Patent Description:
Rotary sensors can be used for angular or rotational measurements. Hall-sensors may for example be employed for contactless angular measurements which are particularly suitable for harsh environments. Conventionally, a disc or ring magnet having a number of poles is mounted to the rotating equipment and the rotation of the magnetic field is detected by the Hall-sensor. To account for external disturbing magnetic fields, plural sensor elements including Hall-sensor pairs may be employed, which can be provided on a single integrated circuit.

As an example, ring magnets may be employed which have four sectors, each sector being magnetized axially, wherein neighboring sectors have an opposite direction of magnetization. Two north poles and two south poles may accordingly be provided on each axial face of the ring magnet. Such magnets are generally produced by using injection molding of magnetizable material mixed with thermoplastic material (with a filling degree of up to <NUM>%).

A Hall-sensor can be arranged opposite to the annular axial face of such ring magnet at a predefined distance thereto. The sensor element is generally offset in a radial direction to be exposed to a relatively large z-component of the magnetic field, in particular of the magnetic flux density Bz. In such configuration, a radial displacement, for example due to mechanical drift, mechanical wear, or mechanical vibrations, may result in a deviation of an angle of rotation measured by the Hall-sensor. To reduce such deviation, the document <CIT> suggests the providing of grooves between the sectors of the ring magnet, which is formed of a single monolithic piece of material. The grooves provide a constant magnetic field gradient in a central region around the axis of the magnet. Such shaping of the magnetic field reduces the angular position error.

It is difficult to make such rotary sensor more compact while maintaining a good measuring accuracy. To be robust against disturbing magnetic fields, the ring magnet has to maintain a minimum flux density, which requires particularly large ring magnets when produced with the conventional injection molding methods. A magnetization of the magnetic material may further become difficult or may not even be possible below a certain size of the ring magnet.

The document <CIT> describes a magnetic component for a Hall effect sensor of an electric supercharger of a combustion engine. The magnetic component includes four magnets distributed around the axis of a body. Additional magnets are provided for increasing the rising fronts of magnet sensor signals to improve the accuracy of detecting the rotation speed above <NUM>,<NUM> rpm.

The document <CIT> describes a joystick controller having a resilient arm with a tube and a handle. The arm flexes around a pivot point, wherein a position of a magnet mounted to the tube affects an output of Hall effect probes.

The document <CIT> describes an operating unit with a rotary toggle. On the rotary toggle, five signaling magnets are provided that migrate over a Hall sensor to generate signals from which a rotation can be characterized.

The document <CIT> discloses a rotary actuator with a coding element having four permanent magnets each being provided as quarter ring section to form a ring, wherein the ring sections are magnetized in a direction that lies in the ring plane.

Accordingly, there is a need to mitigate at least some of the drawbacks mentioned above and to provide an improved rotary sensor, in particular a more compact sensor that provides an improved measuring accuracy.

The dependent claims describe embodiments of the invention.

According to an embodiment of the invention, a rotary sensor comprising a magnet arrangement configured to generate a magnetic field is provided. The magnet arrangement comprises at least four distinct and spatially separate permanent magnets, wherein the at least four permanent magnets are arranged circumferentially about a rotation axis extending in an axial direction. The magnet arrangement is configured to be non-rotatably mounted to a component a rotation of which about the rotation axis is to be measured. The rotary sensor further comprises at least one magnetic field sensor configured and arranged to detect a rotation of the magnetic field generated by the magnet arrangement upon rotation of the magnet arrangement, e.g. due to rotation of the component.

Such magnet arrangement may allow the rotary sensor to become more compact. By providing distinct permanent magnets in the magnet arrangement, the degree of magnetization and thus the magnetic flux density that can be generated by the magnet arrangement may be increased significantly. Furthermore, such distinct permanent magnets may be made more compact and may be arranged closer to, e.g., a shaft of the component, so that the size required by the magnet arrangement may be reduced. Mounting of the magnet arrangement to the component may thus be facilitated, as it may be easier to feed the magnet arrangement through a small space or aperture. Contrary to the general perception, it has further been found that with such arrangement, the robustness of the rotary sensor against misalignment between the magnet arrangement and the magnetic field sensor may further be improved. The rotary sensor may thus provide an improved measurement accuracy and may further be more robust against mechanical vibrations and/or mechanical drift, e.g. due to bearing play. Further, by providing a higher magnetic flux density, the rotary sensor may be more robust against disturbing external magnetic fields, such as homogeneous and inhomogeneous magnetic fields.

According to the invention, the magnet arrangement comprises at least four distinct and spatially separate permanent magnets arranged circumferentially about the rotational axis. It may comprise exactly four distinct and spatially separate permanent magnets arranged circumferentially about the rotational axis. In other configurations, it may comprise even more permanent magnets, such as at least six or exactly six, at least eight or exactly eight, or the like. The component may comprise a shaft or protrusion extending in the axial direction, and the magnet arrangement may be mountable to the shaft or protrusion. The magnet arrangement may comprise an inner recess or hole that extends on the rotation axis in the axial direction and that may be configured to receive such shaft (e.g., a shaft end) of the component. Such recess or hole may have a shape adapted to the shape of the shaft or may simply be a bore, e.g. a through-bore or a dead bore. Such recess or hole may be configured to engage the shaft or component in a formfitting manner, e.g. using an interference fit or a loose fit. A non-circular shape of the recess and shaft, a slot and key arrangement, an interference fit, or the like may be provided for ensuring that the magnet arrangement is not rotatable with respect to the component when mounted to the component.

The at least four permanent magnets may be spaced apart from each other in circumferential direction. By providing a spacing between the permanent magnets, robustness against magnetic field sensor displacements and sensor accuracy may further be improved. For example, a distance by which the at least four permanent magnets are spaced apart from each other in circumferential direction may be less than <NUM>, less than <NUM>, less than <NUM>, or less than <NUM>. With such spacing, a deviation of an angle measurement by the rotary sensor due to a displacement of the magnetic field sensor may thereby be minimized. It should be clear that the optimal spacing between the neighboring permanent magnets will generally depend on the size of the permanent magnets and may thus be chosen accordingly. The spacing relates to the spacing between the outer perimeter of the permanent magnets, i.e. the minimum distance between the outer surfaces of neighboring permanent magnets.

According to the invention, each permanent magnet has a direction of magnetization that is substantially parallel to the axial direction. Permanent magnets that are neighbors in the circumferential direction have an opposite direction of magnetization. An even number of permanent magnets may thus be provided. Substantially parallel may mean parallel or an angle of less than <NUM>°, <NUM>° or <NUM>° between the respective axes.

Each permanent magnet may for example extend in the axial direction and may have at one axial end a magnetic north pole and at the other axial end a magnetic south pole, by which the direction of magnetization of the permanent magnet is defined.

According to the invention, at an axial end face of the magnet arrangement, north and south poles alternate in circumferential direction.

The permanent magnet may in particular be a bar magnet or a rod magnet, with its magnetic poles on the opposite axial end faces.

Each permanent magnet may have a cylindrical shape, and a cylinder axis of the cylindrical shape may be substantially parallel to the axial direction. Cylinder axis generally refers to the central symmetry axis of a cylinder in height direction. By such arrangement of cylindrical permanent magnets, a compact configuration that at the same time provides a high magnetic flux density and robustness against radial magnet sensor displacements may be provided.

In an embodiment, the at least four permanent magnets may be arranged such that in a cross-sectional plane perpendicular to the axial direction, the perimeter (i.e., the external surface) of each of the at least four permanent magnets abuts the same inner circle. Such symmetric arrangement may improve the homogeneity of the field gradients and may facilitate mounting to a central shaft. The perimeter of the permanent magnets may in particular be tangential to the inner circle. For a cylindrical shape of the magnets, which correspond to a circle in the cross-sectional plane, the circular perimeter of each permanent magnet may thus touch or be tangential to the inner circle. In some implementations, the perimeter of each of the at least four permanent magnets may abut the same outer circle. If the permanent magnets are of the same or similar size and shape, they may abut both, the inner circle and the outer circle.

The inner circle may for example have a diameter of less than <NUM>, less than <NUM>, less than <NUM>, or less than <NUM>. A compact rotary sensor may thus be achieved. In particular, such compact size may not be achievable by conventional ring magnets.

The spacing between neighboring permanent magnets may be the same. The arrangement of the permanent magnets in circumferential direction may in particular be rotationally symmetric (e.g., with respect to a <NUM> degree rotation, i.e. a <NUM>-fold symmetry).

The at least four permanent magnets may have the same or a similar size and shape. The diameter of each permanent magnet may be less than <NUM>, less than <NUM>, or less than <NUM>. An extension in axial direction may be less than <NUM>, less than <NUM>, or less than <NUM>. A compact magnet arrangement and thus a compact rotary sensor may thereby be provided. In some implementations, the diameter and the extension in axial direction of the permanent magnets may be similar or the same.

In an embodiment, a magnetic field sensor is provided in an end-of-shaft configuration. A high measurement accuracy and robustness against external magnetic fields may thereby be achieved.

For example, the at least one magnetic field sensor may comprise at least one Hall-sensor arranged in the axial direction on a side of the magnet element that is opposite to a side on which the magnet element is configured to receive or to be mounted to the component (e.g. to receive a shaft). A sensor element of the Hall-sensor may be offset from the rotation axis in a radial direction that is perpendicular to the axial direction.

It should be clear that a Hall-sensor may comprise one or plural different Hall-sensor elements to measure different directions of the magnetic field and/or to compensate for external magnetic fields. The sensor element of the Hall sensor may be a sensor array. The Hall sensor may comprise <NUM>, <NUM> or more respective sensor arrays. A sensor array may form a circle, e.g. a Hall plate circle. The center of such Hall plate circle may be offset from the axis in said radial direction, for example by less than <NUM>, less than <NUM>, or less than <NUM>.

The Hall-sensor may be provided as a single chip or single integrated circuit on which a number of Hall-sensor elements is provided. Depending on the arrangement, the Hall-sensor may comprise a vertical Hall-device. The Hall-sensor may in particular be provided as a sensor chip that comprises the one or more sensor elements and electronics configured to evaluate signals measured by the sensor element(s) and to give out a signal that indicates the angular orientation of the magnetic field or of the rotary shaft.

It should be clear that the rotary sensor may comprise plural magnetic field sensors, for example plural Hall-sensors arranged at different positions relative to the magnet arrangement. For example, additionally or alternatively, the rotary sensor may comprise one or more Hall-sensors arranged radially adjacent to the magnet arrangement, for example to measure a radial or tangential component of the magnetic flux density. Such arrangements are similarly suitable for providing an accurate indication of the rotational state or rotational speed of the magnet arrangement and thus of a component to which it is mounted.

The rotary sensor may be a rotation angle sensor configured to detect an angle of rotation of the component and/or a rotational speed sensor configured to detect a rotational speed of the component.

The permanent magnets may be rare-earth magnets, such as Sm<NUM>Co<NUM> magnets.

Preferably, the permanent magnets each have a magnetic remanence of at least <NUM> mT, preferably at least <NUM> mT or at least <NUM> mT. A sufficiently strong magnetic field for detection by the magnetic field sensor may thus be provided.

The magnet arrangement may be configured to provide an axial component of a magnetic flux density (Bz) of at least <NUM> mT, preferably at least <NUM> mT or at least <NUM> mT at a position in a plane perpendicular to the axial direction, wherein the plane is spaced apart from the magnet arrangement in axial direction by at least <NUM> or at least <NUM>. It should be clear that at other positions of the plane, the magnetic flux density may be higher or may be lower; however, it must achieve in the plane at least the defined minimum magnetic flux density. By such configuration, it may be ensured that the magnetic flux density is sufficiently high so that an accurate measurement of the rotation of the magnet field can be achieved even in the presence of disturbing external magnetic fields.

The plane may in particular be a plane in which the magnetic field sensor is arranged, in particular a sensor element of the Hall-sensor (such as sensitive semiconductor slab of the Hall-sensor). The magnetic flux density is generally designated as the B-field and is measured in Tesla (T).

The rotary sensor may further comprise a housing configured to house the at least four permanent magnets. The housing may be configured to be mounted to the component in a non-rotatable manner. Such housing may accordingly fix the relative positioning of the permanent magnets relative to each other and may further fix their positioning with respect to the component. A stable, reliable and reproducible magnetic field may thereby be provided in the rotary sensor.

The housing may comprise a recess configured to receive a shaft of the component. To fix the housing to the shaft, the shaft may be received in the housing and the shaft may have opening into which a pin is mounted, e.g. screwed or pressed, wherein the pin secures the housing on the shaft, e.g. via a head of the pin. The housing may include a recess configured to receive such head of the pin. A compact configuration may thereby be achieved.

The housing may additionally or alternatively comprise a support member for each permanent magnet. The support member may be configured to hold the respective permanent magnet. The support member may hold the permanent magnet by clamping, by using an interference fit, and/or the housing may have a cover configured to close the housing after insertion of the permanent magnets into the respective support members in order to secure the permanent magnets within the housing.

The housing may additionally or alternatively comprise an interlocking feature configured to receive a complementary interlocking feature of the component in a form-fitting manner, e.g. to mitigate or prevent a rotation of the housing with respect to the shaft or component. For example, the interlocking feature of the shaft may be a shaft end having a non-circular shape, and the interlocking feature of the housing may include a recess having a shape that is complementary to the shape of the end of the shaft to enable the engagement of the shaft and the housing in a form-fitting manner. Preferably, the recess is formed by a central cut-away section of the housing that exposes lateral side walls of the at least four permanent magnets, and the end of the shaft may be formed to engage the cut-away section in a form fitting manner; it may in particular be configured to abut the respective side wall sections of the at least four permanent magnets. The interlocking features may alternatively be configured as a slot and key arrangement, e.g. for a circular shaft or shaft end. A compact configuration which at the same time provides protection against relative rotation may thus be achieved. Other ways of non-rotatably mounting the magnet arrangement to the shaft are certainly conceivable, such as a pin configured to engage the shaft, a clamping member, gluing, soldering, welding or the like.

In an embodiment, compared to a ring magnet having an outer diameter and an inner diameter (measured perpendicular to the rotation axis) of the same size as an outer circle and an inner circle that abut an outer perimeter and an inner perimeter of each of the permanent magnets of the magnet arrangement, respectively, an angular deviation of a measurement by the rotary sensor caused by a radial displacement (with respect to the rotational axis) of the magnetic sensor element may be at least <NUM>%, preferably at least <NUM>%, <NUM>%, or <NUM>%, lower than an angular deviation of a measurement caused by a respective radial displacement of a rotary sensor comprising such ring magnet and the same or a similar magnetic sensor element. The reduction may for example be achieved at a radial displacement of <NUM>% of the diameter of the permanent magnets (e.g., at <NUM> for permanent magnets of <NUM> diameter). The configuration of the rotary sensor may thus reduce such deviation of an angular measurement significantly. Measurement accuracy may thereby be improved, in particular in harsh environments in which the rotary sensor is exposed to vibration, thermal cycling, or other environmental influences that may have a negative impact on measuring accuracy and that may, in conventional sensors, for example result in sensor drift.

The component, and in particular the shaft, may form part of the rotary sensor.

According to the invention, an operating device for a mobile machine is provided, wherein the operating device comprises a pivotable handle and a detection mechanism coupled to the pivotable handle. The detection mechanism comprises a component that is rotated about an axis upon pivoting the handle. The operating device further comprises a rotary sensor having any of the configurations described herein. The magnet arrangement of the rotary sensor is mounted to the component of the operating device detect a rotation of the component. A reliable and precise control of the machine may be enabled by such operating device. Further, by employing detection of the orientation of the magnetic field, and thus a contactless measurement, the operating device can be made durable and well suited for use in harsh environments. The operating device may for example be a joystick control device.

The operating device may have a suspension that rotates about the axis about which the handle pivots, and the component may be mounted to or may form part of such suspension. For example, the handle may be mounted by a gimbal mount, and the component may be mounted to or may form part of a respective gimbal. Thus, by mounting the magnet arrangement directly or indirectly to such gimbal, a precise detection of the degree of pivoting of the handle becomes possible. It should be clear that such operating device may comprise plural respective rotary sensors, e.g. one or two for each direction of pivoting/rotation.

According to a further embodiment of the present invention, a method of assembling a rotary sensor is provided. The method comprises providing a magnet arrangement configured to generate a magnetic field, wherein the magnet arrangement comprises at least four distinct and seatially separate permanent magnets. wherein the at least four permanent magnets are arranged circumferentially about a rotation axis extending in an axial direction, and wherein the magnet arrangement is configured to be non-rotatably mounted to a component a rotation of which about the rotational axis is to be measured. The method may further comprise arranging at least one magnetic field sensor adjacent to the magnet arrangement to detect a rotation of the magnetic field generated by the magnet arrangement upon rotation of the magnet arrangement. By such method, advantages similar to the ones outlined further above may be achieved.

The method may further comprise mounting the magnet arrangement non-rotatably to the component, e.g. to a rotatable shaft thereof that extends in the axial direction. The rotary sensor may thus be enabled to provide a precise measurement of the component's angular position and/or rotational speed.

The method may comprise further steps for assembling a rotary sensor having any of the configurations described herein. Furthermore, the rotary sensor may be assembled by any of the methods disclosed herein.

It is to be understood that the features mentioned above and those yet to be explained below can be used not only in the respective combinations indicated, but also in other combinations or in isolation, without leaving the scope of the present invention. In particular, the features of the different aspects and embodiments of the invention can be combined with each other unless noted to the contrary.

The foregoing and other features and advantages of the invention will become further apparent from the following detailed description read in conjunction with the accompanying drawings. In the drawings, like reference numerals refer to like elements.

It is to be understood that the following description of the embodiments is given only for the purpose of illustration and is not to be taken in a limiting sense. It should be noted that the drawings are to be regarded as being schematic representations only, and elements in the drawings are not necessarily to scale with each other. Rather, the representation of the various elements is chosen such that their function and general purpose become apparent to a person skilled in the art. The terms "comprising," "having," "including," and "containing" are to be construed as openended terms (i.e., meaning "including, but not limited to,") unless otherwise noted.

<FIG> schematically illustrates a rotary sensor <NUM> including a magnet arrangement <NUM> that is configured to generate a magnetic field. The magnet arrangement <NUM> comprises four permanent magnets <NUM>, <NUM>, <NUM>, and <NUM>, which are arranged circumferentially around the rotation axis <NUM>. Axis <NUM> extends in an axial direction perpendicular to the drawing plane. The magnet arrangement <NUM> is configured to be mounted to a rotating component, such as a rotating shaft, which rotates together with the magnet arrangement about the rotation axis <NUM>. The magnet arrangement is rotationally symmetric with respect to rotation axis <NUM>.

In the embodiment of <FIG>, the magnetization of the permanent magnets <NUM> to <NUM> is parallel to the axial direction of the axis <NUM>. The direction of magnetization alternates between neighboring permanent magnets. On the axial end face of the magnet arrangement <NUM> shown in <FIG>, the permanent magnets <NUM>, <NUM> present a north pole at their respective axial end, whereas the permanent magnets <NUM>, <NUM> present a south pole at their respective axial end. On the opposing end face of the magnet arrangement <NUM>, the magnetic poles have naturally the opposite polarity, meaning that permanent magnets <NUM>, <NUM> present a south pole, whereas permanent magnets <NUM> and <NUM> present a north pole. The magnet arrangement <NUM> thus has four pole pairs and presents four magnetic poles on each end face. By using such magnet arrangement <NUM> for detecting a rotation about the axis <NUM>, homogeneous and inhomogeneous external magnetic fields can be compensated by using a magnetic field sensor comprising plural sensor elements.

As illustrated in <FIG>, the permanent magnets <NUM> to <NUM> are preferably spaced apart from each other. The spacing <NUM> between neighboring permanent magnets is illustrated in <FIG> and is the same for each pair of neighboring permanent magnets. An equal spacing is preferred to maintain symmetry of the generated magnetic field. The permanent magnets <NUM> to <NUM> further have the same shape and size. In the present example, they have a cylindrical shape, as also shown in <FIG>. In the top view of <FIG>, they accordingly have a circular end face.

The periphery, or outer edge, of the permanent magnets <NUM> to <NUM> abuts the inner circle <NUM>. The permanent magnets <NUM> to <NUM> are thus equally spaced apart from the central axis <NUM>. Further, the perimeter of the permanent magnets <NUM> to <NUM> abuts the outer circle <NUM>, in particular as the permanent magnets have the same size, in particular the same diameter. In a plane perpendicular to the rotation axis <NUM>, as shown in <FIG>, the permanent magnets <NUM> to <NUM> are thus arranged within an annular surface bounded by the inner circle <NUM> and the outer circle <NUM>. These dimensions may be employed for a comparison with a corresponding ring-shaped magnet having a respective inner and outer diameter <NUM>, <NUM>.

The diameter di of the inner circle <NUM> may for example be less than <NUM>, e.g. less than <NUM> or even less than <NUM>. In the present example, the diameter is di=<NUM>. The diameter do of the outer circle <NUM> may be less than <NUM>, preferably less than <NUM>, or even less than <NUM>. In the present example, it is do=<NUM>. The diameter of the cylindrically shaped permanent magnets is <NUM>. The magnet spacing <NUM> between neighboring permanent magnets is in the present example dm=<NUM>. As an example, the height <NUM> (<FIG>) of the permanent magnets may also be <NUM>.

<FIG> is a perspective view of the magnet arrangement <NUM> of <FIG>. As can be seen, the permanent magnets <NUM> to <NUM> are distributed circumferentially around the axis <NUM> and abut the inner circle <NUM>. The figure further illustrates the extension <NUM> in axial direction of the permanent magnets, i.e. the height of the respective cylindrical shapes. The height <NUM> may be of a comparable dimension as the diameter of the cylindrical shapes.

The magnet arrangement <NUM> is configured to be mounted to a rotatable component, in particular to a rotating shaft, in a non-rotating manner (i.e. it is fixed to the respective shaft). For mounting to the shaft, the magnet arrangement <NUM> may comprise a housing to support the permanent magnets <NUM> to <NUM>, as explained in more detail further below with respect to <FIG>.

Although four permanent magnets <NUM> to <NUM> are shown in the embodiments of <FIG>, any other even number of permanent magnets may be employed as well, such as six, eight, or more permanent magnets. Further, to tune the magnetic field generated by magnet arrangement <NUM>, it is also conceivable to provide permanent magnets of differing sizes and/or shapes. Further, the permanent magnets do not need to be cylindrical, but may have any desirable shape, such as a polygonal shape, e.g. a rectangular, pentagonal, or other cross-section. Permanent magnets <NUM> to <NUM> may for example be rod magnets or bar magnets, with the magnetic poles at the respective axial ends.

Turning briefly to <FIG>, the rotary sensor <NUM> further includes a magnetic field sensor <NUM> that is arranged adjacent to the magnet arrangement <NUM> and that may be or may comprise a Hall-sensor. The magnetic field sensor <NUM> is arranged opposite to an axial end face of the magnet arrangement <NUM> to measure a z-component of the magnetic flux density generated by the magnet arrangement <NUM>, the z-direction being parallel to the rotation axis <NUM>. The magnetic field sensor <NUM> is spaced apart in axial direction from the magnet arrangement <NUM> by a distance <NUM>. Magnetic field sensor <NUM> may comprise one or more Hall-sensor elements <NUM>, <NUM> to measure the magnetic flux density component Bz and to provide compensation for external homogeneous and inhomogeneous magnetic fields. Sensor element <NUM> (and optional further sensor elements <NUM>) of magnetic field sensor <NUM> is radially offset from rotation axis <NUM> by a distance <NUM>. Respective Hall-sensors comprising one or more sensor elements <NUM>, <NUM> are commercially available as single chip solutions, and any respective configuration may be employed here.

By measuring the magnetic flux density, and thus the rotation thereof, the magnetic field sensor <NUM> can provide a precise measurement of the rotation of the magnet arrangement <NUM> around the axis <NUM>. Such angular measurement may be disturbed by a radial displacement between the magnetic arrangement <NUM> and the magnetic field sensor <NUM>, i.e. a relative displacement in left/right direction or in a direction perpendicular to the drawing plane. Such displacement may for example occur due to mechanical vibrations of component <NUM>, wear, or other external mechanical influences.

In the above example, a compact configuration can be achieved, since the inner circle <NUM> can be made small, while the permanent magnets <NUM> to <NUM> can still provide a relatively high magnetic field, and in particular a high magnetic flux density Bz in axial direction at the position of the magnetic field sensor <NUM>. Since the permanent magnets can be pre-magnetized prior to their assembly into the magnet arrangement <NUM>, there is no minimum size requirement on the magnet arrangement <NUM> while a high degree of magnetization can still be ensured. The arrangement illustrated in <FIG> may in particular achieve a magnetic flux density of more than <NUM> mT at a distance <NUM> of more than <NUM>.

Furthermore, magnet material may be conserved compared to a corresponding ring magnet. In a ring magnet, the magnetic material needs to be provided in the whole area of the ring-bounded by the inner and outer circles <NUM>, <NUM>. Calculating the volume of the four separate individual permanent magnets <NUM> to <NUM> and comparing it to the volume of a ring magnet of the respective size, it turns out that the volume of the four permanent magnets is only <NUM>% of the volume of a respective ring magnet. Significant savings in magnetic material may thus be achieved. As noted above, it is however generally not possible to provide a respective ring magnet having the same compactness as the magnet arrangement <NUM>.

The following table compares the volume of magnetic material Vmagnet and the maximum axial magnetic flux density component Bzmax at a radial displacement <NUM> of r = <NUM> for the magnet arrangement <NUM> of <FIG> with differently sized ring magnets, each having a height of <NUM>. The magnetic remanence is Br = 930mT for all magnets. As can be seen, compared to conventional ring magnets, the present magnet arrangement <NUM> provides a relatively high magnetic flux density component Bz at a relatively low volume of magnet material.

In particular, it can be seen that the ratio of Bz/V is the largest for the magnet arrangement <NUM>. Compared to the best ring magnet, the reduction of magnet material is thus <NUM>% for the same magnetic field at r = <NUM>. It is noted that the ring magnet with di=<NUM> may not even be technically feasible, as outlined above.

By the magnet arrangement <NUM>, the error in the measurement of the rotation angle (i.e. the angular deviation) that may be caused by the above-mentioned mechanical displacement in radial direction between the magnet arrangement <NUM> and the magnetic field sensor <NUM> can be reduced significantly. Such displacement may for example be due to bearing play and/or vibrations. This is illustrated in <FIG>, which shows the angular deviation dα on the vertical axis and shows the mechanical radial displacement dr on the horizontal axis. Curve <NUM> shows that for a perfect <NUM>-pole cylinder magnet, there is almost no angular deviation. Curve <NUM> illustrates the angular deviation for the magnet arrangement <NUM> (four permanent magnets of <NUM> diameter and <NUM> height). Curve <NUM> illustrates the angular deviation for a corresponding ring magnet having an outer diameter of <NUM> and an inner diameter of <NUM> and a height of <NUM> (thus corresponding to the ring between circles <NUM> and <NUM> shown in <FIG>). The remanence for both, the magnet arrangement <NUM> and the corresponding ring magnet is Br = <NUM> mT. As can be seen by comparing the curves, the magnet arrangement <NUM> has a significantly improved reaction to a mechanical displacement in a radial direction dr (direction <NUM> in <FIG>) compared to a ring magnet of corresponding size. Using similar dimensions, an improvement by a factor of <NUM> can be achieved.

Curve <NUM> corresponds to a ring magnet with outer diameter <NUM>, inner diameter <NUM> and height <NUM>; curve <NUM> corresponds to a ring magnet of outer diameter <NUM>, inner diameter <NUM> and height <NUM>; and curve <NUM> corresponds to a ring magnet of outer diameter <NUM>, inner diameter <NUM>, and height <NUM>, all with the same magnetic remanence of <NUM> mT. Compared to these ring magnets, it can be seen that the reaction to a radial displacement of the magnetic field sensor is even further improved for magnet arrangement <NUM>, e.g. by a factor of <NUM> or more (for a displacement value dr = <NUM>). It is noted for a different magnetic remanence of the ring magnets of, e.g., <NUM> mT, the respective curves lie essentially behind the curves shown in <FIG>, which illustrates that the magnetic remanence has not much effect on the angular deviation caused by a relative radial displacement of the magnetic field sensor. Ring magnets with an inner diameter of smaller than <NUM>, i.e. corresponding to curve <NUM>, and the required magnetic flux density are difficult to produce as outlined above.

<FIG> illustrates the effect of different magnet spacings dm on angular displacement. The angular displacement dα is shown on the vertical axis. The horizontal axis shows the distance dm between adjacent permanent magnets <NUM>-<NUM> in mm, i.e. the distance <NUM> shown in <FIG>. The distance dm is the same between each pair or neighboring permanent magnets. Curve <NUM> corresponds to a displacement of dr=<NUM>; curve <NUM> to dr=<NUM>; curve <NUM> to dr=<NUM>; curve <NUM> to dr=<NUM>; and curve <NUM> to dr=<NUM> mm. As expected from <FIG>, for a larger radial displacement dr, the angular deviation dα increases. As can be seen, the angular deviation dα has a minimum at a magnet spacing <NUM> of about <NUM>. This observation allows the optimization of the magnet arrangement and making the rotary sensor more robust against radial displacements.

For <FIG> and for the values indicated above, the radial offset <NUM> between the axis <NUM> and the magnetic field sensor <NUM> has been chosen to r = <NUM>. It should be clear that in other embodiments, differently sized magnets, a different spacing between magnets, a different distance <NUM>, a different radial offset <NUM> and differently sized inner and outer circles <NUM>, <NUM> may be used. The above outlined dimensions are only provided for the purpose of illustrating the benefits achieved by the solution disclosed herein and are not of a limiting nature.

<FIG> illustrates a housing <NUM> that may form part of the rotary sensor <NUM> and that is provided for taking up the permanent magnets <NUM> to <NUM>. The housing <NUM> may comprise a support member <NUM> for each permanent magnet, which may be provided in form of a sleeve or recess into which the permanent magnet can be inserted in a formfitting manner or may be pressed in. The recess <NUM> opens the view on the permanent magnets <NUM> to <NUM> which are arranged within the respective supports <NUM>. The housing <NUM> may further comprise an opening <NUM> configured to receive a pin (<NUM> in <FIG>) in a formfitting manner. Housing <NUM> further comprises a circumferential outer wall <NUM> and an axial end cover <NUM>. End cover <NUM> secures the permanent magnets <NUM> to <NUM> in their respective support <NUM>. Optionally, a corresponding end cover may be provided on the opposite axial end of the housing <NUM>. Housing <NUM> may be formed of a single integral piece of material. It may be formed by molding and/or machining.

As shown in <FIG>, the support <NUM> may comprise a clamping feature, such as a ridge, rib, or protrusion <NUM> to ensure that when the permanent magnet is pressed into the support <NUM>, the permanent magnet is held firmly in place. Three such ridges or protrusions <NUM> spaced apart circumferentially by about <NUM>° or another angle may be provided in each support <NUM>.

The housing <NUM> may be configured to receive a part of the component <NUM>, such as a shaft <NUM> (<FIG>), a protrusion, or the like. <FIG> illustrates a respective receiving section <NUM> of housing <NUM>. When the permanent magnets <NUM>-<NUM> are mounted in housing <NUM>, the receiving section <NUM> has a cross-shaped cross section, which provides an interlocking feature. The shaft <NUM> may have a complementary shape to provide a corresponding interlocking feature. The cross-shaped end of the shaft thus engages the receiving section <NUM> in a form-fitting manner. Interlocking is thereby achieved, and the housing <NUM> is prevented from being rotated relative to the shaft <NUM>. The non-rotatable mount to component <NUM> may also be achieved in different ways, such as using a slot and key arrangement, using locking pins extending laterally through housing and shaft, using a pin engaging the outer walls of the housing, e.g. the recess shown in the sidewall <NUM> of <FIG>, or the like.

To hold the housing <NUM> on the shaft <NUM>, a pin <NUM> may be provided (<FIG>) which engages a opening in the shaft. The pin <NUM> may extend through the hole <NUM> and may have a head larger than hole <NUM>. The pin may be pressed into or screwed into the end of shaft <NUM> so that the housing is pressed against the end of the shaft and cannot become disengaged from the shaft. A simple but secure and compact way of mounting housing <NUM> to shaft <NUM> may thus be achieved. The housing <NUM> may have a recess <NUM> configured to take up the head of a respective pin. The assembly may thus be made even more compact.

<FIG> illustrates an embodiment of rotary sensor <NUM> that may be for example be mounted in an operating device <NUM>, e.g. of a mobile machine. Such operating device may include a handle (not shown) to be operated by an operator; it may have a joystick-like configuration. Component <NUM> forms part of the operating device and is coupled to the handle such that if the handle is actuated, in particular pivoted, the component <NUM> is rotated about the rotation axis <NUM>. Component <NUM> can form part of a suspension or can be mounted to such suspension. For example, a gimbal of a gimbal mount may support the handle and may rotate about the axis <NUM> when the handle is pivoted, and the component <NUM> may form part of such gimbal or may be mounted to such gimbal.

As explained above, the housing <NUM> supports the permanent magnets <NUM>-<NUM>, two of which are partly visible in the schematic sectional view of <FIG>. The section shown in <FIG> does not go through the center of the permanent magnets <NUM>, <NUM>, thus showing a wider section through shaft <NUM> and through the outer wall <NUM> of housing <NUM>. The housing <NUM> is secured by pin <NUM> to the end of shaft <NUM>. In other implementations, the component <NUM> may not comprise a shaft, but the housing may directly be mounted to a differently shaped part of component <NUM>, e.g. to the flat disc-shaped part.

The magnetic field sensor <NUM> includes the Hall sensor element <NUM>, and may include one or more additional Hall sensor elements <NUM>. Hall sensor element <NUM> is offset by an offset <NUM> from the axis <NUM>. The offset may be measured to a center of Hall sensor element <NUM>. The Hall sensor element <NUM> may include a sensor array, which may have the form of a Hall plate circle. The center of such Hall plate circle may form the center of the Hall sensor element <NUM>. The offset may for example be about half the diameter of such Hall plate circle. For example, offset <NUM> may be between <NUM> and <NUM>, e.g. between <NUM> and <NUM> (it is r=<NUM> in the above examples).

Magnetic field sensor <NUM> may be provided as a (single) chip, such as a Micronas HAR <NUM> type stray field robust Hall sensor. The chip may include two or more hall sensor elements at different positions on the chip.

The magnetic field sensor may be spaced apart from the magnet arrangement <NUM>, in particular from the permanent magnets <NUM>-<NUM>, by a distance <NUM> in axial direction (z-direction). The distance may be measured to the surface of the chip, the distance of the sensor element <NUM> from the chip surface being generally known. In an exemplary implementation, the distance <NUM> may be more than <NUM> or more than <NUM>. By the magnet arrangement <NUM>, it can be ensured that the magnetic flux density in axial direction Bz is still sufficiently large at the position of the Hall sensor element <NUM>; the magnet arrangement may in particular be configured to provide at least Bz = <NUM> mT in the plane perpendicular to the axis <NUM> in which the Hall sensor element <NUM> is located. A precise measurement of magnetic field rotation and an efficient compensation of external magnetic fields may thereby be ensured.

<FIG> illustrates a method of assembling a rotary sensor, which may have any of the configurations described herein. In step <NUM>, the magnet arrangement is assembled by placing the permanent magnets <NUM> to <NUM> in the housing <NUM>. In step <NUM>, the magnet arrangement is mounted in a non-rotatable manner to the shaft <NUM> of component <NUM> (or to another part of the component). In step <NUM>, the magnetic field sensor <NUM> is arranged adjacent to the magnet arrangement <NUM>. It should be clear that this is only an exemplary implementation of the method, and that the steps may have a different order and that additionally steps may be provided. For example, the rotary sensor <NUM> may first be assembled as a unit and may then be mounted to the component <NUM> by attaching the magnet arrangement <NUM> in a non-rotatable manner to the shaft <NUM>.

Claim 1:
An operating device for a mobile machine, wherein the operating device comprises a pivotable handle and a detection mechanism coupled to the pivotable handle, the detection mechanism comprising a component (<NUM>) that is rotated about a rotation axis (<NUM>) upon pivoting the handle, wherein the operating device (<NUM>) further comprises a rotary sensor (<NUM>), wherein the rotary sensor (<NUM>) is a rotation angle sensor configured to detect an angle of rotation of the component (<NUM>), wherein the rotary sensor (<NUM>) comprises:
- a magnet arrangement (<NUM>) configured to generate a magnetic field, wherein the magnet arrangement (<NUM>) comprises at least four distinct and spatially separate permanent magnets (<NUM>-<NUM>), wherein the at least four permanent magnets (<NUM>-<NUM>) are arranged circumferentially about the rotation axis (<NUM>) extending in an axial direction, wherein each permanent magnet (<NUM>-<NUM>) has a direction of magnetization that is substantially parallel to the axial direction, and wherein at an axial end face of the magnet arrangement (<NUM>) north and south poles of the permanent magnets (<NUM>-<NUM>) alternate in circumferential direction so that in circumferential direction neighboring permanent magnets have an opposite direction of magnetization; and
- at least one magnetic field sensor (<NUM>) configured and arranged to detect a rotation of the magnetic field generated by the magnet arrangement (<NUM>) upon rotation of the magnet arrangement (<NUM>),
wherein the magnet arrangement (<NUM>) of the rotary sensor (<NUM>) is non-rotatably mounted to the component (<NUM>) of the operating device (<NUM>) to detect a rotation of the component (<NUM>) about the rotation axis.