DE10060287A1 - Determination of the angle, angular velocity, and or torque of a rotating body, especially a motor vehicle steering wheel shaft by use of optical code traces on the rotating body and optical sensors for reading a code offset - Google Patents

Abstract

Device comprises two bodies (7, 8) marked with optically readable traces. The code traces (1a, 1b, 2a, 2b) are embodied in the same wave on each body, but are arranged so that signals detected by sensors (4) are offset relative to each other. The angle of rotation is determined from the offset of the sensor digital signals. In an alternative a torsion element (5), of known stiffness, is arranged between the two bodies. A torque transmitted by a rotating body (3) is then calculated from the difference angle of the two devices. As an alternative to optical sensors magnetic sensors can be used.

Description

State of the art

The invention relates generally to a device for Measuring the angle and / or the angular velocity of a rotatable body, and in particular a device for Measuring the angle and / or the angular velocity of a rotatable body and / or the acting on it Torque.

For many systems, e.g. B. in the automotive field, is a very exact Determination of an angle of rotation necessary. A specific one Application for such a device is one Steering wheel angle encoder, with enormous safety requirements consist.

DE-A-195 06 938 from the applicant is a device for measuring the angle and / or the angular velocity of the rotatable body, in particular one by more than 360 ° rotatable body according to the preamble of claim 1, known. In the known device, the first and second devices each with a gear  assigned angle sensor formed, the two Gears with different numbers of teeth with one gear are engaged, which is mounted on the steering wheel shaft is. Using a modified vernier method, you can the angle of the steering axis from the existing existing Angle and / or phase difference of the two gears be determined. This device thus offers the The advantage that multiple revolutions can be detected is however, disadvantageous in that the coverage under Interposition of gears and therefore not done without contact. Furthermore, the space required for such a device relatively high, so a Integration, especially on the steering axis, on which also the Multi-function switches are housed only with difficulty is possible. Finally, to capture the individual Angle of rotation a complex evaluation using a Arc tangent method required.

Various angle sensors are also known which are based on a non-contact detection based. However, these are generally not suitable for capturing angles very precisely. These devices and methods also require complex ones Evaluation circuits and algorithms or alternatively insufficient accuracy or insufficient measuring range, if z. B. the device is only suitable for small angles.

There is therefore a need for an improved device for Measuring the angle and / or the angular velocity of a rotatable body and the torque acting on it. It is an object of the present invention Generic device, such as from DE-A-195 06 938 known with at least first and second facilities that different in response to a rotation of the body Output signals to an evaluation circuit, in such a  Way to train that they only have a small space takes a simple evaluation and determination of the Angle allows, the total capture should be done without contact.

According to the invention, this object is achieved by a device solved with the features of claim 1. Preferred Embodiments are in the dependent claims Are defined.

In particular, the invention proposes that the Generic device each the rotatable body and a fixed part of the device as part of each Establishment of a field generating and / or changing or an arrangement responsive to the field is assigned. In In this way, each of the facilities in different ways on a rotation of the body respond, an output signal ready, which is contactless can be detected. After the angle measurement directly on the rotatable body takes place, the error influence, conditionally through the tolerances of previously used gears, be avoided. Wear-free and quiet operation is beneficial.

Advantageously, the responsive to the field Arrangement a field generating and / or changing Arrangement included, which makes it possible for the mutually influencing or influenced fields evaluate to the angle of rotation to be recorded reach.

To be insensitive to fluctuations in the Distance between the components of the devices achieve, it is preferred that at least one Field flow guide element is provided, in particular for education  closed field lines. This way also tolerances and temporal changes in the Manage fields easier, so z. B. the pole width the use of magnets less critical.

Advantageously, at least one of the field-generating ones and / or changing arrangements periodically changing field, especially an electrical and / or Magnetic field ready. Through a periodically changing With appropriate field, the detection accuracy can Training of the sensors are increased, in particular even minimal angular steps through a periodic changing magnetic field can be determined more precisely. In general, the accuracy increases with the number of pole pairs.

In a preferred embodiment, at least one of the field-generating and / or changing arrangements peripheral formed circumferentially with respect to the rotatable body, in particular fixed to this or integrated in it. This preferred embodiment enables one Device that has minimal space requirements poses so that they are simply used as steering angle sensors can be.

At least one of the field generating and / or changing Arrangements can be a radial field, e.g. B. magnetic field, form an electric field or an electromagnetic field. In this case, the sensors could be radial with respect to the rotating body may be provided.

Alternatively, it is also possible for at least one of the field-generating and / or changing arrangements axial field forms, with a corresponding positioning of the detection sensors.  

At least two field generators are advantageous and / or changing arrangements provided form different fields, especially one defining different field pole numbers, these in particular can be different by one. By the Providing two field-generating and / or - changing arrangements can be a complete decoupling take place, especially if two separate Detection arrangements are formed at appropriate locations are.

In a preferred embodiment, at least one of the field-generating and / or changing arrangements as Multi-pole wheel or multi-pole ring formed. A multi Magnet wheel or ring is an arrangement from Poland, the inverse Have alternating poles or also field-generating and non - field producing or field influencing and sections not affecting the field are alternately included.

The field changing arrangement can advantageously the Shape of a punched, slotted or perforated disc or one Accept punched, slotted or perforated ring, depending on whether radial or axial fields are used.

So that each of the facilities is as simple as possible Output signal to be evaluated, as linear as possible Provides at least one of the field appealing arrangements at least two field sensors that Provide sine or asinus output signals, in particular by a quarter of the by corresponding field-generating and / or changing arrangement formed periodic field spaced. As before can the field be an electric field, a Magnetic field or any electromagnetic field act.  

In this case, the sensors are advantageously in one Bridge circuit, especially a Wheatstone Bridge circuit interconnected and give their signals to this from. A difference can be formed by the bridge circuit be achieved using elements with linear characteristic also leads to the fact that the the respective angle value output directly without use a complex arc tangent method can be determined can.

In a particularly preferred embodiment, everyone is Sensor of a device in a partial bridge circuit, in particular a half bridge of the bridge circuit, interconnected.

Finally, it is preferred that the invention Device is used as a steering wheel angle sensor, wherein at least two field generating and / or changing Arrangements as field pole code tracks, especially magnetic ones Code tracks associated with the steering shaft.

As essential to the invention for the measurement of an angle and / or torque becomes an alternative Embodiment provided that with the help of first and second optical devices with an angle of rotation the fixed sensors. As special it is considered advantageous that the optical devices on the rotatable body, in this case the steering axle Motor vehicle are attached. The two institutions essentially have two optically scannable code tracks on, with each code track being assigned an optical sensor is. The advantage of optical scanning is that Rays of light are easier to detect and from electromagnetic interference fields are not affected  can. In addition, the optically scanned signal very easily into an electrical one using a photo sensor Convert signal. It is also advantageous that through the optical scanning reaches a digital output signal is from which there are angles or changes in angle with high Accuracy and great insensitivity to Have contamination determined.

By those listed in the dependent claims Measures are advantageous training and Improvements to the device specified in the main claim possible. In particular, by a variety of optical recognizable marks the code signal in digital and uniform shape so that by simple Phase comparison between assigned code tracks Angle of rotation can be determined.

It is also favorable that the fields of the markings with respect their light intensity, color and / or size distinguishable are. Especially with adjacent light-dark fields there are clear light-dark transitions that are due to the steep voltage jump of the electrical signal are recognizable. This results in a clear one Delimitation that is largely immune to interference.

The contrast between the light-dark fields or at the Light-dark transitions can still be improved by that the markings by means of a filament be illuminated. This is particularly the case with similar trained traces of a facility two different Signal sequences that allow a particularly simple angle determination, for example with the help of a classic or modified vernier method enables. This will advantageous the number of marks from neighboring Traces of a facility chosen differently to one  changeable over the circumference of the axis of rotation To achieve phase shift.

With a suitable choice of the number of markings on a track as well as an appropriate training of The vernier, especially that, can be marked use a modified vernier method to determine the angle. The measuring accuracy is advantageously increased in that the results of the measurements from the code tracks again corrected using the modified vernier method.

In those cases where a torque is also determined between the two institutions Torsion element with known torsional rigidity is used. Then become both the first and the second Device measured the angle of rotation, then from the Difference between the two angles and the known one Torsional rigidity advantageously determines the torque become. In this way, with the invention Setup two parameters measurable at the same time.

Preferably the markings of the two Facilities chosen so that to the respective Measurement results the classic or modified Nonius procedure can be applied again. So that increases the measuring accuracy and / or the measuring range of the Setup without the need for additional facilities are.

To the optical devices against possible To protect against pollution in the motor vehicle, an encapsulation appears for the device as particularly advantageous.  

An advantageous use of the device is in a Steering axis of a motor vehicle seen to the angle of rotation and / or measure the torque. These sizes can be used for other vehicle functions are used that for example for the determination of dynamic Vehicle stability, to support the steering force and / or navigation are required.

In summary, it can be said that with the solution according to the invention a simple detection of angles and / or angular velocities of a rotatable body is given, which also includes a torque measurement, the evaluation circuit can be designed simply and the space required to implement the Device is very low.

Further advantages and features of the present invention result from the following purely exemplary Description of some preferred embodiments, wherein the description with reference to the accompanying Drawings are made.

Fig. 1 shows a steering wheel angle sensor according to a first preferred embodiment of the invention in a systematic supervision (Fig. 1A), in a tangential sectional view (Fig. 1B) and in radial section views at different angular positions (Fig. 1C and 1D)

FIG. 2 shows a variant of the embodiment shown in FIG. 1 in a corresponding representation, with field-changing devices being implemented instead of the field-generating devices used in FIG. 1.

FIG. 3 shows yet another steering wheel angle sensor device as a third preferred embodiment of the device according to the invention, in which a radial field is used instead of the axial field used in FIGS. 1 and 2.

FIG. 4 is an embodiment variant of FIG. 3, wherein, as in FIG. 2, field-changing devices are used instead of field-generating devices.

Fig. 5 shows a further embodiment for Fig. 3, in different angular positions (Fig. 5A, Fig. 5B), a field-producing arrangement serves as a field-changing arrangement.

FIG. 6 schematically shows the position detection in the embodiment shown in FIG. 5 using field flow guiding elements.

Fig. 7 illustrates an embodiment of a combined steering angle / steering torque sensor is (schematically).

Fig. 8 illustrates another embodiment of a combined steering angle / steering torque sensor is (schematically).

FIG. 9 shows different designs of the sensors according to FIG. 7 or 8, it also being possible to have several sensors per magnetic track for the purpose of averaging.

Fig. 10 shows the analysis of the signals shows a combined steering angle / steering torque sensor.

Fig. 11 shows an optical device with two superimposed optical devices, each with two code tracks and four sensors.

description

In the following description, reference is made to magnetic fields only and, in the embodiment shown in FIG. 4, to an electric field; however, the person skilled in the art should recognize that any combinations, ie any electromagnetic fields, can also be used. For example, light-emitting diodes could be used as field poles instead of magnets, the emitted field of which can be detected by means of appropriate optoelectronic sensors.

The embodiment shown in FIG. 1 comprises a disc mounted on the steering axle 10 , on which code tracks 20 , 22 are provided. Each of the code tracks 20 , 22 comprises a plurality of alternately arranged permanent magnets, as indicated by the arrows with different orientations. The two code tracks 20 , 22 have a different division, with the smallest possible difference being particularly advantageous, such as. B. a difference of only one pole pair. In the embodiment shown, one of the tracks 20 , 22 contains a division of n-pole pairs, while the other comprises division of n + 1-pole pairs. When the rotatable body 10 , here the steering axis, rotates, the code tracks 20 , 22 are thus rotated by a corresponding angle in the embodiment shown. On a stationary part of the device, sensor arrangements 12 and 14 are provided above each of the code tracks 20 , 22 . The relative position of the underlying magnetic code track 20 or 22 can thus be detected by the sensor arrangement 12 , 14 .

The sensing sensor elements can be conventional sine / Measuring elements generating cosine signals, e.g. B. AMR-, GMR- Hall sensors. The evaluation algorithm can be based on the Arc tangent method.

In the embodiment shown, each of the sensor arrangements 12, 14 comprises two sensors 12 a, 12 b and 14 a, 14 b, respectively. The sensors 12 a and 12 b or 14 a and 14 b provided in pairs are advantageously spaced apart by a quarter or eighth period of the periodically changing magnetic field formed by the code tracks 20 , 22 . Such a distance enables the sensors to be connected in each case as a half-bridge of a Wheatstone bridge circuit, so that a simple evaluation circuit can be implemented since, on the one hand, a difference is formed and, on the other hand, when using elements with an essentially linear characteristic curve, an approximately linear, almost linear angle signal can be evaluated provided.

The angular positions thus detected can be related to one another, so that the real angle of the rotatable body 10 can be determined using the generally known vernier method or better using a modified vernier method or a combination of both methods. The extended vernier process is described in the document DE-A-195 06 938, so that this process need not be explained in more detail.

Although in the embodiment shown move field-generating parts of a respective facility, the skilled person will recognize that a corresponding reversal is also conceivable in which the sensor arrangements move with the rotating body while the Code traces stationary around the rotatable Body are provided.

The particularly advantageous spacing between two sensors 12 a, 12 b and 14 a, 14 b can be seen in detail from the tangential sectional view of FIG. 1B.

Finally, it can be seen from the sectional views of FIGS . 1C and D how the respective code tracks are present at different positions with respect to the sensor arrangements at different angles of the rotating body.

In the embodiment shown in FIG. 2, a field-changing device is used instead of the magnetic tracks, which also defines code tracks 24 , 26 . The mode of operation and the general structure is similar to FIG. 1, so that a repeated description is not intended here. However, it should be mentioned that, in the embodiment shown, a fixed permanent magnet 28 is positioned below the disk, which moves with the rotatable body 10 and contains code tracks 24 , 26 . In the embodiment shown, the code tracks are formed by simple cutouts, but the person skilled in the art should recognize that a wide variety of options can be used here. So it would be z. B. conceivable to provide regions with a different magnetic permeability instead of the simple cutouts. If other than magnetic fields are used, a corresponding configuration would be conceivable, taking into account different dielectric properties, optical properties or combined dielectric and magnetic permeability properties.

FIG. 3 shows a further embodiment of the device according to the invention, in which the code tracks 20 , 22 are not arranged on a disk, but rather are embedded directly in the steering axis 10 . Thus, the code tracks represent a radially periodically changing field, e.g. B. magnetic field, ready, which can be detected by appropriately arranged sensor arrangements 12 , 14 . As in the previous embodiments, the evaluation is carried out using the vernier method, so that the present phase difference between the detection signals can be used to determine the total angle of rotation of the steering axis. In this embodiment too, each sensor arrangement 12 , 14 comprises two sensors which are spaced apart by a quarter period λ / 4 of the changing field in order to enable simple evaluation.

FIG. 4 shows a further preferred embodiment of the device according to the invention, which essentially combines the principles of the embodiments shown in FIGS. 2 and 3. In this embodiment, the rotating body 10 is designed as a hollow tube, in the center of which a simple current-carrying wire or an optical waveguide can be arranged as a field-generating device. The rotating body 10 contains two recessed rings which, as before, form code tracks 24 , 26 . As with the other embodiments described so far, each of the code tracks should have a different division, in particular a division that differs by one, ie one of the code tracks should have a number of n openings, while the other has a number of n + 1 recesses . The sensors are arranged in accordance with the embodiment of FIG. 3 in order to detect the respectively changing field above a respective track 24 , 26 when the rotating body 10 rotates. As usual, the entire angle of rotation is determined by means of an evaluation circuit and using the vernier method from the difference, in particular phase difference, of the two signals.

In FIGS. 5a and 5b is shown schematically one of the first and second means, the output in response to rotation of the body 10 different signals to an evaluation circuit, not shown. In the embodiment shown here, ring-like magnetic multipole wheels 20 , 22 and 24 , 26 are used similarly to the embodiment shown in FIG. 3, the inner multipole ring being connected to the rotating body 10 , as in the previous embodiments. The outer magnetic pole ring 24 , 26 is designed to be rotatable with respect to the rotatable body 10 and the inner magnetic pole ring 20 , 22 , so that a periodically changing mutual influence of the respective fields formed results. In the position shown in FIG. 5a, respective magnetic poles oppose each other in such a way that the fields essentially cancel each other out. In the angular position shown in FIG. 5b, the poles are arranged in such a way that the respective field strengths add up.

In Figs. 6a and 6b is shown as a further component of the responsive array a field evaluation means, which in the present case two Hall sensors 12, 14 comprises. The fields generated by the multipole rings shown in FIG. 5 are conducted to the Hall sensors 12 , 14 by field guiding elements 32 , 34 , 36 . As one skilled in the art from the illustrations of FIGS. 6a, will recognize 6b, an upper flux guide piece 32 is provided, which leads the field lines in the transition region between the two Multipolringen 20, 22 and 24, 26 towards one of the Hall sensors. As shown, closed field lines are thus formed in the upper section in the case of an anti-parallel pole position, as shown in FIG. 5a, a T-piece 36 being provided as a further field flow guiding element behind the upper Hall sensor 12 , 14 . After rotation of the rotatable body to a position in which the poles of the multipole rings are parallel, as shown in FIG. 5b, the field lines are closed by the lower field flow guide element 34 and the T-piece 36 , with the T-piece being Piece 36 and the lower field guide element 34 , another Hall sensor is arranged. By providing two Hall sensors in the manner shown, insensitivity to temperature fluctuations and aging can be provided using a difference principle, since the output signal can be normalized to the total flow. However, those skilled in the art should recognize that this difference formation is purely optional. As in the previous embodiments, porting to any other fields than magnetic fields can be provided.

In summary, it can be said that the Device according to the invention an exact and simple Determination of the angle of the rotatable body enables with no intervention from z. B. gears or the like is necessary. In other words, there is one simple and exact angle measurement or also Angular velocity measurement on a non-contact Base using simple known components that like  mentioned, advantageously elements with a linear characteristic should contain. The different adjustments different field generating and / or field influencing Facilities should be familiar to the specialist and Therefore, no further detailed information is required here Description. Having on moving parts completely The device according to the invention can be dispensed with particularly suitable for use as a steering wheel angle sensor, especially since a high measuring accuracy with minimal necessary space is given.

Although the present invention has been described completely and in detail above with reference to currently preferred purely illustrative embodiments, those skilled in the art should recognize that various modifications are possible within the scope of the protection defined by the claims. In particular, the person skilled in the art should recognize that individual features of one embodiment can be combined as desired with other features of other embodiments. In this context it would be e.g. B. also conceivable to provide one of the code tracks corresponding to an arrangement of FIG. 4 or 5, while the other code track is provided in accordance with an embodiment according to FIGS . 1 or 2.

In Figs. 7 to 11 show various embodiments of the combined steering angle / steering torque sensor including the associated evaluation methods are shown. The multipole wheels are each scanned by sensor elements delivering sine / cosine signals. The output signals from the sensor elements are evaluated using the modified vernier method, whereby the following must be observed:

Transfer of the modified vernier principle to the problem described ( Fig. 1e):

Determination of ϕ

n: number of pole pairs
α, β: Measured values from the sensors
i, j: unknown

Identifying and reshaping:

with i = j = k

It follows:

where k is an integer

Errors in the evaluation can be identified reduce special correction procedures where Principles of the classic and / or the modified Nonius principle are taken into account.

With the sensors according to FIGS. 7 and 8, in addition to the angle, the acting torque, for example the steering torque, can also be determined.

The attacking torque during the steering process causes one Twisting of the torsion bar integrated in the steering column.  

The upper end rotates relative to the lower end, for example, by a maximum of +/- 5 °. In order to record the steering torque, this relative angle of rotation, the so-called torsion angle, must be measured. There are two options for this: Either the absolute steering angle of the upper and lower ends of the torsion bar is determined using the methods described under 1). The difference between the two angles then corresponds to the torsion angle. Or you can measure it directly via the relative displacement of two identically coded pole wheels, one of which is attached to the upper and the other to the lower end of the torsion bar. At least three pole wheels are necessary for this. These options are summarized in Fig. 9.

Different embodiments

Magnet wheel combinations: Each magnet wheel can also be used as a considered magnetic code track become.

Steering angle detection with

• - two pole wheels whose number of pole pairs is not prime e.g. B. with n and n + 1 pole pairs; these can also be used as two code tracks on a magnet wheel;
• - three pole wheels with n - 1, n and n + 1 pole pairs. This Combination increases accuracy and creates redundancy at the same time. Expandable to more Magnet wheels with corresponding number of pole pairs;
• - Addition of a "three-pole" pole wheel for Area differentiation when using  Sensor elements with uniqueness areas below 360 °;
• - Extension of the measuring range by number of pole wheels <2.

Steering torque detection

• - from absolute difference formation
• - by measuring the relative angle of identically coded magnet wheels

For the exemplary embodiment according to FIG. 8, it is now described in detail how the simultaneous measurement of the absolute angle and the torque can be carried out using the same measuring principle and a minimal number of sensors and assemblies. The two sizes are recorded without contact and self-diagnosis is possible. Different systems can be accessed, for example via a CAN bus (Controler Area Network).

The proposal relates e.g. B. for simultaneous measurement the steering angle and the steering torque. A magnetic one The measuring method is shown as a measuring principle. The suggestion however, it is not limited to this magnetic one Method. Each principle-optical, eddy current, inductive. . ., that is based on analog sine-cosine signals be used.

As can be seen from FIG. 7, a torsion bar is installed in the steering in order to measure the angle of rotation and the torque. At one end of the torsion bar T there are two multipole rings with M and M + X magnetic poles. At the other end there is a third multipole ring with M magnetic poles. There is a sensor above each ring (AMR, Hall, GMR, field plate). Each sensor supplies a sine and a cosine signal, which depends on the mechanical angle.

Measuring the steering angle

The multipole rings and sensors at one end are used to measure the steering angle. If X = 2, you can use the modified vernier method to determine the absolute angle. This method is to be used here and the absolute angle is calculated with the signals S1 (Usin ( 1 ), Ucos ( 1 )) and S2 (Usin ( 2 ), Ucos ( 2 )).

Torque measurement

The torque is measured via the angle difference. The torque is proportional to the angle difference in the elastic measuring range of the torsion element. The angular difference is recorded at the torsion ends via the two signals S1 (Usin ( 1 ), Ucos ( 1 )) and S3 (Usin G), Ucos ( 3 )).

The sensor delivers two signals:

Usin ( 1 ) = A1. sin (w1) + Osin ( 1 )

Ucos ( 1 ) = A1. cos (w1) + ocos ( 1 )

Sensor 3 also supplies two signals:

Usin ( 3 ) = A3. sin (w3) + Osin ( 3 )

Ucos ( 3 ) = A3. cos (w3) + ocos ( 3 )

Where U are the electrical signals at the respective mechanical angle w. A is the amplitudes and O the offset values of the sensors. The amplitudes and offsets of the four signals from maxima and minima can be determined by the mechanical rotation. An alternative method for offset determination and offset adjustment has been shown in DE-P 199 28 482. The corrected signals U # are offset-adjusted.

U # sin (1) = Usin (1) - Osin (1) = A1. sin (w1)

U # cos (1) = Ucos (1) - Ocos (1) = A1. cos (w1)

U # sin (3) = Usin (1) - Osin (3) = A3. sin (w3)

U # cos (3) = Ucos (3) - Ocos (3) = A3. cos (w3)

The angular difference w1 - w3 is sought. The difference can be determined by analog electronic operations (multiplication, subtraction, comparison) or by processing on a digital level as follows:

U # sin (1). U # cos (3) - U # cos (1). U # sin (3) = A1. sin (w1). A3. cos (w3) - A1. cos (w1). A3. sin (w3) = A1. A3. sin (w1 - w3)

For small angles: sin (w1 - w3) = w1 - w3 with 0.1% relative error in the angular interval (-4.4 ° to + 4.4 °) in degrees or (-0.077 to -0.077) in rad.

So the angle difference

w1 - w3 = (U # sin ( 1 ). U # cos (3) - U # cos (1). U # sin (3)) / (A1. A3)

This evaluation method is very sensitive to the smallest Angular differences. Through the procedure described above the moment can be determined directly from the angle difference. Another approach would be through a closed one Control loop to regulate the difference to zero. The The controlled variable would correspond to the angle difference.  

Remarks:

• 1. Another combination of the signals is possible, the should also lead to a sine of the angular difference.
• 2. The angle difference could also be determined by the difference of reach two absolute angle encoders. You would need 4 Sensors and 4 multipole rings and the method would be too high demands on the absolute angle measurements put. In this case the difference is two large angle values.

Self-diagnosis Absolute angle

The known one is used for the absolute angle Modified vernier principle applied. Tracking the integer k (Allowed / not allowed) jumps made possible error detection and implementation a withdrawal strategy.

Torque

• - If the angle difference exceeds the maximum permissible range, e.g. B. +/- 4 °, so a Error message issued. For example, in the event of an overload is no longer from the system side intervened.
• - The difference to be recalculated (U # cos (1). U # cos (3) + U # sin (1). U # sin (3)) / (A1. A3) must not exceed 0.5% of 1 deviate (cos ^ 2 (4 °) = 0.995).
• - Another alternative would be expression (U # sin (3). U # sin (3) + U # cos (3). U # cos (3)) / (A3, A3). on a Check deviation of 0.5% from 1. At the same time, the integer k must not make illegal jumps.

The device for the contactless and optical measurement of an angle and / or a torque according to FIG. 12 is explained in more detail below. As can be seen from FIG. 12, the two devices 7 and 8 are arranged on a rotatable body 3 . The rotatable body 3 is preferably designed as a steering axle in a motor vehicle and has a torsion element 5 with which a torque acting on the steering axle 3 can be measured. At the two ends of the torsion element 5 , the two devices 7 , 8 are arranged, so that when a torque acts on the torsion element 5, a different angle of rotation can be measured as an angle difference Θ - Ψ.

The two devices 7 , 8 each have two code tracks 1 a, 1 b and 2a, 2b. The code tracks have the same structure with regard to the width of their neighboring fields, but have different numbers of markings 9 over their circumference. For example, the code track 1a has 45 marks 9, the code track 1 b has 50 marks 9, the code track 2 a has 44 marks 9 and the code track 2 b 48 has markings 9 distributed over its circumference. In an alternative embodiment of the invention, provision is also made to provide a multiple of these markings 9 calculated over the circumference. Two adjacent markings or fields 9 differ in terms of their light intensity, their color and / or their size. They are preferably designed as light-dark fields, so that there are sharp and high-contrast light-dark transitions. To increase the contrast, lighting fixtures 6 are provided, which are arranged in relation to the devices 7 , 8 in such a way that they throw the light reflected by the markings 9 into assigned sensors 4 . As can be seen from FIG. 12, each code track 1 a, 1 b, 2 a, 2 b is assigned a sensor 4 , which essentially receives only the reflected light of the assigned code track. The sensor 4 converts the received light signal into uniform electrical signals, which can be tapped as digital signals S1a, S1b, S2a and S2b at the output of the sensors 4 and are fed to an evaluation circuit (not shown).

It is regarded as essential to the invention that the markings 9 of the code tracks 1 a, 1 b or 2 a, 2 b are formed uniformly. Both code tracks 1 a, 1 b and 2 a, 2 b of the devices 7 and 8 are exactly matched to one another and have a relative phase offset. This phase shift also has an effect in the electrical signal S1a, S1b, S2a, S2b, as can be seen in FIG. 12 by the lines shown in broken lines. Thus, the offset from one pulse to the next pulse increases with increasing angle of rotation, so that this difference is evaluated with a standard or in particular with the known modified vernier method, which is also known from DE 195 06 938 A1.

It should be noted that the smallest unit of a marking 9 is determined in particular by the light-dark transition. The better the contrast of these transitions, the lower the sensitivity to interference and the likelihood of measurement errors occurring. In order to reduce the susceptibility to faults, an encapsulating encapsulation 10 is preferably provided which surrounds the rotatable body 3 as tightly as possible.

As previously explained, 44 to 50 markings 9 were chosen for each of the four code tracks 1 a, 1b, 2a and 2b in order to achieve high measurement accuracy and angular resolution for the angle of rotation as far as possible with the modified vernier method. With this choice of markings 9 , the measured values from tracks 1 a, 1 b are repeated five times per circumference and for tracks 2 a, 2 b four times per circumference. If these measured values are subjected to the modified vernier procedure again, a measured value is obtained which is unique over the entire circumference (2π). This achieves a high resolution for the angle, which results from the large number of divisions. At the same time, a range of uniqueness of one full revolution is achieved. The modified vernier method allows, without reducing the accuracy, that a difference angle can be present between the first code tracks 1 a, 1 b and the second code tracks 2 a, 2 b. This difference angle can also result, for example, from the twisting of the torsion bar 5 . If the difference angle Θ - Ψ is measured in accordance with the two devices 7 , 8 , then with known torsional rigidity of the torsion element 5 , the torque transmitted by the steering axis 3 can also be determined in addition to the angle of rotation.

In an alternative embodiment of the invention, one or several more optical code tracks from a third Establishable as previously related to the magnetic devices have been described.

Claims (14)

1. A device for measuring the angle and / or the angular velocity of a rotatable body ( 10 ), with at least first (12, 20; 12, 24) and second ( 14 , 22 ; 14 , 26 ) devices in response to a rotation of the Output body ( 10 ) different signals to an evaluation circuit, characterized in that in each case the rotatable body ( 10 ) and a fixed part of the device as part of each device ( 12 , 20 ; 12 , 24 ; 14 , 22 ; 14 , 26 ) a field-generating ( 20 , 22 ) and / or modified ( 24 , 26 ) or an ( 12 , 14 ) arrangement responsive to the generated and / or changed field is assigned and in addition a measurement of the torque acting on the rotatable body is carried out. 2. Apparatus according to claim 1, characterized in that the arrangement responsive to the field contains a field-generating and / or changing arrangement ( 29 , 22 , 24 , 26 ). 3. Apparatus according to claim 1 or 2, characterized in that at least one field flow guide element ( 32 , 34 , 36 ) is provided, in particular to form closed field lines. 4. Device according to one of claims 1 to 3, characterized in that at least one of the field-generating ( 20 , 22 ) and / or changing ( 24 , 26 ) arrangements provides a periodically changing field, in particular electrical and / or magnetic field. 5. Device according to one of claims 1 to 4, characterized in that at least one of the field-generating ( 20 , 22 ) and / or changing ( 24 , 26 ) arrangements is formed peripherally circumferentially with respect to the rotatable body ( 10 ), in particular fixed to this or is integrated into this. 6. Device according to one of the preceding claims, characterized in that at least one of the field-generating ( 20 , 22 ) and / or changing ( 24 , 26 ) arrangements forms a field which can be changed in the radial direction, in particular a magnetic field and / or an electrical field. 7. Device according to one of the preceding claims, characterized in that at least one of the field-generating ( 20 , 22 ) and / or -modifying ( 24 , 26 ) arrangements forms a field which can be changed in the axial direction, in particular a magnetic field and / or an electrical field. 8. Device according to one of the preceding claims, characterized in that at least two field-generating ( 20 , 22 ) and / or -modifying ( 24 , 26 ) arrangements are provided which form different fields, in particular define a different field pole number, in particular by one is different. 9. Device according to one of the preceding claims, characterized in that at least one of the field-generating ( 20 , 22 ) and / or -modifying ( 24 , 26 ) arrangements is designed as a multipole wheel or ring. 10. Device according to one of the preceding claims, characterized in that the field-changing Arrangement (s) (24, 26) in the form of a punched, slotted or perforated disc or a punched, slotted or perforated ring is / are trained. 11. The device according to any one of the preceding claims, characterized in that at least one of the arrangements responsive to the field ( 12 , 14 ) contains at least two field sensors, in particular by a quarter period of by the corresponding field-generating ( 20 , 22 ) and / or changing ( 24 , 26 ) arrangement formed periodic field, in particular electrical field and / or magnetic field spaced. 12. The apparatus according to claim 11, characterized in that the sensors ( 12 a, 12 b, 14 a, 14 b) output signals via a bridge circuit, in particular a Wheatstone bridge circuit. 13. The apparatus according to claim 12, characterized in that each sensor / 12 a, 12 b, 14 a, 14 b) is connected to a partial bridge circuit, in particular a half bridge of the bridge circuit. 14. Use of a device according to one of the preceding claims as a steering wheel angle sensor, wherein at least two field-generating ( 20 , 22 ) and / or changing ( 24 , 26 ) arrangements are assigned as code tracks, in particular magnetic code tracks of the steering shaft ( 10 ).