DE2442919A1 - Field plate motion pickup - which is used for transmission of test values has a differential field plate with two magnetic field sensitive resistors - Google Patents

Abstract

The two resistors are connected to form a voltage divider, and a magnet is provided, which is movable with respect to the field plate. a compensation resistor (RF) is inserted between the junction point (3a) of the two resistors (R1, R2) and the field plate output (3b) may be connected in turn to the input of an amplifier (V) with a negative feed-back resistor (RK); the compensation resistor provides the whole input resistance of the amplifier or a part of it; and the test value, which is almost completely independent from temperature variations, is collected from the amplifier output.

Description

Field plate displacement transducer, in particular for remote transmission of measured values The invention relates to a field plate transducer, in particular for remote transmission of measured values, consisting of a differential field plate with two magnetic field-dependent resistors, which form a voltage divider, and one that is movable with respect to the field plate Magnetic element.

In metrology it is known to use field plates or

Use differential field plates as displacement transducers. Here will be the two magnetic field-dependent resistances of the differential field plate with the help influenced by a magnet. Corresponds to the path of the magnet in relation to the field plate their change in resistance, which can be measured and displayed. In the normal Such a displacement transducer has an accuracy of temperature ranges from -20 to t70 ° of) 25%.

This considerable measurement error is based almost exclusively on Temperature influences, it should be noted that the temperature coefficient of the field plates is not constant is, but changes in the magnetic field and depending on the field strength. There In addition, the field strength of a magnet is temperature-dependent, also contributes to it Temperature coefficient contributes to the inaccuracy of field plate displacement transducers at.

On the one hand, these circumstances mean that the output signal of the Encoder no longer has a linear relationship with the path of the magnet and they mean that a shift in the zero point of the display can also occur.

To avoid these disadvantages, it has already been tried that Connect the field plate with temperature-dependent resistors. This way out however, has not been able to satisfy, since in this way only the temperature coefficient of the encoder can be compensated in a certain position of the magnet. More than a slight improvement in accuracy is due to the variable temperature coefficient of the field plates cannot be reached in this way. Attempts have also been made to avoid at least the error of the zero point display by using instead of a Magnet a pin made of silver steel was used. The use of silver steel or similar materials as a control organ for the field plate is because of the too small changes in resistance of the field plates -; Man can be done by increasing the gain of a downstream amplifier compensate for the very small output signals of the field plate encoder, however the reinforcement, which is necessary anyway, is already so great that the temperature behavior other components and the leads in the event of a further sharp increase in Amplification would have too great an influence on the measurement result.

The invention is based on the object of the display accuracy of displacement transducers working with field plates and of the usual ones To make changes in ambient temperatures largely free.

Based on a field plate displacement transducer of the type described above Art, the inventive solution to this problem is that between the connection point of the two resistors and the output of the differential field plate a compensation resistor switched and in the '.; Eggeber is housed and that the differential field plate an amplifier coupled back through a resistor is connected downstream, its Input resistance wholly or partially forms the compensation resistance and on the output of which the essentially temperature-independent measured value can be tapped.

The principle of this solution, which is a very significant linearization the display provides, is that a temperature or magnetic field dependent Compensation resistor forms the input resistance of an operational amplifier and in connection with a negative feedback resistor of this amplifier the slope of the amplifier controls. Including those summarized in the subclaims Training options for the compensation resistor can be - related to -that Output signal - any curve of the temperature coefficient of the field plate resistors compensate, so that the field plate encoder has a large area of application in the Measurement technology is opened. The means required to solve the task are also low as the adjustment effort, so that the solution according to the invention is also more economical Respect is beneficial.

A further increase in the measurement accuracy, especially in the area of the Zero point is achieved in that either the magnetic element made of a bipolar circular shape that can be rotated with respect to the differential field plate Magnetic plate consists, or that the magnetic element is opposite to the differential field plate is displaceable four-pole magnetic plate, the poles of which are opposite each other crosswise. When the zero point is displayed, these magnetic elements are centric with their magnetically neutral Zone arranged above the field plate.

The invention is described below with reference to the drawings illustrated preferred embodiments explained in more detail. They show: Fig. 1 is a basic circuit diagram of a known differential field plate; Fig. 2 is a schematic Circuit diagram of an embodiment of the field plate displacement transducer using a Field plate acc.

Fig. 1; Fig. 3 is a plan view of an embodiment of a Field plate transducer with rotatable magnet; and FIG. 4 is one similar to FIG Top view of a field plate displacement transducer for linearly moving magnets.

The differential field plate shown schematically in Fig. 1 contains two magnetically influenceable field plate resistors R1 and R2. These resistances are in series at a voltage divider point 3a. The field plate has two entrances 1, 2 for applying a DC voltage and an output 3b, which is connected to the voltage divider point 3a is connected. Change depending on the position of the magnet (not shown in FIG. 1) the resistors R1 and R2, so that at the output 3b the position of the magnet corresponding output signal can be removed is. The size of this signal but is also dependent on the respective ambient temperature.

With the circuit shown in Fig. 2, temperature influences largely eliminate. On the left in the circuit are the two field plate resistors again R1 and R2 can be seen. Between the voltage divider point 3a and the output 3b lies a compensation resistor RF Inputs 1 and 2 are positive and negative respectively Pole of a voltage source. One input of the operational amplifier is on the one hand at the output 3b of the differential field plate and is on the other hand via a negative feedback resistor RK connected to the output of the amplifier. The other input of the amplifier is connected to the wiper of a potentiometer, which in turn is connected to the inputs 1 and 2 lies. The output signal of the amplifier can be measured by a measuring instrument M displayed or forwarded elsewhere for evaluation. With the potentiometer the zero point of the display is set.

The compensation resistor RF is a temperature-dependent resistor, d. H. an NTC, PTC or a field plate or

Combination of these components. He is in the field plate encoder built in and is therefore subject to the same temperature conditions as the resistors R1 and R2.

When the magnetic element influencing the encoder, not shown in FIG a position in the geometric center of the differential field plate as already assumes described, the signal voltage UA is at the output of the operational amplifier Zero. In this case, a shift in the ambient temperature does not cause any changes the resistance ratio of R1 to R2. However, as soon as the magnetic element is moved or is rotated, changes the magnetic flux to which the two resistors R1 and R2 are exposed so that there are different temperature coefficients.

These are coming but at the output of the amplifier no longer applies, since the amplifier from the compensation resistor RF in Connection with the Geyenkouplungsverbindungen RK is controlled so that the output signal is a practically accurate representation of the movement of the magnetic element. As already is indicated by appropriate choice of NTC and / or PTC resistors, if necessary in connection with a further field plate every temperature error curve within compensated for a given wide temperature range.

Also about a zero point shift due to temperature influences be sure to exclude the field plate displacement transducers according to FIGS. 3 and 4 with equipped with a magnetic element that has so far occasionally occurred Prevents errors. The resistors R1 and R2 are usually in a field plate body 10 housed, the mounting holes 12 and the three connections already mentioned 1, 2, 3b. The resistors R1 and R2 are shown in Figs.

3 and 4 dashed, the compensation resistor RF is not here shown. Centrally above the field plate body 10 is located in the embodiment according to FIG. 3, a circular two-pole magnetic element 14 which is rotatably mounted there and can be rotated by an actuator to generate an output signal.

If the magnetic element 14 is now rotated about its center point, it takes place a symmetrical influencing of the resistors R1 and R2 takes place.

In the embodiment according to FIG. 4, a four-pole magnetic element is used 18 used, in which the magnetic poles are diametrically opposed on an imaginary cross. This version is for the implementation of Linear movements in electrical Signals thought. With a linear displacement of the magnetic element 18 from the illustrated The zero position, in turn, has a symmetrical influence on the resistors R1 and R2 take place by rivers of equal size, but oppositely directed, so that here, too, the temperature coefficient of the magnetic element has no influence on the zero point on the display and on the measured values. In this arrangement, the path of the Control magnets not as planned by the manufacturer of the field plates, but in parallel across the field plate.

In addition to the compensation effect achieved in this way, a Training according to FIGS. 3 and 4, the additional advantage of enlarging the Output signal reached.

Claims (8)

Expectations Field plate displacement transducer, especially for remote transmission of measured values, consisting of a differential field plate with two magnetic field-dependent resistors, which form a voltage divider, and one that is movable with respect to the field plate Magnetic element, characterized in that between the connection point (3a) the two resistors (R, R2) and the output (3b) of the differential field plate Compensation resistor (RF) is switched and housed in the encoder and that the differential field plate is an amplifier with negative feedback through a resistor (RK) (V) is connected downstream, the input resistance of which is wholly or partially the compensation resistor forms and at its output the essentially temperature-independent measured value can be tapped is. 2. Position transducer according to claim 1, characterized in that the compensation resistor (RF) lies in the area of action of the magnetic element (14; 18). 3. Position transducer according to claim 1 or 2, characterized in that the Compensation resistor (RF) is formed by an additional field plate. 4. Position transducer according to claim l or 2, characterized in that the Compensation resistor (RF) is an NTC resistor. 5. Position transducer according to claim 1 or 2, characterized in that the Compensation resistor (RF) is a PTC resistor. 6. Position transducer according to claim 1 or 2, characterized in that the Compensation resistor (RF) from a network of one or more field plates and / or one or more NTC resistors and / or one / more PTC resistors consists. 7. Position transducer according to one of claims 1-6, characterized in that that the magnetic element consists of a two-pole, opposite to the differential field plate rotatable circular magnetic plate (14). 8. Position transducer according to one of claims 1-6, characterized in that that the magnetic element is opposite to the differential field plate transversely to its longitudinal axis displaceable four-pole magnetic plate (18), the poles of which are opposite each other crosswise. Blank page