RU2389977C1 - Measuring transducer - Google Patents

Abstract

FIELD: physics. ^ SUBSTANCE: measuring transducer has a differential measuring circuit whose input is connected to the lead for connecting an excitation source, and the said circuit generates two signals. Difference between these signals is functionally related to the quantity measured. Switch outputs are connected to outputs of the differential measuring circuit. A resistor and two capacitors are connected in the negative feedback circuit of the operational amplifier. The first capacitor is connected between the noninverting input of the operational amplifier and the common wire. ^ EFFECT: increased sensitivity of the measuring transducer. ^ 3 cl, 1 dwg

Description

The invention relates to the field of measurement technology and can be used in instrumentation and automation for the construction of measuring transducers of electrical and non-electrical quantities in mechanical engineering, the chemical and food industries, for example, for inductive sensors of rotation angle of rotational type viscometers used in measuring viscosity of Newtonian and non-Newtonian fluids ( polymer solutions).

A known measuring transducer (see, for example, Prince Levshina E.S., Novitsky P.V. Electrical measurements of non-electric quantities: (Measuring transducers). Textbook for universities. - L.: Energoatomizdat. Leningrad. Department, 1983 Fig. 3-8 and 3-9, pp. 57-59), containing a measuring circuit in the form of at least two resistances connected to the source of the exciting signal, and an operational amplifier with negative feedback, the output voltage of which contains information about the value of the measured value. The disadvantage of such a measuring transducer is the formation of the output signal in the form of a voltage of the same type as the excitation signal. This complicates the use of such measuring transducers when using reactance in the measuring circuit, as it requires the use of phase-sensitive devices for processing the measuring signal.

Closest to the claimed one, which can be taken as a prototype, is a measuring transducer (see, for example, Prince Friden J. Modern sensors. Reference book. - M .: Technosphere, 2006, Fig. 7.10, p. 289), containing a differential measuring circuit made, for example, in the form of a differential transformer and connected to the source of the exciting generator, a synchronous demodulator in the form of a switch controlled by a phase shifting device signal, a smoothing RC filter and an operational amplifier with negative feedback ligature.

The disadvantages of this measuring transducer are the low sensitivity due to the low coefficient of energy use of the useful signal due to the operation of the measuring circuit in idle mode and the loss of signal energy in the smoothing RC filter, the complexity of the circuit due to the presence of a phase shifting device, and the lack of balancing with using an electrical signal.

The objective of the invention is to increase the sensitivity of the measuring transducer, simplifying its circuit, as well as providing the possibility of balancing with an electric signal.

The solution is achieved by the fact that in a measuring transducer containing a differential measuring circuit, a switch connected to it and an operational amplifier with a resistor in the negative feedback circuit, the inputs of the operational amplifier are connected to the outputs of the switch and a capacitor is connected in parallel with the feedback resistor.

The claimed technical solution differs from the prototype in that the capacitor is connected in parallel with the resistor of the negative feedback circuit, and the inverting and non-inverting inputs of the operational amplifier are connected to the outputs of the switch.

The claimed technical solution differs from the prototype in that the inverting and non-inverting inputs of the operational amplifier are connected to the outputs of the switch, and the second capacitor is connected in parallel with the resistor of the negative feedback circuit.

The drawing shows a circuit diagram of the proposed measuring transducer. The circuit contains a series-connected measuring circuit 1, switch 2 and operational amplifier 3 DA1, between the non-inverting input of which and the common wire the first capacitor 4 C2 is connected, and between the output and the inverting input there is a feedback resistor 5 R2 and a second capacitor 6 C1 connected in parallel.

The measuring circuit 1 in the described example is formed by two resistances 7 Z1 and 8 Z2, the connection point of which is connected to terminal 9 for connecting the excitation source. At least one of these resistances is a parametric measuring transducer and has a resistance dependent on the measured value. In this case, the resistances 7 and 8 are inductive, capacitive or resistive primary measuring transducers of the measured value.

Switch 2 in the simplest version is made in the form of four diodes 10 VD1, 11 VD2, 12 VD3 and 13 VD4, connected in a ring circuit. It is also possible to use a transistor switch controlled, for example, by the excitation signal of the measuring circuit 1. The output terminals 14 and 15 of the switch 2 are connected to the non-inverting and inverting inputs of the operational amplifier 3.

In parallel with the first capacitor 4, a resistor 16 R3 can be connected.

A current driver 17 can be connected to the inverting input of the operational amplifier 3, made in this case in the form of a resistor, through which a current is supplied from the output 18 to connect the bias voltage source for electrical balancing of the measuring transducer.

The measuring transducer operates as follows. Under the action of an external source of alternating voltage or current connected to the input 9 of the measuring circuit 1, alternating currents flow through the resistances 7 and 8, which depend on these resistances. The switch 2 switches the indicated currents in such a way that the charge of each of the capacitors 4 and 6 is carried out alternately by the current of one resistance 7 or 8, and the discharge - by the current of the other. When the switch 2 is designed as diodes, the positive half-waves of these currents flow through the diodes 10 and 13, respectively, charging the capacitors 4 and 6. The negative half-waves of the currents of the mentioned resistances flow respectively through the diodes 11 and 12, discharging the capacitors 4 and 6.

In the balanced state of the measuring circuit 1, the resistances 7 and 8 are the same, the currents flowing through them are equal to each other. Therefore, the charge and discharge currents of the capacitors 4 and 6 are the same, the voltage on them, as well as the output voltage of the operational amplifier 3 are equal to zero.

When any resistance 7 or 8 of the measuring circuit 1 changes, the corresponding current changes. The equality of the charge and discharge currents of capacitors 4 and 6 is violated, which leads to a change in them constant voltage, and therefore to a change in the output voltage of the operational amplifier 3.

For example, when the resistance 7 increases, the positive half-wave current, charging the capacitor 6 through the diode 10, and the negative half-wave current, discharging the capacitor 4 through the diode 11, decrease. If the resistance 8 remains unchanged, then the currents flowing through the diodes 12 and 13 practically do not change. The current output 14 of the switch 2 will contain a negative (flowing) constant component, and the current output 15 of the switch 2 will contain a positive (flowing) DC component. The output current 15 charges the capacitor 4, creating a constant voltage component at the resistances 7 and 8, which partially balances the influence of a decrease in the resistance current 7. At the same time, the flowing DC component of the output current 14 increases, which flows further through the resistor 5. As a result, the output of the operational amplifier 3 a voltage is formed, determined by a change in the resistances of the measuring circuit 1.

With a simultaneous increase in resistance 7 and a decrease in resistance 8, similar changes in currents and voltages manifest themselves to a greater extent.

In the absence of a constant component in the excitation signal of the measuring circuit 1 at terminal 9, the voltage across the capacitor 4 in the balanced state of the measuring transducer is practically zero, and there is no need for a resistor 16.

If a voltage containing a constant component, for example, unipolar, is used as an excitation signal, then with equal resistances of resistors 5 and 16 in the balanced state of measuring circuit 1, the same voltage drops are created on them, equal to the constant component of the excitation voltage at terminal 9. Due to the fact that in the circuit the specified voltage drops are subtracted, the output voltage of the operational amplifier is zero. Changing the resistances 7 and 8 leads to the formation of different voltage drops across the resistors 5 and 16, and the output of the operational amplifier produces a voltage proportional to the deviation of the measured value from the value that was with the balanced state of the measuring transducer.

A zero value of the output voltage (balancing of the measuring transducer) for resistance equal to each other 7 and 8 (unbalanced measuring circuit 1) can be obtained by introducing a current shaper 17, made, for example, in the form of a resistor, into the measuring transducer circuit and setting the corresponding voltage at terminal 18 or by adjusting the resistance of the current driver 17. In this case, the difference in the currents of the resistances 7 and 8 is compensated by the current of the current driver 17. The balancing effect is ensured by By connecting the current shaper 17 to both the inverting and non-inverting inputs of the operational amplifier 3. By connecting the current shaper 17 to the output circuit of the switch 2, balancing is achieved using direct current, which facilitates the remote control of the measuring transducer. The current driver 17 can also be made in the form of a nonlinear resistance — an adjustable stabilizer or a current source, for example, based on a diode optocoupler, a transistor connected in a circuit with a common base, etc.

When using inductances and / or active resistances as resistances 7 and 8, an alternating voltage of sinusoidal, rectangular, sawtooth or other shape can be applied to terminal 9. The amplitude values of the resistance currents 7 and 8 do not reach large values, and due to the integrating action of capacitors 4 and 6, the ripple of the output voltage is quite small. When using capacitances 7 and 8, it is possible to apply an alternating voltage of a sinusoidal, sawtooth, trapezoidal shape to the clamp 9, i.e. one that does not have abrupt voltage drops creating current pulses with large amplitudes through the capacitance.

As the resistances 7 and 8 of the measuring circuit 1 can be used differential inductive, capacitive and resistive primary measuring transducers. As one of the resistances 7 or 8, it is possible to use single primary measuring transducers. In this case, as another resistance (8 or 7, respectively), the comparison resistance is turned on. The latter can have any nature of reactivity, however, with the same nature of reactivity, the minimum dependence of the readings on the frequency of the exciting signal and the ripple of the output voltage is ensured.

Depending on the performance of the resistances 7 and 8 of the measuring circuit 1, the proposed measuring transducer can perform various functions, in particular:

- differential inductive (eddy current) measuring transducer (when performing resistances in the form of coils of an inductive sensor);

- differential capacitive measuring transducer (when using capacitive sensor elements as resistances);

- a measuring frequency to DC voltage converter (when using elements with different types of reactance as resistors and applying an alternating voltage to the input 9 with a measured frequency);

- a measuring transducer of increment of the impedance (with any nature of reactivity) to a constant voltage.

From the foregoing, it is obvious that in comparison with the prototype of the proposed measuring transducer has the following advantages:

- a simpler circuit due to the exclusion of the phase-shifting device and the implementation of the switch on diodes instead of transistors;

- a greater coefficient of use of the useful signal due to the fact that the difference in the resistance currents 7 and 8 of the measuring circuit 1 completely flows through the feedback resistor 5, creating an output voltage. Due to this, a higher sensitivity of the measuring transducer is achieved;

- when connecting the current shaper 17, the balancing of the measuring transducer by a DC signal is achieved.

The use of the proposed technical solution in the measuring transducer of a rotational type viscometer for measuring the dynamic viscosity of polymer solutions, characterized by a low energy of the useful signal, made it possible to simplify the circuit with respect to the prototype, increase the accuracy and sensitivity of the device, and also implement automatic compensation of the additive error.

Claims (3)

1. A measuring transducer containing a differential measuring circuit, the input of which is connected to the output for connecting the excitation source, and generating two signals, the difference of which is functionally related to the measured value, a switch, the inputs of which are connected to the outputs of the differential measuring circuit, an operational amplifier, into a negative circuit the feedback of which a resistor is included, and two capacitors, the first of which is connected between the non-inverting input of the operational amplifier and the common wire, The fact that the inverting and non-inverting inputs of the operational amplifier are connected to the outputs of the switch, and the second capacitor is connected in parallel with the resistor of the negative feedback circuit. 2. The measuring transducer according to claim 1, characterized in that it is equipped with a second resistor connected between the non-inverting input of the operational amplifier and the common wire. 3. The measuring transducer according to claim 1, characterized in that it is equipped with a current driver included between one of the inputs of the operational amplifier and the output for connecting the bias source.