WO2022017832A1

WO2022017832A1 - Electronic arrangement, sensor, electromechanical steering system and method for inductive transmission of power and data

Info

Publication number: WO2022017832A1
Application number: PCT/EP2021/069161
Authority: WO
Inventors: Zoltán BARANYAI
Original assignee: Thyssenkrupp Presta Ag; Thyssenkrupp Ag
Priority date: 2020-07-23
Filing date: 2021-07-09
Publication date: 2022-01-27
Also published as: EP4186082A1; DE102020209269A1

Abstract

The present invention relates to an electronic arrangement (1) for the inductive transmission of power and data, comprising a static unit (2) and a rotating unit (3), the static unit (2) having a first coil (4) and a first oscillating circuit (6) which has a first capacitor (5) and can be excited by an oscillator (7). The rotating unit (3) comprises a second coil (10) and a sensor switching circuit (11) which are connected to a first voltage supply (12), the first coil (4) and the second coil (10) forming a coil pair (16) for the inductive transmission of power from the static unit (2) to the rotating unit (3) and for the inductive transmission of data from the rotating unit (3) to the static unit (2), a second capacitor (18) being connected to the second coil (10) to form a second oscillating circuit (19). For data modulation, the second oscillating circuit (19) has a switch (20), controlled by means of the sensor switching circuit (11), to modulate the resonance frequency of the coupled oscillating circuits (6, 19). The static unit (2) has a signal measurement device (15) for determining the resonance frequency.

Description

Electronic arrangement, sensor, electromechanical steering system and method for inductive power and data transmission

The invention relates to an electronic arrangement for inductive power and data transmission comprising a static unit and a rotating unit, the static unit comprising a first resonant circuit which has a first coil and a first capacitor and which can be excited by an oscillator, and the rotating unit comprises a second Coil and a sensor circuit includes, which are connected to a power supply. The invention also relates to a sensor comprising such an electronic arrangement for determining the angle of rotation and/or torque, an electromechanical steering system with a sensor for determining the angle of rotation and/or torque and a method for inductive power and data transmission between a static and a rotating unit.

Torque sensors conventionally have a rotation angle sensor. In this case, two shaft parts that can be twisted to a limited extent in relation to one another are elastically coupled to one another via a torsion spring. When one shaft part is rotated against the other shaft part by a torque applied by the driver of the vehicle, the relative angle of rotation is essentially proportional to the torque introduced. For an accurate determination of the torque, it is important to be able to precisely measure the angle of rotation. Such a torque sensor is known, for example, from published application DE 10 2007 043 502 A1. A ring magnet is arranged on the upper steering shaft, while a holder with a magnetic stator is attached to the lower steering shaft, which is opposite the permanent magnet in the radial direction via a small air gap. The magnetic flux of the magnet is conducted via the stator, which usually consists of two separate stator parts, to a first and a second flux conductor, which then emit the magnetic flux to a magnetic sensor, for example a Hall sensor. Such a Torque sensor is also known as inductive torque sensor due to the way it works.

On an electronic level, the realization of such an inductive torque sensor requires that power and data be transmitted from the rotating part, the rotor, to the static part, the stator. For reasons of redundancy, two pairs of coils are regularly used for this purpose, with the pairs of coils enabling power transmission in any position relative to one another.

The problem with such an electronic arrangement is that it is not only very complicated but also expensive due to the use of two pairs of coils, which enable power transmission in each relative position of the two coils forming a pair different pairs of coils, which entails the risk of erroneous, possibly even dangerous, measurements.

Proceeding from the prior art described above, the invention is therefore based on the object of proposing an electronic arrangement that allows inductive power and data transmission to be carried out between a stator and a rotor in a simple and cost-effective manner, while minimizing any interference effects .

According to the invention, this object is achieved by an electronic arrangement of the type mentioned at the outset, the first and second coils forming a pair of coils for inductive power transmission from the static to the rotating unit and for inductive data transmission from the rotating to the static unit, with the second coil a second capacitor is connected to form a second resonant circuit, which for data modulation a via the sensor circuit controlled switch for modulating the resonant frequency of the coupled resonant circuits and the static unit has a signal measuring device for determining the resonant frequency.

In such an electronic arrangement, the first and second coils form a pair of coils for inductive power transmission from the static to the rotating unit and for inductive data transmission from the rotating to the static unit. This ensures both power and data transmission between the static and rotating units. In this case, a second capacitor is connected to the second coil, as a result of which a second oscillating circuit is formed in the rotating part in addition to the first oscillating circuit in the static part. Such an arrangement enables data modulation in a clever way, in that a switch controlled via the sensor circuit modulates the resonant frequency of the coupled oscillating circuits (the first and second oscillating circuit). In order to acquire or demodulate the data, the static unit has a signal measuring device for determining the resonant frequency of the coupled resonant circuits. In this way, the desired data and power transmission can be implemented inexpensively and simply by implementing a coupled resonant circuit, ie with only one pair of coils.

According to a particularly preferred embodiment of the invention, the switch for data modulation is a pair of MOSFETs, as a result of which a high data modulation can advantageously be achieved.

In a particularly suitable embodiment of the present invention, the oscillator that excites the first resonant circuit is a Royer oscillator. Such a Royer oscillator is particularly powerful and is also characterized by low-loss operation. In a development of the electronic arrangement according to the invention, the signal measuring device is a microcontroller for data demodulation. As a result, in addition to ensuring a high data rate, inexpensive data demodulation can also be provided. According to a further advantageous embodiment, the signal measuring device is implemented by a digital logic unit, in particular an ASIC or FPGA, or by analog signal processing.

According to a particularly preferred development of the electronic arrangement according to the invention, the data rate is up to 900 kHz, in particular in the range from 100 kHz to 900 kHz, preferably in the range from 250 kHz to 300 kHz or from 500 kHz to 600 kHz or from 750 kHz to 900 kHz kHz takes place. As a result, not only high, but electronically particularly suitable data rates can be used.

Furthermore, the invention relates to a sensor for determining an angle of rotation and/or a torque, the sensor having an electronic arrangement according to the invention. Thanks to the electronic arrangement that can be produced inexpensively, this sensor is characterized by particularly low production costs. In particular, the sensor is a rotation angle sensor and/or a torque sensor.

An electromechanical steering system is also proposed, which has a steering shaft, via which a steering command can be specified using a steering handle, a steering gear, which is designed to convert a steering command into a steering movement of steerable wheels of a motor vehicle, taking into account at least one input variable, and a Sensor device for measuring an applied to the steering shaft rotation angle and / or torque comprises, wherein the sensor device comprises a sensor for determining a rotation angle and / or a torque, the sensor an inventive has electronic arrangement. In particular, the sensor is a rotation angle sensor and/or a torque sensor with an electronic arrangement designed according to the invention.

Advantageously, the steering system also includes a computing unit, which is designed to provide the at least one input variable based on a sensor signal provided by the sensor.

In particular, the steering system is a steer-by-wire steering system.

In addition to the electronic arrangement according to the invention, the present invention also relates to a method for inductive power and data transmission between a static and a rotating unit, characterized by the following steps:

- exciting a first coil and a first capacitor having a first resonant circuit in the static unit by an oscillator;

- inductively transferring power from the static unit to the rotating unit having a second coil and a second capacitor connected to the second coil, the second coil and the second capacitor forming a second resonant circuit;

- Inductive transmission of data from the rotating to the static unit, the rotating unit for data modulation having a sensor circuit-controlled switch for modulating the resonant frequency of the coupled oscillating circuits; - measuring the resonant frequency of the received data by a signal measuring device in the static unit.

In this way, the desired data and power transmission can be implemented inexpensively and simply by implementing a coupled resonant circuit, ie with only one pair of coils.

According to a development of the method according to the invention, this is used to operate a sensor, in particular an angle sensor or a torque sensor, in a steering system, in particular to implement a steer-by-wire solution, with the data received by the static unit being sent to a steering system controlling engine control unit. In such a case, the risk of interference reduced by the method according to the invention has a positive effect on the steering safety achieved with a steer-by-wire solution.

According to a further development of the method according to the invention, the data modulation is implemented as frequency shift keying, which results in the advantage that particular insensitivity to interference is achieved.

According to a development of the method according to the invention, the first resonant circuit and the second resonant circuit are coupled, in particular so closely coupled, that both resonant circuits behave like a single resonant circuit, so that the transmittable data rate is advantageously further improved as a result.

Advantageous developments result from the dependent claims, the following description and the figures. The invention is described below using exemplary embodiments with reference to the attached figures. Show it:

1: a schematic representation of a previously known electronic arrangement for inductive power and data transmission, comprising a static and a rotating unit with two pairs of coils,

2 shows a schematic representation of an exemplary embodiment of an electronic arrangement according to the invention for inductive power and data transmission, comprising a static and a rotating unit with a pair of coils,

3 shows a representation of an exemplary embodiment of a method according to the invention for inductive power and data transmission between a static and a rotating unit using a coupled resonant circuit and

4: in a perspective view, a simplified representation of an exemplary embodiment of a steering system designed according to the invention.

In the various figures, the same parts are always provided with the same reference symbols and are therefore usually named or mentioned only once.

A previously known electronic arrangement 1 for inductive power and data transmission shown in FIG an oscillator 7 can be excited. In this case, the oscillator 7 is controlled by a control unit 8 in that electrical power 9 is transmitted from the control unit 8 to the oscillator 7, so that the first Resonant circuit 6 is excited. The rotating unit 3 comprises a second coil 10 and a sensor circuit 11 connected to a power supply 12 . In addition, such a previously known electronic arrangement 1 has a second pair of coils for data transmission from a rotating 3 to a static 2 unit. In this case, the data transmission is driven by a data coil driver 13 . The data 14 transmitted from the rotating unit 3 to the static unit 2 , in particular rotational angle data, are recorded by the signal measuring device 15 of the static unit 2 and forwarded to the control unit 8 . A disadvantage of such an arrangement are the high manufacturing and installation costs due to the two pairs of coils 16, 17. In addition, the different

Pairs of coils easily influence each other, which can lead to an undesirable occurrence of interference signals that, when used in a steering system, in particular a steer-by-wire solution, can negatively affect steering safety.

In contrast, FIG. 2 shows an exemplary embodiment of an electronic arrangement 1 according to the invention, in which only one pair of coils 16 is used. This is made possible in an intelligent manner by using the same pair of coils 16 for data and power transmission. For this purpose, the electronic arrangement 1 according to the invention has a pair of coils 16 for inductive power transmission from the static unit 2 to the rotating unit 3 and for inductive data transmission from the rotating unit 3 to the static unit 2, with a second capacitor 18 being connected to the second coil 10 for Formation of a second resonant circuit 19 is connected, which has a controlled via the sensor circuit 11 switch 20 for modulation of the resonant frequency of the coupled resonant circuits for data modulation. The data demodulation takes place in a signal measuring device 15 located in the static unit 2 to determine the resonant frequency. Furthermore, FIG. 3 shows an exemplary embodiment of a method according to the invention for inductive power and data transmission between a static unit 2 and a rotating unit 3 using a coupled resonant circuit.

In this case, in a first step VI, a first oscillating circuit 6 having a first coil 4 and a first capacitor 5 is excited in the static unit 2 by an oscillator 7 .

Then, in a second step V 2 , a power 9 is inductively transmitted from the static unit 2 to a rotating unit 3 which has a second coil 10 and a second capacitor 18 connected to the second coil 10 , the second coil 10 and the second capacitor 18 form a second resonant circuit 19.

In a third method step V3, data 14 is inductively transmitted from the rotating unit 3 to the static unit 2, the rotating unit 3 for data modulation having a switch 20 controlled by a sensor circuit 11 for modulating the resonant frequency of the coupled oscillating circuits.

Finally, in a fourth step V4 of the method, the resonant frequency of the received data is detected by a signal measuring device 15 in the static unit 2 .

FIG. 4 shows an electromechanical steering system 101 for a motor vehicle in a perspective, simplified representation obliquely from the front in the direction of travel of the vehicle. The steering system 101 includes a steering column with a steering shaft 102. The steering shaft 102 is mechanically coupled via a steering gear 103 to the steerable wheels 104 of a motor vehicle. In this exemplary embodiment, the steering gear 103 comprises a pinion 105 and a toothed coupling rod 106, the steering gear 103 serving to convert a rotational movement of the pinion 105 into a translational movement of the coupling rod 106 along its longitudinal axis. A steering handle 107, in particular a steering wheel, for inputting a driver's steering request or steering command is arranged in a rotationally fixed manner on the end of steering shaft 102 facing the driver.

In this exemplary embodiment, the coupling rod 106, which moves linearly along its longitudinal axis, is mechanically coupled to a tie rod 108 on both sides of the motor vehicle. The tie rods 108 are in turn mechanically coupled to the vehicle wheels 104 respectively. The steering gear 103 is thus designed to convert a steering command into a steering movement of the steerable wheels 104 of the motor vehicle, taking into account at least one input variable.

For this purpose, the steering system 1 further comprises a sensor device 140, shown only schematically in FIG. 4, which has a sensor 112 for detecting a torque. The connecting line 130 in FIG. 4 symbolically represents the corresponding arrangement position of the sensor 112 on the steering shaft 102 in which the sensor 112 can detect a torque applied to the steering shaft 2 . In this case, the sensor 112 comprises an electronic arrangement 1, as explained in particular with reference to FIG. The rotating unit 3 is arranged on the steering shaft 102 in such a way that it also rotates when the steering shaft 102 rotates. The static unit 2 is stationary so that it does not rotate when the steering shaft 102 rotates. For power and data transmission between the rotating unit 3 and the static Unit 2 uses a proposed method for inductive power and data transmission, in particular a method as explained with reference to FIG.

In this exemplary embodiment, the detected sensor signal is transmitted to a computing unit 135 assigned to sensor device 140 via a signal line, which can be wired or wireless. In this exemplary embodiment, the arithmetic unit 135 is part of the sensor device 140. In particular, the arithmetic unit 135 can be a microcontroller circuit, in particular an application-specific integrated circuit (ASIC). Arithmetic unit 135 is designed to determine an input variable on the basis of the sensor signal and to make the input variable available via a signal line, which can be wired or wireless, in particular as a radio link, in particular to steering gear 103 or a control unit assigned to steering gear 103 (in 4 not shown).

Reference List

1 electronic arrangement

2 static unit

3 rotating unit

4 first coil

5 first capacitor

6 first resonant circuit

7 oscillator

8 control unit

9 performance

10 second coil

11 sensor circuit

12 power supply

13 data coil driver

14 dates

15 signal measuring device

16 first pair of coils

17 second pair of coils

18 second condenser

19 second resonant circuit

20 switches

101 electromechanical steering system

102 steering shaft

103 steering gear

104 wheel

105 steering pinion

106 connecting rod

107 steering handle

108 tie rod 112 sensor Connecting line arithmetic unit sensor device

Claims

Expectations

Claims 1. Electronic arrangement (1) for inductive power and data transmission, comprising a static unit (2) and a rotating unit (3), the static unit (2) having a first coil (4) and a first capacitor (5). first oscillating circuit (6) which can be excited by an oscillator (7), and the rotating unit (3) comprises a second coil (10) and a sensor circuit (11) connected to a voltage supply (12), characterized that the first coil (4) and the second coil (10) are a pair of coils (16) for inductive power transmission from the static unit (2) to the rotating unit (3) and for inductive data transmission from the rotating unit (3) to the form a static unit (2), a second capacitor (18) being connected to the second coil (10) to form a second oscillating circuit (19), which has a switch (20) controlled via the sensor circuit (11) for data modulation. for modulating the resonant frequency of the coupled resonant circuits and the static unit (2) has a signal measuring device (15) for determining the resonant frequency.

2. Electronic arrangement (1) according to claim 1, characterized in that the switch (20) is a pair of MOSFETs.

3. Electronic arrangement (1) according to any one of claims 1 to 2, characterized in that the oscillator (7) is a Royer oscillator.

4. Electronic arrangement (1) according to any one of claims 1 to 3, characterized in that the signal measuring device (15) is a microcontroller for data demodulation.

5. Electronic arrangement (1) according to one of claims 1 to 4, characterized in that the data transmission takes place at a data rate of up to 900 kHz, in particular in the range from 100 kHz to 900 kHz, preferably in the range from 250 kHz to 300 kHz or from 500 kHz to 600 kHz or from 750 kHz to 900 kHz.

6. Sensor for determining an angle of rotation and/or a torque, characterized in that the sensor has an electronic arrangement (1) according to one of the preceding claims.

7. Electromechanical steering system (101) comprising a steering shaft (102) via which a steering command can be specified by means of a steering handle (107), a steering gear (103) which is designed to convert a steering command into a steering movement, taking into account at least one input variable of steerable wheels (104) of a motor vehicle, and a sensor device (140) for measuring an angle of rotation and/or torque applied to the steering shaft (102), characterized in that the sensor device (140) comprises a sensor according to Claim 6.

8. steering system (101) according to claim 7, characterized by a computing unit (135), which is designed to provide the at least one input variable based on a sensor signal provided by the sensor.

9. steering system (101) according to claim 7 or claim 8, characterized in that the steering system (101) is a steer-by-wire steering system.

10. Method for inductive power and data transmission between a static unit (2) and a rotating unit (3), characterized by the following steps:

exciting a first resonant circuit (6) in the static unit (2) having a first coil (4) and a first capacitor (5) by an oscillator (7) (VI);

Inductive transmission of power (9) from the static unit

(2) the rotating unit (3) having a second coil (10) and a second capacitor (18) connected to the second coil (10), the second coil (10) and the second capacitor (18) forming a second resonant circuit (19) form (V2);

Inductively transferring data (14) from the rotating unit

(3) on the static unit (2), the rotating unit (3) for data modulation having a sensor circuit (11) controlled switch (20) for modulating the resonant frequency of the coupled oscillating circuits (6, 19) (V3);

measuring the resonant frequency of the received data by a signal measuring device (15) in the static unit (V4).

11. Method for inductive power and data transmission according to claim 10, characterized in that the method for operating a sensor, in particular an angle sensor or a torque sensor, is used in a steering system (101) and the static unit (2) received Data are routed to an engine control unit controlling a steering system.

12. Method for inductive power and data transmission according to claim 10 or claim 11, characterized in that the data modulation is carried out as frequency shift keying.

13. Method for inductive power and data transmission according to one of claims 10 to 12, characterized in that the first resonant circuit (6) and the second resonant circuit (19) are coupled such that both resonant circuits (6, 19) as a single resonant circuit behave.