DE102012101274A1 - Method for controlling a motor vehicle during and immediately after a flight phase - Google Patents

Abstract

The invention relates to a method for controlling a motor vehicle during and immediately after a flight phase, whereby sensors detect a flight phase, record the surroundings in the direction of travel and, taking into account vehicle-dynamic variables, at least the vehicle's own speed, evaluate the surroundings and, depending on this, automatically enter the flight Brake control is intervened. The strength of the brake control intervention preferably varies depending on the detection reliability of a hazard immediately after a flight phase, in particular the strength of the brake control intervention is increased with increasing recognition reliability, on the other hand, the brake control intervention aborted, if the driver operates the accelerator pedal.

Description

The invention relates to a method for controlling a motor vehicle during and immediately after a flight phase according to the preamble of claim 1.

When a phase of a vehicle is understood when one or more wheels or even the entire vehicle have lost contact with the road. This is also taken from English as so-called "Airborne" situation called and occurs in particular when driving over hills, ramps or the like, wherein for a flight phase, the change of the road in the vertical direction, ie in the vertical axis of the vehicle and thus perpendicular to the decisive from the longitudinal axis and transverse axis driving plane is crucial.

Such a phase of flight is due to the uneven center of gravity distribution in the vehicle by a Abnicken, ie a rotation about the transverse axis of the vehicle, characterized as usually located there, heavy engine pulls the front of the vehicle due to the influence of gravity in the direction of the road. Such a phase of flight differs from a so-called rollover situation in that the rollovers associated with the term "rollover" are primarily rotational movements of the vehicle about the longitudinal axis, ie the roll rate and its summation to an absolute roll angle and the achievement of a static roll or dynamic tilt angle goes.

While rollover situations are now well recognized by their own algorithms partly based on additionally arranged in the vehicle yaw rate sensors and avoided by intervention of the ESP system and in case of unavoidable protection devices are activated, suitable measures for such flight phases have been hardly discussed.

However, accident statistics show that such a flight phase often leads to extreme driver misconduct and serious accidents involving serious injury to the occupants as well as other involved road users.

From the EP 2289753 A1 is a method and a control device for detecting or plausibility of such a flight phase of a vehicle refer. In particular, suitable sensors and algorithms for detecting such a flight phase on the basis of the acceleration signal in the direction of the vertical axis of the vehicle are taught there. Primarily, those flight phases are considered in which occupant protection devices must be triggered due to the severity of the impact. However, even in less severe airborne situations, the driver is unlikely to be able to actually drive the vehicle for at least the time period during and immediately after landing.

The object of the present invention is therefore to present suitable measures for controlling a motor vehicle during and immediately after a flight phase.

This object is solved by the features of the independent claims. Advantageous developments of the invention will become apparent from the dependent claims, wherein combinations and developments of individual features are conceivable with each other.

An essential idea of the invention is that the environment detected in the direction of travel, so for example to recognize the course of the lane and any obstacles or oncoming traffic, and taking into account vehicle dynamics variables, at least the vehicle's own speed, evaluated and automatically depending on it in the brake control is intervened. As an intervention in the brake control can be provided that the ESC system adapted, so for example its sensitivity is changed. It can brake preparation measures, such as the construction of the brake pressure (pre-brake) are initiated or even an automatic brake intervention. These interventions in the brake control are alternative measures and intervene differently in the driving behavior. Of course, these can also be used together in combination.

By means of sensors, for example acceleration and rotation rate sensors, but possibly also already environment detection sensors, a flight phase is detected. In addition, the environmental detection sensor system detects the surroundings in the direction of travel and, taking into account vehicle-dynamic variables, at least the vehicle's own speed, assesses and automatically intervenes in the brake control as a function of this.

The strength of the brake control intervention as a function of the detection reliability of a hazard immediately after a flight phase varies, in particular with increasing recognition reliability, the strength of the brake control intervention is increased. The brake control intervention is preferably terminated if the driver actuates the accelerator pedal, that is to say the gas pedal or the like.

From the signals of the environmental sensor, the further course of the road on the one hand and from the driving dynamics signals of the vehicle, the course of movement of the vehicle during and on the other hand, immediately after the flight phase is estimated and the intensity of the brake control intervention varies depending thereon.

For example, it checks whether the vehicle can follow the course of the road after the flight phase. In such a case, the strength of the brake control intervention should not reach the full strength of emergency braking.

If, on the other hand, it is recognized that the vehicle will land outside the road or if the vehicle will land on the opposite lane and collide with oncoming vehicles with high probability, or if the vehicle gets off the lane and is likely to collide with stationary obstacles, strong interventions in the brake control required.

In a particularly preferred development, the braking control intervention is also limited in a landing on or immediate agreement on the opposite lane, so that the vehicle can still be moved away from the opposite lane, preferably the time is reduced on the opposite lane.

• – Eigengeschwindigkeit des Fahrzeugs
• – Lenkwinkel oder Lenkdrehrate
• – Querbeschleunigung
• – Gierdrehrate.

The strength of the brake control intervention is also varied in dependence on at least one of the following driving dynamics variables:

• - Vehicle's own speed
• - Steering angle or steering rotation rate
• - lateral acceleration
• Yaw rate.

Depending on these dynamic parameters, a braking intervention will have a different effect on the further controllability of the vehicle and such automatic intervention in the brake control must by no means worsen this controllability even further in this already difficult traffic situation.

The environmental sensor detects the vertical inclination angle of the road in the direction of travel or the distance to the road or preferably both sizes. From this, considering the intrinsic speed of the vehicle, the severity and the potential danger of the situation are derived and depending on, i. For example, correspondingly strong, automatically intervened in the brake control.

A motor vehicle has for this purpose a control unit, which is connected to at least one environment detection sensor. The control unit has an evaluation algorithm for carrying out the method, wherein the sensor detects the surroundings in the direction of travel and the control unit evaluates the surroundings in consideration of the intrinsic speed of the vehicle and automatically intervenes in the brake control as a function of this, i. give appropriate signals to the brake control or the algorithm is integrated into the brake control unit and converts there.

So it is basically in dangerous situations advantageous to reduce the kinetic energy of the vehicle before it comes to an accident. The standard system for reducing kinetic energy is the brake system. In the prior art, this can be combined with an Electronic Stability Control (ESC) function, which is independent of the driver capable of generating braking forces. This can be used to advantage in the present situation to withdraw kinetic energy from the vehicle. Prerequisite is an unambiguous recognition of the dangerous situation and the consideration of the advantages and disadvantages of a driver-independent braking of the vehicle. The amount of engagement for the "false positive" case can be dosed by the amount of brake intervention.

The prerequisite is a situation detection that is clear and reliable. Such recognitions are already well advanced in research and development and make use of camera- and radar-based systems, which provide a reliable overall picture by merging their individual information.

Thus, a method for reducing the severity of an accident is described when the situation clearly indicates that the vehicle has left or is leaving the road after a jump and after landing. The speed and the yaw angle of the vehicle with respect to the road are so large that the vehicle can not follow the road within the physical limits. In this situation, regardless of the driver all four brakes can be operated evenly. The ABS system ensures that the wheels do not lock and the steering ability of the driver is maintained.

The system will brake to a standstill unless the driver overrides the system and accelerates again. The ESC system has a lower priority in this situation than the described brake intervention.

If it is estimated on the basis of the information from the environmental sensors that the vehicle is getting into the opposite lane and threatens a head-on collision with oncoming traffic, is also braked. The speed and the yaw angle of the vehicle in relation to the course of the road are so great here that the vehicle can no longer follow its own lane within the physical limits of the vehicle. In this Situation, regardless of the driver all four brakes can be actuated evenly. The speed reduction must be limited to a value that represents an optimum for the time that the vehicle is in the opposite lane. Extreme case braking on the opposite lane to 0kmh is not advantageous. Again, the deceleration is stopped by accelerating the driver. The ESC system remains active in this situation and can build up a higher pressure wheel-selectively in order to additionally stabilize the vehicle. In addition, the ESC can be switched sensitive, as described in the next section.

If it can be seen that the vehicle can stay in its own lane, the thresholds for the activation criteria of the ESC system are lowered. This can be done sooner than in the default setting, where a compromise between sensitivity and robustness must be found.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2289753 A1 [0006]

Claims (10)

Method for controlling a motor vehicle during and immediately after a flight phase, wherein by means of sensors a flight phase is detected, characterized in that the environment detected in the direction of travel and considering vehicle dynamics variables, at least the vehicle's own speed, evaluated and automatically depending on it in the brake control is intervened. A method according to claim 1, characterized in that the strength of the brake control intervention in dependence on the detection reliability of a hazard immediately after a flight phase varies, in particular with increasing recognition reliability, the strength of the brake control intervention is increased. A method according to claim 1 or 2, characterized in that the brake control intervention is aborted, if the driver operates the accelerator pedal. Method according to one of the preceding claims, characterized in that from the signals of the environmental sensor and driving dynamics signals of the vehicle, the further course of the road on the one hand and movement of the vehicle during and immediately after the flight phase on the other hand is estimated and the strength of the brake control intervention is varied in dependence. Method according to one of the preceding claims, characterized in that it is checked whether the vehicle can continue to follow the course of the road after the flight phase, and / or whether the vehicle will land off-road, and / or whether the vehicle will land on the opposite lane and is likely to collide with oncoming vehicles, and / or whether the vehicle will be off the road and will most likely collide with stationary obstacles. A method according to claim 5, characterized in that when landing on or immediate agreement on the opposite lane braking control intervention is limited so that the vehicle can still be moved away from the opposite lane, preferably the time is reduced on the opposite lane. Method according to one of the preceding claims, characterized in that the strength of the brake control intervention is also varied in dependence on at least one of the following driving dynamics variables: - Vehicle's own speed - Steering angle or steering rotation rate - lateral acceleration Yaw rate. Method according to one of the preceding claims, characterized in that other controls which control the brake are given a lower priority in this situation. Method according to one of the preceding claims, characterized in that the environmental sensor detects the vertical inclination angle of the road in the direction of travel and / or the distance to the road and evaluated taking into account the vehicle's own speed and intervened automatically depending on the brake control. Control unit for a motor vehicle having an environment detection sensor and an evaluation algorithm for carrying out the method according to one of the preceding claims, wherein the sensor detects the environment in the direction of travel and the control unit evaluates taking into account the vehicle's own speed and automatically engages in the brake control as a function of it.