DE1274359B - Capacitive transmitter - Google Patents

Description

Capacitive transmitter Addition to patent: 1 248959 The invention refers to a capacitive transmitter with a number of fixed, AC-powered individual electrodes that are at a distance from one another, in whose electric field a scanning electrode arranged displaceably and capacitive is coupled to this, so that they are opposite each other when shifted a reference potential changing output voltage supplies that of their relative position corresponds, with the individual electrodes arranged electrically isolated from one another successively different voltages are supplied, according to patent 1 248 959, and a circuit arrangement with a number of taps to select one Reference potential is provided.

The patent 1 248 959 is based on the object of a specific Position of the scanning electrode a certain, to a relative position with respect to the to derive the potential belonging to a fixed row of electrodes, which is useful with is compared to a reference potential. By the present invention this is Task extended to the response characteristic, i. H. the relationship between the relative position and that derived between the scanning electrode and the reference potential To be able to optionally change the potential difference in order to give the capacitive transmitter a As universal as possible usability and adaptability to different measurement technology To create conditions.

It is known in the art, e.g. B. to display the pointer movement sensitive measuring instruments the capacitance of a capacitor or the self-induction a coil to change according to the movement of the pointer and thus an electric one To influence the resonant circuit.

In general, transducers for measuring and remote display of the Known liquid level of containers, where as in the case of the previously discussed Establishing a relative movement changes the capacitive resistance of a capacitor.

It was previously unknown for capacitive measuring transducers, of a number of fixed, spaced apart individual electrodes, one of the Relative position of a scanning electrode with respect to the row of individual electrodes associated with it Derive voltage and compare it with a reference potential. The the Problems underlying the invention are therefore in the field of capacitive measuring transducers completely unsolved. However, inter- or extrapolation devices were already in place known with those of certain reference potentials on the secondary windings of a transformer interpolated according to a quadratic function were derived. These intermediate values were used to form an almost continuous one quadratic or higher function on independent electrodes.

Although the choice of some components gives it a certain constructive quality There is a connection to the present invention, but no relation to the the object underlying the invention and that of a capacitive transducer generally to be fulfilled function.

The object of the invention is based on a capacitive measuring transducer of the type specified at the outset, achieved according to the invention in that the reference potential is derived from a voltage divider, which is connected to via a contact device selectable taps of individual secondary windings of a transformer connected is, and that the secondary windings are individually tapped at the voltage source lying voltage divider are connected.

With the capacitive one equipped in the manner specified according to the invention Transmitter On the one hand, there can be manufacturing-related irregularities the individual electrodes or their distance from one another balanced and on the other hand nonlinear functions are generated arbitrarily; there can also be changes the measuring range and the sensitivity can be made in a simple manner.

According to an expedient development of the invention, it is provided that the reference potential is set by means of a tap on the voltage divider.

Another expedient embodiment of the invention stands out by two voltage dividers connected in parallel and connected to the voltage source from each of which has several tapping points of different potential, contact devices for the selectable establishment of contacts with the points and devices for deriving of the reference potential from the potential difference between the through the contacts connected points.

Another useful embodiment of the invention consists in that the potentials at the fixed electrodes from taps on an inductive Voltage dividers are derived, which have different distances from each other. This refinement is used in particular to create a non-linear relationship between the position of the transmitter and the display.

In a further embodiment, an autotransformer can also be provided which is connected to a variable tap of an inductive voltage divider, the reference potential from a variable tap on the autotransformer is derived.

In the following, the invention is intended for example with reference to the drawing explained. The figures of the drawing represent simplified embodiments of the invention.

Fig. 1 shows schematically the basic structure of a capacitive measuring transducer, as shown in a similar form in the main patent. In a dashed The main parts of the capacitive transducer are indicated, consisting of a rectangle from a row of spaced apart individual electrodes 21 and a scanning electrode 22 movable relative to these. In the present case the individual electrodes 21 are arranged in a stationary manner, and the electrode 22 is movable. The individual electrodes are fed by an alternating voltage source 23 to which also an inductive voltage divider or a choke coil 24 is connected is. The choke coil 24 has a number of taps, each with one Electrode 21 are connected. These connections each form one of six secondary windings 25 of a transformer 26, whose primary winding 27 is also from the voltage source 23 is fed. -With this arrangement, the relative potentials at the individual electrodes 21 by the vector sum of the voltages at the taps of the choke coil 24 and the voltages occurring at the individual secondary windings 25 are determined.

By suitable selection of the taps and the size of the voltages on the secondary windings can be the type of potential gradient across the series of Individual electrodes 21 selected or set in a wide functional range will. In this way the gradient can be more linear or non-linear Law and follow it Corrections can be made to address the inaccuracies of the Transmitter 20 or in the arrangement of the taps on the choke coil 24 into account.

When the scanning electrode 22 travels in the manner described above moves the row of individual electrodes 21, so it decreases in relation to a reference point a potential that corresponds to their position relative to the individual electrodes of the transducer is equivalent to.

The arrangement and the selection of the reference point can be made in this way be that when the electrode 22 in relation to the individual electrodes 21 a predetermined Position reached, the potential of the electrode 22 is the same as that of the reference point is. Thus, the setting of the movable electrode can be made by the potential difference between the electrode and the reference point can be controlled, and the electrode can be brought into their predetermined position by moving it until the potential difference is zero.

One arrangement for creating the reference point is shown in FIG. 1 shown: A second inductive voltage divider 29 is supplied by the AC voltage source 23 fed and has a variable tap 30.

The potential difference between the tap 30 and the electrode 22 is fed to an amplifier 32 via a transformer 31. The amplifier 32 controls a reversible motor 34 which - as indicated by the line 35 - The electrode 22 in a corrective, balancing the potential difference to zero Sense moves until the electrode 22 is in its predetermined position.

In operation, the tap 30 is brought into a position that the desired position of the movable electrode 22 corresponds. If the electrode is not in the desired position, occurs between the tap 30 and the Electrode 22 has a voltage which is a function of positional deviation; these Potential difference can be referred to as an error signal. The error signal indicates by its size and phase position, both the extent and the direction of the distance the movable electrode from the desired position.

If the device is used to display the position of a moving component is used in relation to the setting of the tap 30, a display device 34 used or the motor 33 can be modified so that it controls the position of the tap 30 at the inductive voltage divider 29 changes until the error signal has fallen to zero is, as indicated by line 36. The position of the tap 30 can be displayed on any suitable display device.

In the circuit according to FIG. 1 becomes a correction of the response characteristic the device effected by the transformer 26 which cooperates with the transducer 20; however, this correction can be effected even more precisely by means of a similar transformer which interacts with the inductive voltage divider 29. An arrangement of this type is shown in FIG. 2 shown. As shown in FIG. 2 are the individual electrodes 21 is connected directly to the corresponding taps on the choke coil 24 by placing them Choke coil provided with a plurality of taps 37 and each of these taps direct is connected to an electrode 21. The voltage divider 29 also has taps 39, and these are connected to a series via secondary windings 25 of the transformer 26 connected by contact devices 40. Another voltage divider 41 can with two adjacent contacts 40 are connected. The reference point or the reference voltage is determined by selecting the contacts 40 with which the element 41 is connected, and also by an adjustable tap 42 on the element 41 elected. While the element 41 provides a rough adjustment or control, the adjustment tap 42 results in a fine adjustment.

F i g. 3 and 4 represent arrangements in which the dependency or response characteristic of a law deviating from linearity follows, which can be approximated to any function. The taps have 39 predetermined, non-uniform distances that result in a dependency function, which consists of a train of straight lines that approximately form a curve. The arrangement in FIG. 4 shows the use of a transformer 26 for correction the potentials occurring at the contacts 40. It can do this in the arrangements 3 and 4, an inductive voltage divider, such as that designated by 41 is applied will. F i g. 4 illustrates an example of another arrangement by which the Dependency characteristic can be changed. With this arrangement, the Voltage that is supplied to the primary winding 27 of the transformer 26 is changed. This voltage can be generated by connecting the primary winding to an intermediate tap of the voltage divider 29 be lower than the voltage of the voltage source 23 and can according to the arrangement in F i g. 4 for example through various settings of the tap 30 can be set.

According to Figure 4, this is done by connecting the primary winding of the Transformer between a point of the voltage divider 29 and the tap 30.

Guard rings or electrodes can be used together with the electrode 22 be used. F i g. 5 is an example in which the guard electrodes 44 are connected to each other and connected to the output of a unified amplifying amplifier 48. The amplifier 48 may form part of the amplifier 32.

In this way, the potential of the protective electrodes can be substantially to which the electrode 22 can be brought. The circuit according to FIG. 5 corresponds otherwise the in F i g. 1 without the transformer 26.

The protective electrodes or protective rings can on the other hand also with Be set with respect to the scanning electrode 22 or the individual electrodes 21, to give a desired effect. For example, the effective gap between the protective electrodes and the receiving electrode in relation to the voltages these elements can be changed.

In the case of the in FIG. 6 are also protective electrodes 44 used. These electrodes are held at ground potential, and so are they Means are provided by which the scanning electrode 22 also on the during operation or is held approximately at ground potential. For this purpose is the secondary winding another transformer 50 in series with the primary winding of the transformer 31 and earth switched. Both in Figs. 5 and 6 arrangements shown have the Advantage of good sensitivity.

In the circuit in Fig.7 there is a different arrangement for setting of the reference point. To the voltage divider 29 is another inductive one Voltage divider 52 connected in parallel, which has an adjustable tap 53. A transformer shown as an autotransformer consists of an induction coil 54, on which a tap 55 engages. The coil 54 is between the taps 53 and 30 is connected, and the reference potential is picked up at tap 55.

The potential at the reference point depends on the setting of the two adjustable taps 53 and 30, but the relative influence of the two settings depends on the tap ratio of the autotransformer with the coil 54.

F i g. 8 shows an arrangement by which a zero shift is achieved can be. As shown, the number of individual electrodes is the capacitive one Transmitter larger than the number of taps on the Drosselspule24, of which the Potentials are fed to the individual electrodes. Two contact devices 56 and 57 are used to select those individual electrodes that have a potential difference and the extent of the shift. The outer contacts on each end of the contact device 57 are interconnected so that as many separate Contact groups are formed, as taps on the coil 24 are present.

F i g. 9 shows an arrangement in which the individual electrodes 21 the capacitive transducer 20 supplied potential via taps on the choke coil 24 is supplied. The ends of the coil 24 are provided with two adjustable taps 58, 59 of the choke coil 29 is connected. Thus, by adjusting the relative position of the taps the size of the voltage across the choke coil 24 can be changed and thus also the size of the corresponding potentials on the individual electrodes of the potentiometer. An enhanced effect can be obtained by reversing the arrangement and the voltage divider 29 is connected to two taps on the coil 24.

After the circuit in FIG. 10 can have a similar splitting effect can be achieved by using an additional autotransformer 60, which is about an adjustable part of the voltage divider 29 is switched on. The tap 61 on the autotransformer then represents the reference voltage.

It is clear that these methods of division are combined with one another can be, for example by means of switches to set different division or scale ranges, sensitivities, shifts or the like, as desired to manufacture. Also the other modifications and embodiments described can be combined with one another in a suitable manner. For the sake of simplicity the correction transformer 26 has been omitted in some figures. To the more precise correction of the reference and electrode potentials is the use, however useful in all arrangements.

Claims (5)

Claims: 1. Capacitive transmitter with a number of fixed, AC voltage-fed individual electrodes that are at a distance from one another, in whose electric field a scanning electrode arranged displaceably and capacitive is coupled to this, so that when it is shifted, it faces one another a reference potential changing output voltage supplies that of their relative position corresponds, with the individual electrodes arranged electrically isolated from one another successively different voltages are supplied, according to patent 1 248 959, and a circuit arrangement with a number of taps to select one Reference potential is provided, d a d u r c h g e - indicates that the reference potential is derived from a voltage divider (41), which via contact devices (40) connected to selectable taps of individual secondary windings of a transformer is, and that the secondary windings are individually tapped at the voltage source (23) lying voltage divider (29) are connected. 2. Capacitive transmitter according to claim 1, characterized in that that the reference potential by means of a tap (42) on the voltage divider (41) is set. 3. Capacitive transmitter according to claim 1, characterized by two connected in parallel the voltage source (23) lying voltage divider, whose each has several tapping points of different potential, contact devices for the selectable establishment of contacts with the points and devices for deriving of the reference potential from the potential difference between the through the contacts connected points. 4. Capacitive transmitter according to claim 1, characterized in that that the potentials at the fixed electrodes from taps on an inductive Voltage dividers are derived, which have different distances from each other. 5. Capacitive transmitter according to claim 1, characterized by an autotransformer connected to a variable tap of an inductive voltage divider and that the reference potential is from a variable tap on the autotransformer is derived. Considered publications: German Patent Specifications No. 366 223, 872 643, 898 565; Swiss patents No. 336 608, 339 748.