STEERING SYSTEM

Abstract

A steering system for a vehicle including at least one pair of wheel units which can be actuated and deflected independently of each other. Each wheel unit is paired with at least one sensor device for detecting a deviation from a specified deflection of the wheel units relative to each other, and each wheel unit is paired with at least one actuation device in order to actuate the wheel units. At least one control unit is designed to actuate the actuation devices of the wheel units when the sensor devices detect a specified deviation of the specified deflection of the wheel units relative to each other.

Claims

1. A steering system for a vehicle, comprising: at least one pair of wheel units configured to be actuated and deflected independently of each other; each wheel unit being paired with at least one sensor device for detecting a deviation from a specified deflection of the wheel units relative to each other; at least one wheel unit being paired with at least one actuation device for actuating the wheel unit; and at least one control unit configured to actuate the at least one actuation device when the sensor devices detect a specified deviation of the specified deflection of the wheel units relative to each other.

2. The steering system according to claim 1, wherein at least one connecting means is provided between the sensor devices of two wheel units to provide a tensile or compressive load to the sensor devices when the deflection of the wheel units relative to each other exceeds a specified deviation.

3. The steering system according to claim 1, wherein at least two connecting means are provided between the sensor devices of the wheel units, wherein each connecting means is anchored on one side and is configured on a second side to provide a tensile or compressive load to a respective sensor device when the deflection of the wheel units relative to each other exceeds a specified deviation.

4. The steering system according to claim 1, wherein at least one flexible connecting means is provided between the sensor devices, the connecting means configured to deliver a measured variable that can be detected by the sensor devices when the deflection of the wheel units relative to each other exceeds a specified deviation.

5. The steering system according to claim 1, wherein the sensor devices comprise sensor means configured to detect a respective deflection of a wheel unit and to transmit same by means of at least one of a wireless or wired signal connection to the control unit or to further sensor devices.

6. The steering system according to claim 1, wherein the steering system is a steer-by-wire steering system and does not include a central control unit for the wheel units.

7. The steering system according to claim 1, wherein the wheel units are not connected via a mechanical steering means.

8. The steering system according to claim 1, wherein the steering system comprises at least a first pair of wheel units and at least a second pair of wheel units, and wherein one of the pairs of wheel units is actuated depending on the deflection of the wheel units of the other pair of wheel units.

9. A vehicle, comprising at least one steering system, the steering system including: at least one pair of wheel units configured to be actuated and deflected independently of each other; each wheel unit being paired with at least one sensor device for detecting a deviation from a specified deflection of the wheel units relative to each other; and at least one wheel unit being paired with at least one actuation device for actuating the wheel unit; at least one control unit configured to actuate the at least one actuation device when the sensor devices detect a specified deviation of the specified deflection of the wheel units relative to each other.

10. A method of use of a steering system for a vehicle comprising: providing a steering system having: at least one pair of wheel units that can be actuated and deflected independently of each other; each wheel unit being paired with at least one sensor device for detecting a deviation from a specified deflection of the wheel units relative to each other; and at least one of the wheel units being paired with at least one actuation device for actuating the at least one wheel unit; at least one control unit configured to actuate the at least one actuation device when the sensor devices detect a specified deviation of the specified deflection of the at least one wheel unit relative to the other; detecting a deviation from a specified deflection of the wheel units relative to each other with the sensor devices; and actuating the at least one actuation device in response to detecting the deviation to deflect at least one of the wheel units.

11. The vehicle according to claim 9, wherein at least one connecting means is provided between the sensor devices of two wheel units to provide a tensile or compressive load to the sensor devices when the deflection of the wheel units relative to each other exceeds a specified deviation.

12. The vehicle according to claim 9, wherein at least two connecting means are provided between the sensor devices of the wheel units, wherein each connecting means is anchored on a first side and configured on a second side to provide a tensile or compressive load to a respective sensor device when the deflection of the wheel units relative to each other exceeds a specified deviation.

13. The vehicle according to claim 9, wherein at least one flexible connecting means is provided between the sensor devices, the connecting means configured to deliver a measured variable that can be detected by the sensor devices when the deflection of the wheel units relative to each other exceeds a specified deviation.

14. The vehicle according to claim 9, wherein the sensor devices comprise sensor means which are configured to detect a respective deflection of a wheel unit and to transmit same by means of at least one of a wireless or wired signal connection to the control unit or to further sensor devices.

15. The vehicle according to claim 9, wherein the steering system is a steer-by-wire steering system and does not include a central control unit for the wheel units.

16. The vehicle according to claim 9, wherein the wheel units are not connected via a mechanical steering means.

17. The vehicle according to claim 9, wherein the steering system comprises at least a first pair of wheel units and at least a second pair of wheel units, and wherein one of the pairs of wheel units is actuated depending on the deflection of the wheel units of the other pair of wheel units.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] Further advantages and possible applications of the present disclosure result from the following description, the exemplary embodiment and the figures. In the figures:

[0022] FIG. 1 shows a schematic view of the preferred embodiment of a steering system according to the disclosure;

[0023] FIG. 2 shows a schematic view of a parallel alignment of the wheel units of a steering system according to the disclosure;

[0024] FIG. 3 two schematic views of a non-parallel alignment of the wheel units of a steering system according to the disclosure; and

[0025] FIG. 4 shows a schematic view of a second preferred embodiment of a steering system according to the disclosure.

DETAILED DESCRIPTION

[0026] FIG. 1 shows a schematic view of a first preferred embodiment of a steering system 10 according to the disclosure. The steering system 10 comprises a first wheel unit 15 and a second wheel unit 20.

[0027] The wheel units 15, 20 each comprise an actuating means 16, 21 by means of which the orientation of the wheel units 15, 20 can be changed. In addition, the wheel units 15, 20 each include a sensor device 17, 22 for detecting a deflection of the wheel units 15, 20, or for detecting a deviation in the alignments of the wheel units 15, 20 relative to each other. A connecting means 30 is arranged between the sensor devices 17, 22 in the preferred embodiment shown. Finally, the preferred embodiment shown comprises a central control unit 35. The control unit 35 serves to process the signals from the sensor devices 17, 22 and to control the actuation devices 16, 21. Alternatively, the control unit 35 can also be designed in several parts and/or also be integrated in the sensor devices 17, 22 and/or the actuating means 16, 21. As already explained, in addition to the control unit 35, a central control unit of a steer-by-wire system can also be provided.

[0028] The connecting means 30 can be designed, for example, to provide/deliver a tensile or compressive load to the sensor devices 17, 22 if the deflection of the wheel units 15, 20 relative to each other exceeds a specified deviation. For example, such a connecting means 30 can be a hydraulic pressure cable connection and/or a rigid rod made of a pressure-resistant material such as metal, fiberglass, or aluminum.

[0029] As long as the wheel units 15, 20 are arranged in parallel or synchronously (cf. FIG. 2), the connecting means 30 does not transmit any tensile or compressive load to the or one of the sensor device(s) 17, 22. However, if the wheel units 15, 20 are no longer arranged as intended (see FIGS. 3a and 3b), the connecting means 30 is pressed onto the or one of the sensor device(s) 17, 22, so that a corresponding deviation can be detected. The rigid connecting means 30 shown is attached to both the left and right wheel units 15, 20 in such a way that the attachment points of the connecting means 30 to the left and right wheel units 15, 20 remain unchanged when both the left and right wheel units 15, 20 maintain the same orientation (see FIG. 2). So if both wheel units 15, 20 change their alignment in parallel, the connecting means 30 moves accordingly and the attachment points are not affected. However, if a wheel unit 15, 20 changes its alignment in a non-parallel manner (cf. FIGS. 3a and 3b), for example due to a mechanical wheel failure or a failure of the steering system, the connecting means 30 is pressed or pulled so that a deviation in alignment is detected and the control unit 35 can react accordingly. The control unit 35 is preferably designed in such a way that when a specified deviation in the deflection of the wheel units 15, 20 relative to each other is exceeded, i.e., in the event of a synchronization error, for example caused by a faulty control signal from a central control unit of a steer-by-wire steering system, the alignment and/or the speed of one or more wheel units 15, 20 is adjusted. For example, a potentially faulty wheel unit 15, 20 can be switched from a master mode to a slave mode or a freewheel mode to provide synchronization of the wheel units 15, 20 again. A corresponding warning message can also be sent to the vehicle's electronic control system or emitted to the driver.

[0030] Alternatively, the connecting means 30 can also be provided by two rigid rods, each of which is firmly anchored on opposite sides and arranged on the other opposite sides to provide a tensile or compressive load on a respective sensor device 17, 22 when the deflection of the wheel units 15, 20 relative to each other exceeds a specified deviation. For example, the rods can be connected to both the left and the right wheel unit, so that one rod is firmly connected to a left wheel unit and the other rod is firmly connected to the right wheel unit, wherein the rods are connected at the opposite ends thereof to the respective wheel unit in sensory engagement with the respective sensor device 17, 22. Alternatively or additionally, the connecting means 30 can be embodied as a flexible connecting means 30 that is designed to deliver a measured variable that can be detected by the sensor devices 17, 22 when the deflection of the wheel units 15, 20 relative to each other exceeds a specified deviation. Such a flexible connecting means 30 can be provided, for example, by a metal wire that is pulled or pushed, a rubber band for which the tension and strain level is measured, or a gas-filled hose that is modulated and generates a positive and negative pressure that can be measured at both ends. Furthermore, the sensor devices 17, 22 can comprise a sensor means that is designed to detect the respective deflection of a wheel unit 15, 20 and to be transmitted by means of a wireless and/or wired connecting means 30 in the form of a signal connection to the control unit 35 and/or to the further sensor devices 17, 22. A wireless signal connection can be implemented, for example, by using appropriate radio signal standards. Magnetic field fluctuations, electromagnetic field fluctuations, ultrasonic signals, vibrations that are transmitted through the body or chassis of the vehicle, or light pulses that are used by the corresponding visible or non-visible range can also be used for a signal exchange. For example, radio communication, infrared light communication, current-modulated communication and/or ultra-wideband communication can be used to enable provision of a corresponding signal exchange.

[0031] FIG. 2 shows an alignment of the wheel units 15, 20 in parallel normal operation, in which the two wheel units 15, 20 are aligned synchronously, i.e., both wheel units 15, 20 have the same angle ? to a direction of travel. Two examples of a deviation in the alignment of the two wheel units 15, 20 relative to each other are shown in FIGS. 3a and 3b. In the examples shown, the angle ? of the left wheel unit 15 is smaller (see FIG. 3a) or larger (see FIG. 3b) than the angle ?, and the wheel units 15, 20 are no longer aligned synchronously relative to each other. In this context, it should be pointed out that the deviations or synchronization errors of the wheel units 15, 20 shown are only given as examples, and a wide variety of other incorrect alignments can be present. For example, the two wheel units 15, 20 with different angles can also point in the same direction. Such a non-synchronous constellation of the wheel units 15, 20 can also be detected and dealt with by the present disclosure.

[0032] FIG. 4 shows a schematic view of a second preferred embodiment of a steering system 10 according to the disclosure. In contrast to the exemplary embodiment shown in FIG. 1, this exemplary embodiment includes two pairs of wheel units 15, 20, 15, 20. In the preferred embodiment shown, the two wheel units 15, 20 form the front wheel units 40 and the two wheel units 15, 20 form the rear wheel units 45 of a vehicle. The wheel units 15, 20, 15, 20 in turn each comprise an actuating means 16, 21, 16, 21 by means of which the orientation of the wheel units 15, 20, 15, 20 can be changed. In addition, the wheel units 15, 20, 15, 20 each have a sensor device 17, 22, 17, 22 for detecting a deflection of the wheel units 15, 20, 15, 20 or for detecting a deviation in the alignments of the wheel units 15, 20, 15, 20 relative to each other. A connecting means 30 is arranged between the sensor devices 17, 22 in the preferred embodiment shown. In this embodiment shown, the control unit is integrated in one or in the four wheel units 15, 20, 15, 20, wherein the control unit can also be integrated in two or three of the wheel units 15, 20, 15, 20. In this connection, it should be pointed out that the present disclosure is not limited to a specific constellation/distribution of the control unit(s). As can be seen clearly in FIG. 4, in this particularly preferred embodiment the wheel units 15, 20, 15, 20 are connected to each other with corresponding connecting means 30, 30, 30, 30. In this exemplary embodiment, the control unit can also be designed to adjust the alignment of a pair of rear wheel units 45 in accordance with the alignment of a pair of front wheel units 40, for example, to reduce the turning radius of the vehicle. The orientation of a pair of rear wheel assemblies 45 can be the same as the orientation of a single front wheel assembly 15, 20. The orientation of a pair of rear wheel units 45 can be made to correspond to the orientation of a pair of front wheel units 40, for example to enable special maneuvers such as sideways or diagonal driving of the vehicle. There is also the possibility of adapting the driving mode of the wheel units 40, 45 in the light of the road condition and/or the road grip, which can be detected with corresponding sensor devices, for example to be able to provide better traction. As shown in FIG. 4, several redundant (virtual) pairings can also be generated between the wheel units 15, 20, and a wheel unit 15, 20 can also be synchronized with more than one other wheel unit 15, 20 at the same time.

[0033] With the embodiments shown, it can thus be determined whether, for example, two front and/or rear wheel units 40, 45 are still deflected or positioned synchronously relative to each other, or synchronously with each other within a specified range, as should be the case for proper operation. Thus, the function of a steering axle, with which wheel units can be mechanically positioned relative to each other, is simulated, and a kind of virtual steering axle can be provided. The present disclosure can be used as additional redundancy for a central control system to increase the operational reliability and error tolerance in the control and steering of a vehicle, or as an alternative to a central control system.

[0034] However, the present disclosure is not limited to the previously preferred exemplary embodiments as long as it comprises the subject matter of the following claims.

LIST OF REFERENCE SYMBOLS

[0035] 10 Steering system [0036] 15 First wheel unit [0037] 16 Actuation means [0038] 17 Sensor device [0039] 20 Second wheel unit [0040] 21 Actuation means [0041] 22 Sensor device [0042] 30 Connecting means [0043] 35 Control unit [0044] 40 Front wheel unit [0045] 45 Rear wheel unit