SU636547A1 - Transformer bridge - Google Patents

Claims (1)

(54) TRANSFORMATOR BRIDGE to the terminals is connected to the primary winding of a compensating transformer, the secondary winding of which is connected to the input of a scaling operational amplifier, and the output of the mentioned amplifier is connected to the winding of the inductive divider. Figure 1 is a schematic diagram of the proposed transformer bridge, and figure 2 presents its equivalent circuit, where E (, is the EMF induced in the winding of the inductive divider; and is the output voltage of the scaling operational amplifier; the magnitude of the reference resistor; Up is the drop in voltage resistor R; and, - voltage at the input of a scaling operational amplifier; measured impedance; g - total resistance of wires and contacts connected in series with ZX; 1 V, R - resistor values m scaling operational amplifier; I - current in branch Z 5J Offered transformer bridge contains generator 1, inductive divider 2 forming the two arms of the bridge, model complex resistance 3, clamps 4 and 5 for connecting from measured complex resistance 6, indicator 7, one output connected to the reference impedance and the clamp 5 for connecting, the measured impedance connected in series with the measured impedance of the reference resistor 8, parallel to the terminals The primary winding of the compensating transformer 9 is turned on, the secondary winding of which is connected to the input of the scaling operational amplifier 10, and the output of said amplifier is connected to the winding of the inductive divider. Transformer bridge works. in the following way. The voltage of the generator goes to the inductive divider and shoulders, formed by the model and measured complex resistances. The current flowing through the measured impedance creates a voltage drop across the sample resistor, which is removed by a compensating transformer, amplified by a scaling operational HfcJM amplifier, injected into the inductive divider arm, and changes the ratio of the voltages in the bridge arms. Thanks to the feedback thus implemented, compensation is obtained for the resistances of wires and contacts connected in series with the measured complex resistance. Neglecting the shunting of a resistor by a transformer 9 can be written at the same time where n is the transformer transformer ratio 9, and, (3), in the case of bridge equilibrium, the potential of point a is zero, and the expression for current 1 looks like: 1 1 ;, (4 ) Substitution of expressions of formulas (1), (2), (3) into formula (4) gives the expression for current 1 as EO R, E 1 RJ It follows from the last equation that, if the condition H is met, compensation of parasitic resistances is achieved, connected in series with 2. The application of the proposed scheme allows accurate measurements of low complex resistances with their two-clamping switching on, which creates conditions for increasing the reliability of contact and simplifying the mechanical components of the control and measuring devices. The invention includes a transformer bridge containing a generator, an inductive divider forming the two arms of the bridge, an exemplary impedance and clamps for connecting the measured impedance, forming the other two arms of the bridge, an indicator connected to the exemplary impedance with one end and a terminal for connecting the measured impedance compensating transformer, characterized in that, in order to improve the measurement accuracy of small impedances at two times clamp connection, an exemplary resistor and a scaling operational amplifier are inserted into it, while the exemplary resistor is connected to the bridge arm in series with the measured impedance and parallel to its terminals is the primary winding of the compensating transformer, the secondary winding of which is connected to the input of the scaling operational amplifier, and A power amplifier is connected to the winding of the inductive divider.