SU957117A1 - Compensating bridge measuring device - Google Patents

Description

one

The invention relates to electrical measuring equipment and is intended to measure the components of the impedance.

A known measuring circuit comprising a harmonic signal generator, the output terminals of which are connected to the diagonal of the power bridge, formed by two branches, one of which is composed of a series-connected measuring impedance and an exemplary element that is uniform to one of the components of the measured impedance, and the second is from series-connected exemplary complex resistance and the second exemplary element, homogeneous to the exemplary element of the first branch 1.

The information obtained from the described measuring circuit allows to form separately and simultaneously

regulatory impact, however, it has low noise immunity. It’s also difficult to compensate for the parasitic parameters of the bridge and the supply wires.

Known compensation bridge.

Claims (2)

10 a measuring circuit containing a harmonic signal generator connected to the primary winding of a voltage transformer, the beginning of the first and the end of the second secondary windings of which are connected to a common busbar, and the free clips of the secondary windings of a voltage transformer are connected to the first terminals of the measured and exemplary complex two-pole respectively, Free clips of which are connected respectively via the first and second primary windings of the current comparator connected to the common busbar, the secondary winding a comparator connected to the output currents of the measuring drawback of the known measuring circuit is the impossibility of forming the control interventions for the separate and simultaneous equilibration of comprised between the sequential integrated circuit substitution resistance, which increases the equilibration time. The aim of the invention is to reduce the equilibration time of the measuring circuit by separately and simultaneously forming control actions on the components of the measured complex resistance in any, replacement circuit of the latter. This goal is achieved by the fact that in a coordination-bridge measuring device containing an alternating signal generator connected to the primary winding of a voltage transformer, the beginning of the first and the end of the second secondary windings of which are connected to a common bus and the free clips of the secondary windings of a voltage transformer are connected with the first clamps, respectively, of the measured and exemplary complex two-terminal networks, the free clamp of the measured (reference) impedance is connected through the primary The current transformer winding is connected to the common bus, the secondary winding of the current transformer is connected to the output of the measuring circuit, the second current transformer is inserted, and the free clip of the exemplary (measured) complex two-terminal device is connected via the primary winding of the second current transformer to the common bus connected to the second output of the measuring circuit. The introduction of a current transformer allows, using the output voltage of a current transformer, to form regulating actions for balancing across the components of the complex resistance with any replacement circuit separately and simultaneously. FIG. 1 shows a functional diagram of the measuring circuit; in fig. 2 is a vector diagram illustrating the balancing process of the compensatory bridge measuring circuit. The measuring circuit comprises an alternating signal generator 1, a voltage transformer 2 with windings 3, and 5, a measurable impedance 6, an exemplary impedance 7 and two current transformers 8 and 9. The vector diagram combines the vector voltage diagram and the vector current diagram and denotes: ab - the power supply voltage of the circuit containing, for example, the measured impedance; af is the supply voltage of a circuit containing, for example, an exemplary impedance; am, an are the voltage drops at the active component, respectively, of measured and exemplary complex resistances; md, nd are the voltage drops on the reactive component, respectively, of the measured and model complex resistances; ac is the voltage vector proportional to the current I flowing through the measured impedance 6; ad is the voltage vector proportional to. national current 1 flowing through the exemplary impedance. 7; cd is the unbalance voltage vector proportional to the difference of the currents I. and os, 4, y are the trajectories of the movement of the points c and d when changing, respectively, the active and reactive component of the complex resistance. The trajectories of moving points c and d when the reactive parameters of the measuring circuit change can be described as l + ze and when the active parameter changes. E / x where E - EMF shoulder power circuit; (- active and reactive components of the complex resistance; 5957 - module and phase of the complex resistance, which corresponds to circles with diameters - D fi - - | - In accordance with the generalized depiction of bridge measuring circuits, these circles are called V and ( 3. It is obvious that the condition of a quasi-equilibrium compensation bridge circuit for any component of the impedance is equality of the diameters of the component circles, for example, Dpc Df3j (5) is an equilibrium condition for reactive the component of complex resistance, and equality is a quasi-equilibrium condition on the active component of complex resistance. Using various methods for constricting the exit of points c and d to one or another circle, it is possible to form regulating actions on the components of complex resistance separately and simultaneously. Specifically in the measuring balancing is a process of comparing the ratios of ac, ad and cd voltages taken from current transformers 8 and 9 according to the above-mentioned algorithms, followed by by switching the sample elements of the complex impedance 7 The measured impedance is measured after balancing from conditions (5) and (6 in the form of di ,,; TN, lSc-Li, .Wi.X. ab., R af W ° where W and W2 are the number of turns of the secondary windings, respectively, and 5 transformer 2 voltages. 11 The use of the proposed compensation bridge measuring circuit allows one to increase the measurement speed of the components of the complex two resistance of a two-pole device (various capacitive and inductive sensors), which is especially important when developing an automated process control system. Compensation bridge measurement device comprising an alternating signal generator connected to the primary winding of a voltage transformer, the beginning of the first and the end of the second secondary windings of which are connected to the common bus, and the free terminals of the secondary windings of a voltage transformer are connected to the first terminals of the measured and exemplary complex two-terminal, free terminal of the measured (reference) impedance connected through the primary winding current transducer to the common busbar, the secondary winding of the current transformer is connected to the output of the measuring circuit, characterized in that, in order to reduce the balancing time of the measuring circuit by separate and simultaneous formation of regulatory influences on the components of the measured impedance, A second current transformer is introduced, the free terminal of the exemplary (measured) complex two-terminal device being connected via the primary winding of the second transformer eye to the common bus, the secondary obmotk.a -sec current transformer connected to the second output measurement mis- chain. Sources of information taken into account in the examination 1.Karandeev K.V. Special methods of electrical measurements. M.-L., Gosenergoizdat, 19bЗ “ 2. Transformer measuring bridges. In general ed. K. B. Karandeeva. M., Energie, 1970. but  D9LG / fug f of (/