EP2269004A1

EP2269004A1 - Magnetic position sensor comprising a tapping layer consisting of an amorphous metal

Info

Publication number: EP2269004A1
Application number: EP09733974A
Authority: EP
Inventors: Werner Dengler; Gerhard Peter
Original assignee: Hirschmann Automotive GmbH
Current assignee: DENGLER, WERNER
Priority date: 2008-04-24
Filing date: 2009-04-23
Publication date: 2011-01-05
Also published as: WO2009130035A1; US20110101966A1; DE102009018342A1

Abstract

The invention relates to a magnetic position sensor (1) consisting of an electrically non-conductive, non-magnetic carrier (2), on which a resistive layer (3) and a tapping layer (4), which lies at a distance from and at least partially overlaps said resistive layer, are arranged. The distance is selected in such a way that under the action of a magnetic unit (5) that is moved along the regions of the resistive layer (3) and the tapping layer (4) lying above one another, said layers (3, 4) come into contact with one another. According to the invention, the tapping layer (4) is a foil consisting of an amorphous metal, upon which the force of the magnetic unit (5) acts.

Description

Magnetic position sensor with a pick-up layer of an amorphous metal

description

The invention relates to a magnetic position sensor, consisting of an electrically non-conductive, non-magnetic support on which a resistive layer and at a distance therefrom at least partially superimposed, a Abgreifschicht is arranged, wherein the distance is selected such that under the action of one along the superimposed Areas of resistive layer and Abgreifschicht movable magnetic device of contact between the resistive layer and the Abgreifschicht arises, according to the features of the preamble of the respective independent claim.

Position sensors that detect the position of an element relative to a reference position are known in principle. Example of such a position sensor is disclosed in DE 43 39 931 C1. However, this position sensor has the disadvantage that it works mechanically under pressure, so that this position sensor is exposed to high wear.

In order to reduce this wear effect, magnetic position sensors have already become known, e.g. from DE 196 48 539 C2 or DE 10 2004 004 102 B3.

A generic, passive, magnetic position sensor is known from DE 195 26 254 C2. This position sensor consists of an electrically non-conductive, non-magnetic carrier on which a resistive layer and at a distance

to at least partially lying one above the other a Abgreifschicht is arranged. The Abgreifschicht is a bending beam structure which is meander-shaped and arranged between two spacers. The distance between the Abgreifschicht and the resistance layer is chosen so that under the action of a movable along the superimposed areas of resistive layer and Abgreifschicht magnetic device, here a permanent magnet, a contact between the resistive layer and the Abgreifschicht, resulting in application of an electrical voltage to the Resistor layer is a change in resistance, which is detectable and represents a measure of the relative position of the permanent magnet with respect to the position sensor.

Although such a sensor already minimizes the wear effects, but it is still disadvantageous in terms of its complex structure, since the tapping is only complex to produce in the form of a meandering bending beam structure. In addition, it is necessary to arrange this meandering bending beam structure between two spacers, which further has the disadvantage that this meandering bending beam structure can be damaged in the operation of the position sensor under mechanical stresses.

A generic sensor is known from DE 10 2007 055 253.1.

The invention is therefore based on the object to provide a magnetic position sensor which operates wear-free, which is further improved in terms of its structure and its durability.

This object is achieved on the one hand by the features of claim 1. According to the invention it is provided that the Abgreifschicht is an existing of an amorphous metal foil on which the force of the magnetic device acts. This means that the tapping layer is at least partially, preferably completely formed by the a-morph metal. In this invention, the positive properties of amorphous metals are advantageously used to generate a mechanical bending or a wave in response to the movement of an object to be detected by means of the magnetic position sensor with a magnetic force on the amorphous metal foil. In total, the properties purely elastic, soft magnetic, thin film and electrically conductive of the tapping layer according to the invention are used in order to produce a magnetic position sensor with such an amorphous metal film easier to reduce the height and to improve the durability. So far, it was only known that these properties of amorphous metals were only used separately for objects. For example, transformer cores used only the soft magnetic properties, or the purely mechanical properties of amorphous metals were used, for example, for filigree mobile phone hinges. The design of the Abgreifschicht as a film of an amorphous metal (also called metallic glass) has the advantage that these amorphous metals are harder, more corrosion resistant and solid (thus durably durable), but within certain limits deformable than ordinary metals. Another advantage is that the deformations are small (about 1%) and these amorphous metals behave purely elastically. That is, the energy absorbed by the Abgreifschicht when moving the object relative to the position sensor is not lost as deformation energy, but is fully released when springing back (ie, the further movement of the object relative to the position sensor). Another advantage is that amorphous metals are the best commercially available soft magnetic materials, thereby increasing the manufacturing cost of the position sensors with such a tapping layer an amorphous metal can be lowered. Furthermore, very thin films, preferably 20 microns thick films (+/- 25%) can be produced in an advantageous manner. In addition, these amorphous metals are electrically conductive, so that with the production of Abgreifschicht already the required property of the electrical conductivity is realized.

The use of a Abgreifschicht in the form of a film of an amorphous metal thus has the advantage that this film is much more robust against mechanical external effects on the position sensor and such a film is much easier to manufacture and handle in the production. Since the Abgreifschicht consists of the amorphous metal material, it can optimally be used by the magnetic device, in particular a permanent magnet, selectively in the field of magnet action on the resistive layer, so that from the desired change in resistance, which is detectable results. This makes it possible that both the magnetic device is smaller and the height of the position sensor can be reduced, since the smaller magnet can be brought closer to the position sensor. In addition, with appropriate shaping of the carrier, the resistive layer and also the Abgreifschicht arranged on this carrier, i. be fastened so that the spacers required from the prior art can be omitted. This also results in a reduction in the overall height of the entire position sensor.

In a particularly advantageous manner, both the carrier and the resistance layer, the Abgreifschicht and a cover of the carrier are formed of a rigid or flexible film, which in turn reduces the overall height of the position sensor is reduced. In development of the invention, the Abgreifschicht is protected by a cover, wherein the cover is connected to the carrier of the position sensor. As a result, a simple production of the position sensor is possible, since first the carrier is produced, is provided with the resistive layer, then the Abgreifschicht is applied and then this entire arrangement of the already functioning position sensor is protected with an additional cover against external influences. This also has the advantage that a position sensor can be manufactured in this way in any length. If the above-mentioned elements of the position sensor consist of a flexible film, it is furthermore possible in an advantageous manner to produce in this way z. B. to manufacture the basic shape of the position sensor on a roll, wherein, depending on the desired length of a position sensor to be manufactured, the endless material can be easily cut and processed into a finished position sensor on. The further processing is carried out, for example, such that at the ends of the deflected piece of the position sensor end pieces are attached, wherein on one side of the end piece a cable is led out, which is connected to the resistance layer and the Abgreifschicht, wherein further at the end of the cable to Example, but not necessarily, a connector is present. About this connector, the position sensor can be connected to an evaluation device to which the position sensor is connected and which is adapted to detect the change in resistance in relative movement of the magnetic device to the position sensor.

In a further development of the invention, it is essential that the cover is a flux guide plate or comprises a flux guide plate. By such a flux guide plate, the magnetic effect can be amplified and the sensitivity of the position sensor increases or the magnetic force of the magnetic device associated with the size thereof can be reduced. In this embodiment, it is conceivable that the For example, a plastic housing in which a suitable flux guide plate is inserted and secured there. The attachment can be done for example by gluing or Verstämmen. In addition, it is conceivable to produce the cover in an injection molding process, wherein the flux guide plate with the plastic material which forms the cover, at least partially or in particular also completely encapsulated. In addition, it is alternatively conceivable that the cover is a rigid plastic part or a flexible plastic part, in particular a film, wherein the flux baffle is formed by an element which is part of whose position is to be detected. As an example, be noted here that the position sensor is attached to a seat rail of a seat of a vehicle, wherein by linear movement of the seat, the magnetic device is relatively moved relative to the position sensor, which is for example attached to the chassis (floor) of the vehicle.

In a further development of the invention, a combination of pick-off layer (pick-off film) and resistance layer takes place on an opposing partner film. The resistance side is constructed as follows. The basis is a film of amorphous metal. This can, but does not have to be thinly coated with a dielectric. This is thinly coated with a resistive paint. The pick-up foil as well as the partner foil with the applied resistance path also form contact springs and a magnet armature. The contact operation is carried out by an externally applied magnetic field, which is generated by a nearby brought permanent magnet or in an associated magnetic coil electrically. Due to the magnetic field, the two contact tongues (wave crest and wave trough) attract each other, touch each other at their vertex and thus close the electric circuit in which the resistance layer lies. As soon as the magnetic field drops or falls below a certain force (in particular when the magnetic device is moved vertically away from the position sensor), the contact opens due to the effect again, ie the trough dissolves from the wave crest. Since the contact tongues are attracted only in the area of the magnet, a potentiometric circuit is formed. However, when the magnet is moved longitudinally relative to the position sensor, the shaft of the pick-off layer and / or the resistance layer rolls over the length of the position sensor.

The position sensor according to the invention can find the following applications (without claim to completeness):

• Linear and Rotary 360 °

• Linear also wound axially around the shaft

• Mounting: straight, waves, curves, 3D installation

• Sensor is fixed and magnet is moved or vice versa.

• Application preferably in vehicles in: o Sunroof o Seat adjustment o Loading floor o Sliding door o Door o Tailgate o Convertible roof o Cylinder, Hydraulic and Gas o Wing, Spool adjustment o Window o Gear lever, Joystick o Strut o Fluid level o Backrest o Steering angle

o pedal travel and angle o switch Fuzzi logic

• Possible designs: o Straight o Waveform o Wavy o Curved o Linear o Rotary

In an alternative embodiment of the invention, it is conceivable that the at least one resistance layer and / or the at least one Abgreifschicht is formed like a finger. These fingers are aligned transversely to the longitudinal extent in a longitudinally formed position sensor and overlap at least partially so that they can come into contact with the action of the magnetic field of the magnetic device. This finger or comb-like configuration of the resistive layer or tapping layer is e.g. only in the lateral end region (ie, away from the region in which, for example, the Abgreifschicht is clamped in the spacer) or can also reach into the region in which the respective layer is attached to the respective element, or even extend.

Another significant advantage of the position sensor according to the invention is the fact that due to its construction and the choice of materials, a gluing of the resistive layer with the Abgreifschicht can not be done even if the magnetic device has been located at one and the same place for a long time. In this connection, it will be explained as an example that the position sensor is attached to a seat rail of a seat of a vehicle, wherein with the Position sensor, the position of the seat with respect to the chassis of the vehicle to be detected. For this purpose, the magnetic device is attached to the seat. Here is the case conceivable that the seat is not moved for a long time, since the vehicle is always controlled by one and the same driver. If, after a very very long time, the seat is moved out of its once set position, there is no reason to fear that the deflected shaft (wave trough or wave peak) of the tapping layer will adhere to the resistance layer. Due to the changing magnetic field due to the displacement of the seat also a Wegwandern of the wave crest or the wave trough from its original position, so that thereby the Abgreifschicht does not adhere to the resistive layer, although for the purpose of detecting the position and thus the resistance of the position sensor to the plant came.

As another new Anwedungsbereiche invention provided, either that the position sensor is designed as a potentiometer and a collector of the potentiometer is formed by an amorphous metal, or that the position sensor is designed as a reed switch and a switching contact of the reed switch is formed of an amorphous metal.

A collector formed of the amorphous metal is particularly advantageous for a non-contact and therefore wear-free potentiometer whose shaft rolls wear-free and replaces the previous scraping grinder. Likewise advantageously, the switch contacts are formed in a reed switch of the amorphous metal, so that also the wear-free is achieved. Also conceivable is a bending beam system with applied strain gauges. Amorphous metal foils are advantageous because they are very elastic and repeatable at a bending load. In combination with a magnetic device (for example a magnetic target), the following can be realized:

o Non-contact electronic switch (can replace mechanical reed switches), o Magnetic detector, o Non-contact displacement sensor, o Magnetic pulse counter, o Proximity switch.

Compared to normal reed switches, not only the switching position ON and OFF can be evaluated, but also all intermediate positions.

Further embodiments of the invention, from which the corresponding advantages result, are given in the subclaims. In addition, a description of the features of the subclaims follows in the following in connection with the figures.

In the figures, as far as shown in detail, a magnetic position sensor is provided with the reference numeral 1. In Figure 1 it can be seen that the position sensor 1 consists of an electrically non-conductive, non-magnetic support 2, on which a resistive layer 3 is arranged or fixed and spaced apart at least partially superposed a Abgreifschicht 4 is provided from an amorphous metal. The arrangement of the resistance layer 3 takes place, for example, in a recess in the carrier 2, wherein a further heel-shaped embodiment of the carrier 2 also receives the Abgreifschicht 4 in the form of the film of an amorphous metal. These two layers 3, 4, for example, laterally, partially or completely embossed with the carrier 2, glued or the like. Furthermore, in the form of a permanent magnet 5, a magnetic device is provided which is movable relative to the position sensor 1. The previously described Elements of the position sensor are protected by a cover 6, wherein the cover 6, for example, also made of an electrically non-conductive, non-magnetic material and is connected, for example, in the side regions with the carrier 2. Furthermore, the upper portion of the cover 6 consists of a flux guide plate to increase the magnetic effect of the magnet 5, which in turn results in an advantageous manner that the entire position sensor 1 can build flatter.

FIGS. 2 and 3 show different modes of operation of the position sensor 1. From FIG. 2 it can be seen that in the region of the magnetic device 5 the tapping layer 4 is pulled in the direction of the resistance layer, since the one pole of the magnetic device 5 pulls the tapping layer 4 in the direction of the resistance layer 3. This results in the recognizable in Figure 2 indentation. FIG. 3 shows that the tapping layer 4 is arranged on a lateral spacer 7 and is thus pulled onto the resistance layer 3 only parallel to the side of the spacer 7 in the region of the permanent magnet 5. Thus, when the magnet 5 is moved relative to the position sensor 1 (when viewing FIGS. 2 and 3 to the right or left), the magnet 5 attracts the tapping layer 4 in the form of the foil in a shaft only in the area of the permanent magnet 5 and presses them on the resistive layer 3, so that the respective position of the magnet 5 relative to the position sensor 1 can be detected.

In Figure 4 it is shown that the position sensor 1 consists of a Abgreifschicht 4, which is netisiert on the cover 6, which consists for example of a ferromagnetic material, on mag. This has the advantage that the lateral spacer 7 according to Figure 2 can be omitted. The permanent magnet 5 now attracts the tapping layer 4 in the form of the foil again in the form of a clean wave only in the region of the magnet 5 and thus presses it onto the resistance layer 3. The same structure is shown in FIG. 5, but the magnet 5 is reversed, so that its magnetic field presses the tapping layer 4 in the opposite direction, with the result that the tapping layer 4 can be deliberately pushed away by the resistance layer 3. This is for example advantageous if the reversed permanent magnet 5 is once moved over the entire extension of the position sensor 1 to bring the Abgreifschicht 4 in a defined starting position.

In FIG. 6, a further permanent magnet 8 is present analogously to the structure of the position sensor 1 described above, the polarity of the two magnets 5, 8 being opposite, and furthermore two resistance layers 3 with a tapping layer 4 located therebetween. Due to the reverse polarity of the two magnets 5, 8, the Abgreifschicht 4 is pressed or used in the region of the respective magnet once to the lower and once to the upper resistance layer 3. Thus, therefore, the position of the two magnets 5, 6 relative to the position sensor 1 can be detected.

A further embodiment of the position sensor 1 in section is shown in FIG. Here it can be seen that two resistance layers 3, 10, are present, between which the Abgreifschicht 4 is interposed in the form of the film. In this case, between Abgreifschicht 4 in the middle and the two resistive layers 3, 10, in turn, a distance is present, so that upon movement of the permanent magnet 5 relative to the position sensor 1 and as a function of polarity of the magnet 5, the tapping layer 4 is either pulled to the lower resistance layer 3 or pressed against the upper resistance layer 10. The magnet 5 is, for example, a permanent magnet or an electromagnet and may be designed in the form of a block, rod, ring, disc or the like, in each case coordinated with the position sensor 1.

In accordance with the structure according to FIG. 7, FIG. 8 shows that again there are two resistance layers 3, 10 in which the tapping layer 4 arranged therebetween can be attracted or pushed down by magnets 5, 11 arranged above and below the position sensor 1.

While in the previous figures always individual magnets 5, 8, 11, which were arranged on one side or on the same side of the position sensor, are shown in FIG. 9, a single magnet 12 is shown with alternating pole sequence within this magnet 12. From this within the single magnet 12 resulting pole sequence, the tapping layer 4 is again used or pressed either to the lower resistance layer 3 or the upper resistance layer 4.

FIG. 10 shows the structure of a position sensor 1, in which the at least one pick-off layer 4 is arranged between two spacers 13, 14, wherein these spacers 13, 14 are fixed by the cover 6 and the carrier, or a single spacer 15 is provided fixing the resistance layer 4 to the carrier 2 and to the cover 6, respectively. The configuration with the two spacers 13, 14 or the single spacer 15 corresponds to the embodiment shown in Figure 3, wherein in Figure 10, the peculiarity is that with the spacers (either 13, 14, or 15) not only a tapping 4 on Carrier 2 or on the cover 6 is set, but that two Abgreifschichten 4 are provided, which cooperate with the one resistive layer 3 (alternatively, a plurality of resistive layers). This means that the flat tapping layers 4 (or else only one tapping layer 4) is fixed laterally between the lateral end of the carrier and cover 6, floats freely in the region of the resistance layer 3 and is pulled in the direction of the resistance layer 3 only when the magnet acts.

FIG. 11 shows the position sensor 1 according to one of the embodiments as shown in FIGS. 1-10, wherein the position sensor 1 comprises a protective housing 16 made of a non-magnetic metal. This may be, for example, a metal such as aluminum, copper, brass, nickel silver or the like. Such a protective housing 16 has the advantage that thereby the position sensor 1 is much more robust, that its temperature resistance is increased and that it can be used for purposes of protection IP 69. The protective housing 16 surrounds the position sensor 1 at least partially (as shown in FIG. 11) or also completely, wherein, according to the embodiment in FIG. 11, flanges 17 are present on the sides which enclose the lateral areas of the carrier 2 and the cover 6. As an alternative to beading, the side regions can also be glued together, soldered, welded or the like.

The contacting of the resistance layer 4 and the Abgreifschicht 3 (sensor film) to the outside is sealingly, for example, by heat seal, conductive adhesive, a Nietpressverbindung, flanging shown or similar means / method. Alternatively, the contacting of the resistance layer 4 and the Abgreifschicht 3 (sensor film) to the outside can be done open by a conductive rubber, soldering, welding or the like.

FIG. 12 shows a further embodiment of the position sensor 1. Similar to the structure as shown in FIG. 1, this position sensor 1 has the carrier 2 provided with the resistive layer 3. Laterally spacers 13, 14 are present, in which the Abgreifschicht 4 is clamped. On the opposite side of the one-piece spacer 15 is available again. About this arrangement, the cover 6 is arranged. This basic structure of the position sensor 1, as already mentioned above, in any form or

be made of any length. In the event that a processing of the output signal of this position sensor 1 is desired, as shown in Figure 12, an interface 18, in particular at the end of the position sensor 1 are mounted. This interface 18 includes a housing with an evaluation electronics, not shown here, which in turn can be connected via cables, connectors or the like with a downstream electronic devices. For contacting the electronics present in the interface 18, corresponding contacts 19, here e.g. Pins, led out of the housing, wherein on the side of the position sensor 1 openings 20 are provided, which are prepared for example by punching. The position of the openings 20 corresponds to the contact pins 19, wherein the openings 20 and the associated pins 19, depending on their position with respect to the position sensor 1 have mechanical and / or electrical functions.

By installing an interface such as a voltage interface in the interface, the sensor data can be adapted to the most diverse requirements of customer evaluation units. The sensor is thus also protected from overloading and faulty switching on the part of the customer. Furthermore, damage to the sensor can be detected and reported to the evaluation unit.

FIGS. 13 and 14 show a further embodiment of the position sensor 1. Shown again is the at least one pick-off layer 4 and the resistance layer 3, in which case the resistance layer 3 has a ferromagnetic core. This has the consequence that upon exposure to the magnetic field of the permanent magnet 5, both the resistance layer 3 and the Abgreifschicht 4 wave-shaped deformed during relative movement of the permanent magnet 5. As a result, as in the embodiments described in the preceding figures,

ren shown and explained, formed by a magnetic field activated potentiometer. Since no contact grinding takes place, but only a contact of the wave trough or the wave crest of the resistive layer or Abgreifschicht wear is excluded. That is, the contact in the contact region of the resistive layer to the Abgreifschicht is actively closed and opened, resulting in the desired and detectable change in resistance.

In the figures, a permanent magnet 5 is always shown, with one pole pointing in the direction of the position sensor 1 and the other pole facing away from it. In addition, the magnet is always arranged on one side and or the other side of the position sensor 1. Alternatively, it is also possible in such a position sensor 1 in elongated or other design that the magnet partially ring-shaped or annular or similar geometric design (for example, horseshoe-shaped) surrounds the position sensor 1. In addition, it is conceivable to arrange the poles rotated 90 degrees to the orientation shown either in the longitudinal direction or in the transverse direction of the position sensor 1 to this. In addition to an alignment of the poles of the magnet parallel or transverse to the axis of the position sensor 1 also deviating arrangements are conceivable (oblique orientation), but not the preferred orientation, since in an alignment of the poles of the magnet parallel or transverse to the axis of Position sensors 1, the forces acting on the Abgreifschicht are greatest.

Claims

claims

1. Magnetic position sensor (1) consisting of an electrically nonconductive, nonmagnetic support (2) on which a resistance layer (3) and at a distance at least partially superposed a Abgreifschicht (4) is arranged, wherein the distance is selected such in that a contact between the resistance layer (3) and the tapping layer (4) arises from the action of a magnetic device (5) movable along the superimposed regions of the resistance layer (3) and the tapping layer (4), characterized in that the tapping layer (4 ) is an amorphous metal foil on which the force of the magnetic means (5) acts.

2. Position sensor (1) according to claim 1, characterized in that the Abgreifschicht (4) by a cover (6) is protected, wherein the cover (6) is connected to the carrier (2).

3. Position sensor (1) according to claim 1 or 2, characterized in that the cover (6) is a Flußleitblech or comprises a Flußleitblech.

4. Position sensor (1) according to claim 1 or 2, characterized in that the Abgreifschicht (4) via a lateral spacer (7, 13, 14, 15) on the carrier (2) and / or the cover (6) is arranged ,

5. position sensor (1) according to claim 1 or 2, characterized in that the Abgreifschicht (4) is magnetized at least partially detached on the cover (6) and the cover (6) consists of a ferromagnetic material.

6. position sensor (1) according to any one of the preceding claims, characterized in that at least two Abgreifschichten (4) are provided which cooperate with the resistance layer (3).

7. Position sensor (1) according to any one of the preceding claims, characterized in that the at least one Abgreifschicht (4) between two spacers (13, 14) or by a spacer (15) on the cover (6) and / or the carrier ( 2) is held.

8. position sensor (1) according to any one of the preceding claims, characterized in that the position sensor (1) comprises a protective housing (16) made of a non-magnetic metal.

9. position sensor, characterized in that the position sensor is designed as a potentiometer and a collector of the potentiometer is formed by an amorphous metal.

10. Position sensor, characterized in that the position sensor is designed as a reed switch and a switching contact of the reed switch is formed by an amorphous metal.