DE102018203203A1 - Control of a motor vehicle team - Google Patents

Abstract

An apparatus (130) for determining the driving stability of a trailer (100) comprising a motor vehicle (105) and a towed trailer (110) comprises a sensor (140) mounted on the motor vehicle (105) for sensing an orientation of the trailer (110 ) relative to the motor vehicle (105); and processing means (135) for determining a running stability of the towed trailer (110) based on the determined orientation.

Description

The present invention relates to the control of a motor vehicle combination. In particular, the invention relates to the determination of the driving stability of the team.

State of the art

A team comprises a motor vehicle, in particular a passenger car, and a trailer pulled behind it, for example a caravan, a transport trailer or a trailer. The driving stability of the trailer significantly depends on the driving stability of the trailer. For example, on a longer downhill slope of the trailer push the vehicle reinforced and break out laterally. Such a tendency may be determined by means of an acceleration or yaw rate sensor on board the motor vehicle. However, until the influence of the trailer on the driving condition of the motor vehicle is sufficiently large for a safe determination, a dangerous condition may already exist. A measure to avoid an accident may then no longer be successful or even endanger the driving stability of the team.

An object of the invention is to provide an improved technique for determining and / or increasing the driving stability of a team. The invention solves this problem by means of the subjects of the independent claims. Subclaims give preferred embodiments again.

Disclosure of the invention

An apparatus for determining the driving stability of a trailer comprising a motor vehicle and a towed trailer comprises an on-vehicle sensor for sensing an orientation of the trailer relative to the motor vehicle and processing means for determining a driving stability of the towed trailer based on the determined orientation.

The motor vehicle may in particular comprise a passenger car. The trailer is preferably uniaxial or equipped with a double axle. In other embodiments, a multi-axle trailer, in particular with drawbar, or a semi-trailer may be included. The motor vehicle drives in front of the trailer and is connected to it by means of a trailer hitch. By sensing the relative orientation of the trailer with respect to the motor vehicle, it can be determined at an early stage whether the trailer has assumed an unstable driving condition or is about to occupy. Advantageously, the orientation of the trailer with respect to the motor vehicle can be determined directly, and not only as a derived value based on, for example, an orientation of the motor vehicle.

The sensor is preferably configured to determine a distance between the motor vehicle and at least one point of the trailer. The point may be dictated by its position relative to the motor vehicle or trailer, or may include a feature of the trailer such as an edge or a corner. With optical detection, the feature may also be recognizable by means of a change in brightness, color or contrast. By determining the distance, an emigration of the trailer with respect to the motor vehicle in the horizontal or vertical direction can be determined. A rotation of the trailer about a vertical axis (yaw) or a longitudinal axis (rollers) can be easily determined. A commuting, a rocking or other driving instability can be counteracted so improved. In particular, it can be prevented at an early stage that an initially small driving instability increases. The driving stability can be determined on the basis of these movements. In particular, these movements may be assessed in response to a movement of the motor vehicle to determine the driving stability of the trailer and further of the trailer.

In a particularly preferred embodiment, the sensor comprises a reversing camera. The reversing camera is directed to the rear and the trailer is at least partially in their field of vision. By means of image processing, the orientation of the trailer with respect to the motor vehicle can be determined quickly, frequently and with high accuracy. The camera can be set up for night use, for example by means of a light source, a high residual light amplification or operation in the infrared range, so that the optical scanning of the trailer can be done even in the dark. The reversing camera can be firmly mounted on the motor vehicle and integrated in this.

In another embodiment, the sensor includes a rearward ultrasonic sensor. The ultrasonic sensor is configured to determine a distance to an object behind the motor vehicle. Usually, the rearward ultrasonic sensor is used only when reversing to assist a parking operation. An existing rearward ultrasonic sensor can be used without further changes to scan the trailer.

It is further preferred that several sensors with different measuring principles be used. The orientation of the trailer can be determined based on the different sensors improved. Measuring errors that only affect the measuring principle of one of the sensors can thus be eliminated in an improved manner.

It is particularly preferred that the sensor comprises an environment scanning system of the motor vehicle. In this case, an interface may be provided for connection to the environment scanning system. The environment scanning system may scan the environment of the motor vehicle to the rear, to the sides and / or to the front. For example, a radar sensor, an ultrasound sensor, a lidar sensor, a camera or an inductive sensor can be used for this purpose. The individual sensors may have different scanning ranges and scanning distances. For evaluating the driving stability of the trailer, it is possible, in particular, to use results of sensors pointing backwards when the motor vehicle is traveling forwards.

A method for determining a vehicle stability stability of a vehicle and a towed trailer comprises steps of sensing an orientation of the trailer relative to the motor vehicle by means of a sensor mounted on the motor vehicle, and determining the driving stability of the towed trailer based on the sensed orientation ,

The method can be carried out in particular by means of the device described above. The device may in particular comprise a processing device and the method may be in the form of a computer program product and run on the processing device. Features or advantages of the method may also be related to the device and vice versa.

In a variant of the method, a yaw angle of the trailer is determined and the driving stability is determined on the basis of the determined yaw angle. If the yaw angle with respect to the motor vehicle exceeds a predetermined threshold value, for example, an instability of the trailer can be determined. In a further variant, a roll angle of the trailer is determined and the driving stability is determined on the basis of the determined roll angle. Exceeding the roll angle of the trailer with respect to the motor vehicle, for example, a predetermined threshold, it can be assumed that an instability of the trailer.

On the basis of one of the certain angles, a yaw or rolling movement of the trailer can also be determined. If this movement exceeds an associated threshold in terms of speed or extent, an instability of the trailer can be determined. In a particularly preferred embodiment, the movement of the trailer relative to the motor vehicle is determined and the driving stability is determined on the basis of the determined movement and movement of the motor vehicle. For example, if a yaw or roll motion of the trailer deviates from a yaw or roll motion of the motor vehicle by more than a predetermined amount, an unstable driving condition of the trailer may also be deduced.

It is preferable that the driving stability of the trailer is increased when an instability of the trailer has been determined. For this purpose, in particular a wheel of the motor vehicle or a wheel of the trailer can be braked individually. The wheel-specific braking can be carried out, for example, by means of an electronic stability program (ESP) or an anti-lock braking system (ABS).

• 1 ein Gespann mit einem Kraftfahrzeug und einem Anhänger;
• 2 beispielhafte Ansichten eines Anhängers von einem ziehenden Kraftfahrzeug aus; und
• 3 ein Ablaufdiagramm eines Verfahrens zum Bestimmen einer Fahrstabilität eines Gespanns

darstellt.The invention will now be described in more detail with reference to the attached figures, in which:

• 1 a trailer with a motor vehicle and a trailer;
• 2 exemplary views of a trailer from a towing vehicle; and
• 3 a flowchart of a method for determining a driving stability of a team

represents.

1 shows a team 100 with a motor vehicle 105 and a trailer 110 , By way of example, it is the motor vehicle 105 to a passenger car and further example of the trailer 110 around a caravan. Other types of motor vehicles 105 or trailer 110 are also possible. In the presentation of 1 drives the motor vehicle 105 to the left. The trailer 110 located in the direction of travel behind the motor vehicle 105 and is by means of a trailer hitch 115 , which may be designed in particular as a ball-headed coupling, connected thereto.

When driving forward of the motor vehicle 105 becomes the trailer 110 behind the motor vehicle 105 moved here. A driving instability of the team 100 can be due to a driving instability of the trailer 110 be conditional. For example, the trailer 110 yawing by moving around a vertical axis (vertical axis, z -Axis) is rotated. Next, the trailer 110 roll by a horizontal, extending in the direction of travel axis (longitudinal axis, x -Axis) is rotated. Finally, the trailer 110 also nodding by a horizontal, transverse to the direction of travel axis (transverse axis, z -Axis) is rotated. For example, yawing can be occur when the motor vehicle 105 delayed more than the trailer 110 , Rolling may occur, for example, when the at least two-track trailer 110 with one or more wheels 120 only a track over an obstacle or through a sink rolls. In 1 is an example of a coordinate system with axes x . y and z located. The coordinate system can also be predetermined at a location other than the marked location, for example at the trailer hitch 115 or in the area of an axle, the two wheels 120 of the trailer 110 connects with each other.

The car 105 is usually two lanes and has at least one wheel 125 on. On the motor vehicle 105 is a device 130 attached, which is a processing device 135 includes, with at least one sensor 140 connected is. In the presentation of 1 are an example of a first sensor 140 in the form of a reversing camera 145 and a second sensor 140 in the form of a rearward ultrasonic sensor 150 on the motor vehicle 105 intended. The sensors 140 are each set to the trailer 110 from the motor vehicle 105 to scan out. Preferably, a non-contact measurement is performed, in particular a distance of the trailer 110 or one of its characteristics of the motor vehicle 105 certainly. The processing device 135 is arranged to, based on the at least one sensor 140 an orientation of the trailer 110 with respect to the motor vehicle 105 to determine. There can be any number of sensors 140 used and the individual sensors 140 can pursue different measurement principles, for example, as shown optically and by ultrasound, in other embodiments, for example by means of radar or LiDAR signals. It is further preferred that the signals of the sensors 140 by means of the processing device 135 linked together or compared with each other to the orientation of the trailer 110 with respect to the motor vehicle 105 improved to determine.

In another embodiment, the orientation of the trailer 110 to an orientation of the motor vehicle 105 based. An inertial sensor 155 , which may in particular include an acceleration sensor and / or yaw rate sensor, for this purpose on board the motor vehicle 105 be provided. In another embodiment, based on the orientation of the trailer 110 also his movement with respect to the motor vehicle 105 be determined. The processing device 135 can analyze a variety of sensor or alignment values over time.

Was found that the trailer 110 is in an unstable driving condition or the occurrence of an unstable driving condition imminent, so can a corresponding signal on board the motor vehicle 105 be issued. The signal may, for example, to a driver of the motor vehicle 105 or a security system on board the motor vehicle 105 be issued. The signal is preferred to a driving stability system 160 issued, which is preferably adapted to the driving stability of the motor vehicle 105 , the trailer 110 and / or the team 100 by an intervention in the longitudinal control, the lateral control or a chassis of the motor vehicle 105 or the trailer 110 to increase. In particular, one or more wheels 120 . 125 of the team 100 be braked wheel individually. Further, a driving force transmitted via a drive train usually on one of the wheels 125 of the motor vehicle 105 acts, be influenced. Also, a suspension tuning, in particular a suspension or damping of the wheel 120 opposite the trailer 110 or the wheel 125 opposite the motor vehicle 105 can be affected. An intervention to stabilize can also be done via the steering (front or rear), for example, the steering angle of at least one of the wheels 125 of the vehicle 105 to be influenced.

2 shows exemplary views of the trailer 110 from a perspective directed from the direction of travel of the motor vehicle 105 out. The views shown can, for example, by means of the rear view camera 145 of the team 100 from 1 be included. 2A shows an exemplary rolling movement of the trailer 110 about its longitudinal axis ( x -Axis), with a roll angle 215 changed, and 2 B shows an exemplary yaw motion of the trailer 110 around its vertical axis ( z Axis), which is a yaw angle 220 changed. In both illustrations, broken lines indicate a view of the trailer 110 in normal operation, so when driving forwards the motor vehicle 105 shown in the plane on a straight line.

The sensor 140 , here the reversing camera as an example 145 , is fixed or in a known manner on the motor vehicle 105 appropriate. An orientation and a focal length of the reversing camera 145 are therefore known. The orientation of the trailer 110 can therefore with respect to a relative to the motor vehicle 105 fixed field of view 205 respectively. The determination of an orientation angle can be carried out, for example, by finding the position and / or size of an optical feature such as an edge or a corner on both the reference image and a current image. Because of a and optionally with the aid of a known size such as an average distance of the trailer 110 from the motor vehicle 105 then the orientation can be determined. It can also be a position of the drawbar of the trailer 110 to the motor vehicle in the area of the trailer hitch 115 be determined.

3 shows a flowchart of a method 300 for determining a driving stability of a team 100 like that of 1 , The procedure 300 is preferred for draining on the device 130 , in particular the processing device 135 , set up.

In an optional step 305 are calibration conditions of the team 100 detected. These are fulfilled when the trailer 110 opposite the motor vehicle 105 is oriented so that when driving on a flat, straight track in the forward direction, the orientation of the trailer 110 opposite the motor vehicle 105 not or not significantly changed. In particular, it can be determined that the team is 100 in forward drive on a flat, straight stretch. The team is moving 100 preferably slow, for example less than about 10 kilometers per hour or stands still. If the given calibration conditions are met, then in step 310 a calibration done. It is preferred that the orientation or the distance of at least one feature of the trailer 110 with respect to the motor vehicle 105 certainly. In the case of the ultrasonic sensor 150 In particular, a longitudinal distance between the motor vehicle 105 and the trailer 110 be determined. This distance is preferably determined as far as possible outside, that is as far as possible in or against the transverse axis ( y -Axis). An oblique measurement, for example from the left rear side of the motor vehicle 105 to the right front of the trailer 110 , is also possible. The calibration in step 310 the purpose is a deviation of a safe orientation of the trailer 110 with respect to the motor vehicle 105 to be able to determine. The calibrated alignment is considered safe.

In one step 315 can be determined that the team 100 in forward drive. In one step 320 becomes the orientation of the trailer 110 with respect to the motor vehicle 105 by means of at least one of the sensors 140 sampled. Preference is given to several sensors 140 used and the orientation of the trailer 110 is determined with respect to several, possibly all sensor results.

In one step 325 a deviation of current measured values from measured values of the calibration is determined. On this basis can in one step 330 the deviation of the orientation from the calibrated orientation can be determined. In another embodiment, a first orientation can also be determined on the basis of the calibrated sensor values, and a second orientation can be determined on the basis of current sensor values. The two orientations can then be compared with each other to determine a deviation. In another embodiment, the orientation or its deviation or the deviation of the measured values from the calibrated measured values over time can be considered to be a movement of the trailer 110 to determine one of its axes. In determining the orientation or movement of the trailer 110 with respect to the motor vehicle 105 may also be an orientation or movement of the motor vehicle 105 to flow around its longitudinal axis, transverse axis or vertical axis, by means of the inertial sensor 155 can be determined.

In one step 335 is based on the specific orientation or movement the driving stability of the trailer 110 assessed. Should the alignment deviate from the calibrated values by more than a predetermined amount or the trailer movement 110 around one of its axes faster or greater than predetermined, it can be determined that the trailer 110 is unstable. In this case, in one step 340 an engagement on a drive train, a braking device, a steering device or a component for tuning a chassis of the motor vehicle 105 and / or the trailer 110 respectively. For this purpose, an instability signal to the driving stability system is preferred 160 sent. Subsequently, or if the driving condition of the trailer 110 in step 335 has been found to be stable, the process can 300 with the step 315 continue and go through again.

LIST OF REFERENCE NUMBERS

100

team

105

motor vehicle

110

pendant

115

trailer hitch

120

Wheel the trailer

125

Wheel of the motor vehicle

130

device

135

processing device

140

sensor

145

backup camera

150

ultrasonic sensor

155

inertial sensor

160

Dynamic Stability Control

205

field of view

210

Illustration

215

roll angle

220

yaw

300

method

305

Capture calibration conditions

310

Calibrate the sensor system

315

Capture forward travel

320

Scanning trailer

325

Determine deviation

330

Determine alignment

335

Determine driving stability

340

Engage drive, brake or chassis

Claims (14)

An apparatus (130) for determining the driving stability of a trailer (100) comprising a motor vehicle (105) and a towed trailer (110), the device (130) comprising: a sensor (140) mounted on the motor vehicle (105) Sensing an orientation of the trailer (110) relative to the motor vehicle (105); and processing means (135) for determining a running stability of the towed trailer (110) based on the determined orientation. Apparatus (130) according to any one of the preceding claims, wherein the sensor (140) is arranged to determine a distance between the motor vehicle (105) and at least one point of the trailer (110). Device (130) according to Claim 1 or 2 wherein the sensor (140) comprises a reversing camera (145). Device (130) according to Claim 1 or 2 wherein the sensor (140) comprises a rearward ultrasonic sensor (150). Device (130) according to one of the preceding claims, wherein a plurality of sensors (140) are used with different measuring principles. Apparatus (130) according to any one of the preceding claims, wherein the sensor (140) comprises an environment scanning system of the motor vehicle (105). A method (300) for determining a driving stability of a trailer (100) comprising a motor vehicle (105) and a towed trailer (110), the method (300) comprising the steps of: sensing (320) an orientation of the trailer (110) opposite the motor vehicle (105) by means of a sensor (140) mounted on the motor vehicle (105); and determining (335) the driving stability of the towed trailer (110) based on the sensed orientation. Method (300) according to Claim 7 wherein a yaw angle (220) of the trailer (110) is determined and the driving stability is determined based on the determined yaw angle (220). Method (300) according to Claim 7 or 8th wherein a roll angle (215) of the trailer (110) is determined and the driving stability is determined based on the determined roll angle (215). Method (300) according to one of Claims 7 to 9 wherein a movement of the trailer (110) relative to the motor vehicle (105) is determined and the driving stability is determined (335) based on the determined movement and movement of the motor vehicle (105). Method (300) according to one of Claims 7 to 10 wherein at least one wheel (120, 125) of the motor vehicle (105) or the trailer (110) is individually braked (340) to increase the driving stability. Method (300) according to one of Claims 7 to 11 wherein the driving force on at least one wheel (120, 125) of the motor vehicle (105) is influenced in order to increase the driving stability. Method (300) according to one of Claims 7 to 12 in which at least one wheel (120, 125) is influenced by a component of the chassis tuning relative to the vehicle (105) or the trailer (110) in order to increase the driving stability. Method (300) according to one of Claims 7 to 13 wherein at least the steering angle of a wheel (120, 125) is influenced in order to increase the driving stability.

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