The present invention relates to a motor vehicle, and in particular to a utility vehicle.
The motor vehicle shown, for example, in DE 100 32 179 A1 has an electronically controlled drive train which comprises at least one steering system, one braking system and one drive unit of the vehicle. Manually operated activation elements such as, for example, an accelerator pedal, a brake pedal and a steering handle or a joystick or drive stick which comprises the functions of the brake pedal, accelerator pedal and/or steering wheel, are provided for activating the drive train. When they are activated, the activation elements generate control commands which are executed by actuators of the respective components of the drive train. The commands are transferred electronically in the form of electrical signals. There is basically no need for mechanical or hydraulic positive coupling between the activation elements and the associated components of the drive train, the coupling being, for example, a steering column, a brake hydraulic system or a Bowden cable for the accelerator pedal. Such an electronically controlled drive train is thus a drive-by-wire system or generally an X-by-wire system.
When motor vehicles are maneuvered, in particular when they travel in reverse, a person to give instructions is useful especially in the case of trucks in order to reduce the risk of collision and risk of an accident. This is all the more so the case for vehicle combinations composed of a tractive unit and trailer or semitrailer which exhibit particularly complex kinematics when traveling in reverse. Since the person to give instructions is comparatively expensive for commercial vehicles, there is desire to simplify the maneuvering operation to such an extent that it is possible to do without a costly person to give instructions.
WO 03045726 A discloses a utility vehicle having a maneuvering assistance system. In one development, an emergency braking system is also disclosed and is intended to reduce the risk of a collision when maneuvering. Electronic actuation of the steering, of the brakes and of the drive is described for the purpose of operating these automatic driver assistance systems.
EP 1 332 948 A1 describes an embodiment of an automatic parking system for a motor vehicle. That system parks a vehicle automatically into a parking space after an input means has been activated. Further driver assistance systems are disclosed in DE 38 44 340 A and in DE 101 13 323 A.
The present invention is concerned with solving the above problem by providing an improved vehicle in which in particular maneuvering is simplified.
This problem has been solved according to the invention by means of the subject matter of the independent claim. Advantageous embodiments are the subject matter of the dependent claims.
The present invention is based on the general concept of equipping the motor vehicle with a maneuvering assistance system in which the actual situation of the vehicle with respect to the surroundings of the vehicle is displayed on a monitor, in which a requested desired situation for the vehicle can be predefined and in which a suitable maneuvering algorithm is used to actuate the drive train in such a way that the vehicle is transferred automatically from its actual situation into the requested desired situation while taking into account the surroundings of the vehicle.
For example, a passenger car which is configured according to the present invention can be parked automatically in a parking space to the side. Likewise, a vehicle combination according to the present invention can be actuated in such a way that its trailer is automatically moved in reverse to a (narrow) loading ramp. The display device proposed according to the present invention for displaying the actual situation of the vehicle and the current surroundings of the vehicle simplifies the inputting of the desired situation.
Furthermore, the monitor permits the satisfactory functioning of the maneuvering assistance system to be checked visually. The automatic maneuvering of the vehicle by way of a maneuvering algorithm makes it in particular possible to avoid hazardous situations which may arise due to the vehicle dynamics (rolling, tilting) or from the vehicle kinematics (jack-knifing of the vehicle combination). The operation of the vehicle is thus made safer.
A determining device which is fixed to the vehicle and has the purpose of acquiring the data for the actual position, the actual orientation and the surroundings of the vehicle can expediently be provided. With respect to the displaying of the actual situation of the vehicle and the current surroundings of the vehicle on the monitor, the vehicle according to the invention is autonomous in this embodiment, that is to say independent of external devices. The usability of the maneuvering assistance system is thus increased.
In addition or alternatively, a determining device which is remote from the vehicle can also be provided. The, said determining device can be connected to a data transmitter and thus permit data to be transmitted to a data receiver which is fixed to the vehicle and is connected to the maneuvering assistance system. For example, a dispatching center can be equipped with such a determining device which is remote from the vehicle, thus permitting greater precision to be obtained for the actual values of the position and orientation of the vehicle and for the surroundings of the vehicle, that is to say in particular the position of obstacles. For example, the positions of loading stations within the dispatching center are known and invariable so that the associated position data can be acquired comparatively precisely. Furthermore, a determining device which is remote from the vehicle can simplify the coordination of the maneuvering operation of a plurality of motor vehicles.
In one development, the input device communicates with the display device so that the display device additionally displays on the monitor the desired situation of the vehicle which has been input with the input device. The driver of the vehicle can thus particularly easily check whether the requested desired situation matches the surroundings of the vehicle which have been acquired. In one particularly convenient development, the desired situation can be input using an input element while the desired situation is simultaneously displayed on the monitor. The input element is configured, for example, such that a cursor can thus be adjusted on the monitor. As a result, the requested desired situation can be predefined particularly easily using the monitor. This thus results in particularly easy handling for the maneuvering assistance system.
The vehicle can also be equipped with an emergency braking system which communicates with a distance sensor system which is fixed to the vehicle and is configured to automatically brake the vehicle if the emergency braking system detects a risk of a collision between the vehicle and an obstacle. In one particularly expedient development of the present invention, the maneuvering assistance system can be coupled to such an emergency braking system so that the vehicle is automatically braked if a risk of a collision arises for the vehicle when the maneuvering algorithm is being processed. For example, the conditions of the surroundings of the vehicle may change during maneuvering, and this can be taken into account in this embodiment in order to avoid a collision. This development thus increases the safety of the vehicle.
Other objects, advantages and novel features of the present invention will become apparent from the following detailed description of the invention when considered in conjunction with the accompanying drawings.
According to
As shown in
The motor vehicle according to the present invention is also equipped with a maneuvering assistance system 6 which is represented in
The display device 7 is constructed so that it can display or represent an actual orientation and an actual position of the vehicle 1 as well as the relatively close surroundings of the vehicle 1 on the monitor 10. Examples of such displays are explained in more detail below with reference to
In the present context, the term “vehicle position” describes the geographic position of the vehicle 1, while the term “vehicle orientation” describes the orientation of a longitudinal axis of the vehicle 1 in a reference coordinate system which can be defined, for example, by the points of the compass. The relatively close surroundings of the vehicle comprise at least partially an area which surrounds the vehicle 1 at a distance, and the surroundings thus include obstacles in the vicinity of the vehicle, for example other vehicles, crash barriers, posts, lighting pylons, curbstones, house walls, walls and the like.
The input device 8 is configured so that it can be used to input a desired orientation and a desired position for the vehicle 1 into the maneuvering assistance system 6.
The control system 9 has access to a maneuvering algorithm 12 and is connected to the drive train 2 via a line 13. The control system 9 is configured in such a way that it can process the maneuvering algorithm 12. When the maneuvering algorithm 12 is processed, the control system 9 actuates the drive train 2 so that it transfers the vehicle 1 from the actual orientation and the actual position into the desired orientation and desired position, and this transfer is carried out while taking into account the surroundings of the vehicle. That is a collision between the vehicle 1 and an obstacle is automatically avoided, and the obstacles are driven around.
The maneuvering assistance system 6 also comprises a determining device 14 which is fixed to the vehicle and which can be used to acquire the data for the actual position, the actual orientation and the surroundings of the vehicle. For this purpose, the determining device 14 communicates with the display device 7, here by way of the control system 9. The determining device 14 interacts with a distance sensor system 15 which is fixed to the vehicle and which is either mounted on the vehicle 1 specifically for the maneuvering assistance system 6 or is already present on the vehicle 1 and is used within the scope of other systems for acquiring distances between the vehicle 1 and obstacles (for examples a distance maintaining system).
In addition or alternatively, the maneuvering assistance system 6 can have a determining device 16 which is remote from the vehicle and which also serves to acquire the data for the actual position, the actual orientation and the surroundings of the vehicle. The determining device 16 which is remote from the vehicle is connected to a first data transmission device 17 which comprises in particular a data transmitter. The maneuvering assistance system 6 is then equipped with a second data transmission device 18 which is fixed to the vehicle and which comprises, in particular, a data receiver. The second data transmission device communicates with the display device 7, here again via the control system 9.
As seen in
The additional input device 21 is equipped here with an input element 23 which can be used to input the desired orientation and the desired position of the vehicle 1 into the system manually. This input element 23 is, for example, a trackball or the like. The additional input device 21 can also have at least one further input element. It is clear that the input device 8 which is fixed to the vehicle has corresponding input elements, but these need not be illustrated here.
According to one advantageous development, the input device, that is to say the input device 8 which is fixed to the vehicle and/or the additional input device 21 which is remote from the vehicle, communicates with the display device 7. The display device 7 is then expediently configured so that it additionally displays on the respective monitor 10 or 20 the desired orientation and desired position of the vehicle 1 which have been input using the respective input device 8, 21. As a result, the user can see directly the result of his input and check, and possibly correct it. The maneuvering assistance system 6 is thus made considerably easier to handle.
As shown in
Additionally or alternatively, the distance sensor system 15 can have a camera 28 on the rear of the vehicle 1. Since the present illustration is concerned with a vehicle combination 26, 27, such a camera 28 is mounted both on the rear of the trailer 27 and on the rear of the tractive unit 26. The surroundings to the rear of the vehicle 1 can be photographed using such a camera 28.
Additionally or alternatively, the distance sensor system 15 can have a radar device 29 which is arranged on the front of the vehicle 1 and which can be used to scan the surroundings in front of the vehicle 1 for obstacles. The aforesaid components of the distance sensor system 15 are in each case components which may be already present within the scope of other vehicle systems on the vehicle 1. As already explained, the maneuvering assistance system 6 according to the present invention then expediently has recourse to the elements of the distance sensor system 15 which are present in any case on the vehicle 1. The expenditure on implementing the maneuvering assistance system 6 according to the invention is thus comparatively low.
Further components of a distance sensor system 15 which is fixed to the vehicle may be, for example, a laser scanner, a satellite navigation device such as, for example, a GPS, and a compass which can be read out.
The method of functioning of the maneuvering assistance system 6 according to the invention is explained in more detail below with reference to
In the example shown in
Then, the actual maneuvering process during which the control system 9 processes the maneuvering algorithm 12 is started, in particular manually. At the same time, the control system 9 actuates the drive train 2 so that the trailer 27 is automatically transferred from its actual orientation and actual position into the requested desired orientation and desired position.
As already mentioned above, the actual orientation and actual position and the surroundings 30 of the vehicle can also be acquired using an external determining device 16 and displayed on the monitor 10, 20. For example, a dispatching center may be equipped with a comparatively precisely operating position and orientation detecting device for the vehicles 1 located at it, and the device 16 can be used to determine relatively precisely the current actual values for the orientation and position of the vehicles 1 located at the dispatching center. Furthermore, fixed conditioning factors in the surroundings such as, for example, loading ramps, buildings and other obstacles are known to such a system and are also measured relatively precisely. As a result, in particular the surroundings of the vehicle 1 in a comparatively large area can be displayed completely on the monitor 10, 20. The data for the actual orientation, actual position and surroundings can be transferred to the maneuvering assistance system 6 by the data transmission devices 17, 18.
The vehicle 1 can also be equipped with an emergency braking system of known type (not illustrated). Such an emergency braking system communicates with the distance sensor system 15 which is fixed to the vehicle and causes the vehicle 1 to be braked automatically and in good time if the emergency braking system detects a risk of a collision between the vehicle 1 and an obstacle in the surroundings of the vehicle 1.
The maneuvering assistance system 6 according to the invention can then expediently be coupled to such an emergency braking system, specifically so that the emergency braking system is automatically activated while the maneuvering assistance system 6 is operating. This ensures the vehicle 1 can be braked automatically in good time even if a risk of collision arises while the control system 9 is processing the maneuvering algorithm. For example, a risk of collision may arise if a mobile obstacle is located in or moves into the path of the vehicle 1 which is acquired by means of the maneuvering algorithm.
According to
Number | Date | Country | Kind |
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10339075.8 | Aug 2003 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/09294 | 8/19/2004 | WO | 10/4/2006 |