DE102019202781A1 - Method for controlling movement of an electrically powered trailer - Google Patents

Abstract

In a method (V) for controlling a movement of an electrically driven trailer (1) which is connected to a vehicle (2), a steering angle (3a) of the vehicle (2) is determined when cornering. A steering angle (3b) of the trailer (1) is determined. A current steering angle ratio (x) is determined from the steering angle (3a) of the vehicle (2) and from the steering angle (3b) of the trailer (1). Starting from a comparison of the current steering angle ratio (x) to a target steering angle ratio (y), a drive device (4) of the trailer (1) is activated. The drive device (4) selectively provides a torque (M) for each wheel (5) of an axle (6) of the trailer (1), so that the current steering angle ratio (x) is within a range around the target Steering angle ratio (y).

Description

The present invention relates to a method for controlling a movement of an electrically driven trailer with the features according to claim 1, a control device with the features according to claim 5 and a trailer with the features according to claim 6.

Trailers and caravans are not powered these days and usually have to be towed by a vehicle. Applications with powered trailers can be found today on trucks on construction sites, tractors with trailers and on the camping market. The caravans are heavy and therefore burden the vehicle. These are particularly problematic for electric vehicles because here the associated reduction in range and the associated need for charging infrastructure and time must be taken into account.

Out DE 102010019480 A1 a vehicle trailer is known, which is equipped with wheel hub motors, steered axle and various sensors to support the vehicle when driving and braking and, in particular when reversing, to maintain a certain track or to be guided on it. An electrical connection is provided for the power supply and control of the trailer.

Out DE 102010062979 A1 a push trailer for a vehicle is known. This vehicle is a passenger vehicle with a drive unit of a first drive type and an energy store for operating the drive unit. The vehicle comprises a drive unit of a second drive type. The push trailer can be mechanically coupled to the vehicle using a trailer coupling. The push trailer has sensors for detecting dynamic movement and state variables of the combination of vehicle and trailer for evaluating the sensor signals and for controlling its drive unit. Depending on the movement and state variables detected by the sensors, a propulsion or braking force acting on the vehicle is generated by the drive unit of the push trailer.

In addition, an e-caravan is known from a press release by Dethleffs (August 2018). This has an electric drive, which is formed by means of two hub electric motors, control electronics and a high-performance battery. The e-caravan has a strain relief module that controls the two electric drive motors so that the trailer load on the coupling head of the vehicle is at a predetermined value, e.g. B. 100 kg reduced. This enables heavy trailers to be towed, even with small vehicles, whose total mass is far above the permissible trailer load of the car. The drive motors can be operated as generators, so that z. B. when driving downhill the batteries can be recharged by means of recuperation. In addition, the e-caravan has a bike-specific power distribution, which is referred to as “torque vectoring”. A central control unit continuously evaluates all driving dynamics data and controls the drive units individually for each wheel based on the evaluated data. For example, different speeds of the inside wheel and the outside wheel can be realized. It can also prevent roll movements. Furthermore, the e-caravan can implement a maneuvering function based on these wheel-specific drive units, so that the e-caravan can be rotated 360 ° in one place. The e-caravan can also be remotely controlled using an app and can be parked without a vehicle. Furthermore, the e-caravan can be equipped with a photovoltaic system on the roof. Furthermore, it is presented to provide the e-caravan as a mobile electricity storage for buildings.

Based on the prior art, the present invention is based on the object of proposing an alternative method for controlling the movement of an electrically driven trailer.

Starting from the above object, the present invention proposes a method for controlling a movement of an electrically driven trailer according to claim 1, a control device according to claim 5 and a trailer according to claim 6. Further advantageous refinements and developments emerge from the subclaims.

In a method for controlling a movement of an electrically driven trailer which is connected to a vehicle, a steering angle of the vehicle is determined when cornering. A steering angle of the trailer is determined. A current steering angle ratio is determined from the steering angle of the vehicle and from the steering angle of the trailer. Starting from a comparison of the current steering angle ratio to a target steering angle ratio, a drive device of the trailer is activated. The drive device selectively provides a torque for each wheel of an axle of the trailer, so that the current steering angle ratio lies within a range around the target steering angle ratio.

The vehicle can be a land vehicle, for example a car, truck or commercial vehicle. The trailer can preferably be a caravan, can also be a trailer for an agricultural or other utility vehicle. The trailer has at least one axis. Each axle has two wheels, which face each other on the axle. Of course, the axle can also have more than two wheels, e.g. B. two wheels per side. Each wheel is movably supported on the axle. This means that each wheel can perform at least both a rotation about its wheel rotation axis and a compression movement along its vertical axis. Possibly. each wheel can swivel around its swivel axis. Connected here means that the wheel is connected to its axle in such a way that a power transmission can take place between the wheel and the axle. In addition, the trailer has service brakes that z. B. can be designed as conventional overrun brakes.

At least two wheels, which lie opposite one another on an axle, are designed to be drivable and can be driven by means of the drive device connected to them. The drive device is thus connected to at least two wheels of the trailer. In the case of a trailer with an axle and two wheels, the drive device preferably has two electric motors which can be operated both as a generator and as an electric motor. The drive device can additionally have a transmission for each of these wheels. In addition, the drive device for each of these wheels a shaft, for. B. have a propeller shaft. Furthermore, the drive device has at least one energy store, by means of which electrical energy can be stored. This at least one energy store is connected to the electric motors, so that they can either be supplied with energy when the electric motors are operated by a motor, or that they can feed and charge the at least one energy store when the electric motors are operated as a generator. In other words, the electric motors provide energy during motor operation, which is used to drive the respective wheel. In generator operation, the electric motors provide energy to charge the at least one energy store. The electric motors can be designed as external rotors or as internal rotors.

The electric motors can for example be arranged close to the wheel and form a wheel hub drive. Alternatively, the electric motors can be arranged near a longitudinal axis of the trailer, the longitudinal axis simultaneously representing a central axis of the trailer. In this case, each electric motor is connected to its respective wheel by means of a shaft. In both cases, the wheels can be connected to the respective electric motor via a gear. In the second alternative, the torque is thus transmitted from the electric motor via the transmission to the respective wheel via the shaft. In the case of a trailer with two wheels which are mounted on an axle, a first electric motor is connected to a first transmission. The first transmission is connected to a first shaft. The first shaft is connected to the first of the two wheels. A second electric motor connected to a second transmission. The second gear is connected to a second shaft. The second shaft is connected to the second of the two wheels.

The gears can be designed, for example, as planetary gears or spur gears, which can represent at least one gear. Thanks to the gearbox, the electric motors can be dimensioned smaller than with an electric drive without a gearbox.

The at least one energy store is designed as an accumulator. The at least one energy store can forward energy to the electric motors or the electric motors can forward energy to the at least one energy store. This depends on the driving situation. Depending on the driving situation, the electric motors can be operated by motor or generator. A driving situation is present when the trailer is in operation, e.g. B. if it is moving along a route and may be connected to the towing vehicle. The at least one energy store can be charged, for example, by means of the energy that is made available by means of recuperation, for. B. when the trailer is braked or moves along a slope. If, on the other hand, the trailer is not only pulled by the vehicle but driven, energy from the energy store is used to operate the electric motors. This represents different driving situations.

The trailer has at least one control device which is set up to control the drive device of the trailer. The control device can be designed, for example, as an ECU or domain ECU. The electric motors can be controlled by means of the control device, so that, on the one hand, it is possible to switch from motor to generator operation and, on the other hand, energy supply can be determined by the electric motors. The control device is also set up to control the electric motors individually and independently of one another. For example, the first electric motor can provide a higher torque for the first wheel than the second electric motor for the second wheel. The control device can also be connected to the gears and control them. The control device can also be set up to evaluate sensor data generated by at least one sensor device of the trailer can be provided. Furthermore, the control device is set up to determine current steering angle relationships from the sensor data made available to it. To do this, it can use a computer program product. Possibly. The control device can be set up to determine target steering angle ratios from the sensor data made available to it. To do this, it can use a computer program product. The control device also has an interface by means of which communication with a control unit of the vehicle can be carried out. The control device is connected to the control unit of the vehicle via this interface, so that data and signal exchange can take place. The connection can be wireless or wired.

The steering angle of the vehicle is determined when cornering. This is done using a vehicle's own sensors, e.g. B. by means of sensors for determining a steering angle, a yaw rate, a vehicle speed, wheel speeds and / or wheel speeds. This is done using methods that are known from the prior art.

Furthermore, the steering angle of the trailer is determined when cornering. The trailer or the vehicle has at least one sensor device which is set up to determine an orientation of the trailer in space. The angle between the trailer and the vehicle is determined using this orientation. This can be done in several ways.

In a first embodiment, the angle between the vehicle and the trailer is determined by detecting a rotational speed of the wheels of the trailer. The at least one sensor device can, for. B. be designed as a speed sensor per wheel of the trailer. The sensor data are evaluated by the control device or by a separate control device with respect to a differential speed of the wheels of the trailer. An orientation of the trailer in space is determined on the basis of this differential speed. When driving straight ahead, there is no speed difference or only an extremely small speed difference, which is close to 0. When cornering, there is a differential speed other than 0, from which the orientation of the trailer can be concluded. This differential speed is to be recorded precisely, especially when the trailer is traveling slowly, for example when maneuvering or reversing.

In a second embodiment, the angle between the vehicle and the trailer is determined by detecting a yaw rate of the trailer. This is done by means of a yaw rate sensor, which the trailer has and which detects the yaw of the trailer. The orientation of the trailer in space can be determined by evaluating the yaw rate using the control device or using a separate control device. When the trailer is traveling straight ahead, there is no yaw or very little yaw. When cornering, however, the trailer yaws and the yaw rate is different from 0.

In a third embodiment, the angle between the vehicle and the trailer is determined by means of an imaging sensor system. The imaging sensor system can be, for example, a camera, e.g. B. an existing rear-view camera of the vehicle, an ultrasound sensor system, a radar system, a lidar system or another suitable sensor system. The imaging sensor system is arranged on the vehicle so that it can detect the trailer that is connected to the vehicle. Based on the determined data of the sensor system, an evaluation can be carried out with regard to the orientation of the trailer in space. The evaluation can be carried out either by the control device of the trailer, by a separate control device or by the control unit of the vehicle. In the case of a camera that shapes the imaging sensor system, the image data can be evaluated using an image recognition algorithm. This algorithm can use an artificial neural network, for example. The algorithm can be present, for example, in the control device of the trailer or in the control unit of the towing vehicle.

Das aktuelle Lenkwinkel-Verhältnis stellt also eine Beziehung zwischen dem Lenkwinkel des Anhängers und dem Lenkwinkel des Fahrzeugs her. Liegen der Lenkpol des Fahrzeugs und der Lenkpol des Anhängers in einem Punkt liegt ein ideales Lenkwinkel-Verhältnis vor. Dies definiert gleichsam das Soll-Lenkwinkel-Verhältnis. The current steering angle ratio is determined from the steering angle of the vehicle and from the steering angle of the trailer. This is preferably carried out by the control device. The current steering angle ratio is calculated as follows $$\frac{{\text{Head angle}}_{\text{vehicle}}}{{\text{Head angle}}_{\text{pendant}}}$$

The current steering angle ratio thus establishes a relationship between the steering angle of the trailer and the steering angle of the vehicle. If the steering pole of the vehicle and the steering pole of the trailer are at one point, there is an ideal steering angle ratio. This defines the target steering angle ratio as it were.

The target steering angle ratio can be set in different ways. For example, one or more measurement runs can be carried out with the vehicle and trailer combination. For example, they can be constant Be circular drives. From these, the steering angle of the vehicle and the steering angle of the trailer are stored, which have led to a common steering pole of the vehicle and the trailer and thus to an ideal target steering angle ratio. These are stored, for example, in a storage device of the control device. Alternatively, the target steering angle ratio can be determined by means of a computer program product during regular driving operation of the vehicle and trailer combination. This determines the steering angle of the vehicle and the steering angle of the trailer, which have led to a common steering pole of the vehicle and the trailer and thus have resulted in an ideal target steering angle ratio. These are stored, for example, in a storage device of the control device. Again, alternatively, the target steering angle ratio can be determined by a driver of the team. The latter can enter the target steering angle ratio, for example by means of an input device of the vehicle or the trailer, and store it in the storage device of the control device.

This current steering angle ratio is therefore compared with the target steering angle ratio. This comparison is carried out by the control device. If the current steering angle ratio is less than the target steering angle ratio, the trailer oversteers. The steering pole of the trailer and the steering pole of the vehicle are therefore spaced apart, the steering pole of the vehicle being more distant from the vehicle than the steering pole of the trailer. The trailer buckles too much compared to the vehicle. If the current steering angle ratio is greater than the target steering angle ratio, the trailer is understeered. The steering pole of the trailer and the steering pole of the vehicle are therefore spaced apart from one another, the steering pole of the trailer being more distant from the vehicle than the steering pole of the vehicle. The trailer buckles too little compared to the vehicle. Both cases can e.g. B. with bumps in the road, uneven loading of the trailer or with different tire pressure of the tires of the trailer.

On the basis of this comparison, the drive device of the trailer is activated. More specifically, the actuators of the drive device of the trailer are controlled. The drive device selectively provides a torque for each wheel of an axle of the trailer, so that the current steering angle ratio lies within a range around a target steering angle ratio. Each electric motor is controlled individually, so that an individual drive torque is available on each driven wheel. The torque that is made available for the first wheel can be different from the torque that is made available for the second wheel. For example, the torque that is provided for the first wheel can be higher than the torque that is provided for the second wheel. This enables both longitudinal and transverse guidance of the trailer. The transverse guidance of the trailer by means of the individually controlled electric motors can be referred to as torque vectoring.

The moments made available are such that when cornering, the current steering angle ratio is in a range around the target steering angle ratio. This means that the target steering angle ratio does not have to be exactly achieved. Rather, it is sufficient if the target steering angle ratio is approximately reached. For example, 90% of the target steering angle ratio can be achieved. In other words, the transverse guidance of the trailer is influenced by the electric motors in such a way that the steering pole of the trailer approaches the steering pole of the vehicle. This can be done both when cornering forwards and when cornering backwards.

It is advantageous here that a breakout of the trailer or even wedging of the trailer is counteracted. This ensures safe travel, safe maneuvering and safe parking with the trailer.

The control device for the trailer, which can be connected to the vehicle, has means for carrying out the method which has already been described in the previous description. The drive device of the trailer can be controlled by means of the control device. The control device has the interface by means of which communication with the control unit of the vehicle can be carried out. The control device and its functions have already been described in the previous description.

The means for performing the method can, for example, be in the form of a computer program product. The computer program product can, for example, be embodied in a data carrier, e.g. B. in a USB stick, CD, DVD, Blu-ray or similar. Alternatively, the computer program product may be embodied in a downloadable data stream.

The trailer with the control device, which has already been described in the previous description, can be connected to the vehicle. The trailer has an electric drive device. This has already been described in the previous description.

• 1 eine schematische Darstellung eines Gespanns mit einem Anhänger und einem Fahrzeug nach einem Ausführungsbeispiel,
• 2 eine schematische Darstellung eines Verfahrens, welches von dem Anhänger aus 1 angewendet wird.

Various exemplary embodiments and details of the invention are described in more detail with reference to the figures explained below. Show it:

• 1 1 shows a schematic illustration of a team with a trailer and a vehicle according to one exemplary embodiment,
• 2nd is a schematic representation of a method, which from the trailer 1 is applied.

1 shows a schematic representation of a team with a trailer 1 and a vehicle 2nd according to an embodiment. The team is greatly simplified and shown partially cut. The trailer 1 is designed here as a caravan. The vehicle 2nd moves with the trailer 1 in the direction of travel 18th around a curve. The trailer 1 has an axis 6 on which two wheels 5 are connected. The wheels 5 are on the axis 6 movably mounted, ie the wheels 5 can perform a rotational movement, a compression movement and possibly a swivel movement. The trailer 1 via a trailer hitch 17th with the vehicle 2nd connected. The trailer 1 is on the vehicle 2nd attached.

The trailer 1 has a drive device 4th on. This drive device 4th has an energy storage 16 , two electric motors 7 , two gears 11 and two waves 12th on. It can be clearly seen how the electric motors 7 who have favourited Gears 11 , the waves 12th , the wheels 5 and the energy storage 16 are interconnected. A first electric motor 7 is with a first gear 11 connected. The first gear 11 is with a first wave 12th connected. The first wave 12th is with a first wheel 5 connected. The first electric motor 7 is also with the energy storage 16 connected. Now the first wheel 5 are driven by the energy storage 16 Energy to the first electric motor 7 forwarded. This provides a torque M ready which to the first gear 11 transferred and translated there. The first gear 11 gives the torque M to the first wave 12th further. This transmits the torque M on the first wheel 5 .

A second electric motor 7 is with a second gear 11 connected. The second gear 11 is with a second wave 12th connected. The second wave 12th is with a second wheel 5 connected. The second electric motor 7 is also with the energy storage 16 connected. Now the second wheel 5 are driven by the energy storage 16 Energy to the second electric motor 7 forwarded. This provides a torque M ready which to the second gear 11 transferred and translated there. The second gear 11 gives the torque M to the second wave 12th further. This transmits the torque M on the second wheel 5 .

Any electric motor 7 is connected to the control device 8th that can control them individually and independently of each other. Here, the control device 8th the electric motors 7 control so that the torque M of the first wheel 5 can be different from the torque M of the second wheel 5 . The electric motors 7 can be operated both as a generator and as a motor. The control device 8th can also with the gears 11 be connected so these are the gears 11 can control, for example, to initiate a gear change.

The trailer 1 also points to each of his wheels 5 a speed sensor 15 on. The speed sensors 15 serve the speed of each wheel 5 capture. The speed sensors 15 are with the control device 8th of the trailer 1 connected. The control device 8th can evaluate the determined speeds. The control device determines on the basis of the evaluated speeds 8th a speed difference and there can be an orientation of the trailer 1 be determined in space. When driving the trailer straight ahead 1 the speed difference is zero or close to zero. In contrast, when cornering, the speed difference is greater than zero. Thus, the steering angle of the trailer 1 be determined. The turning point of the trailer 1 , which results from the steering angle of the same, lies here so far from the pivot 19th of the vehicle 2nd that this is no longer shown. The trailer 1 understeered.

The vehicle 2nd has four vehicle wheels 13 on, two of which are turned to face in the direction of travel 18th to drive the curve. The vehicle 2nd also has a control unit 10th on. This control unit 10th is with the control device 8th of the trailer 1 connected. The control device 8th has an interface for this 9 on. This connection enables communication between the control unit 10th and the control device 8th , so that data and signal exchange can take place.

The vehicle 2nd also has a steering angle sensor 14 on. This is with the control unit 10th of the vehicle 2nd connected. Using the steering angle sensor 14 becomes a steering angle of the vehicle 2nd determined. Based on this, an orientation of the vehicle can 2nd in the room from the control unit 10th be determined. Thus, the steering angle of the vehicle 2nd be determined. The vehicle 2nd therefore moves in the curve around its pivot 19th .

The steering angle of the vehicle 2nd is sent to the control device 8th of the trailer 1 communicates. Starting from the steering angle of the vehicle 2nd and the steering angle of the trailer 2nd becomes a current steering angle ratio x determined according to the following formula: $$x=\frac{{\text{Head angle}}_{\text{vehicle}}}{{\text{Head angle}}_{\text{pendant}}}$$

In the control device 8th of the trailer 1 is a target steering angle ratio y saved. The current steering angle ratio x is compared with the target steering angle ratio y . The target steering angle ratio y corresponds to the steering angle ratio at which the rotating pole 19th of the vehicle 2nd and the turning point of the trailer 1 are congruent or almost congruent. This is in 2nd shown in more detail.

The control device controls on the basis of this comparison 8th the electric motors 7 the drive device 4th so that for the wheels 5 a respective moment M can be made available. These moments M are chosen such that the current steering angle ratio x in a range around the target steering angle ratio y moves or even the target steering angle ratio y reached. This is the turning point 19th of the vehicle 2nd and the turning point of the trailer 1 one above the other or almost one above the other.

2nd shows a schematic representation of a method V which from the trailer 1 is applied. In a first step 101 become the steering angle during cornering 3b of the trailer and the steering angle 3a of the vehicle. This can be done, for example, by detecting and evaluating the wheel speeds of the trailer and by evaluating the steering angle sensor system of the vehicle. Determining the two steering angles 3a , 3b preferably takes place simultaneously.

Then in a second step 102 a current steering angle ratio x from the steering angle 3a of the vehicle and from the steering angle 3b of the trailer determined according to the following formula: $$x=\frac{{\text{Head angle}}_{\text{vehicle}}}{{\text{Head angle}}_{\text{pendant}}}$$

In a third step 103 becomes the current steering angle ratio x with a target steering angle ratio y compared. The target steering angle ratio y can, for example, have been ascertained and stored by means of a test drive or while driving. If the current steering angle ratio x is greater than the target steering angle ratio y understeered the trailer. If the current steering angle ratio x is smaller than the target steering angle ratio y the trailer oversteers. Based on this comparison, the drive device of the trailer is activated, so that each electric motor has an individual drive torque on its corresponding wheel M provides.

In a first alternative of the fourth step 104a the electric motor that is assigned to a first wheel provides the requested torque for the first wheel M to disposal. In a second alternative of the fourth step 104b the electric motor that is assigned to a second wheel sets the requested torque for the second wheel M to disposal. The trailer is driven and by means of the different torques M steered such that it drives around the curve in the direction of travel. The electric motors are controlled in such a way that the current steering angle ratio x in a range around the target steering angle ratio y is arranged or the target steering angle ratio y corresponds. This prevents the trailer from oversteering or understeering.

The procedure V runs continuously. That is, the steering angle 3a of the vehicle and the steering angle 3b of the trailer are constantly monitored to ensure that the current steering angle ratio x is always adjusted so that it is in the range of the target steering angle ratio y emotional.

Reference list

1

pendant

2nd

vehicle

3a

Steering angle vehicle

3b

Steering angle trailer

4th

Drive device

5

wheel

6

axis

7

Electric motor

8th

Control device

9

interface

10th

Control unit

11

transmission

12th

wave

13

Vehicle wheel

14

Steering angle sensor

15

Speed sensor

16

Energy storage

17th

trailer hitch

18th

Direction of travel

19th

The center of rotation of the vehicle

101

first step

102

second step

103

Third step

104a

fourth step first alternative

104b

fourth step second alternative

V

Procedure

x

current steering angle ratio

y

Target steering angle ratio

M

moment

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included 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.

Patent literature cited

• DE 102010019480 A1 [0003]
• DE 102010062979 A1 [0004]

Claims (6)

Method (V) for controlling a movement of an electrically driven trailer (1) which is connected to a vehicle (2), when cornering - a steering angle (3a) of the vehicle (2) is determined, - a steering angle (3b) of the trailer (1) is determined, a current steering angle ratio (x) is determined from the steering angle (3a) of the vehicle (2) and from the steering angle (3b) of the trailer (1), - starting from a comparison of the current steering angle ratio (x) to a target steering angle ratio (y), a drive device (4) of the trailer (1) is activated, - By means of the drive device (4) for each wheel (5) an axle (6) of the trailer (1) selectively a moment (M) is made available, so that the current steering angle ratio (x) within a range around the target Steering angle ratio (y). Method (V) according to Claim 1 The steering angle (3b) of the trailer (1) is determined by detecting a rotational speed of the wheels (5) of the trailer (1). Method (V) according to Claim 1 The steering angle (3b) of the trailer (1) is determined by detecting a yaw rate of the trailer (1). Method (V) according to Claim 1 The steering angle (3b) of the trailer (1) is determined by means of an imaging sensor system. Control device (8) for a trailer (1) which can be connected to a vehicle (2), the control device (8) having means for carrying out a method (V) according to one of the Claims 1 to 4th The control device (8) can be used to control a drive device (4) of the trailer (1), and the control device (8) has an interface (9) by means of which communication with a control unit (10) of the vehicle (2 ) is feasible. Trailer (1) with a control device (8) Claim 5 The trailer (1) can be connected to a vehicle (2) and the trailer (1) has an electric drive device (4).

Images