller at the current time is smaller than the preset first driving torque threshold value is detected, the second driving torque is determined according to the obtained second opening of the accelerator pedal and the current speed of the electric vehicle, and then the motor controller is controlled to switch to the torque control mode, so that the motor controller controls the electric vehicle to enter a state to be started based on the second driving torque.

S313: the second timer is cleared and the first timer is started.

In the specific execution process of step S313, when the absolute value of the actual driving torque at the current time is not greater than the preset first driving torque threshold, the second timer is cleared, that is, the second timer is cleared, and the first timer is started, so that when the cumulative time counted by the first timer is greater than the second time threshold, the second opening of the current accelerator pedal and the current vehicle speed of the electric vehicle are obtained, and the second driving torque is determined according to the obtained second opening of the accelerator pedal and the current vehicle speed of the electric vehicle, and then the motor controller is controlled to switch to the torque control mode, so that the motor controller controls the electric vehicle to enter the state to be started based on the second driving torque.

S314: when the accumulated time of the first timer is greater than the second time threshold, step S315 is executed.

In the specific execution process of step S314, after the preset second timer is started, the timing time of the second timer is accumulated, and when the timing time of the accumulated second timer is greater than the first time threshold, the second opening of the current accelerator pedal and the current vehicle speed of the electric vehicle are obtained, so as to determine a second driving torque according to the obtained second opening of the accelerator pedal and the current vehicle speed of the electric vehicle, and further control the motor controller to switch to the torque control mode, so that the motor controller controls the electric vehicle to enter a to-be-started state based on the second driving torque.

In the embodiment of the application, in the process of accumulating the first timer, when the condition that the absolute value of the actual driving torque at the current moment is greater than the preset second driving torque threshold value is detected, the first timer is cleared, that is, the first timer is cleared, so that the motor controller is prevented from being out of order due to overlong stalling time of the motor controller.

S315: and acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile.

In the specific execution of step S315, when the handbrake state of the handbrake is the pull-up state, it is determined that the driver pulls up the handbrake, and the current opening degree of the accelerator pedal and the current vehicle speed of the electric vehicle can be acquired (for convenience of distinguishing, the acquired opening degree of the accelerator pedal is referred to as a second opening degree of the accelerator pedal). The current accelerator pedal is not stepped, and the current accelerator pedal opening may be determined to be an initial accelerator pedal opening, that is, the second accelerator pedal opening is the initial accelerator pedal opening.

S316: and acquiring a preset second driving torque corresponding to the current speed of the electric automobile at a second opening of the accelerator pedal, wherein the second driving torque is 0.

In the specific execution of step S316, when the second opening degree of the accelerator pedal and the current vehicle speed of the electric vehicle are acquired, the driving torque corresponding to the vehicle speed of the electric vehicle at the second opening degree of the accelerator pedal is acquired based on the correspondence relationship between the vehicle speed of the electric vehicle and the driving torque at the second opening degree of the accelerator pedal (for convenience of distinction, the driving torque acquired here is referred to as the second driving torque).

S317: and controlling the motor controller to switch to a torque control mode, so that the motor controller controls the electric automobile to enter a starting state based on the second driving torque.

In the specific execution of step S317, after acquiring a preset second driving torque corresponding to the current speed of the electric vehicle at the second opening degree of the accelerator pedal, before controlling the electric vehicle to start, a torque control mode command may be sent to the motor controller, so that the motor controller switches from the rotation speed control mode to the torque control mode based on the received torque control mode command, so that the motor controller controls the electric vehicle to enter a state to be started based on the second driving torque in the torque control mode, and thus the electric vehicle is controlled to start without backward slip or jerk during a later period.

Corresponding to the electric vehicle parking method disclosed in the embodiment of the present invention, as shown in fig. 4, an embodiment of the present invention further provides an electric vehicle parking apparatus, including:

the first detection unit 41 is used for detecting the opening degree of a brake pedal and the speed of the electric automobile in real time;

the required braking torque determining unit 42 is configured to determine a required braking torque according to the speed of the electric vehicle, the opening degree of the brake pedal and a second preset speed when it is detected that the opening degree of the brake pedal is smaller than a preset opening degree of the brake pedal and the speed of the electric vehicle is smaller than a first preset speed and larger than the second preset speed;

a first adjusting unit 43 for adjusting a braking torque of the electric vehicle to the required braking torque for reducing a vehicle speed of the electric vehicle;

a setting unit 44 for setting the braking torque adjusted to the required braking torque to 0 when it is detected that the vehicle speed of the electric vehicle is less than the second preset vehicle speed;

and a first control unit 45, configured to control the motor controller to switch to a rotation speed control mode, so that the motor controller controls the electric vehicle to stop based on a preset required rotation speed, where the preset required rotation speed is 0.

The specific principle and the implementation process of each unit in the electric vehicle parking apparatus disclosed in the embodiment of the present invention are the same as those of the electric vehicle parking method disclosed in fig. 1 in the embodiment of the present invention, and reference may be made to corresponding parts in the electric vehicle parking method disclosed in fig. 1 in the embodiment of the present invention, which are not described herein again.

The invention provides an electric automobile parking device, when detecting that the opening degree of a brake pedal is smaller than a preset opening degree of the brake pedal and the speed of an electric automobile is in a certain range, determining a required braking torque according to the detected opening degree of the brake pedal and a preset minimum speed (a second preset speed) so as to further reduce the speed of the electric automobile according to the determined required braking torque, setting the braking torque adjusted to the required braking torque to be 0 when the speed of the electric automobile is reduced to the preset minimum speed, controlling a motor controller to switch to a rotating speed control mode, enabling the motor controller to control the electric automobile to park based on the preset required rotating speed (0rpm), and improving the utilization rate of braking energy without canceling motor recovery braking, and realizing parking without using air brake, thereby improved the comfort level, reduced simultaneously and used the air brake, corresponding can reduce the pump work duration of inflating, can reduce the vehicle power consumption to a certain extent.

Further, the electric vehicle parking apparatus provided by the embodiment of the present invention further includes:

the first obtaining unit is used for obtaining a preset first brake torque corresponding to the speed of the electric automobile under the opening degree of a brake pedal when the opening degree of the brake pedal is detected to be smaller than a preset opening degree of the brake pedal and the speed of the electric automobile is detected to be not smaller than a first preset speed;

and the second adjusting unit is used for adjusting the braking torque of the electric automobile to the first braking torque and returning to the step of detecting the opening degree of a brake pedal and the speed of the electric automobile in real time, wherein the first braking torque is used for reducing the speed of the electric automobile.

Preferably, the required braking torque determination unit includes:

the second acquisition unit is used for acquiring a preset second braking torque corresponding to the speed of the electric automobile under the opening degree of the brake pedal;

the calculating unit is used for calculating to obtain a third braking torque by using a PID (proportion integration differentiation) adjusting method by taking the speed of the electric automobile as an independent variable and the second preset speed as a target value;

and a required braking torque determination subunit configured to take the larger of the second braking torque and the third braking torque as a required braking torque.

Further, the electric vehicle parking apparatus provided by the embodiment of the present invention further includes:

the second detection unit is used for detecting the opening degree of the accelerator pedal in real time;

the third acquiring unit is used for acquiring the first opening degree of the accelerator pedal and the current speed of the electric automobile when the opening degree of the accelerator pedal is detected to be larger than the preset opening degree of the accelerator pedal;

the fourth acquisition unit is used for acquiring a preset first driving torque corresponding to the current speed of the electric automobile under the first opening degree of the accelerator pedal and an absolute value of an actual driving torque of the motor controller at the current moment;

and the second control unit is used for controlling the motor controller to switch to a torque control mode if the first driving torque is larger than the absolute value of the actual driving torque at the current moment, so that the motor controller controls the electric automobile to start based on the first driving torque.

Further, the electric vehicle parking apparatus provided by the embodiment of the present invention further includes:

the third detection unit is used for detecting the hand brake state of the hand brake in real time if the opening degree of the accelerator pedal is detected to be not more than the preset opening degree of the accelerator pedal;

the fifth acquisition unit is used for acquiring a second opening degree of an accelerator pedal and the speed of the electric automobile when the hand brake state of the hand brake is detected to be a pull-up state;

a sixth obtaining unit, configured to obtain a preset second driving torque corresponding to the current vehicle speed of the electric vehicle at a second opening of the accelerator pedal, where the second driving torque is 0;

and the third control unit is used for controlling the motor controller to switch to the torque control mode, so that the motor controller controls the electric automobile to enter a starting state based on the second driving torque.

Further, the electric vehicle parking apparatus provided by the embodiment of the present invention further includes:

the first judgment unit is used for judging whether the absolute value of the actual driving torque at the current moment is greater than a preset first driving torque threshold value or not when the hand brake state of the hand brake is detected to be a release state;

the second judgment unit is used for clearing the preset first timer if the absolute value of the actual driving torque at the current moment is larger than the preset first driving torque threshold value, and judging whether the difference value between the absolute value of the actual driving torque at the current moment and the absolute value of the actual driving torque at the previous moment is smaller than the preset second driving torque threshold value or not;

the first returning unit is used for returning to execute the second detection unit if the difference value is not smaller than a preset second driving torque threshold value;

the first starting unit is used for starting a preset second timer if the difference value is smaller than a preset second driving torque threshold value;

a fifth obtaining unit, configured to obtain a second opening degree of an accelerator pedal and a current speed of the electric vehicle when the counted time accumulated by the second timer is greater than a first time threshold;

the second starting unit is used for clearing the second timer and starting the first timer if the absolute value of the actual driving torque at the current moment is not greater than a preset first driving torque threshold value;

a fifth acquisition unit: and the controller is used for acquiring a second opening degree of the accelerator pedal and the current speed of the electric automobile when the accumulated timing time of the first timer is greater than a second time threshold.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, the system or system embodiments are substantially similar to the method embodiments and therefore are described in a relatively simple manner, and reference may be made to some of the descriptions of the method embodiments for related points. The above-described system and system embodiments are only illustrative, wherein the units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative components and steps have been described above generally in terms of their functionality in order to clearly illustrate this interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.