SU457038A1 - AC bridge with close inductive coupling - Google Patents

Description

one

The invention relates to the field of electrical measuring equipment, in particular to devices for measuring the parameters of complex resistances, mainly small conductors.

A closely inductively coupled AC bridge is known, in which two amplifiers with deep negative feedback are used to reduce the error caused by the difference in the resistance of the supply lines. The disadvantage of this device is that the degree of compensation of the fault caused by the presence of the resistances of the lead wires is determined by the value of the gain of the amplifiers used. However, increasing the gain of the amplifiers leads to a loss of stability of the compensation system. Therefore, a real reduction in incidence cannot be sufficient.

In order to improve the measurement accuracy, the proposed bridge is equipped with an I1Nverto | and an adder, the additional winding of the transformer of limits being connected between the potential terminal of the measured resistance and the inverter input, the additional winding of the current comparator between the current terminal of the measured resistance and one of the inputs of the adder, the second input of the adder connected to the output of the investor, and

the output of the adder is connected in series with the transformer primary winding limits.

The drawing shows a schematic diagram of the proposed bridge.

It contains a generator 1, a voltage transformer 2, a limit transformer 3, a current comparator 4, measured 5 and an exemplary 6 resistance, an equilibrium indicator 7, an inverter 8 and an adder 9. The inverter 8 and an adder 9 icoBMecTHo with additional windings applied to the limit transformer , and the current comparator form correction circuits. The bridge is balanced by adjusting the number of turns of the secondary winding of the voltage transformer 2.

The proposed device differs from the known one in that for correcting the error caused by the influence of residual resistances Zj and Z2, deep negative coupling is not used.

As can be seen from the drawing, the input voltage Ul of the inverter 8 is equal to the fall of 1nap. On the residual resistance Zi of the circuit of the transformer's main winding limits. The input voltage Zo of the adder 9 is equal, in turn, to the voltage drop on the residual resistance of the main winding circuit of the current comparator. The voltages of the errors f / d and Ui are summed by adder 9, the output of which is connected in series with the primary winding of the transformer of limits 3. Therefore, the output voltage of the adder Us is summed with the voltage Ui. As a result, the voltage Uz acting on the transformer primary winding of limits 3, 1 rises. This compensates for the decrease in voltage across the measured resistance b, which occurs due to the presence of residual resistances Zi and Za of the main windings of the voltage transformer and the current comparator, connected in turn with the measured complex resistance. In order to fully compensate for the measurement error in the proposed device, there is no need to increase the transmission coefficients of any cascades. Necessary and sufficient conditions of the polynomial error margin in the proposed device is the equality of the unit transfer coefficients of the inverter 8 and the adder 9, as well as the number of turns of the transformer's additional winding. The limits must be equal to the number of turns of the secondary winding of this tractor circuit. The number of turns of the additional winding of the current comparator must be equal to the number of turns of its winding connected to the circuit of the measured resistance. This makes it possible to create compensation circuits that are absolutely stable and allow full compensation of the effect of the residual resistance of the windings on the measurement accuracy. The subject of the invention is an AC coupled inductively coupled network, comprising a generator, a voltage transformer, an equilibrium indicator, a limit transformer, and a current comparator with additional windings, measurable and exemplary resistance, which is distinguished by the fact that it is detected by an inverter and an adder, with the additional winding of the transformer connected between the potential terminal of the measured resistance and the input of the inverter, the additional winding of the current comparator connected between the current terminal of the measured resistance and one of the inputs of the adder, the second input of the adder is connected to the output of the inverter, and the output of the adder is connected in series with the primary winding of the transformer limits.

WITH,