DE102006054662A1 - Method for manufacturing torque sensor, involves producing a magnetic field in circumferential direction in magnetoelastic binding and counteract of positive hysteresis in torque sensor, and negative hysteresis are effected in binding - Google Patents

Abstract

The method involves producing a magnetic field in circumferential direction within magnetoelastic binding, which has a desired magnetic field direction. Another magnetic field is produced in circumferential direction within magnetoelastic binding in another desired magnetic field direction, which is opposite to the former magnetic field direction. The former magnetic field is spatial arranged in an axial distance from the latter magnetic field. The counteract of a positive hysteresis are produced within the torque sensor (12) and negative hysteresis are effected within magnetoelastic binding. Independent claims are also included for the following: (1) a method for reduction of hysteresis in magnetoelastic torque sensor (2) a torque sensor arrangement with a reduced hysteresis.

Description

Background of the invention

These This invention relates generally to a method and apparatus for producing a magnetoelastic torque sensor. Especially This invention relates to a method and apparatus for Reducing the magnetic hysteresis in a magnetoelastic Torque sensor.

One magnetoelastic torque sensor uses the inverse Wiedemann effect, which generates a magnetic field in a magnetoelastic material, which responds to the application of torque. A magnetoelastic Torque sensor includes a substrate to which an applied torque and that holds a band of magnetoelastic material. On the magnetoelastic bands acts a load in the circumferential direction, which is a magnetically light Axis provides, in turn, a desired magnetic field in the circumferential direction within the magnetoelastic band. The torque on the substrate is transferred to the band of magnetoelastic material, around a distortion in the circumferential Orientation of the magnetic field to induce. That on the substrate acting torque leads to that the normally circumferentially oriented magnetic field is distorted so that the magnetic field is spirally shaped becomes. The distortion out of the circumferential direction is through a magnetic field detection device is measured. The size and the Amplitude of the distortion correspond to that applied to the substrate Torque.

In disadvantageously, the magnetic field does not return in certain cases desired Orientation in the circumferential direction back as soon as the torque is released. The remaining axial components of the magnetic field can a Causing displacement of the zero point, known as hysteresis is. At least part of the zero offset is due to smaller as the desired load in the circumferential direction in the magnetoelastic bands and by an undesirable high magnetocrystalline Causing anisotropy on the magnetoelastic material. The material properties of the magnetoelastic material are used for compatibility with a selected specific application and in certain cases can Materials selected and used, which do not limit the hysteresis.

Accordingly, it is desirable, to develop a method and an apparatus that the unwanted hysteresis effects in a considered magnetoelastic material and one economically favorable Use of materials provides.

Summary of the invention

One exemplary method for producing a torque sensor according to this Invention includes the step of holding a magnetoelastic Material on a substrate and the action of a first magnetic field in the circumferential direction within the magnetoelastic material in a first desired Direction. A second magnetic field in the circumferential direction acts in the magnetic material in a second, opposite to the first direction Direction and is spatially separated from the first magnetic field in the circumferential direction.

The exemplary methods according to this invention represents the generation of an adjacent negative-hysteretic structure within the magnetoelastic material. The negative-hysteretic Structure incorporated in the magnetoelastic material acts opposed to the positive hysteresis, which is due to the magnetoelastic Material acts by applying the torque.

One exemplary torque sensor according to this invention is with magnetic remanences in the circumferential direction by rotating the tape of magnetic material near a permanent magnet busy. Two permanent magnets are used, each one Magnetic field generates an opposite direction. The generating an opposite magnetic field within the magnetoelastic Materials ensures a magnetic dipole structure, which is the distinction of torque-related Magnetic fields of non-divergent Fields nearby allows the torque sensor.

The first and second permanent magnets that are used to the preferred magnetic fields in the circumferential direction in the magnetoelastic Producing material are at an axial distance from each other spaced. By arranging the permanent magnets at an axial distance from each other are the first and second remanent magnetic fields also in a desired axial distance from each other. The space between the first and second magnetic fields is with a band of a weak magnetic field occupied, which has no specific direction. The weak magnetic field, which is arranged between the first and second fields, has a Orientation that is neither in the direction of the first nor the second magnetic field goes and which is much weaker. This distance generates the intrinsic negative hysteresis within the magnetoelastic Material that works against the positive hysteresis caused by the Applying the torque is generated.

Accordingly used the method and the device according to this device hysteretic Effects imposed on the magnetoelastic material undesirable To consider hysteresis and to counteract that within the torque sensor due to the concern of torque was generated.

These and other features of the present invention may best be understood by reference to the following Description and figures are understood, in the following a Brief description of the figures is given.

Brief description of the figures

1 is a schematic representation of a torque sensor according to this invention.

2 is another schematic representation of an exemplary torque sensor according to this invention.

3 FIG. 12 is a schematic representation of a method for generating preferred magnetic fields in a torque sensor according to this invention. FIG.

4 FIG. 10 is another schematic illustration of an exemplary method of generating preferred magnetic fields within a torque sensor according to this invention. FIG.

5 FIG. 12 is yet another exemplary method, shown schematically, for generating preferred and desired magnetic fields in a torque sensor according to this invention.

Detailed description of the preferred embodiment

With reference to 1 is a torque sensor arrangement 10 schematically illustrated and includes a torque sensor 12 that a wave 14 which has a magnetoelastic ring 16 wearing. The wave 14 includes an axis 18 and is capable of applying an applied torque with 20 is designated to receive. The torque sensor 12 has the magnetoelastic ring 16 on. Inside the magnetoelastic ring 16 Preferably, residual magnetic fields are oriented. These preferred residual magnetic fields are arranged in an orientation in the circumferential direction. During the application of torque, the preferred magnetic fields are circumferentially distorted in a helical direction and are covered with an axial magnetic component.

The on the torque sensor 12 imposed axial magnetic component is determined by magnetic field vector sensors 30 measured. The size and direction of the axial component of the magnetic fields are measured and a control device 32 provided. The control device 32 translates the vector quantities of the measured magnetic fields and determines an applied torque according to a known relationship.

When releasing the applied torque 20 would the torque sensor 12 preferably return to the same zero position in which he had originally started. The torque sensor 12 and especially the wave 14 and the ring of magnetoelastic material 16 however, plastically deforms to some degree each time torque is applied 20 , The plastic deformation together with other phenomena including the application of insufficient circumferential stress within the magnetoelastic material or excessive magnetocrystalline anisotropy of the magnetoelastic material combine to cause a hysteresis effect. This hysteresis effect results in a shift of a zero point. The displacement of the zero point results in undesirable torque reading values since the measured torque value never returns to its original zero position.

A shift in the zero point of the torque sensor 12 in the same direction as the applied torque 20 is called a positive hysteresis. The positive hysteresis causes the sensor to return to a value greater than the original zero value. The torque sensor 10 according to this invention, the torque sensor 12 on that with a negative hysteresis inside the magnetoelastic ring 16 is occupied. The negative hysteresis acts in an amount to counteract the results and effects of the positive hysteresis imposed by the application of torque.

The desired negative hysteresis is achieved by and during the action of the residual magnetic fields in the circumferential direction within the ring of magnetoelastic material 16 imposed. The sensor 12 has the magnetoelastic ring 16 on, the generated magnetic fields in the circumferential direction 22 . 24 having. The first residual magnetic field 22 is arranged in a first direction. The second residual magnetic field 24 is arranged in a second direction, which is opposite to the first direction. The oppositely arranged magnetic remanences in the circumferential direction of the first and second magnetic fields 22 . 24 take into account and make the distinction between the torque-related fields and other nearby magnetic fields countries.

The first residual magnetic field 22 and the second residual magnetic field 24 are at an axial distance 28 spaced apart. The axial distance 28 between the first residual magnetic field 22 and the second residual magnetic field 24 creates a weak magnetic field that is oriented in neither the first nor the second direction. This weak magnetic field provides the source of the negative hysteresis signals that are used to cancel and account for the positive hysteresis effects that are generated during the application of torque. A certain axial distance 28 between the first residual magnetic field 22 and the second residual magnetic field 24 is application-dependent and is determined with regard to certain material properties that the torque sensor 12 having. Further, the amount or magnitude of the negative hysteresis effect that is desired is determined by varying the axial distance 28 between the first residual magnetic field 22 and the second residual magnetic field 24 customized.

With reference to 2 includes another exemplary torque sensor 35 according to this invention, a torque sensor 38 that the wave 14 and the magnetoelastic ring 16 having. The magnetoelastic ring 16 has axial ends 46 on. In the torque sensor 38 are a first residual magnetic field 40 and a second residual magnetic field 42 from the axial ends 46 of the magnetoelastic ring 16 spaced. The axial distance 48 between the first residual magnetic field 40 and the second residual magnetic field 42 and each of the axial ends 46 is not with a magnetic field of orientation relative to that of the first residual magnetic field 40 and the second residual magnetic field 42 filled. A third magnetic field 44 becomes within the axial distance 48 each between the first and second residual magnetic fields 40 . 42 and the axial ends 46 generated and produced. This third magnetic field 44 is the weak magnetic field that generates the negative hysteresis that is desired, by the positive hysteresis caused by the application of torque 20 is generated to counteract.

With reference to 3 a method for producing a torque sensor according to this invention is shown and generally with 60 designated. The method according to the invention comprises the first step of generating the first residual magnetic field in the circumferential direction 22 within the magnetoelastic ring 20 , The method continues to cause the second residual magnetic field 24 in the circumferential direction within the magnetoelastic ring 16 in a to the first residual magnetic field 22 opposite direction. The first and second residual magnetic fields 22 . 24 are by the axial distance 28 spaced apart.

During de generating the magnetic fields, the torque sensor 12 in the presence of a first permanent magnet 62 and a second permanent magnet 64 rotates. Each of the permanent magnets 62 . 64 emits a magnetic field 70 . 72 of such strength to the magnetoelastic ring 16 magnetically saturate and the preferred, circumferentially oriented residual magnetic fields 22 . 24 cause. The distance 66 between the permanent magnet 62 and the second permanent magnet 64 is based on the desired strength of the third magnetic field 26 determined within the axial distance between the first magnetic field 22 and the second magnetic field 24 is arranged. As appreciated results in adjusting the axial distance 66 between the permanent magnets 62 . 64 in a change of the axial distance 28 the residual magnetic fields in the circumferential direction 22 . 24 that are inside the magnetoelastic ring 16 are arranged. This axial distance 28 is set to provide the desired positive hysteresis drag required by the application of torque to the torque sensor 10 was developed and has its origin.

With reference to 4 Another method of manufacturing a torque sensor is generally known 76 and comprises the steps of causing the first residual magnetic field 40 in the axial distance 48 from an axial end portion 47A of the magnetoelastic ring 16 , The method further includes causing a second residual magnetic field in the circumferential direction 42 at the axial distance 48 from a second axial end 47B , Accordingly, the first and second residual magnetic fields 40 . 42 adjacent to each other at a central distance of the magnetoelastic ring 16 oriented. The residual magnetic fields in the circumferential direction 40 . 42 However, they are arranged in opposite directions relative to each other and do not extend to the axial end portions 47A . 47B of the magnetoelastic ring 16 , The third magnetic field 44 is within the space between each of the first and second residual magnetic fields 40 . 42 and the corresponding axial end portions 47A . 47B arranged.

During the generating step, the permanent magnets are 62 . 64 at an axial distance 78 from the axial ends 47A . 47B spaced. The permanent magnets 62 . 64 call the desired oppositely oriented residual magnetic fields 40 . 42 out. The third magnetic field 44 is between the first and second residual magnetic fields 40 . 42 arranged and thus generates the desired negative hysteresis within the magnetoelastic ring 16 ,

With reference to 5 is another method according to this invention schematically with 85 and comprises the first step of generating the preferred residual magnetic fields in the circumferential direction 94 . 96 within the magnetoelastic ring 16 , The first magnetic field in the circumferential direction 94 is arranged in a first circumferential direction and the second residual magnetic field in the circumferential direction 96 is disposed in a second circumferential direction opposite to the first circumferential direction. Once the preferred circumferentially oriented residual magnetic fields become 94 . 96 within the magnetoelastic ring 16 caused. The entire sensor 38 is exposed to an alternating magnetic field, which in the scheme with 88 is designated.

The alternating magnetic field 88 is through a magnetic field generator 86 generated with an alternating current 90 is supplied. An alternating magnetic field generator 88 , which is an alternating magnetic field 88 is used to portions of the torque sensor element 38 to demagnetize. Demagnetizing certain portions of the torque sensor element 38 creates and eliminates the circumferential magnetic remnants in sections of the magnetoelastic ring 16 , In the method according to the invention, the magnetic remanences in the circumferential direction by the alternating magnetic field 88 in the axial end sections 92 of the magnetoelastic ring 16 eliminated.

The resulting torque sensor element 38 has the third magnetic remanence 98 on that between the first and second magnetic fields 94 . 96 and are arranged in each case the axial ends. The magnetic remanences 98 are not oriented in the circumferential direction and provide for the weak magnetic field, the negative hysteresis within the magnetoelastic ring 16 generated. Accordingly, the duration and the strength of the exposure to the alternating magnetic field become 88 different amounts and amounts of third magnetic remanences 98 within the magnetoelastic ring 16 produce. The amount of the third magnetic field 98 is set to provide the desired negative hysteresis within the magnetoelastic ring 16 is caused. By adjusting the amount of negative hysteresis within the magnetoelastic ring 16 For example, the amount of positive hysteresis that can be neutralized to provide a more accurate sensor can be adjusted.

Accordingly offers the according to this Method produced torque sensor, which the magnetic fields in Circumferentially having within the magnetoelastic ring are arranged, the consideration and counteracting the positive hysteresis by provoking the negative hysteresis during of the magnetization process. Counteracting the positive hysteresis leads to the negative hysteresis to a more accurate torque sensor with a much more accurate and more reliable Measurement.

Even though a preferred embodiment of this Invention was disclosed a person skilled in the art will recognize that certain changes within the scope of this invention. For that reason should the following claims be studied to understand the true nature and content of this invention to determine.

Claims (17)

Method for producing a torque sensor with the following steps: a) generating a first magnetic field in the circumferential direction within a magnetoelastic tape, the a first desired Magnetic field direction has; b) generating a second magnetic field in the circumferential direction within the magnetoelastic band in one second desired Magnetic field direction opposite to the first magnetic field direction is; and c) spatial Arranging the first magnetic field at an axial distance from the second magnetic field. The method of claim 1, wherein the steps a) and b) rotating the magnetoelastic material in the presence a magnet of a field strength which is suitable to saturate the magnetoelastic tape. The method of claim 1, wherein the spatial Arranging between the first magnetic field and the second magnetic field produces a magnetic remanence, which is a magnetic field orientation which differs from the first magnetic field direction and to the second magnetic field direction. The method of claim 3, wherein the magnetic Remanence, which is arranged between the first and second magnetic fields is the section of the magnetoelastic band in the direction of a presets negative hysteresis. The method of claim 4 including the step the counteracting of a positive hysteresis occurring within the Torque sensor is generated, the negative hysteresis within the Magnetoelastic band is caused. The method of claim 1 including the step of disposing the torque sensor within an alternating magnetic field to demagnetize axial portions of the magnetoelastic tape. The method of claim 1 including the step the spaced arrangement of the first magnetic field in the circumferential direction and the second magnetic field in the circumferential direction of axial end portions of the magnetoelastic band. Method for reducing hysteresis in a magnetoelastic Torque sensor with the following steps: a) invoking a first residual magnetic field in a first circumferential direction within a ring of magnetoelastic material resting on a substrate is held; b) causing a second residual magnetic field in a second circumferential Direction, the first circumferential Opposite direction, within the magnetoelastic ring Material; and c) Orienting the arrangement of the first residual magnetic field to the second magnetic field around areas within the magnetoelastic Material with a third magnetic field of lesser strength than that cause the first magnetic field or the second magnetic field. The method of claim 8, wherein the third magnetic field has an orientation extending from both the first circumferential one Direction as well as the second circumferential direction. Method according to claim 9 including the Step of the spatial Arranging the first residual magnetic field axially separated from the second Residual magnetic field around the third residual magnetic field in a space in between to build. The method of claim 9 including the step of the spatial Arranging the first and second circumferential magnetic fields axially from axial ends of the magnetoelastic material ring the third magnetic field at remote axial portions of the ring made of magnetoelastic material. The method of claim 8, wherein the third magnetic field as responsive to the generation of the first circumferential magnetic field and the second circumferential Magnetic field is generated. The method of claim 8, wherein the first and second circumferential Magnetic fields generated with a permanent magnet of a strength which is suitable, the magnetoelastic material magnetic to saturate. Torque sensor arrangement with a reduced Hysteresis with: a substrate for receiving an applied torque; and a magnetoelastic ring held on the substrate wherein the magnetoelastic ring is a first residual magnetic field region with a first circumferential Orientation, a second residual magnetic field region with a second peripheral Orientation opposite to the first circumferential orientation and one third residual magnetic field region having a third orientation possesses, which are different from the first and the second peripheral Orientation is. Arrangement according to claim 14, wherein the third residual magnetic field region arranged between the first magnetic field region and the second magnetic field region is. Arrangement according to claim 15, wherein the first and second residual magnetic field regions by applying a magnetic field formed of such a size to magnetically saturate the material that magnetoelastic Ring and the third residual magnetic field region when passing through the Interaction between the first and second residual magnetic field regions is formed. Arrangement according to claim 14, wherein the first and second residual field areas of axial ends of the magnetoelastic Are spaced annular, and the third Restmag netfeldbereich between respectively the first and second residual magnetic field regions and the respective one axial end is arranged.