This application claims priority to German Patent Application No. 102021125949.5 filed on Oct. 6, 2021, the content of which is incorporated by reference herein in its entirety.
The present disclosure relates to sensor devices. Furthermore, the present disclosure relates to methods for operating and for producing sensor devices.
Sensor devices can be used in a large number of technical applications. By way of example, EPS (Electronic Power Steering) systems may use torque sensors. Magnetic stray fields may occur in certain environments and may undesirably influence and corrupt the measurements of the sensor devices. Manufacturers and developers of sensor devices constantly endeavour to improve their products and associated methods. In particular, it may be desirable to provide sensor devices and also associated operating and production methods which work reliably and accurately despite the occurrence of magnetic stray fields.
Various aspects relate to a sensor device. The sensor device includes a first stator pair, comprising a first ferromagnetic stator and a second ferromagnetic stator. The sensor device furthermore includes a second stator pair, comprising the second ferromagnetic stator and a third ferromagnetic stator. The sensor device furthermore includes a multipole magnet, which is rotatable relative to the two stator pairs, wherein a magnetic field is induced as a result of the rotation of the multipole magnet relative to the stator pairs. The sensor device furthermore includes a first magnetic field sensor configured to output a first sensor signal. The sensor device furthermore includes a second magnetic field sensor configured to output a second sensor signal. The sensor device furthermore includes a magnetic flux concentrator configured to concentrate the induced magnetic field at the location of the first magnetic field sensor and at the location of the second magnetic field sensor. The magnetic flux concentrator and the two magnetic field sensors are arranged in such a way that an influence of a rotation-independent magnetic stray field on the two sensor signals is compensated for upon difference formation or summation applied to the two sensor signals.
Various aspects relate to a sensor device. The sensor device includes a first stator pair, comprising a first ferromagnetic stator and a second ferromagnetic stator. The sensor device furthermore includes a second stator pair, comprising the second ferromagnetic stator and a third ferromagnetic stator. The sensor device furthermore includes a multipole magnet, which is rotatable relative to the two stator pairs, wherein a magnetic field is induced as a result of the rotation of the multipole magnet relative to the stator pairs. The sensor device furthermore includes a magnetic field sensor configured to output a sensor signal. The sensor device furthermore includes a magnetic flux concentrator configured to concentrate the induced magnetic field at the location of the magnetic field sensor. Upon rotation of the multipole magnet relative to the stator pairs, a first magnetic circuit is formed by the magnetic flux concentrator and the first stator pair and a second magnetic circuit is formed by the magnetic flux concentrator and the second stator pair. The magnetic flux concentrator and the magnetic field sensor are arranged in such a way that an influence of a rotation-independent magnetic stray field on the sensor signal is compensated for upon coupling of the two magnetic circuits.
Various aspects relate to a method. The method includes rotating a multipole magnet relative to a first stator pair and a second stator pair, wherein a magnetic field is induced. The method furthermore includes concentrating the induced magnetic field at the location of a first magnetic field sensor and at the location of a second magnetic field sensor using a magnetic flux concentrator. The method furthermore includes outputting a first sensor signal using the first magnetic field sensor and a second sensor signal using the second magnetic field sensor. The magnetic flux concentrator and the two magnetic field sensors are arranged in such a way that an influence of a rotation-independent magnetic stray field on the two sensor signals is compensated for upon difference formation or summation applied to the two sensor signals.
Various aspects relate to a method for producing a sensor device. The method includes providing a first stator pair and a second stator pair. The method furthermore includes providing a multipole magnet, which is rotatable relative to the two stator pairs, wherein a magnetic field is induced as a result of the rotation of the multipole magnet relative to the stator pairs. The method furthermore includes providing a first magnetic field sensor configured to output a first sensor signal. The method furthermore includes providing a second magnetic field sensor configured to output a second sensor signal. The method furthermore includes providing a magnetic flux concentrator configured to concentrate the induced magnetic field at the location of the first magnetic field sensor and at the location of the second magnetic field sensor. The magnetic flux concentrator and the two magnetic field sensors are arranged in such a way that an influence of a rotation-independent magnetic stray field on the two sensor signals is compensated for upon difference formation or summation applied to the two sensor signals.
Sensor devices and also associated production and operating methods in accordance with the disclosure are explained in greater detail below with reference to drawings. Identical reference signs may denote identical components.
The torque sensor situated at the torsion bar 4 can have a rotor and a stator.
Upon rotation of the first rotary shaft 2A relative to the second rotary shaft 2B, the multipole magnet 6 can be rotated relative to the ferromagnetic stators 10A and 10B. In this case, a rotation of the multipole magnet 6 can be based on a rotation of the steering column or a rotation of a steering wheel. In the example in
The sensor device 100 can be for example part of an EPS system, e.g., of an electrical power-assisted steering system. The EPS system can have an electric motor (not illustrated) for steering assistance of the power-assisted steering system. From the information about the applied torque provided by the magnetic field sensor 14, a control unit (ECU, Electronic Control Unit) (not illustrated) of the EPS system can ascertain required steering assistance of the electrical power-assisted steering system. In order to provide the steering assistance, the electric motor can be driven by way of a 3-phase driver IC, for example. It should be noted that an application of the sensor devices described herein is not restricted to electrical power-assisted steering systems. Rather, the sensor devices described herein can be implemented in any applications for whose operation a determination of an angle of rotation or a torque is intended to be provided.
The sensor device 200 in
The sensor device 400 can have a first stator pair 8A and a second stator pair 8B. The position of the stator pairs 8A and 8B relative to one another can be fixed. The first stator pair 8A can consist of a first ferromagnetic stator 10A and a second ferromagnetic stator 10B. Analogously, the second stator pair 8B can consist of a third ferromagnetic stator 10B and a fourth ferromagnetic stator 10C. In the example in
The sensor device 400 can have a multipole magnet 6. The multipole magnet 6 can be embodied in a ring-shaped fashion (or in the shape of a rim) and can have a multiplicity of alternating magnetic north poles and magnetic south poles. In the example in
The multipole magnet 6 can be rotatable relative to each of the stator pairs 8A and 8B. In the example in
The sensor device 400 can have a first magnetic flux concentrator 12A and a second magnetic flux concentrator 12B. In
The sensor device 400 can have a first magnetic field sensor 14A and a second magnetic field sensor 14B. The magnetic field sensors 14A and 14B are not explicitly illustrated in
A position of the first magnetic field sensor 14A can be rotated relative to a position of the second magnetic field sensor 14B about the axis of rotation or symmetry. In particular, it is discernible in the plan view in
In
On account of the north and south poles arranged in an alternating fashion, a rotation of the multipole magnet 6 can induce a magnetic field. The generated magnetic field can be concentrated at the locations of the magnetic field sensors 14A and 14B by the magnetic flux concentrators 12A and 12B, respectively. The directions of the concentrated magnetic fields can be dependent on the direction of rotation of the multipole magnet 6. In one example, the magnetic field concentrated at the location of the first magnetic field sensor 14A can run in the positive z-direction, and the magnetic field concentrated at the location of the second magnetic field sensor 14B can run in the negative z-direction. The magnetic fields concentrated at the locations of the magnetic field sensors 14A and 14B, respectively, can substantially have an identical absolute value and opposite signs.
Based on the measurements of the magnetic field sensors 14A and 14B, it is possible to determine a difference (or a sum) from the sensor signals output by the magnetic field sensors 14A and 14B. The difference (or sum) can be determined for example by one or both of the magnetic field sensors 14A and 14B or by a further component, such as a control unit, for example. As described below, an influence of magnetic stray fields on the detected difference (or sum) can be compensated for.
From the two signals output by the magnetic field sensors 14A and 14B, it is possible to form a difference signal in accordance with
In this case, Boutput is the difference signal that is output, Bsensor1 is the signal that is output by the first sensor, and Bsensor2 is the signal that is output by the second sensor. In the case of a magnetic stray field, an output signal can arise in accordance with
The magnetic flux concentrators 12A, 12B and the magnetic field sensors 14A, 14B can be arranged in such a way that the first output signal S1 and the second output signal S2 are inverted with respect to one another and identical in terms of absolute value if no magnetic stray field is present. In other words, it can hold true that
S2=−S1 (3)
This can give rise to the following for the output signal
On account of an identical influence of the magnetic stray field on the first sensor signal S1 and on the second sensor signal S2, the components of the magnetic stray field can thus cancel one another out upon difference formation.
In accordance with the above explanations, accordingly, the chosen arrangement of the magnetic flux concentrator 12A, 12B and of the two magnetic field sensors 14A, 14B makes it possible to compensate for an influence of the rotation-independent magnetic stray field on the two sensor signals upon difference formation applied to the two sensor signals. In this context, it should be pointed out that a difference between the two sensor signals need not necessarily be formed in further examples. Compensation of the magnetic stray field can also be achieved by way of summation applied to the two sensor signals, for example if one of the two magnetic field sensors 14A, 14B is turned over and its output signal only changes sign as a result. The terms difference formation and summation may therefore be regarded as interchangeable in the examples described herein.
The sensor device 400 in
As is additionally evident from table 1 discussed below, the value calculated using the difference formation under the influence of a magnetic stray field corresponds to the value calculated using the difference formation without a disturbance by a magnetic stray field. Table 1 below shows various output signals of two magnetic field sensors of a sensor device in accordance with the disclosure. By way of example, they can be the output signals of the magnetic field sensors 14A and 14B of the sensor device 400. The first column of table 1 includes values of a difference signal in the absence of a magnetic stray field. The second and third columns of table 1 include values of the signals output by the first magnetic field sensor 14A and the second magnetic field sensor 14B, respectively, in the presence of a magnetic stray field in the z-direction. The fourth column of table 1 includes values of a difference signal in the presence of the magnetic stray field.
Table 1 reveals that the respective values of the difference signal in the first and fourth columns are substantially identical and thus substantially independent of the magnetic stray field. Furthermore, table 1 reveals a substantially linear dependence between the difference signal obtained in accordance with equation (1) and the angle of rotation of the multipole magnet. Referring further to the preceding figures, a rotation angle between a first rotary shaft and a second rotary shaft and/or a torque applied to the first rotary shaft can thus be determined based on the difference formed from the first magnetic field and the second magnetic field.
The magnetic flux concentrator 12 can have a first section 22A coupled to the first ferromagnetic stator 10A, a second section 22B coupled to the second ferromagnetic stator 10B, and a third section 22C coupled to the third ferromagnetic stator 10C. Each of the three sections 22A to 22C can run substantially parallel to the axis of rotation of the multipole magnet 6. In the example shown, the sections 22A to 22C can each be embodied in the shape of a beam. The positions of the magnetic field sensors 14A, 14B are discernible in the enlarged view in
The sections 22A to 22C of the magnetic flux concentrator 12 can be configured to concentrate, at the positions of the magnetic field sensors 14A, 14B, the magnetic field generated upon rotation of the multipole magnet 6 relative to the stator pairs 8A, 8B. In this case, the concentrated magnetic fields can extend between the first section 22A and the second section 22B, and respectively between the second section 22B and the third section 22C. In this context, the magnetic flux concentrator 12 can optionally have circle-arc-shaped sections 18 which run along the ferromagnetic stators 10 and which can be configured to guide the magnetic flux generated as a result of the rotation of the multipole magnet 6 to the sections 22A to 22C. The first magnetic field sensor 14A and the second magnetic field sensor 14B can each be arranged such that they are sensitive in a direction substantially perpendicular to the axis of rotation of the multipole magnet 6. The directions of the concentrated magnetic fields and the sensitivity directions of the magnetic field sensors 14A, 14B can thus be aligned substantially parallel to one another.
Analogously to the sensor device 400 in
In comparison with the sensor device 400 in
In terms of construction, the sensor device 1200 can for example be similar to the sensor device 1100 in
In contrast to the previously described sensor devices 400 and 1100 in
The magnetic stray field can influence each of the two magnetic fluxes. In the example in
In practice or in an overall consideration, the magnetic field sensor 14 will not measure the individual signal contributions of the magnetic circuits separated from one another, rather a measurement will be associated with a coupling of the two magnetic circuits. The measurement can thus involve adding up the error-increased signal contribution (cf. path 30B) together with the error-reduced signal contribution (cf. path 30A), thereby making it possible to compensate for the magnetic stray field in the sensor signal S1. In other words, the magnetic stray field can be imposed oppositely on the signal contributions of the two (opposite) magnetic fluxes. This opposite imposing of the magnetic stray field makes it possible to compensate for the contribution of the magnetic stray field in the sensor signal S1.
The compensation of the influence of the magnetic stray field on the sensor signal S1 upon coupling of the two magnetic circuits can be provided in the sensor device 1200 in particular by way of the arrangement of the magnetic flux concentrator 12 and of the magnetic field sensor 14 or by way of the design of the magnetic circuits and of the associated magnetic fluxes. The arrangement chosen enables the magnetic flux concentrator 12 to align the magnetic field generated as a result of the rotation of the multipole magnet 6 with the magnetic field sensor 14 in such a way that the described opposite imposing of the magnetic stray field on the magnetic fluxes is achieved. In this context, it should be noted that the arrangement of the magnetic flux concentrator 12 and magnetic field sensor 14 shown is by way of example and is not restrictive. In further examples, the magnetic flux concentrator 12 and the magnetic field sensor 14 can also be arranged differently, such that an influence of the magnetic stray field on the sensor signal is compensated for upon coupling of the two magnetic circuits.
The sensor device 1800 in
At 34, a multipole magnet can be rotated relative to a first stator pair and a second stator pair, a magnetic field being induced. At 36, the induced magnetic field can be concentrated at the location of a first magnetic field sensor and at the location of a second magnetic field sensor by a magnetic flux concentrator. At 38, a first sensor signal can be output by the first magnetic field sensor and a second sensor signal can be output by the second magnetic field sensor. The magnetic flux concentrator and the two magnetic field sensors are arranged in such a way that an influence of a rotation-independent magnetic stray field on the two sensor signals is compensated for upon difference formation or summation applied to the two sensor signals.
At 40, a first stator pair and a second stator pair can be provided. At 42, a multipole magnet can be provided, which is rotatable relative to the two stator pairs, wherein a magnetic field is induced as a result of the rotation of the multipole magnet relative to the stator pairs. At 44, a first magnetic field sensor can be provided, which is configured to output a first sensor signal. At 46, a second magnetic field sensor can be provided, which is configured to output a second sensor signal. At 48, a magnetic flux concentrator can be provided, which is configured to concentrate the induced magnetic field at the location of the first magnetic field sensor and at the location of the second magnetic field sensor. The magnetic flux concentrator and the two magnetic field sensors are arranged in such a way that an influence of a rotation-independent magnetic stray field on the two sensor signals is compensated for upon difference formation or summation applied to the two sensor signals.
Sensor devices and also associated production and operating methods are explained below.
Aspect 1 is a sensor device, comprising: a first stator pair, comprising a first ferromagnetic stator and a second ferromagnetic stator; a second stator pair, comprising the second ferromagnetic stator and a third ferromagnetic stator; a multipole magnet, which is rotatable relative to the first stator pair and the second stator pair, wherein a magnetic field is induced as a result of the rotation of the multipole magnet relative to the first stator pair and the second stator pair; a first magnetic field sensor configured to output a first sensor signal; a second magnetic field sensor configured to output a second sensor signal; and a magnetic flux concentrator configured to concentrate the induced magnetic field at a location of the first magnetic field sensor and at a location of the second magnetic field sensor, wherein the magnetic flux concentrator, the first magnetic field sensor, and the second magnetic field sensor are arranged in such a way that an influence of a rotation-independent magnetic stray field on the first sensor signal and the second sensor signal is compensated for upon difference formation or summation applied to the first sensor signal and the second sensor signal.
Aspect 2 is a sensor device according to Aspect 1, wherein the magnetic flux concentrator, the first magnetic field sensor, and the second magnetic field sensor are arranged in such a way that the first sensor signal is inverted with respect to the second sensor signal.
Aspect 3 is a sensor device according to Aspect 1 or 2, wherein: each of the first ferromagnetic stator, the second ferromagnetic stator, and the third ferromagnetic stator is embodied in a ring-shaped fashion and has a multiplicity of teeth, and the first ferromagnetic stator and the second ferromagnetic stator of the first stator pair are arranged oppositely to each other and the teeth of the first and second ferromagnetic stators intermesh and the second ferromagnetic stator and the third ferromagnetic stator of the second stator pair are arranged oppositely to each other and the teeth of the second and third ferromagnetic stators intermesh.
Aspect 4 is a sensor device according to any of the preceding Aspects, wherein the multipole magnet is embodied in a ring-shaped fashion and has a multiplicity of alternating magnetic north poles and magnetic south poles.
Aspect 5 is a sensor device according to Aspect 3 and Aspect 4, wherein in a non-rotated state of the multipole magnet, each tooth of the stators is at an identical distance from a magnetic north pole and a magnetic south pole of the multipole magnet.
Aspect 6 is a sensor device according to any of the preceding Aspects, wherein: the multipole magnet is attached to a first rotary shaft, the first stator pair and the second stator pair are attached to a second rotary shaft, and the first rotary shaft is connected to the second rotary shaft via a torsion bar.
Aspect 7 is a sensor device according to Aspect 6, wherein the sensor device is configured to determine at least one of the following based on the difference formation or summation applied to the two sensor signals: a rotation angle between the first rotary shaft and the second rotary shaft, or a torque applied to the first rotary shaft.
Aspect 8 is a sensor device according to Aspect 6 or Aspect 7, wherein the first rotary shaft is mechanically coupled to a steering column of a vehicle and a rotation of the multipole magnet is based on a rotation of the steering column.
Aspect 9 is a sensor device according to any of the preceding Aspects, wherein the sensor device is configured to be used in an electrical power-assisted steering system.
Aspect 10 is a sensor device according to any of the preceding Aspects, wherein: the magnetic flux concentrator has a first section coupled to the first ferromagnetic stator, a second section coupled to the second ferromagnetic stator, and a third section coupled to the third ferromagnetic stator, each of the first section, the second section, and the third section runs parallel to an axis of rotation of the multipole magnet, the first magnetic field sensor is arranged between the first section and the second section, the second magnetic field sensor is arranged between the second section and the third section, and the first magnetic field sensor and the second magnetic field sensor are each sensitive in a direction perpendicular to the axis of rotation of the multipole magnet.
Aspect 11 is a sensor device according to any of Aspects 1 to 9, wherein: the magnetic flux concentrator has a first section coupled to the first ferromagnetic stator and to the third ferromagnetic stator, and a second section coupled to the second ferromagnetic stator, each of the first section and the second section runs parallel to an axis of rotation of the multipole magnet, the first magnetic field sensor and the second magnetic field sensor are each arranged between the first section and the second section, and the first magnetic field sensor and the second magnetic field sensor are each sensitive in a direction perpendicular to the axis of rotation of the multipole magnet.
Aspect 12 is a sensor device according to any of Aspects 1 to 9, wherein: the magnetic flux concentrator has a first section coupled to the first ferromagnetic stator, a second section coupled to the second ferromagnetic stator, a third section coupled to the second ferromagnetic stator, and a fourth section coupled to the third ferromagnetic stator, each of the first section, the second section, the third section, and the fourth section runs perpendicular to an axis of rotation of the multipole magnet, the first magnetic field sensor is arranged between the first section and the second section, the second magnetic field sensor is arranged between the third section and the fourth section, the first magnetic field sensor and the second magnetic field sensor are each sensitive in a direction parallel to the axis of rotation of the multipole magnet, and a position of the first magnetic field sensor is rotated relative to a position of the second magnetic field sensor about the axis of rotation of the multipole magnet.
Aspect 13 is a sensor device according to any of the preceding Aspects, furthermore comprising: a first electromagnetic shield arranged around the magnetic flux concentrator, the first magnetic field sensor, and the second magnetic field sensor.
Aspect 14 is a sensor device according to any of the preceding Aspects, furthermore comprising: a ring-shaped second electromagnetic shield arranged around the first stator pair, the second stator pair, and the multipole magnet.
Aspect 15 is a sensor device according to any of the preceding Aspects, wherein the first magnetic field sensor and the second magnetic field sensor are each configured to detect an absolute value and a sign of the induced magnetic field in relation to a sensitivity direction.
Aspect 16 is a sensor device according to any of the preceding Aspects, wherein each of the first magnetic field sensor comprises a first Hall sensor and the second magnetic field sensor comprises a second Hall sensor.
Aspect 17 is a sensor device, comprising: a first stator pair, comprising a first ferromagnetic stator and a second ferromagnetic stator; a second stator pair, comprising the second ferromagnetic stator and a third ferromagnetic stator; a multipole magnet, which is rotatable relative to the first stator pair and the second stator pair, wherein a magnetic field is induced as a result of a rotation of the multipole magnet relative to the first stator pair and the second stator pair; a magnetic field sensor configured to output a sensor signal; and a magnetic flux concentrator configured to concentrate the induced magnetic field at a location of the magnetic field sensor, wherein upon rotation of the multipole magnet relative to the first stator pair and the second stator pair, a first magnetic circuit is formed by the magnetic flux concentrator and the first stator pair and a second magnetic circuit is formed by the magnetic flux concentrator and the second stator pair, and wherein the magnetic flux concentrator and the magnetic field sensor are arranged in such a way that an influence of a rotation-independent magnetic stray field on the sensor signal is compensated for upon coupling of the first magnetic circuit and the second magnetic circuit.
Aspect 18 is a sensor device according to Aspect 17, wherein: the magnetic flux concentrator comprises a first section coupled to the first ferromagnetic stator and to the third ferromagnetic stator, and a second section coupled to the second ferromagnetic stator, each of the first section and the second section runs parallel to an axis of rotation of the multipole magnet, the magnetic field sensor is arranged between the first section and the second section, and the magnetic field sensor is sensitive in a direction perpendicular to the axis of rotation of the multipole magnet.
Aspect 19 is a method comprising: rotating a multipole magnet relative to a first stator pair and a second stator pair, wherein a magnetic field is induced; concentrating the induced magnetic field at a location of a first magnetic field sensor and at a location of a second magnetic field sensor using a magnetic flux concentrator; and outputting a first sensor signal using the first magnetic field sensor and a second sensor signal using the second magnetic field sensor, wherein the magnetic flux concentrator, the first magnetic field sensor, and the second magnetic field sensor are arranged in such a way that an influence of a rotation-independent magnetic stray field on the first sensor signal and the second sensor signal is compensated for upon difference formation or summation applied to the first sensor signal and the second sensor signal.
Aspect 20 is a method for producing a sensor device, wherein the method comprises: providing a first stator pair and a second stator pair; providing a multipole magnet, which is rotatable relative to the first stator pair and the second stator pair, wherein a magnetic field is induced as a result of the rotation of the multipole magnet relative to the first stator pair and the second stator pair; providing a first magnetic field sensor configured to output a first sensor signal; providing a second magnetic field sensor configured to output a second sensor signal; and providing a magnetic flux concentrator configured to concentrate the induced magnetic field at a location of the first magnetic field sensor and at a location of the second magnetic field sensor, wherein the magnetic flux concentrator, the first magnetic field sensor, and the second magnetic field sensor are arranged in such a way that an influence of a rotation-independent magnetic stray field on the first sensor signal and the second sensor signal is compensated for upon difference formation or summation applied to the first sensor signal and the second sensor signal.
Although specific implementations have been illustrated and described herein, it is obvious to the person of average skill in the art that a multiplicity of alternative and/or equivalent implementations can replace the specific implementations shown and described, without departing from the scope of the present disclosure. This application is intended to cover all adaptations or variations of the specific implementations discussed herein. Therefore, the intention is for this disclosure to be restricted only by the claims and the equivalents thereof.
Number | Date | Country | Kind |
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102021125949.5 | Oct 2021 | DE | national |