EP4277817A1

EP4277817A1 - Method for monitoring traction for a motor vehicle

Info

Publication number: EP4277817A1
Application number: EP21835979.2A
Authority: EP
Inventors: Florian HUELSMANN
Original assignee: Bayerische Motoren Werke AG
Current assignee: Bayerische Motoren Werke AG
Priority date: 2021-01-18
Filing date: 2021-12-02
Publication date: 2023-11-22
Also published as: CN116507532A; DE102021100896A1; WO2022152461A1; US20240051505A1

Abstract

The invention relates to a method for monitoring traction for a motor vehicle, in particular for a single-track motor vehicle, comprising a PID drive slip regulator (2) for regulating the drive slip κ of at least one driven wheel. An actual wheel slip κ_ist and a target wheel slip κ_soll are used as input variables of the PID drive slip regulator (2), wherein the PID drive slip regulator (2) ascertains a wheel drive torque M_AR,PID from the sum of a P component M_AR,P, an I component M_AR,I, and a D component M_AR,D of the PID drive slip regulator (2) and feeds said wheel drive torque back to the at least one driven wheel; a transverse force potential F_x,max, which constitutes the maximally transmissible transversal force of the at least one driven wheel onto a lane under current operating conditions, is determined using the I component M_AR,I of the PID drive slip regulator (2); and the target wheel slip κ_soll is determined using the transverse force potential F_x,max.

Description

Traction control method for a motor vehicle

Description:

The invention relates to a method for traction control for a motor vehicle, in particular a single-track motor vehicle, with a PID traction controller for controlling traction K of at least one driven wheel. A traction control system describes a system that controls the drive torque of a motor vehicle in such a way that maximum propulsion or maximum traction is generated while maintaining vehicle stability. The controlled system of a traction control system essentially consists of a motor, a drive train and at least one driven wheel or a tire of the at least one driven wheel. While the transmission behavior of the engine and drive train can be regarded as constant, the transmission behavior of the tire is depends on many influencing variables and is therefore highly variable. For optimal parameterization of the traction control system, all tire influencing variables and their effect on the transmission behavior of the tire must be known. As a rule, however, this is not possible with the traction control systems known from the prior art.

A PID controller (proportional-integral-derivative controller) consists of the parts of a P element, an I element and a D element and can be defined either from a parallel structure or a series structure. In this case, the P element has a proportional transmission behavior and the P component accordingly consists exclusively of a proportional component of an amplification and is therefore proportional to the input signal with its output signal. The I-element has an integrative transmission behavior and accordingly the I-part acts on the manipulated variable by integrating the input signal over time. Furthermore, the D-element has a differentiating transmission behavior and does not react to the level of the input signal, but rather to its rate of change. Accordingly, the D component depends on the rate of change of the input signal.

A common approach is to let the driver of the motor vehicle adapt the traction control system to specific tire influencing variables, such as a coefficient of friction on the road. For this purpose, the driver can choose from a number of different parameterizations of the traction control system, e.g. in the form of driving modes. Accordingly, the driver can select the driving mode which seems best suited to the prevailing conditions.

In addition or instead, an attempt is made to measure or estimate as many of the tire influencing variables as possible and to adapt the traction control system in accordance with the influencing variables determined. This requires However, it requires a lot of development effort and is prone to errors due to the large number of influencing factors. The usual components for measuring and estimating the tire influencing variables are also very expensive, for example due to special sensors and/or very complex to develop, for example for a friction value estimator.

It is therefore an object of the present invention to provide a method for traction control for a motor vehicle, in particular a single-track motor vehicle, with a PID traction slip controller for controlling traction K of at least one driven wheel, in which the control behavior improves and the development effort for data entry of the PID -Traction slip controller is reduced.

This object is achieved by the combination of features according to claim 1.

According to the invention, a method for traction control for a motor vehicle, in particular a single-track motor vehicle, with a PID traction controller for controlling a traction slip K of at least one driven wheel is proposed. An actual wheel slip Kactual and target wheel slip Ksoii are used as input variables of the PID traction slip controller. The PID traction controller determines a wheel drive torque MAR, RID from a sum of a P component MAR.P, an I component MAR.I and a D component MAR.D of the PID traction controller, which this to the at least one driven wheel returns. A longitudinal force potential Fx.max, which represents a maximum transferrable longitudinal force of the at least one driven wheel on a roadway under current operating conditions, is determined using the I component MAR.I of the PID traction controller and the target wheel slip Ksoii is calculated using the longitudinal force potential Fx,max. Since the longitudinal force potential F _x ,max cannot be measured directly and is difficult to calculate, the longitudinal force potential Fx.max is estimated using the I component of the PID slip controller. If the setpoint slip of the controller is optimal, the controller regulates the maximum longitudinal force of the tire. The I component MAR.I of the PID controller reflects exactly the longitudinal force potential F _x ,max of the tire and can therefore be used to adapt the traction control system. The advantage of this is that a fully adaptive traction control system is designed, which does not require expensive sensors and complex estimation algorithms and can therefore be developed and sold inexpensively. The method for traction control according to the invention enables the developer to resolve existing conflicts of interest in the application of the traction control system, which arise due to the limited number of driving modes and measured or estimated variables. In addition, the driver gains other advantages, such as improved safety and performance as well as increased ease of use, since the driver does not have to select different driving modes.

In an advantageous embodiment it is provided that the P component MAR.P, the I component MAR.I and the D component MAR, ö of the PID traction controller are each multiplied by a factor for parameterizing the PID traction controller, the respective factors for the parameterization of the PID drive slip controller based on the longitudinal force potential Fx.max. In this way, the optimal parameterization of the PID traction slip controller is matched to the longitudinal force potential F _x ,max, and thus to a roadway under current operating conditions.

In a preferred embodiment of the invention, the traction controller regulates the traction by adjusting an engine torque, as a result of which the wheel drive torque MAR.PID is changed. As a result, the traction control process or the PID Drive slip controller for controlling the drive slip K of at least one driven wheel in the engine control and regulates the corresponding slip.

In an exemplary embodiment of the invention, provision is made for the actual wheel slip Kact to be determined using a vehicle speed VFZG and a circumferential wheel speed VAR.

In one embodiment variant, the method according to the invention determines the longitudinal force potential F _x ,max, which represents a maximum transmissible longitudinal force of a tire of the at least one driven wheel under current operating conditions. The current operating conditions include at least an influence of a road surface, a temperature, a speed, a wheel load, an internal tire pressure and/or an intermediate medium which is arranged between the tire and the road surface. The advantage of this is that the longitudinal force potential F _x ,max of the tire(s) whose drive torque is/are controlled by the traction control system represents an overarching state variable of the tire, which can be used to adapt the traction control system to all tire influencing variables. The longitudinal force potential F _x ,max represents the maximum transferrable longitudinal force of the tire under the prevailing conditions. This state variable is determined by all tire influencing variables that influence the traction control system and represents a representative summary of all tire influencing variables. Using the longitudinal force potential F _x ,max, all relevant parameters of the traction control system can be adjusted to the tire influencing variables. In particular the wheel slip Ksoii, as well as the control parameters of the slip controller, in particular the P, I and D factors of a PID slip controller.

Furthermore, an embodiment is favorable in which the I component MAR.I is low-pass filtered using a low-pass filter. Accordingly, the target Slip control a setpoint wheel slip Ksoii as an input variable of the PID traction slip controller using the longitudinal force potential F _x , max, which is determined using the low-pass filtered I component MAR.I. Feedback effects can be avoided by means of a heavily low-pass filtered I component I MAR.I before it is used as longitudinal force potential F _x ,max for the adaptation of the traction control system.

According to the invention, a PID traction slip controller for controlling a traction slip K of at least one driven wheel of a motor vehicle, in particular a single-track motor vehicle, preferably for carrying out the method according to one of the preceding claims, comprising a. Sensors for measuring a vehicle speed VFZG and a circumferential wheel speed VAR and b. a setpoint slip control for determining a longitudinal force potential Fx.max, which represents a maximum transmissible longitudinal force of the wheel, in particular a tire, under current operating conditions and can be determined using the I component MAR.I of the PID traction slip controller.

Furthermore, a target wheel slip Ksoii can be determined as an input variable of the PID traction slip controller by the target slip control using the determined longitudinal force potential Fx,max.

The advantage of this is that the method for traction control for a motor vehicle, in particular a single-track motor vehicle, can be used to control a drive slip K of at least one driven wheel by means of the corresponding PID traction slip controller.

In an advantageous variant, it is provided according to the invention that the PID traction controller has a low-pass filter for low-pass filtering of the I Share MAR.I has. Correspondingly, a target wheel slip Ksoii can be determined as an input variable of the PID traction slip controller by the target slip control using the longitudinal force potential F _x ,max, which is determined using the low-pass filtered I component MAR.I. It is favorable here that feedback effects can be avoided with a heavily low-pass filtered I component I MAR.I before it is used as longitudinal force potential Fx.max for adapting the traction control system.

The features disclosed above can be combined as desired, insofar as this is technically possible and they do not contradict one another.

Other advantageous developments of the invention are characterized in the dependent claims or are presented in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. It shows:

1 shows a block diagram of a PID traction slip controller for controlling a traction slip K of a driven wheel of a motor vehicle.

The figures are schematic by way of example. The same reference numbers in the figures indicate the same functional and/or structural features.

FIG. 1 shows a block diagram of a PID traction slip controller 2 for controlling a traction slip K of a driven wheel of a motor vehicle. The PID traction controller 2 for controlling the traction K of the driven wheel of a motor vehicle includes sensors for measuring a vehicle speed VFZG and a circumferential wheel speed VAR as well as a target slip controller 3 for determining a longitudinal force potential F _x ,max, which is a maximum transmissible longitudinal force of the wheel, in particular of a tyre, under current operating conditions and using the I component MAR.I of the PID Traction controller 2 can be determined. Furthermore, a target wheel slip Ksoii can be determined as an input variable of the PID traction slip controller 2 by the target slip controller 3 using the determined longitudinal force potential F _x ,max.

Furthermore, the PID traction controller 2 has a low-pass filter 5 for low-pass filtering of the I component MAR.I. A target wheel slip Ksoii can be determined as an input variable of the PID traction slip controller 2 by the target slip controller 3 using the longitudinal force potential F _x ,max, which can be determined using the low-pass filtered I component MAR.I.

In addition, the PID traction controller 2 is designed to carry out the method described below for traction control for a motor vehicle to regulate a traction K of a driven wheel.

In the method, an actual wheel slip Kactual and setpoint wheel slip Ksoii are used as input variables of the PID traction slip controller 2 and the PID traction slip controller determines 2 a wheel drive torque MAR.PID from a sum of a P component MAR.P, an I Portion MAR.I and a D portion MAR.D of the PID traction controller 2, which is fed back to the at least one driven wheel. The actual wheel slip Kactual is determined using a vehicle speed VFZG and a circumferential wheel speed VAR. Furthermore, a longitudinal force potential F _x ,max, which represents a maximum transmissible longitudinal force of the at least one driven wheel on a roadway under current operating conditions, is determined using the I component MAR.I of the PID traction controller 2 . In addition, the setpoint wheel slip Ksoii is determined using the longitudinal force potential F _x ,max.

The longitudinal force potential F _x , max also represents a maximum transmissible longitudinal force of a tire of the at least one driven wheel under current operating conditions. The corresponding current In this case, operating conditions include at least an influence of a road surface, a temperature, a speed, a wheel load, an internal tire pressure and/or an intermediate medium which is arranged between the tire and the road surface.

The method also includes that the P component MAR.P, the I component I MAR.I and the D component MAR, ö of the PID traction controller 2 are each multiplied by a factor for parameterizing the PID traction controller 2 . The respective factors for parameterizing the PID traction controller 2 are determined on the basis of the longitudinal force potential F _x ,max. In addition, the traction controller 2 regulates the traction by adjusting an engine torque, which changes the wheel drive torque MAR, piD.

In addition, the I component MAR.I is low-pass filtered using a low-pass filter 5 . Accordingly, the setpoint slip control 3 determines a setpoint wheel slip Ksoii as an input variable of the PID traction slip controller 2 using the longitudinal force potential F _x ,max, which is determined using the low-pass filtered I component MAR.I.

The implementation of the invention is not limited to the preferred exemplary embodiments given above. Rather, a number of variants are conceivable which make use of the solution shown even in the case of fundamentally different designs.

Claims

Claims Method for traction control for a motor vehicle, in particular a single-track motor vehicle, with a PID traction slip controller (2) for controlling a traction slip K of at least one driven wheel, with an actual wheel slip Kactual and target wheel slip Ksoii as input variables of the PID traction slip controller (2nd ) are used, with the PID traction slip controller (2) generating a wheel drive torque MAR, RID from a sum of a P component MAR.P, an I component MAR.I and a D component MAR.D of the PID traction slip controller ( 2) determined and fed back to the at least one driven wheel, with a longitudinal force potential F _x , max, which represents a maximum transferrable longitudinal force of the at least one driven wheel on a roadway under current operating conditions, using the I component MAR.I of the PID traction slip controller (2) is determined, with the setpoint wheel slip Ksoii being determined by means of the longitudinal force potential F _x ,max. Method according to Claim 1, in which the P component MAR.P, the I component MAR.I and the D component MAR.D of the PID traction slip controller (2) are each multiplied by a factor for parameterizing the PID traction slip controller (2). with the respective factors for the parameterization of the PID traction controller (2) being determined on the basis of the longitudinal force potential Fx.max. Method according to one of Claims 1 or 2, in which the traction controller (2) controls the traction slip by adjusting an engine torque, whereby the wheel drive torque MAR.PID is changed.

4. The method according to any one of the preceding claims, wherein the actual wheel slip Kactual is determined using a vehicle speed VFZG and a circumferential wheel speed VAR.

5. The method according to any one of the preceding claims, wherein the longitudinal force potential F _x ,max represents a maximum transmissible longitudinal force of a tire of the at least one driven wheel under current operating conditions, the current operating conditions having at least one influence of a roadway, a temperature, a speed, a Wheel load, a tire pressure and / or an intermediate medium, which is arranged between the tire and the road surface include.

6. The method according to any one of the preceding claims, wherein the I component MAR.I is low-pass filtered by means of a low-pass filter (5), wherein the setpoint slip control (3) calculates a setpoint wheel slip Ksoii as an input variable of the PID traction slip controller (2) by means of the Longitudinal force potential determined as Fx.max, which is determined using the low-pass filtered I component MAR.I.

7. PID traction controller (2) for controlling a traction slip K of at least one driven wheel of a motor vehicle, in particular a single-track motor vehicle, preferably for carrying out the method according to one of the preceding claims, comprising a. Sensors for measuring a vehicle speed VFZG and a circumferential wheel speed VAR and b. a target slip control (3) for determining a longitudinal force potential F _x ,max, which is a maximum transmissible longitudinal force of the wheel, in particular a tire, under current operating conditions (4) and can be determined by means of the I component MAR.I of the PID traction slip controller (2), with a target wheel slip Ksoii as an input variable of the PID traction slip controller (2) by the Target slip control can be determined by means of the determined longitudinal force potential Fx,max. PID traction slip controller (2) according to claim 7, wherein the PID traction slip controller (2) has a low-pass filter (5) for low-pass filtering of the I component MAR.I, with a target wheel slip Ksoii as an input variable of the PID traction slip controller (2 ) through the target

Slip control (3) can be determined by means of the longitudinal force potential F _x ,max, which can be determined by means of the low-pass filtered I component MAR.I.