SU918862A1 - Bridge-type meter of passive four-component two-termal network parameters - Google Patents

Description

(54) bridge PARAMETER METER. FOUR-ELEMENT PASSIVE

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. The invention relates to electrical engineering and can be used in information-measuring equipment, automation and industrial electronics, in particular for measuring the composition of the components — two active and one reactive or physical quantity of passive two-terminal network.

An electrical bridge is known for measuring three parameters, comprising a power generator, a comparison arm, made according to the replacement scheme of the object under investigation, and ratio arms, which represent the exemplary elements of a single PS arm, using three components: active, capacitive and inductive; which limits the amount of information received from one bridge and does not allow measurements of more complex objects, containing: 111 of them more than three components.

Closest to the invention is a two parameter meter. TWO-POLLERS

of the pole cells, containing a pulse generator, included in one diagonal of the bridge, the other diagonal of which is measuring, with two opposite arms of the bridge formed by resistors, and the other two are bipolar 21.

In this device, three components are measured: two active and one reactive, which limits the volume

10 of the information received and does not allow measurements of more complex objects containing more than three components. The latter limits the range of application of the two-terminal meter meter.

The goal of the invention is to increase the number of measurable bipolar elements.

The goal is achieved by

20 that in a bridge meter parameters of four-element passive two-terminal network, containing a complex-shaped pulse generator, included in one

The diagonal bridge is diagonal, the other diagonal of which is measuring, and two opposite arms of the bridge are formed by resistors and the other two are passive two-pole, one of which is measurable, the other is balancing, one of them is in the form of a chain consisting from a series-connected capacitor and inductance coil, shunted by a resistor, in parallel with which a second resistor is connected and the other in the form of a series-connected resistor and inductance coil, in parallel to which A resistor and a capacitor are connected in series.

The drawing shows a schematic electrical diagram of a bridge meter for the parameters of four-element passive two-terminal networks,

The bridge meter contains a trapezoidal impulse generator 1 supplying a bridge, a resistor 2 of one arm and a series-connected capacitor 3 inductance coil 4. A resistor 5 is connected in parallel with the inductor k inductance. In the non-adjacent arm there are series-connected resistor 6 and inductor 7. In parallel with the inductor coil 7, a series-connected capacitor 8 and a resistor 9 are connected. The remaining two non-adjacent arms include resistors 10 and 11.

Bridge meter works as follows.

In the initial state, i.e. in the absence of a pulse from the generator 1, capacitors 3 and 8, coils and 7 inductances are free from energy reserves.

From generator 1, an electric impulse is supplied to the electric bridge in the form of a rectangular trapezium. Under the action of a flat top in a steady state, a zero current is established through the capacitor 3, and the voltage on the inductance coil 7 becomes zero. Therefore, the imbalance voltage in this area depends only on the resistances of the resistors 2, 6, 10 and 11. Suppose that four measured Shements are included in the first shoulder and four equilibrium ones in the non-adjacent shoulder. Adjusting the resistance value of the resistor 6 causes the non-equilibrium voltage in this time interval to zero, i.e. 5, the first equilibrium condition and the resistor 2 resistor 2 are satisfied. When the linearly varying part of the supply pulse is applied after the transition /: 1 process terminates, a constant current is set through the capacitor 3, the value of which does not depend on the coil inductance and the resistance of the resistor 5, and inductor coil 7 is set to a constant voltage, independent of the capacitance 8 of the capacitor 8 and the resistance of the resistor 9. As a result, the voltage across this time is not equal to Only the magnitude of the capacitor 3 and the inductance of the coil 7. Changing the value of the inductance of the coil 7 causes the voltage to be unbalanced here to zero,

5 i.e. the second equilibrium condition is satisfied and the capacitance 3 capacitance value is taken. During the action of a jump in the supply pulse during transients after

When the first two equilibrium conditions are fulfilled, the imbalance voltage now depends on the inductance of the coil L, the capacitance of the capacitor 8 and the resistances of the resistors 5 and 9. The alternating adjustment of the capacitance of the capacitor 8 and the resistance of the resistor 9 causes the imbalance voltage to zero here, i.e. the third and fourth equilibrium conditions are satisfied and the inductance values of the coil 4 and the resistance of the resistor 5 are measured.

The proposed passive two-pole parameter meter allows four components to be measured, which increases the amount of information received and broadens the scope of its application. The meter has separate balancing in two of the four measured components.

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Claims (2)

1. Author's certificate of the USSR 200662, cl. G 01 R 17/10, 19b7. 2. USSR author's certificate №, cl. G 01 R 17/10, 197 (prototype)..