DE102004026415A1 - Object position detector, e.g. for motor vehicle intelligent door braking system, sums voltages in induced in secondary coil to provide measure of strain on magnetic core - Google Patents

Abstract

A magnetic core is completely or partially made of magnetoelastic material. The magnetic core is connected mechanically with the object so that force on the object produces a strain in the magnetic core, changing its magnetic permeability. The sum of the voltages induced in a secondary coil represents a measure of the strain in the magnetic core.

Description

The The invention relates to a device for detecting the position of a A measuring object to which a permanent magnet is attached so that this by change of position of the test object without contact along one with an AC powered excitation coil and two secondary coils wrapped magnet core and depending on its position the Stray flux of the system influenced so that the difference of in the secondary coils induced voltages are a measure of the position represents the permanent magnet.

From the DE-OS 23 25 752 For example, a position transducer is known in which the position of a permanent magnet connected to a measurement object is determined in the longitudinal direction of an AC-energized excitation coil wound across a ferromagnetic core. The permanent magnet generates in the ferromagnetic core a local saturation acting as a virtual air gap and thus causes a division of the magnetic flux into two magnetic circuits which are each excited only by a part of the excitation coil defined by the position of the magnet. In each of the two magnetic circuits there is a secondary coil whose induced voltage is thus influenced by the position of the permanent magnet. The position of the permanent magnet can be determined from the values of the voltages induced in the two secondary coils, essentially their difference. By based on this principle measuring arrangements, often referred to simply as PLCD sensors (permanent magnet linear contactless displacement), only path or angle signals can be measured. Further measuring arrangements based on a similar principle are described in US Pat EP 0 238 922 B1 and DE 44 25 903 C1 described.

Numerous applications, such as the position control of an actuated object, which is exposed to external disturbance forces, or an intelligent braking device, which is to detect not only a movement of an object but also its cause (eg, an intelligent door brake on a motor vehicle), require both the detection of a Position signal as well as the detection of a force or torque signal. For this purpose was approximately in the DE 198 39 412 A1 presented a magnetoelastic dynamometer, inside which a protractor is integrated. However, the functionality of both sensor components is realized by different elements of the overall arrangement, which is why the detection of both types of signals with a higher material, development and integration costs associated with the detection of only one signal of the two types of signals mentioned. A combined force and position sensor system, which is composed of two largely independent subsystems and thus also has the disadvantages described, is also known from WO 02/23135 A1.

task The invention is an apparatus for detecting both a Position signal as well as a force signal to create the one possible small increase of the material, development and integration costs compared to one Has device for detecting only one position signal.

Under the term of a position signal is in the following optionally a Rotation angle or a translational shift to understand by which the position of a measuring object in space or relative to another Object is marked. Under the concept of a force signal is in the Fogenden optionally a physical object acting on a measurement object Force or a physical torque acting on a measurement object to understand.

Is solved the task by equipping a Lageaufnehmers after known Principle with a magnetic core of magnetoelastic material, the at the same time as force-transmitting Element acts as well as a modified one Evaluation of the secondary coils induced voltage signals.

In a device according to the invention is a Lageaufnehmer according to the state the technology around the functionality a force transducer extended by the magnetic core of the Lageaufnehmers completely or partially carried out in magnetoelastic material, by the mechanical overall arrangement is chosen so that the to be detected transferred to the test object force on the magnetic core is that in this one approximately in longitudinal direction acting mechanical stress is generated, and for determination the force is the sum of the voltage values induced in the secondary coils is evaluated.

Of the Advantage of a device according to the invention is thus that the combined measurement function according to the task without the use of additional mechanical components opposite a Lageaufnehmer according to the state the technology can be realized.

The inventive redesign of a Lageaufnehmers according to the prior art is based on that of the EP 0 070 442 known principle of a magnetoelastic force transmitter. In this case, the magnetic permeability of the magnetic core material, which is modified by mechanical stresses as a result of a force acting on a magnetoelastic magnetic core, influences those in a secondary coil lenanordnung induced voltage values. From these voltage values, the force signal acting on the element can be determined. A reference to the possibility of applying this measurement principle to extend the functionality of a Lageaufnehmers is not apparent from the patent literature.

There the embodiment of the invention Magnet core completely or partially in magnetoelastic material manufacturing technology easy to consider leaves, is compared to the cost of materials the detection of only one position signal only minimally increased. Because the principle measuring arrangement of the Lageaufnehmers unchanged received stays is opposite the detection of only one position signal no additional mechanical integration effort afford to. Also, the choice of the overall mechanical arrangement so that the magnetic core of the Lageaufnehmers acts as a force-transmitting element, is in most applications in which a combined invention Position and force measurement desirable is, without or with very little development effort compared to the Detecting only one position signal possible. To determine the The force acting on the target only has to be the sum of the values in the secondary coils induced and already tapped voltage values evaluated become. The on the evaluation of a relative difference of in the secondary coils induced voltage values based functionality of the Lageaufnehmers is this is not affected.

Especially easy is the extra functionality to introduce the force measurement into systems in which the magnetic core a Lageaufnehmers already before introduction as a force-transmitting Element acts. For this only the magnetic core has to be completely or partially executed in magnetoelastic material and the sum of in the secondary coils induced voltages are evaluated accordingly.

One Another advantage of the invention is that by a device according to the invention no additional Space opposite a device for exclusive Measurement of a position signal is claimed, resulting in cramped spatial conditions in certain circumstances only the combined measurement of both a position signal and a force signal allows becomes.

Based the attached Drawings, the invention is further explained. It shows

1 a schematic diagram of an intelligent door brake for a motor vehicle, which contains a combined position and force transducer system according to the invention, and

2 the input and output variables of an evaluation circuit for a combined position and force transducer system according to the invention.

1 shows a schematic diagram of an intelligent door brake for a motor vehicle, which includes a combined position and force transducer system according to the invention, through which a standing for the opening angle of the door path signal and a force signal which is due to possible user intervention or external interference torques generated on the door measured become.

In the mechanical arrangement of the door brake own the door 1 and the door lever 2 different axes of rotation on the body 3 , This results in a relative movement between the door when opening and closing the door 1 and door lever 2 , At the same time, a door-mounted brake actuator which is not considered here in detail in its mode of operation can be used 4 between door 1 and door lever 2 a force is applied, which is a holding or braking moment on the door 1 conditionally. On the door lever 2 This force always acts approximately in its longitudinal direction.

The transducer system includes an excitation coil 5 and two secondary coils 6 . 7 all mounted on a magnetic core. The magnetic core functions according to the invention simultaneously as a force-conducting door lever 2 , According to a preferred embodiment of the invention, the entire door lever is made of magnetoelastic material. An embodiment of the door lever 2 as a steel core with a magnetoelastic coating (eg Fe ₈₁ (B, Si, C) ₁₉ ) is also conceivable.

The displacement transducer system is based on a magnetic-inductive action principle. Through the exciter coil 5 An alternating current i (t) flows with sinusoidal course, through which the magnetic core 2 is magnetized time-varying. A firm at the door 1 arranged permanent magnet 8th moves in contactless manner with the exciter coil as a function of the door opening angle 5 along and has a magnetization that is so large that through this a local saturation of the field in the magnetic core 2 achieved and the magnetic flux is interrupted in the magnetic core near the permanent magnet. The permanent magnet thus generates a location-variable virtual air gap. It form two separate magnetic flux circuits, each of which is only part of the excitation coil 5 be fed. The effective proportion of the exciter coil for each of the two magnetic circuits is dependent on the relative position of the permanent magnet to the exciter coil. Each of the two magnetic flux circuits passes through one of the secondary coils 6 . 7 , The secondary coils measure the magnetic flux in the form of the induced voltage U _{ind sek1} or U _{ind sek2} and thus allow the exact determination of the position of the permanent magnet relative to the exciter coil and from there the determination of the door opening angle.

Using a quotient formula for the relative voltage difference of the two secondary coils relative to the total induced voltage 6 . 7 This results in an approximately linear characteristic for the detected by a change in voltage path change. In the determination of the position of the permanent magnet thus enters the relative voltage difference according to the following equation:

2 shows the input and output variables of an evaluation circuit 9 in which, on the basis of the above equation and kinematic data of the overall arrangement, an output signal y ₁ is established for the opening angle of the door.

According to the invention, the magnetic core functions 2 at the same time as a force-conducting door lever. On the one hand it is hinged to the body, on the other there is a force introduced by the brake actuator 4 , If the door is moved while the door brake is released, no or very little force acting on the by the inclusion of the brake actuator 4 sliding door lever 2 , If a torque is exerted on the door while the brake actuator is activated, depending on the effective direction, a tensile or compressive force is generated on the door lever 2 , This force causes mechanical stresses in the material of the door lever 2 , Due to the pronounced magnetoelastic properties of the door lever material, the relative permeability μ _{r of} the door lever material changes as a result of the load. This change can also be made over in the secondary coils 6 . 7 induced voltage values are measured. Depending on the direction, changes in the force _signal can be measured via a simultaneous sudden increase or decrease in the voltages U _{ind sek1} and U _{ind sek2} . Therefore, to determine the temporal force curve, the sum of the secondary coils 6 . 7 evaluated voltage values. In the determination of the door lever 2 Thus acting force enters the absolute voltage sum according to the following equation: U ind = U ind sek1 + U ind sek2

This sum is independent of the position of the permanent magnet 8th , The force measurement can thus be carried out in principle independently of the distance measurement. In the evaluation circuit 9 For example, based on the above equation, characteristic values of the magnetoelastic material and kinematic data of the overall arrangement, an output signal y ₂ standing for the torque acting on the door can be generated.

It should be noted, however, that the permeability μ _{r of} the magnetoelastic door lever 2 depends not only on mechanical but also on thermal factors. The force measurement is therefore also subject to thermal influences, which is why it may be necessary to provide a temperature compensation. In the evaluation circuit 9 For this purpose, a temperature compensation curve can easily be stored. The required measurement of the temperature T can be made by taking advantage of the temperature dependence of the electrical resistance by DC resistance measurement of the secondary coils. Another possibility is through the use of an additional temperature sensor. In many cases, can be completely dispensed with a temperature compensation, since the force signal typically changes much faster than the ambient temperature. This is especially true if the time derivative of the induced voltage is evaluated to determine the temporal force curve.

According to the here described preferred embodiment the invention, the sensor system completely in the body of the Door one Motor vehicle be accommodated. As the bodywork usually Made of steel, there is no need to use the sensor system shield electromagnetically. In case of using plastic or light metal may optionally be a separate shell ferromagnetic material for electromagnetic Provide shielding.

According to the embodiment the translational movement of the permanent magnet becomes relative to the magnetic core predominantly caused by a rotation of the measurement object, which is why the first Output signal of the evaluation circuit for this rotation is. The Mechanical stress in the magnetic core becomes predominant according to this preferred embodiment caused by acting on the measurement torque, which is why the second output signal of the evaluation circuit for this Torque stands. The basic mode of operation of the combined invention Position and load cell system is however easily transferable on cases, in which the translational movement of the permanent magnet relative to the magnetic core predominantly caused by a translation of the measuring object and a first output signal for this Translation is and / or the mechanical stress in the magnetic core predominantly is caused by a force acting on the measurement object and a second output signal for this power stands.

In addition, the inventive principle of detecting mechanical stresses in the magnetic core remains 2 obtained even if this is not quite, but only partially made of magnetoelastic material or coated with magnetoelastic material.

Claims (2)

Device for detecting the position of a test object, to which a permanent magnet is mounted such that it is moved without contact by a change in position of the measurement object along a magnetic core wound with an AC-energized excitation coil and two secondary coils and depending on its position influences the leakage flux of the system so that the Difference of the induced voltages in the secondary coils is a measure of the position of the permanent magnet, characterized in that the magnetic core consists wholly or partly of magnetoelastic material, that the magnetic core is mechanically connected to the measurement object that by applying force to the measurement object, a mechanical stress is generated in the magnetic core and its magnetic permeability is changed, and that the sum of the voltages induced in the secondary coils represents a measure of the mechanical stress in the magnetic core. Device according to claim 1, characterized in that that in an evaluation circuit, a temperature compensation of the induced in the secondary coils Tension is made.