Method, system and device for controlling a vehicle brake system

To operate an electrically controlled pressurized-fluid brake system, an external brake request signal is received, a curve radius of a vehicle track of the vehicle is determined, at least one limit value is determined based on the curve radius, at least one variable representing a brake pressure to be supplied to wheel brakes is compared with the at least one limit value, the at least one variable is limited based on the comparison, the at least one variable is outputted, and braking pressure is supplied to the wheel brakes based on the outputted at least one variable.

FIELD OF THE INVENTION

The present invention generally relates to vehicle brake systems, and more particularly, to a method and control unit for operating an electrically controlled pressurized-fluid brake system for vehicles.

BACKGROUND OF THE INVENTION

DE 102 38 221 B4 discloses a traction control system with braking action, in particular for motor vehicles, wherein a slip-wheel is braked on exceeding a slip pressure threshold by brake engagement. When driving in a curve on a road with a low friction coefficient, the slip threshold of the outer driven wheel is set lower independently of the inner wheel. When driving in a curve with a low friction coefficient, the brake pressure of the outside wheel is slightly increased before the outside wheel exceeds the slip threshold.

DE 10 2007 06 111 4 A1 discloses a device for supporting a two-wheeler driver when cornering, comprising means for monitoring the running state at least in relation to a turn and for pressing the vehicle brake, and a unit for determining a maximum braking force or maximum value for an equivalent variable and for limiting an exerted braking force to the maximum value.

DE 199 58 772 B4 discloses a method for traction slip control of a motor vehicle, comprising several sensors for measuring a transverse acceleration, driving speed of the wheels and a curve radius of the road. These measured values are used for determining a slip value of each wheel, respectively, which are compared with a pre-determined slip threshold. If the determined slip value exceeds the pre-determined slip threshold, the threshold value of the inner driven wheel is changed by using a linear equation.

DE 10 2010 003 951 A1 discloses a method for stabilizing a two-wheeler in driving situations where the two-wheeler is oversteered. A variable representing the oversteered status of the two-wheeler is determined and compared with a pre-determined threshold. If the variable exceeds the pre-determined threshold, a loop control is employed by one or more of exerting a steering torque, varying a brake pressure exerted to the front wheel brake, varying the driving torque exerted to the rear wheel, and varying the brake pressure exerted to the rear wheel.

DE 10 2006 044 777 A1 discloses a process for direction-stabilization of vehicles, in particular motor vehicles, in which the existence of an oversteering driving state generated by the brake intensity is determined. The oversteering status is determined by using wheel speed or steering angle data.

DE 10 2009 047 190 A1 discloses a method for increasing the driving stability and the breaking performance of a motor vehicle in a curve during a braking process. In a brake control operation, the rear axle is controlled by a select-low strategy, in which a lateral acceleration quantity based on a curve specific value or a measured transversal acceleration is determined and the braking pressure is amended. Two strategies are then alternately or additionally used, wherein the second strategy includes the reduction of the brake pressure of the outer front wheel to a value of the brake pressure below the current possible contact of this front wheel.

DE 10 2007 022 614 A1 discloses a method for reducing motor vehicle turning radii, comprising the steps of sensing a turn of a motor vehicle, determining which rear wheel of the motor vehicle is an inner wheel of the turn, and selectively applying a brake of the inner rear wheel in automatic response to the step of sensing to thereby effect a reduction in the turning radius.

Such systems and methods may enhance the stability of a vehicle in the above mentioned situations.

However, external brake requests of driver assistance systems sometimes result in brake demands or requests of a brake force that may be too high in the current situation. Those driver assistance systems include cruise controls (CC) and automatic cruise controls (ACC) or distance regulation systems. Cruise controls regulate the vehicle speed to a pre-determined value. In the case of a downhill driving situation, a brake request may be sent to the brake control unit. Automatic cruise controls are used to keep a distance to a traffic object ahead or in front of the vehicle constant. If the distance to the traffic object is less than a distance threshold value, an external brake request is sent to the brake control unit.

SUMMARY OF THE INVENTION

Generally speaking, it is an object of the present invention to provide a method, a control unit device, and a system for operating an electrically controlled pressurized-fluid brake system for a vehicle with high stabilization in the case of an external brake request.

According to one embodiment of the present invention, the brake control unit is also provided for further functions, such as for distributing a total brake pressure to the wheel brakes based on a load situation. The brake control unit may also be used for stability functions, such as electronic stability program (ESP), ABS, and slip traction control (ASR).

According to an aspect of the present invention, a variable representing the brake pressure of the brake fluid is limited based on a curve radius of the current driving situation of the vehicle. In one embodiment, the variable may, in particular be the brake pressure itself that is exerted to the vehicle brakes. In another embodiment, the variable may be a deceleration demand used in a subsequently performed brake pressure adjusting process. In yet another embodiment, the variable can be a pressure gradient, i.e., the derivation of the brake pressure in time, which represents the dynamic brake pressure behavior.

The terms “curve” and “curve radius” refer to the driving situation of the vehicle, where the curve may be the curve of the road or the lane of the vehicle, or can differ from the lane curve, if the vehicle does not follow its lane. As a rough determination of the curve radius, map data can be used. In a preferred embodiment, the curve may be detected by a detection system, such as a radar system or an optical detection system of the vehicle that is provided for detecting road markers, and/or on the basis of data available in the vehicle, such as driving dynamics data of the vehicle (e.g., yaw rate and vehicle speed).

The terms “external brake request” and “external brake request signal” refer to a request or signal from an external system, i.e., a system different from the braking system itself. This external system preferably detects an environmental situation of the vehicle and is intended to adapt a driving situation of the vehicle to this environmental situation. The external system may, in particular, be an automatic cruise control (ACC) or a distance keeping system for keeping a distance to a traffic object driving in front of the vehicle constant. Further, the external system may be a cruise control function or system for keeping a vehicle speed constant. Such external systems are, in particular, driver assistance systems that provide general assistance to the driver, rather than stability.

Thus, these external systems differ from internal brake systems, such as ABS, ESC, and slip traction control (ASR), which automatically initiate a braking process as part of a vehicle stabilization program.

According to an embodiment of the present invention, the curve of the vehicle track or vehicle lane is determined and used for the evaluation, if the external brake request may result in a deceleration is too high in the current driving situation and therefore, may lead to instability of the vehicle (e.g., due to significant wheel slip).

The dependency of the variable representing the brake pressure on the curve radius may be an arithmetic function. However, a table or map, such as a matrix, map, or table that comprises limit values of the variable for specific curve radius values, can be employed.

One advantage of the present invention is that instabilities due to high brake requests of the external system can be avoided.

The limitation of the brake pressure or the variable representing the brake pressure can, in particular, be performed independently of the μ value or friction coefficient of the road. Many processes and systems of the prior art use a detection of such a friction coefficient in order to adapt the braking force.

In contrast, according to an aspect of the present invention, the limitation of the variable representing the brake pressure can be performed without using estimations of the friction coefficient, since friction coefficients may often change and thus, may not be a good basis for a pressure limitation.

According to yet another aspect of the present invention, limitation of a brake pressure is not so problematic in the case of an external request, contrary to internal demands. The braking action required by an external system is evaluated to be less important, whereas an internal brake requirement of the brake system is used for driving stabilization.

According to a further aspect of the present invention, the method, control unit, and brake system are provided to limit the variable representing the brake pressure before the brake pressure is applied, and can also be provided even in situations when the vehicle is not unstable.

The present invention accordingly comprises the features of construction, combination of elements, and arrangement of parts as well as the various steps and the relation of one or more of such steps with respect to each of the others, all as exemplified in the following disclosure, and the scope of the invention will be indicated in the claims.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1shows a top view of a vehicle1in a curve.FIG. 2is a schematic illustration of vehicle1. As shown inFIG. 1, a vehicle1, in particular a commercial vehicle such as a truck or the like, drives on a lane2of a road. The vehicle drives with a speed (velocity) v behind another traffic object, in particular, another vehicle3. The vehicle1is equipped with an automatic cruise control-system4comprising a distance sensor5for measuring a distance d to the traffic object3ahead of the vehicle1using radar signals, ultrasound signals, a stereo camera system or the like, and an ACC control unit6that receives distance signals51from the distance sensor5and evaluates whether the current vehicle speed v is too fast on the basis of the measured distance d and the speed of the vehicle.

ACC systems such as this are well known. The ACC control unit6can receive the vehicle speed v via a vehicle data bus system, such as a CAN bus or the like. Moreover, the ACC control unit6can calculate the speed of the traffic object3on the basis of a long term measurement. If the vehicle's speed v is too large, then a brake request signal XBR can be output from the ACC control unit and applied to a brake system8of the vehicle1.

The brake system8may comprise several driver stability functions, such as an ABS, an EBS, an ESP (electronic stability program), an ASR (slip traction control), and other assistance functions. The brake system8is preferably electro-pneumatic and, as shown inFIG. 2, comprises a brake control unit10with a signal interface10a, a pressurized air supply system (not shown in the figures), and pneumatic wheel brakes11on each wheel12and ABS valves14, which receive control signals S2from the brake control unit. The brake control unit receives an internal brake request S3from the driver via a brake pedal20and a pedal sensor21. The brake system8may also comprise pneumatic and electric devices for the distribution of the brake pressure to the axles of the vehicle and for pressure limitation, as well as valve devices for avoiding damage by increased pressure. Such devices are common and are therefore not shown in the figures.

The brake pressure p supplied to the wheel brakes11can be measured by pressure sensors13, which output a pressure measurement signal S4to the brake control unit10. However, it is also possible to calculate the brake pressure from a known supply pressure and the actuation of the ABS valves14.

In an alternate embodiment, the brake system8is pneumatic rather than electro-pneumatic, where analog pressurized air lines or pipes run through the vehicle to the brakes11, and the brake pressure p is adjusted in a central brake module. In yet other embodiments, hydraulic brake systems or air over hydraulic brake systems are employed. Because all of these embodiments are within the scope of the present invention, it is only relevant that the brake control unit10adjusts a brake pressure p in the brakes11.

The vehicle1drives on a track22, which in general is defined by the lane2. As shown inFIG. 1, the vehicle1drives in a curve with a specific curvature and a curve radius R, which is the distance from the vehicle1to the center M of the curve.

The brake control unit10either calculates the radius R or receives the calculated value of the radius from another control unit in the vehicle1via the internal data bus of the vehicle. The brake control unit also limits a variable representing the brake pressure p supplied to each pneumatic brake11, respectively, to a pressure limit p_lim based on the radius R, by outputting control signals S2to the ABS valves14.

According to an embodiment of the invention, the variable representing the brake pressure p may be the brake pressure p itself. In this case, the pressure limit p_lim is a function of the curve radius R.

Additionally, or alternatively, the variable representing the brake pressure p may be the derivation in time dp/dt, or a function of dp/dt. In this case, a limit dp_lim is relevant.

According to a further embodiment of the invention, a brake demand or intended deceleration Zs, which is to be used in a subsequent calculation of a distribution of the brake pressure p to the wheel brakes11, can be used as the variable representing the brake pressure p. In this case, a limitation Zs_lim can be used.

According to yet another embodiment of the invention, the variable representing the pneumatic brake pressure p can also be limited based on the vehicle speed v. However, the brake pressure p can be also limited independently of the vehicle speed v.

The radius R may be calculated on the basis of street map data, which may be supplied via map signals S5by a navigation system30of the vehicle on the basis of stored map data and GPS data. Further, the distance sensor4can be used to determine the lane2and road markers, and the radius R can then be calculated on the basis of these data. In a preferred embodiment of the invention, dynamic vehicle data are used to determine the curve of the track22and thereby the radius R. In particular, obstacles on the road or the lane2which are not marked in map data may lead to curves of the track22of the vehicle1. Furthermore, a change of the lane or other drive actions can lead to curve motions. Thus, the curve radius R can be determined by a detected or calculated yaw rate, or by the wheel speed signals of the ABS.

The limitation of the brake pressure p and/or its derivative over time dp/dt may be specified in maps, tables or matrices. According to one embodiment, the initial values can be set in a table such as Table 1 below.

Thus, as an example, a detected or determined radius of 90 meters leads to a p_lim=2.0 bar and a dp_lim=0.75 bar/s. As another example, a radius of 500 meters leads to a p_lim=10 bar and a dp_lim=100 bar/s. Moreover, any radius between the values in Table 1 can be linearly interpolated between the two closest radius points. For example, a radius of 125 meters leads to a p_lim=2.5 bar and a dp_lim=0.875 bar/s (interpolated from the values at 100 meters and 150 meters). As another example, a radius of 225 meters leads to a p_lim=3.0 bar and a dp_lim=1.5 bar/s (interpolated from the values at 150 meters and 300 meters). As yet another example, a radius of 350 meters leads to a p_lim=6.5 bar and a dp_lim=51 bar/s (interpolated from the values at 300 meters and 400 meters). It should be appreciated that the values of p_lim and dp_lim for a radius of curvature equal to or greater than 400 meters can be set sufficiently high such that the pressure and the derivative thereof are essentially not limited and system response is unaffected.

According to another embodiment, however, linear or other functions are possible.

The pressure limitation is only provided for an automatic brake that is initiated on the basis of an external brake request signal XBR. In the case of an emergency stop or emergency brake, the pressure limitation may be switched off. If the ACC system4detects an emergency situation with a rapidly decreasing distance d to the traffic object3, which may be due to a crash or sudden brake of the traffic object3, then the limitations of p and dp/dt may be switched off. However, according to one embodiment, no bypassing of the limitation is provided and steps St4and St5are cancelled from the flow chart ofFIG. 3. Accordingly, step St6is subsequent to step St3.

The method according to this embodiment of the present invention thus comprises the following steps.

In step St0, the method of automatically applying a brake pressure to vehicle brakes starts when the ignition is switched on or the motor is started. Step St1includes checking if an external brake request signal XBR is present. The external brake request signal XBR may, in particular, be sent from the ACC control unit6.

If XBR=1, i.e., in the case of an external brake request signal, the method proceeds to step St2via branch y1. If no external brake request is present, the method returns to step St1via branch n1.

In step St2, the curve radius R is determined. This determination or calculation may be performed in the brake control unit10itself, or can be available via a data bus system.

In step St3, one or more limit values p_lim and dp_lim is/are determined based on the curve radius R.

In step St4, the presence of an emergency brake signal Se for a sudden brake request is checked. If, for example, XBR contains such an emergency brake signal, i.e., Se=1, then step St5is bypassed or bridged and the method proceeds to step St6via branch y2. If no emergency request is present, then the method proceeds to St5via branch n2, where one or more of the brake pressure p, its derivative dp/dt, and the deceleration request Zs are limited to its limit value, respectively. In step St6, the brake pressure p, its derivative dp/dt, or the deceleration request is output, i.e., with or without a limitation.

When an external brake request is sufficiently limited, vehicle stability can be achieved. As an example,FIG. 4Ais a graph depicting an unstable condition of a vehicle when an external brake request is not limited. A curve402represents a stable yaw rate for the vehicle, and a curve404represents the actual yaw rate of the vehicle. A curve406represents a requested deceleration (e.g., −4 m/s2), and a curve408represents the deceleration that is actually honored (e.g., by the vehicle's ABS unit). As shown inFIG. 4A, the actual deceleration (curve408) is not limited, and thus approaches the requested deceleration (curve406). This causes the actual yaw rate (curve404) of the vehicle to deviate from the stable yaw rate (curve402), resulting in an oversteering condition.

In contrast,FIG. 4Bis a graph depicting a stable condition of the vehicle when the external brake request is limited based on a radius of curvature of the track of the vehicle. A curve412represents a similar stable yaw rate for the vehicle, and a curve414represents the actual yaw rate of the vehicle. A curve416represents a similar requested deceleration (e.g., −4 m/s2), and a curve418represents the deceleration that is actually honored (e.g., by the vehicle's ABS unit). As shown inFIG. 4B, the actual deceleration (curve418) curves or ramps down towards, but does not reach, the requested deceleration (curve416). The actual deceleration is limited based on the radius of curvature, of which a curve420represents 1/radius of curvature. The radius of curvature can be provided by a radar system or device of the vehicle. As shown inFIG. 4B, the allowed or actual deceleration is limited to a smaller value as the radius becomes smaller. Accordingly, the actual yaw rate (curve414) of the vehicle remains close to the stable yaw rate (curve412), and the vehicle remains in a stable condition.