METHOD FOR ASCERTAINING VEHICLE CHARACTERISTIC VARIABLES

Abstract

A method for determining vehicle characteristic variables of a motor vehicle. The motor vehicle has active dampers which can set adjusting forces at the respective wheel suspensions in order to be able to raise and/or lower the body of the motor vehicle and which can also measure the acting forces. Specific predefined adjusting forces of the active dampers are imparted in order to ascertain vehicle characteristic variables from the resulting adjustment and the resulting measured forces.

Claims

1. A method for determining vehicle characteristic variables of a motor vehicle, wherein the motor vehicle has active dampers which are configured to set adjusting forces at the respective wheel suspensions in order to be able to raise and/or lower a body of the motor vehicle and which can also measure acting forces, said method comprising: imparting specific predefined adjusting forces by the active dampers; ascertaining a vehicle characteristic variable from the resulting adjusting forces and the resulting measured forces.

2. The method as claimed in claim 1, further comprising raising, pitching and/or rolling of the body of the motor vehicle by means of the imparted adjusting forces.

3. The method as claimed in claim 1, wherein the method for determining vehicle characteristic variables is executed when the motor vehicle is at a standstill.

4. The method as claimed in claim 1, wherein the method for determining vehicle characteristic variables is executed only after prior initiation and/or confirmation by a driver of the motor vehicle, and/or wherein the method for determining vehicle characteristic variables is executed in predefined parking locations and/or during travel through predefined route positions.

5. The method as claimed in claim 1, wherein the ascertainable vehicle characteristic variable is one of the following vehicle characteristic variables: a spring characteristic curve of a respective damper, friction of a respective damper, vertical natural frequency, vehicle mass, roll frequency, pitch frequency, center of gravity position in a vehicle longitudinal direction, center of gravity position in a vehicle transverse direction, center of gravity position in a vehicle vertical direction, imbalance of a respective wheel, rotation resistance of a respective wheel, and wheel natural frequency.

6. The method as claimed in claim 1, wherein the ascertained vehicle characteristic variables are output to a driver of the motor vehicle either visually on a display or acoustically.

7. The method as claimed in claim 1, wherein the ascertained vehicle characteristic variables are transmitted to a control unit and/or a control program in order to perform control of the motor vehicle on the basis of at least one of the vehicle characteristic variables.

8. The method as claimed in claim 1, wherein actuation of the dampers is set on the basis of the ascertained vehicle characteristic variables in specific driving programs and/or in specific driving situations.

9. The method as claimed in claim 1, wherein the method for determining vehicle characteristic variables is executed only after prior initiation and/or confirmation by a driver of the motor vehicle.

10. The method as claimed in claim 1, wherein the method for determining vehicle characteristic variables is executed in predefined parking locations.

11. The method as claimed in claim 1, wherein the method for determining vehicle characteristic variables is executed during travel through predefined route positions.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] Below, the invention will be discussed in detail on the basis of an exemplary embodiment and with reference to the drawing. In the drawing:

[0015] FIG. 1 shows a schematic view of a motor vehicle,

[0016] FIG. 2 shows a diagram for explanation of the method according to aspects of the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0017] FIG. 1 shows a motor vehicle 1 with a body 2 and with wheels 3, wherein the wheels 3 are connected to the body 2 in adjustable fashion by means of active dampers 4. Here, the active dampers 4 engage at one side on a wheel suspension 5 or on a wheel carrier and at the other side on a body articulation point 6.

[0018] By means of an active damper 4, adjusting forces can be set at the respective wheel suspensions 5 in order to raise and/or lower the body 2 of the motor vehicle 1.

[0019] Here, the active dampers 4 also have integrated sensors, which can for example detect the acting force and optionally also the adjustment travel and/or the present adjustment position.

[0020] In the method for ascertaining vehicle characteristic variables, specific predefined adjusting forces of the active dampers 4 are imparted in order to ascertain a vehicle characteristic variable from the resulting adjustment and the resulting measured forces.

[0021] By means of the actuation of the active dampers 4, a raising, pitching and/or rolling of the body 2 of the motor vehicle can be effected by means of the imparted adjusting forces, see the arrows 7, 8.

[0022] Here, a raising means a lifting movement of the body 2 as a whole, in particular to substantially the same extent at the front and at the rear on the motor vehicle 1 or at the front axle 9 and at the rear axle 10.

[0023] Furthermore, a pitching means an oscillating movement about an axis lying parallel to the vehicle transverse direction, such that the motor vehicle 1 is moved up and down at the front in a manner opposite to an up-and-down movement at the rear.

[0024] Furthermore, a rolling means an oscillating movement about an axis lying parallel to the vehicle longitudinal direction, such that the motor vehicle 1 is moved up and down on the driver's side in a manner opposite to an up-and-down movement on the front-passenger side.

[0025] For the safe execution of the method for determining vehicle characteristic variables, the method may for example be carried out only in specific measurement operating situations of the motor vehicle 1. This may occur in particular when the motor vehicle 1 is at a standstill or at low vehicle speeds, in particular below 50 km/h.

[0026] It can also increase safety if the method for determining vehicle characteristic variables is executed, in particular only, after prior initiation and/or confirmation by the driver of the motor vehicle, and/or in that the method for determining vehicle characteristic variables is executed, in particular only, in predefined parking locations and/or during travel through predefined route positions. It is thus achieved that predefined safety conditions must be present in order to be able to execute the method.

[0027] It is particularly advantageous if the ascertainable vehicle characteristic variable is one of the following vehicle characteristic variables: a spring characteristic curve of a respective spring-damper strut, friction of a respective spring-damper strut, vertical natural frequency, vehicle mass, roll frequency, pitch frequency, center of gravity position in a vehicle longitudinal direction, center of gravity position in a vehicle transverse direction, center of gravity position in a vehicle vertical direction, imbalance of a respective wheel, rotation resistance of a respective wheel, wheel natural frequency.

[0028] The determination of the spring characteristic curves of a respective spring-damper strut 4 and the determination of the friction of a respective spring-damper strut 4 may be carried out for each spring-damper strut 4 at one of the wheels 3.

[0029] FIG. 2 shows the measurement of the force as a function of the travel in the case of such a determination of the spring characteristic curve. Here, the difference in the forces between the force during raising and the force during lowering gives rise to the hysteresis, from which the friction can be ascertained.

[0030] For the determination of the spring characteristic curve or the spring characteristic curves and the friction of the spring-damper strut 4 at the wheels 3, a vertical up-and-down movement is imparted at the dampers 4 of all of the wheels 3. Here, the forces of the active dampers 4 required for this are ascertained as a function of the adjustment travel, and from these a spring characteristic curve can be ascertained, wherein, from this respective spring characteristic curve for each damper 4, it is also possible to ascertain the hysteresis, from which the friction can be ascertained for each damper 4. The respective spring characteristic curve is thus ascertained from a directly measured relationship of force and travel, and the friction is ascertained from the width of the hysteresis band.

[0031] The determination of the vertical natural frequency and of the vehicle mass can be performed as follows: The body is raised and allowed to fall so as to effect a vertical reciprocating movement. The natural frequency of the body can be ascertained from this. The occurring oscillating movement with damping can thus be evaluated, such that, with the spring constants from the spring characteristic curve and the friction, the body natural frequency and the vehicle mass can be ascertained. The natural frequency can be ascertained by means of a frequency analysis of the occurring oscillating movement. The vehicle mass can be ascertained from the relationship f˜√(/), with the spring stiffness c of the spring constants. The frequency f is measured. The vehicle mass m can thus be estimated.

[0032] The roll/pitch natural frequency can thus be ascertained:

[0033] Rolling/pitching movement inducement is performed, and the body is allowed to oscillate in as far as possible undamped fashion. The roll or pitch natural frequency is ascertained from this. The roll natural frequency is ascertained by means of the rolling movement inducement and a frequency analysis of the occurring undamped oscillation. The pitch natural frequency is ascertained by means of the pitching movement inducement and a frequency analysis of the occurring undamped oscillation.

[0034] The center of gravity position in the vehicle longitudinal direction (x) and in the vehicle transverse direction (y) respectively is ascertained as follows: A vertical reciprocating movement, with falling and braking of the falling movement by the dampers, is imparted. From the forces ascertained during the braking for each wheel, together with the spring stiffnesses, the respective friction and the damping, it is possible for the respective center of gravity position in the x direction and in the y direction to be ascertained. The center of gravity position in the x direction: The force required for braking the body falling movement of the body and the associated acceleration are measured on an axle-specific basis, that is to say for the front axle and the rear axle. From =•, the axle load is calculated, and from this the center of gravity position in the x direction can be ascertained. The center of gravity position in y: The force required for braking the body falling movement of the body and the associated acceleration are measured on a right-left split basis, that is to say for the driver's side and the front-passenger side. From =•, the side load is calculated, and from this the center of gravity position in the y direction can be ascertained.

[0035] The center of gravity position in the vehicle vertical direction (z) is ascertained as follows: Steady-state pitching/rolling is imparted by means of the dampers 4. From this, the acting forces are measured. By means of the geometrical relationship of pitch/roll angle and the steady-state wheel load shift, the height of the center of gravity is calculated. For this purpose, by means of the forces and by means of the vehicle weight and the spring stiffnesses, the center of gravity position in the z direction is ascertained.

[0036] The determination of imbalances or rotation resistances is performed as follows: A single wheel 3 is raised and is driven for example by means of a wheel-specific motor. From the rotational speed and the fluctuation thereof and acting forces, a detection of possible imbalances can be performed by means of the damper 4. At an axle which is further remote from the center of gravity, single wheels 3 can be raised and driven. From =(•.sup.2)/, an imbalance yields a force or vibration which is periodic with the rotational speed and which can be measured by means of the damper 4. Brake/bearing friction can be measured directly from the required drive torque.

[0037] The determination of the wheel natural frequency can be performed as follows: A single wheel 3 can be raised and allowed to fall. The natural frequency can be performed by means of a frequency analysis of the occurring oscillating movement.

[0038] In one advantageous exemplary embodiment, the ascertained vehicle characteristic variables may be output to the driver, in particular visually on a display or acoustically. The driver can thus be made aware of the ascertained values.

[0039] It is also advantageous if the ascertained vehicle characteristic variables are transmitted to a control unit and/or a control program in order to perform control of the motor vehicle on the basis of at least one of the vehicle characteristic variables.

[0040] Correspondingly, the actuation of the dampers 4 can be set on the basis of the ascertained vehicle characteristic variables, in particular in specific driving programs and/or in specific driving situations.

LIST OF REFERENCE DESIGNATIONS

[0041] 1 Motor vehicle [0042] 2 Body [0043] 3 Wheel [0044] 4 Damper [0045] 5 Wheel suspension [0046] 6 Body articulation point [0047] 7 Arrow [0048] 8 Arrow [0049] 9 Front axle [0050] 10 Rear axle