DE10232362B4 - Method and device for stabilizing a single-track motor vehicle - Google Patents

Abstract

A method for stabilizing a single-track motor vehicle during a present cornering braking, in which
- The output signal (aq) of a mounted on the motor vehicle lateral acceleration sensor is evaluated (201) and
- Depending on this output signal (aq) at least at one wheel of the motor vehicle, the braking torque is reduced (203),
characterized in that
- In addition, a yaw rate sensor (301) is mounted on the motor vehicle and is determined depending on the output signal of the yaw rate sensor on which wheel or wheels, the braking torque is reduced.

Description

State of the art

The invention relates to a method and a device for stabilizing a single-track vehicle.

From the DE 38 39 520 A1 is a anti-lock brake system for single-track motor vehicles known. This brake system provides that the decisive for the initiation of a control process threshold with respect to the rotational deceleration and / or the slip of a braked wheel is changed depending on whether the vehicle lateral acceleration occurs. The measurement of the lateral acceleration is possible in four-wheel vehicles, for example, with simple mechanical devices such as a pendulum or the like, because the vehicle assumes no bias disturbing the measurement during cornering. However, a motorcycle goes into cornering in a dependent of the centrifugal force tilt, so that simple mechanical means for the determination of the lateral acceleration are not available. The determination of the lateral acceleration is therefore carried out by evaluating the axle loads.

From the generic DE 42 44 112 A1 An anti-lock control system for motorcycles is known. In order to achieve that after a clearly identified cornering a modified anti-lock control is activated, which adapts dynamically to the degree of tilt reached, it is proposed to detect the cornering and the degree of skew by two acceleration sensors and to supplement the monitoring circuit by an auxiliary circuit , which causes the ABS controller by control signals to stop the brake pressure on the front wheel before reaching the expected blocking pressure.

Advantages of the invention

The object of the invention is to enable the output signals of a lateral acceleration sensor and a yaw rate sensor effective stabilization of a single-track motor vehicle during a present curve braking.

This object is achieved by a method having the features of claim 1 and an apparatus having the features of claim 6.

• – das Ausgangssignal eines am Kraftfahrzeug angebrachten Querbeschleunigungssensors ausgewertet wird und
• – abhängig von diesem Ausgangssignal wenigstens an einem Rad des Kraftfahrzeugs das Bremsmoment reduziert wird,

Der Kern der Erfindung ist dadurch gekennzeichnet, dass

• – am Kraftfahrzeug zusätzlich ein Gierratensensor angebracht ist und abhängig vom Ausgangssignal des Gierratensensors festgelegt wird, an welchem Rad oder welchen Rädern das Bremsmoment reduziert wird.

The invention relates to a method for stabilizing a single-track motor vehicle during a present curve braking, in which

• - The output of a mounted on the motor vehicle lateral acceleration sensor is evaluated and
• Is dependent on this output signal at least at one wheel of the motor vehicle, the braking torque is reduced,

The essence of the invention is characterized in that

• - In addition, a yaw rate sensor is mounted on the motor vehicle and is determined depending on the output signal of the yaw rate sensor on which wheel or wheels, the braking torque is reduced.

By evaluating the output signal of the lateral acceleration sensor, it is possible to detect a risk of slipping due to insufficient cornering force and as a remedy to reduce the braking torque in the longitudinal direction. Transverse acceleration sensors are proven components and are already being used as part of the vehicle dynamics control system for two-lane vehicles. By evaluating the output signal of the yaw rate sensor can be determined in a simple manner (by the sign) that wheel on which there is a too low cornering force. Similar to the lateral acceleration sensors, yaw rate sensors are proven components and are already being used as standard within the vehicle dynamics control of two-lane vehicles.

An advantageous embodiment is characterized in that the braking torque at at least one wheel is reduced when the change of the output signal of the lateral acceleration sensor per unit time (i.e., the change of the output signal divided by the length of the considered time interval) exceeds a first limit value.

An alternative embodiment is characterized in that the braking torque is reduced at least one wheel when the output signal of the lateral acceleration sensor exceeds a second threshold.

Both embodiments can be implemented easily and inexpensively in a control unit.

An advantageous embodiment is that the braking torque is reduced at least one wheel until the output of the lateral acceleration sensor falls below a third threshold. The undershooting of the third limit value by the output signal ensures that the vehicle has stabilized again, a further reduction of the braking torque is then no longer necessary.

An advantageous embodiment is characterized in that the braking torque is reduced at both wheels when a rapid variation of the transverse acceleration takes place during braking, wherein the yaw rate signal is not changed by the reduction of the braking torque on both wheels ensures that a sufficiently large for both wheels Cornering force can be built.

• – einen am Kraftfahrzeug angebrachten Querbeschleunigungssensor aufweist sowie
• – Bremsmittel, durch die abhängig vom Ausgangssignal des Querbeschleunigungssensors wenigstens an einem Rad des Kraftfahrzeugs das Bremsmoment reduziert wird, gekennzeichnet durch
• – einen am Kraftfahrzeug zusätzlich angebrachten Gierratensensor, wobei
• – abhängig vom Ausgangssignal des Gierratensensors festgelegt wird, an welchem Rad oder welchen Rädern durch die Bremsmittel das Bremsmoment reduziert wird.

Furthermore, the invention comprises a device for stabilizing a single-track motor vehicle during a present braking curve, which

• - Has a mounted on the motor vehicle lateral acceleration sensor and
• - Braking means by which the braking torque is reduced depending on the output signal of the lateral acceleration sensor at least on a wheel of the motor vehicle, characterized by
• - An additionally mounted on the motor vehicle yaw rate sensor, wherein
• - Is determined depending on the output signal of the yaw rate sensor on which wheel or which wheels by the braking means, the braking torque is reduced.

drawing

Methods and devices for stabilizing a single-track motor vehicle during a present curve braking and an embodiment of the invention are shown in the drawings 1 to 4.

1 shows the forces acting on the motor vehicle forces. In this case, the centrifugal force Fz is plotted on the arrow pointing to the left (= outside of the curve) and the weight G is applied on the arrow pointing downwards.

2 shows the sequence of a method for stabilizing a single-track motor vehicle during a present curve braking.

3 shows the construction of a device for stabilizing a single-track motor vehicle during a present curve braking.

4 shows the sequence of the method according to the invention.

embodiments

In stable cornering, for a single-track motor vehicle, such a balance of forces of centrifugal force Fz and gravitational force G prevails that the resulting line of force from the center of gravity of the single-track motor vehicle (or motorcycle) passes through the tire footprint. This is in 1 shown, which shows in schematic form a front view and rear view of the motorcycle. It indicates 101 the wheel of the motorcycle, 102 indicates the side of the tire which has road contact and 100 marks the construction of the motorcycle including the driver. In addition, the forces Fz (centrifugal force) and G (gravitational force) as well as the resulting force (ie the vectorial sum of Fz and G), which goes through the tire contact patch are plotted. A cross-acceleration sensor mounted on the motorcycle tilts with the motorcycle while cornering. Consequently, in such a trip, a transverse acceleration sensor installed in the motorcycle does not indicate any relevant lateral acceleration (this is due to the fact that the total vectorial force with the components Fz and G is perpendicular to the lateral acceleration sensor). A stable driving state in the curve is thus essentially characterized by the fact that the measured lateral acceleration is very small. If braking takes place when cornering, with the tires always applying the required cornering force, the lateral acceleration signal will hardly change. However, if the required cornering force can no longer be applied by the contact roadway tire, the described balance is disturbed and the lateral acceleration signal is clearly different from zero. If, for example, the cornering force breaks spontaneously to the value zero, then the lateral acceleration sensor indicates the value g · sin (β), where β describes the inclination of the motorcycle against the perpendicular.

If a strong change in the lateral acceleration signal occurs during a braking intervention, then this is a clear sign that the driving condition is critical and that more cornering force is needed to stabilize the vehicle again. Therefore, it is proposed that the braking torque is reduced until the lateral acceleration signal is again within limits yet to be determined. For example, the braking torque on at least one wheel can be reduced if the change per unit time of the output signal aq of the lateral acceleration sensor exceeds a first limit daq1 / dt (the notation daq1 / dt denotes a first limit value of the quantity daq / dt). Alternatively, it is also possible that the braking torque is reduced when the output signal aq of the lateral acceleration sensor exceeds a second limit value aq2. This reduction of the braking torque is continued until the output signal aq again falls below a third limit value aq3.

The procedure of a method for stabilizing a single-track motor vehicle during a present cornering braking is in 2 shown. It will be in block 200 Brake information collected, ie it is determined whether a braking is present and with what intensity is braked. In the block 201 the output signal of the lateral acceleration sensor or its time derivative is detected. The output signals of the blocks 200 and 201 become the correlation block 202 fed. In the correlation block 202 It is determined whether there is a braking intervention and whether the change per unit time of the lateral acceleration signal aq exceeds a predetermined limit. This limit is called daq1 / dt. The output signal of the block 202 gets to the regulator 203 passed. Will be in the block 202 a correlation between braking intervention and temporal change of the lateral acceleration signal detected, then the braking torque by the controller 203 at the wheels reduced until the lateral acceleration signal is again approximately zero or until this value is again within yet to be determined limits (aq3). This will be in the block 204 a comparison of the lateral acceleration signal aq with, for example, a limit aq3 instead, ie it is queried whether | aq | <aq3 is satisfied.

In a non-inventive exchange stage of this controller can be used, for example, with two spatially separated lateral acceleration sensors to determine which wheel was built to high side slip. Each of these two lateral acceleration sensors is assigned to a wheel. This decision is made according to the invention by means of a yaw rate sensor whose measuring axis points in the direction of the motorcycle vertical axis. If the change in the lateral acceleration signal correlates to an increase or decrease in the yaw rate, then either the front or the rear wheel has too little cornering force, because the yaw rate is a measure of the rotational movement and direction of rotation of the motor vehicle. Therefore, the "slipping" of a wheel over the yaw rate can be observed. If during the braking process a rapid variation of the measured lateral acceleration takes place, whereby the yaw rate signal does not change, then there is a loss of cornering forces on both wheels.

The structure of a device for stabilizing a single-track motor vehicle during a present cornering braking is in 3 shown. This characterizes Block 301 the sensor means. According to the invention, these are a lateral acceleration sensor and a yaw rate sensor

The output signals of the sensor means 301 be to the device for vehicle stabilization 302 forwarded. There, the evaluation of the sensor signals. The output signals of block 302 be to the actuator means 303 passed on. At the actuator means 303 it is brake means for braking the two wheels.

• – in Block 404 die Bremskraft am Vorderrad reduziert und/oder
• – in Block 406 die Bremskraft am Hinterrad reduziert.

The sequence of the method according to the invention with a lateral acceleration sensor and a yaw rate sensor is shown in FIG 4 shown. It is in block 401 Brake information collected, ie it is determined whether and with what intensity is braked. Subsequently, in block 402 the output signal of the lateral acceleration sensor or its time derivative (ie, the change per unit time) determined. Subsequently to block 402 will be in block 403 evaluated the output of the yaw rate sensor. After that becomes block 405 moved on. In block 405 it is determined which wheel has too little cornering force. Depending on the result in block 405 will be after that

• - in block 404 reduces the braking force on the front wheel and / or
• - in block 406 reduces the braking force on the rear wheel.

In the case of the use of two lateral acceleration sensors running for example for each wheel in 2 sketched separately.

Claims (6)

Method for stabilizing a single-track motor vehicle during a present braking of a curve, in which - the output signal (aq) of a vehicle-mounted lateral acceleration sensor is evaluated ( 201 ) and - depending on this output signal (aq) at least at one wheel of the motor vehicle, the braking torque is reduced ( 203 ), characterized in that - additionally a yaw rate sensor ( 301 ) is attached and is determined depending on the output of the yaw rate sensor on which wheel or wheels, the braking torque is reduced. A method according to claim 1, characterized in that the braking torque is reduced at least one wheel when the change per unit time of the output signal (aq) of the lateral acceleration sensor exceeds a first limit (daq1 / dt). A method according to claim 1, characterized in that the braking torque is reduced at least one wheel when the output signal (aq) of the lateral acceleration sensor exceeds a second limit value (aq2). Method according to one of claims 2 or 3, characterized in that the braking torque is reduced at least one wheel until the output signal (aq) of the lateral acceleration sensor falls below a third limit value (aq3). A method according to claim 1, characterized in that the braking torque is reduced at both wheels when during braking, a rapid variation of the lateral acceleration takes place, wherein the yaw rate signal does not change. Device for stabilizing a single-track motor vehicle during a present braking of a curve ( 302 ), which - a transverse acceleration sensor attached to the motor vehicle ( 301 ) and - braking means ( 303 ), by the depending on the output signal of the lateral acceleration sensor at least at one wheel of the motor vehicle, the braking torque is reduced, characterized by - a motor vehicle additionally mounted yaw rate sensor, - is determined depending on the output signal of the yaw rate sensor on which wheel or which wheels by the braking means Braking torque is reduced.

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