RU2037770C1 - Measuring converter of nonelectric values - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: measuring converter of nonelectric values has source of reference voltage, commutator, differential capacitive pickup and amplifier, phase-sensitive demodulator connected to it, comparator and integrator. Common electrode of capacitive pickup is linked to output of integrator and two other electrodes to inputs of differential amplifier which are connected to input of integrator through resistors. Compensation unit allows error related to misalignment of electrodes of differential capacitive pickup to be reduced. EFFECT: reduced errors of measuring converter. 2 cl, 1 dwg

Description

 The invention relates to instrumentation and can be used to measure linear and angular displacements.

Known capacitive displacement meter containing an alternating voltage generator, working and reference capacitors, amplifiers, demodulators, a control pulse shaper and a division unit [1]
The disadvantage of this device is the relatively high complexity, reducing the reliability of its operation.

Closest to the invention is a non-electric quantity converter with a capacitive sensor, comprising a reference voltage source with a switch, an amplifier whose input is connected to one of the capacitive sensor electrodes, and an output with a phase-sensitive demodulator, a reference capacitor and a square-wave generator, while the output of the phase-sensitive demodulator connected through the second switch to the second plate of the reference capacitor. The output of the square-wave generator is connected to the control inputs of the switches and the phase-sensitive demodulator [2]
The disadvantage of this measuring transducer is the presence of a high level of alternating voltage at the electrodes of the capacitors, and one of the voltages varies over a wide range, which creates cross fields of mutual interference. In addition, the capacitive sensor is a capacitor of variable capacitance, and an exemplary capacitor of constant capacitance, so it is difficult to technologically fabricate them so that the ratio of their values does not depend on temperature, humidity, etc.

 The disadvantage is the error associated with a change in the value of the total capacitance of the capacitors, which depends on the non-parallelism of the moving electrode of the sensor relative to the stationary one.

 The proposed measuring transducer containing a reference voltage source, a controllable switch, a capacitive sensor, an amplifier and a phase-sensitive demodulator connected to its output, is supplemented by an integrator, three resistors and a comparison unit, the capacitive sensor and amplifier are made differential, the switch output is connected through the first resistor to the integrator input, the output of which is connected to the common electrode of the capacitive sensor, the second and third electrodes of this sensor are connected to the corresponding inputs differential amplifier, the second and third resistors are connected to the second and third electrodes of the differential sensor, respectively, and the input of the integrator, the input of the comparison unit is connected to the outputs of the switch and integrator, respectively, and its output is with the control input of the switch and phase-sensitive demodulator.

 In this measuring transducer, under the high potential of a constant value, only the common electrode of the differential capacitor is located, and the others under almost zero, which eliminates mutual interference between the capacitors.

 The measuring transducer can also be equipped with a unit that compensates for the error caused by the non-parallelism of the electrodes, made in the form of an operational amplifier and a compensating capacitor, connected between the output and the input of the integrator.

 In the case of distortion of the electrodes of the differential capacitor, compensation is made for changes in the capacitance caused by the distortion.

 The drawing shows a block diagram of a measuring transducer.

It contains a reference voltage source 1, connected through a switch 2 to an integrator 3 through a first resistor 4. The integrator output is connected to a common electrode 5 of the differential capacitive sensor, and its second C _p1 6 and third C _p2 7 electrodes are connected to the corresponding inputs of the differential amplifier 8, connected to a phase-sensitive demodulator 9.

Each of the inputs of the differential amplifier 8 is connected through an appropriate resistor R ₆ 10 and 11 to the input of the integrator 3. The outputs of the integrator 3 and switch 2 are connected to the input of the comparison unit 12, the output of which is connected to the control inputs of the switch 2 and the phase-sensitive demodulator 9.

The measuring transducer is equipped with a compensating unit 13 connected between the common element of the sensor 5 and the input of the integrator 3 and consisting of a series-connected operational amplifier 15, resistors R ₁ 14 and R ₂ 17 and a compensating capacitor C _to 16.

Compensating capacitor C _to 16 can be turned on at the input of the operational amplifier 15. In this case, two additional resistors are introduced, one between the output of the operational amplifier 15 and the input of the integrator 3, the other between the common bus of the measuring transducer and the common point of the resistor R ₁ 14 and the compensating capacitor C _to 16.

The converter operates as follows. The integrator 3 integrates the DC voltage available at its input, determined by the reference voltage source and switch 2. The voltages from the outputs of the switch 2 and integrator 3 are supplied to the input of the comparison unit 12. When the output voltage at the output of the integrator 3 reaches the threshold, the comparison unit switches the switch 2, applying a constant voltage of a different polarity to the input of the integrator 3, a new integration and comparison cycle takes place. As a result, two synchronous voltages are formed: rectangular at the input of the integrator 3 and triangular at its output. Resistors R _about 10 and 11 are usually the same in size and significantly less than the value of the resistor 4.

The capacitances of the second C _p1 6 and the third C _p2 7 electrodes of the differential sensor are selected so that they are current generators with respect to the resistors 10 and 11 connected in series with them.

In this case, with the same capacitance values C _p1 6 and C _p2 7 at the inputs of the differential amplifier 8, a rectangular voltage of the same amplitude is set. As a result, the potential at the input of the phase-sensitive demodulator is zero. At C _p1 ≠ C _p2 , an output signal appears at the output of the measuring transducer, the value of which is proportional to this difference and practically independent of the ambient temperature, humidity, and the change in the distance between the centers of the movable and fixed electrodes.

To compensate for the error caused by the non-parallelism of the electrodes of the differential capacitive sensor, an additional capacitance C _to 16 is placed on the same plates on which the capacitive sensor is made, and when they are skewed, when the capacitance values increase, using the operational amplifier 15 and resistors 14 and 17 are subtracted from the capacitance of the sensor 5, the compensation capacitance C _to 16 in a ratio determined by the ratio R ₂ / R ₂ .

 The proposed structural diagram of the measuring transducer can be used not only for capacitive sensors, but also for resistive and inductive ones.

Claims (2)

 1. MEASURING CONVERTER OF NON-ELECTRIC VALUES, comprising a reference voltage source, a controlled switch connected to its output and a capacitive sensor, an amplifier and a phase-sensitive demodulator connected to each other, characterized in that it is equipped with an integrator, three resistors and a comparison unit, the capacitive sensor and amplifier are made differential, the output of the switch is connected through the first resistor to the input of the integrator, the output of which is connected to the common electrode of the capacitive sensor, the second and third electrodes of this sensor are connected to the corresponding inputs of the differential amplifier, the second and third resistors are connected between the second and third electrodes of the differential sensor and the integrator input, and the comparison unit is connected by two inputs to the outputs of the switch and integrator, respectively, and the output to the control input of the switch and phase-sensitive demodulator .  2. The Converter according to claim 1, characterized in that it is equipped with a compensating non-parallel electrode unit made in the form of an operational amplifier and a series-compensating capacitor connected to it and connected between the output and input of the integrator.

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