DE1951942A1 - Measuring transducer, especially for capacitive sensors - Google Patents

Description

Measured variable converter especially for capacitive sensors. The invention relates to a transducer for deriving capacitance in particular capacitively effective encoder analog DC voltages with an encoder or the one to be measured AC power source feeding capacitor.

In measurement and control technology, capacitive sensors are known, the physical ones Quantities such as paths, pressure, angular rotations, humidity or the like. Detect and reproduced by analog values of their capacitance. For triggering measurement, control and The changes in capacity obtained in this way are difficult to control processes evaluate, and'it is therefore customary to convert the respective capacitance values into analog electrical To convert current or voltage values. Such transformations can be achieved by bridge circuits are caused, in which, in general, depending on capacity changes, the in the The voltage occurring in the bridge diagonal changes. In the case of the introduction of only one limb within the bridge, however, the voltage changes achieved are only within one very small working area linearly from the changes in the element to be monitored dependent, so that either special, complex equalization measures are required are, or only a narrow work area can be used, and the converter is a has only low sensitivity.

It is also known to have an alternating current-fed oscillating circuit whose circuit capacitance includes the capacitance to be measured9 and whose Amplitude is monitored.

Here, too, sufficient linearity can only be achieved with a narrow one Achieve part of a flank of the resonance curve of the oscillating circuit.

The difficulties of measured value conversion therefore have the capacitive values that are easy to create and that deliver reproducible values In practice, donors can only enforce to a limited extent: As soon as there is a linear relationship is necessary between the measured variable to be detected and transformed, for example when recording travel ranges, are mainly inductive or as a voltage divider effective donors are used, although they are more complex, more susceptible to failure and in their overall effect are less manageable.

The invention is based on the object of providing a transducer create that allows, with little effort, within a wide linear Working area to convert capacitance values into electrical voltage values.

This is achieved according to the invention by the to be measured Capacitor or the capacitive transmitter having, by an alternating current source Powered circuit via a current-controlled, operated in basic circuit The output circuit of the transistor feeds a rectifier arrangement. By feeding the capacitor having the capacitance to be determined by means of an alternating voltage, a current is generated via this, which of the to be determined Capacity is strictly proportional. The transistor operated in common base interferes with due to the low resistance of its path in the circuit, the linearity of the current following the capacity, while at the same time allowing a in turn to deliver this current proportional voltage, which is in a downstream Rectifier arrangement into a DC voltage proportional to the respective capacitance lets walk.

It was recognized that the base-emitter path with the encoder is essential. of the transistor to be connected in series and the supply of the rectifier arrangement from its collector from effect. It was recognized as advisable a generator working with constant voltage amplitude as an alternating current source to choose whose 'voltage constancy through regulation and / or choice of a low Internal resistance can be achieved.

The collector circuit of the transistor can be used to draw voltage Resistance and / or an oscillating circuit tuned to the frequency of the generator be assigned. As a rectifier arrangement, the clamping circuit with a downstream Tried and tested R-C sieve element. To reinforce the voltage gained as well as optionally Provision of a voltage and a current output has proven itself an operational amplifier downstream of the rectifier arrangement. This op amp can also be used to compensate for the output or open circuit voltage. Such compensation can be achieved by adding a whose opening voltage is arranged downstream of an adjustable compensation device will. The compensation can, however, already be carried out on the AC voltage side, by having the alternating current source in phase opposition to the measuring circuit an appropriately adjustable one Compensation circuit having a capacitor feeds; Measuring and compensation circuit are closed together via the base-emitter path of the transistor. as It was also recognized that the alternating current source feeds two converter circuits, which is worth imitating to let, the first of which is the encoder and the second of which an adjustable capacitor has, and their outputs are preferably made effective in opposite directions together will.

In more detail, the invention is based on the following description of FIG Embodiments explained in connection with these illustrative drawings. They show: FIG. 1 a capacitively effective, travel-dependently actuated sensor Figure 2 is a block diagram of a variable capacitor with downstream transducer and operated display device, Dg. 3 the circuit diagram of the transducer according to FIG. 2, FIG. 4 is arranged in a manner similar to the modulator according to FIG Operational amplifier FIG. 5 shows a measuring transducer having a compensation branch and FIG. 6 shows a measuring transducer f In equipped with a compensation channel Fig. 1 shows a capacitively effective transmitter in which a tube 1 has a core 2 and is isolated from it.

Under the influence of the measured variable to be recorded, the tube and core are against each other displaceable so that the resulting capacitance Cx of the encoder 3 is: Cx = CO + kx.

In Fig. 2, the block diagram of the transmitter 3 is arranged downstream Shown transducer, which is used to operate the display level 4. In the first Block an HF generator 5 is provided, which has a constant frequency and voltage amplitude swings. The HF generator 5 feeds the Stromkreis6, which contains the encoder 3: The HF current flowing in circuit 6 is both the frequency and voltage of the HF generator 5 as well as the respective capacity of the encoder 3 proportional; there frequency and voltage are kept constant, the developing HF current follows the capacity of the Encoder 3 linear. This HF current flows as an impressed control current into the low-resistance Input 7 of a base-operated transistor 8 and causes one in its collector circuit provided a working resistance proportional to the HF current HF voltage that is proportional to the controlling HF current and thus the capacity of the transmitter 3 is. The HF voltage is fed to the rectifier arrangement 9 and that in it The DC voltage caused by the HF voltage is used to control the display level 4. Accordingly, in the first stage of the transducer because of the capacity of the encoder 3 develops a proportional HF current that is in the following, formed by the transistor 8 stage in a reaction-free proportional HF voltage is converted. In another proportional one It is converted to direct voltage in the following rectifier arrangement 9.

A circuit diagram of the transducer is shown in Fig. 3 with neglect the direct current paths are shown. The encoder 3 is via a coupling coil 10 with connected to the HF generator 5 and feeds the emitter input 7 of the transistor 8.

An oscillating circuit 11 is arranged in the collector circuit of transistor 8, tuned to the frequency of the HF generator 5 and by means of the resistor 12 is attenuated. The diode 14 is coupled via the capacitor 13, and the Developing DC voltage is screened by means of the R-C element 15, the terminal 16 removable. The linearity of the transducer essentially depends on it from the fact that in the multiple reshaping only processes are used that are strictly linear within wide limits. This is how the high frequency current follows Any change in capacitance as long as the other resistances provided in circuit 6 are sufficiently small compared to the alternating current resistance of the encoder 3.

This condition can be met with the low-resistance input 7 of the base circuit operated transistor 8 in conjunction with the known order of magnitude the capacity of the encoder 3 by appropriate choice of the frequency of the HF generator 5 easily meet. The gain within the transistor 8 can be sufficient hold linear, and the rectifier arrangement 9 works linearly as soon as they is operated in the range of sufficient amplitudes. This means that at terminal 16 a DC voltage that can be used to initiate regulation or control processes and which, as FIG. 2 shows, is also used to achieve a linear display can be.

In many cases the interfering with the beginning or middle capacity of the encoder 3 is set at the terminal 16 basic voltage. The optional setting the voltage zero at a given capacitance value of the encoder can be achieved by that the rectifier arrangement 9 according to FIG. 4 is followed by a compensation device that the optional tap of a compensation voltage on a potentiometer 18 allowed and the demodulation voltage taken from the rectifier arrangement 9 merges with the compensation voltage via decoupling resistors. Supports is the process of compensation by a downstream operational amplifier 19, the optional wiring of both a voltage and a current output provides.

The compensation of the resulting basic value of the output voltage can also be effected according to Fig. 5 by the arrangement of a compensation branch, which is designed to be similar to the measuring branch and is out of phase with this from the HF generator 5 is fed. The HF generator feeds in a manner known from FIG. 3 via a coupling coil 20 the current branch of the encoder 3. A second, anti-phase coupling coil 21 feeds an adjustable compensation capacitor 22. The base points of the coupling coils 20 and 21 are connected to the input of transistor 8. Out of phase currents of the same amplitude can occur at the connection point of the coupling coils 20 and 21 to compensate a so that the low-resistance input 7 of the transistor 8 only with the non-compensated portion of the HF current, the differential current applied will. The compensation capacitor 22 can be set so that in a predetermined Position of the encoder 3 the full compensation is achieved and at terminal 96 the Tension disappears.

Another possibility of compensation is shown in FIG. 6. Both a measuring channel 23 and a comparison channel 24 are provided by the HF generator 5 fed. The measuring channel corresponds in its arrangement to that in Fig. -3 3, and the comparison channel that replaces of the transmitter 3 of the measuring channel 23 contains a compensation capacitor 22. The exits Both channels are connected to the input of an operational amplifier via decoupling resistors 19 connected. The voltages emitted by the channels are of opposite polarity, since the diode 14 of the MeRkanales 23 in the-Fig. 3 removable polarity used is, but the corresponding diode 25 of the comparison channel is provided with opposite polarity is. By adjusting the compensation probe 22 it can be determined that for a given operating point that from the measuring channel 23 to the operational amplifier 19 given measuring voltage according to the amount given by the balancing channel 24 Comparative voltage corresponds, however, is polarized in opposite directions, so that the two Compensating tensions for each other. Furthermore, depending on the direction of the Migration of the capacity of the encoder 3 from the working point positive or negative Signals. Due to the similar structure of both channels, temperature and age-related Drift phenomena of the transducer compensated. This only at the exit of the The compensation made by the measuring transducer requires a somewhat higher one Effort, but the measuring transducer constructed in this way is characterized by high linearity the end. Last but not least, this is achieved by the fact that in the work area both the Diode 14, as the diode 15, is not driven into the area of the kink in the characteristic curve will.

The invention allows the construction of simple, strictly linear working Measuring transducers for measuring or converting the capacitance of capacitors, in particular Encoders, and is particularly suitable for controlling display systems as well for actuating control and regulating circuits.

Claims (10)

Claims X transducer for deriving the capacitance, in particular one capacitively effective encoder analogue DC voltages with one that feeds the encoder AC power source, which is not shown in the encoder (3) having circuit (6) a current-controlled, operated with basic maintenance Transistor (8) is provided, the output circuit of which is a rectifier arrangement (9). 2. Measurement transducer according to claim 1, d a d u r c h g e k e n n z E i c h n e t »that with the transmitter (3) the base-emitter path of the transistor (8) is connected in series, the collector of which feeds the rectifier arrangement (9) causes. 3. Measurement transducer according to claims 1 and 2, d a d u r c h g e k e n n z e i c Ii n e t that as an alternating current source a with constant voltage amplitude working generator (5) is provided. 4. Measurement transducer according to claims 1 to 3, d a d u r c h g e k It is noted that the collector circuit of the transistor (8) has a resistor (12). 5. Measuring transducer according to claims 1 to 3 or 4, d a d u r c h g e k e n n n z e i c h n-e t that the collector circuit of the transistor (8) has an oscillating circuit (11) tuned to the frequency of the generator (5). 6. Measurement transducer according to claims 1 to 5, d a d u r c h g e k E n n z e i c h n e t that as a rectifier arrangement (9) a clamping circuit (capacitor 13, diode 14, 25) with a downstream R-C filter element (15) is provided. 7. transducer according to claims 1 to 6, d a du r c h g e k e n n z e i c h n e t that the rectifier arrangement (9) is an operational amplifier (19) is subordinate. 8. measuring transducer according to claims 1 to 7, d a d u r c h characterized, that the rectifier arrangement (9) has an adjustable output voltage Compensation device (17) is arranged downstream. 9. measuring transducer according to claims 1 to 8, d a d u r c h g e k It is indicated that the alternating current source is in phase opposition to the measuring branch a compensation branch having an adjustable compensation capacitor (22) feeds, and that the measuring branch and the compensation branch jointly via the base-emitter path of the transistor are closed. 10. Measurement transducer according to claims 1 to 9, d a d u r c h g e k It is noted that the alternating current source (HF generator 5) has two channels feeds the first, the measuring channel (23), the encoder (3) and the second, the comparison channel (24), an adjustable compensation capacitor (22), and their outputs are preferably made effective in opposite directions together.