WO2001032483A1

WO2001032483A1 - Method and system for detection of wheel oscillations

Info

Publication number: WO2001032483A1
Application number: PCT/DE2000/002632
Authority: WO
Inventors: Ulrich Hessmert; Jost Brachert; Thomas Sauter; Helmut Wandel; Norbert Polzin
Original assignee: Robert Bosch Gmbh
Priority date: 1999-11-04
Filing date: 2000-08-05
Publication date: 2001-05-10
Also published as: DE19953030B4; DE19953030A1; KR20010089762A; JP2003512970A; EP1140596A1

Abstract

A method and a system for the detection of wheel oscillations for use in skid control systems for vehicles is disclosed, whereby an oscillation signal is detected by means of tyre sensors (102, 103, 104, 105). It is possible to determine not only the oscillating behaviour of the drive train, but also the oscillating behaviour of a tyre itself (106, 110). A rapid elimination of the effects of disturbances on the regulator performance (108) caused by frictional oscillations is thus possible.

Description

Method and system for detecting wheel vibrations

State of the art

The invention relates to a method for detecting wheel vibrations for use in anti-lock control systems according to the preamble of claim 1 and an associated system.

Wheel vibrations have a significant impact on wheel slip control systems. With the detection of wheel vibrations, controller sizes such as wheel speeds, wheel differentiators can be filtered or corrected in order to improve the control comfort and the controller performance.

From DE 195 16 120 AI em anti-lock control system is known in which brake pressure control signals are generated. The speed at the differential of the drive axle is determined and a frequency analysis of this speed detects the presence of drive train vibrations. In response to this, the activation times of the brake pressure control devices are then influenced in such a way that the drive train vibrations subside. In addition, if drive train vibrations are present, this will result resulting torsional moment with which the

Control times for the brake pressure control devices can be varied in the sense of damping the line vibrations.

In the known anti-lock control system, conventional speed sensor signals are evaluated in order to derive the

Calculate wheel speeds and derived sizes. These input variables serve as detection signals of wheel vibrations.

DE 196 20 581 AI shows, as a way of obtaining signals for the moments transmitted from the wheel to the road and / or for the instantaneous coefficient of friction, a device for determining the rotational behavior of a vehicle wheel, magnetizing surfaces or strips being provided on a tire. Transducers are attached to the body at two or more different positions in the direction of rotation and are also at a different distance from the axis of rotation of the wheel. If the tire is deformed as a result of the forces acting on the tire, a change in the phase position occurs between the measurement signals emitted by the sensors. This change in the phase position is evaluated as a measure of the moments transmitted from the wheel to the driving track and / or for the current row value. DE 196 20 581 AI thus shows tire sensors and signals detected by these tire sensors.

Starting from an anti-lock control system, as is known, for example, from DE 195 16 120 AI, it is the object of the present invention to provide a method and a system for the simple detection of wheel vibrations, whereby e disturbing influence of wheel vibrations on the operation of the anti-lock control system can be further reduced. This object is achieved by the features specified in claims 1 and 10. Advantageous developments of the invention are specified in the dependent claims 2 to 9.

Advantages of the invention

In particular, according to the invention

Powertrain vibrations can be easily determined. By detecting wheel vibrations by means of measurement signals determined with tire sensors according to the invention, a slip control can regulate the desired wheel slip in accordance with the physical course of the wheel. Malfunctions caused by tire vibrations have no influence on the controller performance.

drawing

The invention is explained below with reference to the embodiments described in the drawing.

Figure 1 shows a block diagram of a system for

Performing the method according to the present invention; and

Figures 2a, 2b and 2c show illustrations for explaining the method according to the present invention.

Description of exemplary embodiments

FIG. 1 shows a block diagram of a system for carrying out the method for detecting wheel vibrations according to the present invention. A tire 101, which is representative of all the tires on the vehicle: is provided with measuring surfaces (strips) 102, 103 with field lines, preferably with circumferential directions, as can be seen in FIG. The magnetizing surfaces 102, 103 can be in the tires 101 be incorporated or provided on the outside of the tire 101. The magnetization always takes place in sections in the same direction, but with the opposite orientation, ie it has an alternating polarity. In FIG. 2, the magnetizing surface with positive polarity is designated 102, and the magnetizing surface with negative polarity is designated 103. The magnetized strips 102 and 103 preferably run in the vicinity of the rim flange and in the region of the tire. The sensors 102 and 103 thus rotate at the wheel speed.

Transducers 104 and 105 are attached to the body at two or more points that are different in the direction of rotation and also have a different radial distance from the axis of rotation or the wheel axis 100. This results in an inner signal si, which the sensor 104 detects in the vicinity of the wheel hub, and an outer signal sa, which detects the sensor 105 further away from the wheel hub. The signals si and sa are phase-shifted from one another with a phase position D, as shown in FIG. 2a.

If the tire 101 is deformed or deformed as a result of forces acting on it, such as while driving or braking, a shift in the phase position D between the inner signal si and the outer signal sa by d1 or d2 occurs, as is the case with it is shown in Figures 2b and 2c, respectively.

A rotation of the tire 101 is preferably detected in the circumferential direction via the changing polarity of the measurement signals si and sa. The detected measurement signals si and sa with their respective amplitudes and phases are fed to an evaluation unit 106 shown in FIG. 1 for determining speed signals and phase positions, which with the aid of the known inner and outer circumference of the tire 101 in accordance with the arrangement of the measurement sensors 104, 105, which are also called tire sensors, calculates respective speed signals vi and va, which can then each serve as an input signal for a wheel slip control system 108.

The evaluation unit 106 furthermore determines a change in the phase position from D + dl to D-d2, or vice versa, between the inner signal si and the outer signal sa, which change indicates a deformation of the tire 101 when driving or braking.

The speed signals vi, va are also fed to a unit 110 for determining an oscillation amplitude and frequency. This determination is made by forming a difference va-vi between the speed signals vi and va.

Occurring wheel vibrations initially lead to a rapidly changing peripheral speed vi and va. This rapid change takes place in accordance with a spinning of wheels when starting off or in accordance with a locking of wheels when braking. The (rapidly changing) circumferential speed vi, va in the unit 110 becomes the oscillation amplitude by forming the difference between the speeds va and vi and the associated one

Vibration frequency calculated. If, in addition, a deformation of the tire is detected, which can be determined from a change in the phase position from D + dl to D-d2 between the inner signal si and the outer signal Sa according to the speeds vi and va, as described above with reference to FIG 2b and 2c is described, it is drive train vibrations that can shake the entire vehicle.

Depending on the determined frequencies and amplitudes of the wheel vibration m of the unit 110, the can Wheel slip control system 108 with suitable filter measures or

Corrective measures calculate the control-relevant control deviation as the difference between the filtered speed signal of the slipping wheel and a reference speed Vref. The reference speed Vref can be determined as is known in the prior art. For example, it can be determined from the engine speed.

In addition, vehicle-specific wheel speed profiles of different wheel vibrations can also be stored in the wheel slip control system 108 as a correlation of the values sa, si and va, vi, in order to immediately initiate controller damping measures when a vibration occurs. The correlation between a changing wheel load and the measurement signal allows the following direct reactions to a detected wheel vibration.

- With a small vibration amplitude, holding the (brake) pressure does not stimulate any further vibrations and the vibration amplitude is damped asymptotically. If the braking torque is increased, the brake pressure on the wheel is increased if no vibration maximum has been reached.

In the case of a large vibration amplitude, active damping takes place by means of targeted brake pressure pulses on the vibrating wheel. A brake pressure increase occurs when a wheel differentiator becomes greater than zero. Brake pressure is reduced when the wheel differentiator becomes less than zero.

The further control in the wheel slip control system 108 takes place as is known from the prior art, for example from DE 195 16 120 AI mentioned at the beginning.

According to the invention, drive train vibrations are identified using measurement signals detected by means of tire sensors. This can cause a Vibration of the tire itself can be recognized, which was previously not possible in the prior art. According to the invention, the influence of disturbing vibrations on the behavior of a controller can be eliminated immediately.

Claims

Expectations

1. A method for recognizing wheel vibrations for use in slip control systems for vehicles, wherein wheel speed signals are fed to an evaluation unit (110) with which control signals for drive train vibrations are taken into account

Wheel slip control systems ( ^" 108) are produced in such a way that the drive train vibrations subside, characterized in that measurement signals (Si, Sa) are detected by means of tire sensors (104, 105) provided on the tire (101) and the drive train vibrations from the measurement signals (Si, Sa) be determined.

2. The method according to claim 1 that the

Drivetrain vibrations can be determined from the measurement signals (Si, Sa) when the speed signals (vi, va) calculated from the measurement signals (Si, Sa) in the evaluation unit (106) change quickly and, at the same time, a deformation of the tire in the evaluation unit (106) (101) by change

(dl, d2) of the phase position (D) between the measurement signals (Si, Sa) from (D + dl) to (D-d2), or vice versa, is detected.

3. The method according to claim 1 or 2, characterized in that the frequency and the amplitude of the wheel vibration is calculated by forming the difference between the speed signals (vi, va) in the unit (110) for determining a wheel vibration.

4. The method according to any one of the preceding claims, characterized in that the speed signals (vi, va) serve as input signals for the wheel slip control system (108).

5. The method according to claim 4, characterized in that the wheel slip control system (108) depending on the frequency and amplitude of the wheel vibration with suitable filter measures the control-relevant control deviation as the difference between the filtered speed signal (va-vi) of a slipping wheel and a reference speed (Vref) ,

6. The method according to claim 5, characterized geκennzeιchnet in that the reference speed (Vref) is determined from the engine speed.

7. The method according to any one of the preceding claims, characterized in that the measurement signals (Si, Sa) em m near the rim of the tire (101) detected measurement signal (Si) and em Latschnahe tire (101) detected measurement signal (Sa), the Measurement signals (Si, Sa) are each taken as measuring sensors (104, 105) from m sensors arranged at different radial distances in the direction of the axis (100) of the vehicle.

8. The method according to any one of the preceding claims, characterized in that in the wheel slip control system (108) vehicle-specific wheel speed curves of different wheel vibrations are stored as a correlation of the values for the measurement signals (sa, si) and the speeds (va, vi) in order to directly eliminate e enable recognized wheel vibration zα.

9. The method according to claim 8, dadurcn characterized in that in the wheel slip control system (108) at a small Schwmgungsamlitude when holding the brake pressure, the Schwmgungsamlitude is asymptotically damped and with increased braking torque the brake pressure on the wheel is increased when no vibration maximum has been reached, and that with a large one

Vibration amplitude active damping takes place through targeted brake pressure pulses on the vibrating wheel, with an increase in brake pressure when a change in wheel difference tends to be larger, and a brake pressure reduction when the change in wheel difference tends to be smaller.

10. System for carrying out the method for detecting wheel vibrations for use in slip control systems for vehicles according to one of the preceding claims, the system comprising: tire sensors (104, 105), a unit (106) for calculating orbital speeds (vi, va) of the tire (101) and a unit (110) for determining drivetrain oscillations by forming a difference (va-vi) between the rotational speeds (vi, va), the values determined for drivetrain oscillations together with values for the tire speed and a reference speed for a wheel slip control system ( 108) can be supplied.