RU2103695C1 - Bridge-type meter of passive one-port parameters - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: meter has pulse generator 1, electrical bridge and balance indicator 18. First arm of bridge is formed by capacitor 5 and object being measured which includes series-connected capacitor 6, resistor 7 and inductance coil 8 in parallel to which resistor 9 is connected. Common lead of capacitor 5 and of measured object form first output of bridge. Second arm of bridge is formed by series-connected circuit consisting of seven elements and resistor 10 of second arm. Seven-element circuit has resistor 11. Series-connected capacitor 12, inductance coil 13 and resistor 14 are connected in parallel to resistor 11. Series-connected resistors 16 and 17, the common lead of which serves as second output of bridge are connected in parallel to inductance coil 13. Balance indicator 18 is connected to first and second outputs of bridge. Novelty of meter is as follows. Resistors 14-17 are introduced additionally; generator of sequence of pulse signals of rectangular, linearly-varying, source and cubic forms is used as pulse generator 1; third input of balance indicator 18 is connected to third output of pulse generator 1, and fourth input of balance indicator is connected to common bus of device to which second terminal of diagonally opposite pair of bridge supply terminals is also connected. EFFECT: higher measurement results. 1 dwg

Description

 The invention relates to the field of information technology, industrial electronics and can be used to measure the parameters of objects with a bipolar equivalent circuit, as well as physical quantities by means of parametric sensors included in the bridge circuit.

 Known electric bridge [1], containing a series-connected generator of supply pulses, a bridge circuit and an equilibrium indicator.

 Its disadvantage is the inability to measure the parameters of three-element bipolar, containing heterogeneous reactive elements (inductance, capacitance).

 The closest in technical essence and the achieved result to the claimed device is a bridge meter of passive two-terminal parameters selected as a prototype [2], containing a pulse generator in the form of a rectangular trapezoid, the first capacitor in the arm of the relationship of the branch with the measurement object, the equivalent circuit of which consists of series-connected a second capacitor, a first resistor and a first inductive coil, a comparison arm, consisting of a second resistor with adjustable resistance, pairs Along with which a variable capacitor and an inductance coil with adjustable inductance are connected in series, in the non-resinous arm of the branch relation with the comparison arm is a third resistor, an equilibrium indicator connected by one output to the common point of the measurement object and the capacitor of the ratio arm, and the other to the common point of the capacitor and an inductive coil of the comparison arm, the second terminal of which is connected to a common point of the second and third resistors.

 The disadvantage of this bridge meter is the inability to measure the parameters of four-element bipolar with heterogeneous reactive elements.

 The aim of the invention is to reduce the weight and dimensions when measuring the parameters of objects with a four-element equivalent circuit due to the use of only adjustable resistors as balancing reference elements.

 The goal is achieved in that in a bridge meter of parameters of passive two-terminal devices, containing a pulse generator, two outputs of which are connected to two vertices of the power supply diagonal of the electric bridge, the other diagonal of which is measuring, and the first branch of the electric bridge is formed by the first capacitor connected in series, the first output of which forms the first vertex diagonal power supply of the measuring bridge, and the measurement object, the equivalent circuit of which consists of series-connected second of the second capacitor, the first resistor and the first inductive coil, in parallel with which the second resistor is connected, and the second branch of the electric bridge contains a third capacitor connected in series, connected by the first terminal to the first terminals of the first capacitor and the third resistor, and a second inductive coil, the second terminal of the third resistor is connected to the first output of the fourth resistor, the second output of which is combined with the second output of the first inductive coil @ forms the second vertex of the power diagonal electrically of the first bridge, the equilibrium indicator, the first input of which is connected to the first vertex of the measuring diagonal of the electric bridge, formed by the common output of the first and second capacitors, are introduced from the fifth to the eighth resistors, and the pulse generator is a rectangular, linearly-varying, quadratic pulse generator and cubic, with the fifth and sixth resistors connected in series and connected in parallel to the second inductive coil, between the second output of which and the common The seventh resistor is turned on by the output of the third and fourth resistors, the eighth resistor is connected in parallel with the second inductor, the common output of the fifth and sixth resistors forms the second vertex of the measuring diagonal of the electric bridge and is connected to the second input of the equilibrium indicator, the third input of which is connected to the third output of the rectangular pulse generator , linearly varying, quadratic form, and the fourth input of the equilibrium indicator is connected to the common bus of the device with which it is connected inena is also the second peak of the diagonal of the power supply of the electric bridge.

 In the claimed combination, the distinguishing features showed a new property, which consists in reducing the weight and dimensions when measuring the parameters of objects with a four-element equivalent circuit containing heterogeneous reactive elements due to the use of only adjustable resistors as balancing model elements. No solutions having features similar to those distinguishing the claimed device from the prototype were not found. The achievement of such an effect does not follow from the solutions known in the technical literature. The proposed bridge meter corresponds to the necessary inventive step.

 The drawing shows a functional diagram of a bridge meter for passive two-terminal devices.

 The bridge passive two-terminal parameter meter contains a pulse generator 1, consisting of serially connected shaper 2 of rectangular, linearly-varying, quadratic and cubic pulses, switch 3 and power amplifier 4, an electric bridge and an equilibrium indicator 18. The first branch of the electric bridge is formed by a capacitor 5 (C1 ) of the shoulder ratio and series-connected capacitor 6 (C2), resistor 7 (RI) and inductive coil 8 (L1), in parallel with which a resistor 9 (R2) is connected, which form the object Nia. The second branch of the bridge is formed by a series-connected circuit of seven elements and a resistor 10 (R7) of the second arm of the relationship. The seven-element circuit contains a resistor 11 (R4), in parallel with which a capacitor 12 (C3), an inductive coil 12 (L2) and a resistor 14 (R3) are connected in series. In parallel to the inductive coil 13, a resistor 15 (R8) and series resistors 16 (R5) and 17 (R6) are connected. The general conclusion of the measurement object and resistor 10 forms one of the vertices of the diagonal of the bridge power supply, which is grounded. The other peak of the power diagonal is formed by the common output of the capacitor 5 and a circuit of seven elements. The outputs of the bridge form the common output of the capacitor 5 and the measurement object, as well as the common output of the resistors 16 and 17. These two outputs of the electric bridge are connected to two inputs of the equilibrium indicator 18. Two output terminals of the power amplifier 4 form two outputs of the pulse sequence generator, which are connected to two vertices of the diagonal of the power supply of the electric bridge. The synchronizing output of the pulse generator 2 forms the third output of the generator 1, which is connected to the third input of the equilibrium indicator 16, which is the synchronization input. The fourth input of the equilibrium indicator 18 and the general output of the pulse shaper 2 are connected to a common bus of the device, to which the second vertex of the power supply diagonal of the electric bridge is also connected.

 The generator 1 includes a synchronization cascade, which is built on the basis of a self-oscillating multivibrator according to ed. testimonial. USSR N 517992, bull. N 2, 1976. One of its outputs is connected to the inputs of the formers of rectangular, linearly-varying, quadratic and cubic pulses, and the other forms the synchronization output of the generator (third output). The rectangular pulse shaper is based on a braked multivibrator on an operational amplifier (OA) (Design of electronic devices on integrated circuits. Edited by S.Ya. Shatsk, M .; Soviet Radio, 1976, p. 154, 155). The ramp voltage pulse generator (LIN) is constructed on the basis of a series-connected inhibited multivibrator on an op-amp (Frolkin V.T., Popov L.N. Pulse devices. M; Sovetskoe radio, 1980, p. 216, 217) and a generator LIN on the OS (see ibid., p. 254, 255). The quadratic pulse generator is made on a series-connected braked multivibrator mentioned above, a LIN generator (see ibid., P. 216, 217 and p. 254, 255) and an integrator on an op-amp (Horowitz P., Hill W. Art of circuitry. M.: Mir, 1983, vol. 1, p. 408, 409, Fig. 6.55). The output of the braked multivibrator here is also connected to the "Reset" terminal of the integrator. The cubic pulse shaper is configured as the quadratic pulse shaper discussed above, the output of which is connected to another integrator on the op-amp, the “Reset” input of which is also connected to the output of the inhibited multivibrator. These cascades form a 2 pulse shaper. As switch 3, a switch of type PR2-10P1NVR (K) was selected, and as an amplifier 4 of power, an emitter follower. As an indicator of equilibrium 18, an oscilloscope was used.

 The bridge meter works as follows. In the initial state, the voltages at the input and output of the bridge are zero. First, the switch 3 connects to the bridge the rectangular pulses of the generator 1. When exposed to the next rectangular pulse in the steady state, unchanging voltages are established in the branches of the bridge. The nonequilibrium voltage depends only on the values of the capacitances of the capacitors 5, 6 and the resistances of the resistors 10 and 11. By a single adjustment of the resistance value of the balancing resistor 11, the flat top of the nonequilibrium signal is brought to zero and thereby the first equilibrium condition is fulfilled. Hereinafter, the equilibrium of the bridge is noted by the equilibrium indicator 18. Then, using the switch 3, linearly varying voltage pulses from the generator 1 are applied to the bridge. When another such pulse is applied, a pulse signal with a flat top is established in the measuring diagonal of the bridge after the end of the transition process, which depends on taking into account the fulfillment of the first equilibrium condition from the resistance values of only one balancing resistor 14. By a single adjustment it leads to a flat peak signal imbalance to zero, and the second condition of equilibrium. After that, using a switch 3, quadratic pulses from the generator 1 are connected to the bridge. Upon receipt of the next pulse of this shape in the measuring diagonal of the bridge, after the end of the transition process, a pulse signal with a flat top is established, which, taking into account the fulfillment of the first two equilibrium conditions, depends on the resistance values of the third balancing resistor 17. By adjusting it once, the flat top of the nonequilibrium signal is brought to zero and the third equilibrium condition is fulfilled. Then, with a switch 3, cubic pulses from the generator 1 are connected to the bridge. When a next pulse of this form arrives in the measuring diagonal of the bridge, after the end of the transition process, a pulse signal with a flat top is established, which, taking into account the fulfillment of the first three equilibrium conditions, depends on the resistance values of the fourth balancing resistor 15 By adjusting it once, the flat peak of the nonequilibrium signal is brought to zero and the fourth equilibrium condition is fulfilled.

The countdown of the desired values of the quantities is taken from the expressions obtained on the basis of the equilibrium conditions:
C ₂ = R ₄ C ₁ / R ₇ ,
R ₁ = C ₃ (R ₇ R ₄ + R ₇ R ₃ + R ₄ R ₃ ) / C ₁ R ₄ ,
L ₁ = L ₂ C ₃ R ₆ (R ₇ + R ₄ ) / C ₁ R ₄ (R ₅ + R ₆ ),
R ₂ = L ₂ C ₃ R ₈ A (R ₇ + R ₄ ) ² / C ₁ [C ₃ R ₄ R ₈ R ₅ (R ₅ + R ₆ ) (R ₇ R ₄ + R ₇ R ₃ + R ₄ R ₃ ) + L ₂ R ₄ R ₆ (R ₇ + R ₄ ) (R ₈ + R ₅ + R ₆ )],
Where
C ₂ is the capacitor 5 in Fig. 1, R ₄ is the resistor 11, C ₁ is the capacitor 5, R ₇ is the resistor 10, R ₁ is the resistor 7, C ₃ is the capacitor 12, R ₃ is the resistor 14, L ₁ is inductive coil 8, L ₂ - inductive coil 13, R ₆ - resistor 17, R ₂ - resistor 9, R ₈ - resistor 15, R ₅ - resistor 16.

 It can be seen from them that with the third balancing, if necessary, you can adjust the resistance value of the resistor 16. After four balancing, short exponential bursts remain in the measuring diagonal, therefore, the bridge circuit can be considered quasi-balanced.

 Thus, this bridge meter allows you to reduce weight and dimensions when measuring the parameters of objects with a four-element equivalent circuit with heterogeneous reactive elements due to the use of only adjustable resistors as balancing reference elements. The balancing of the bridge is separate, which is promising for automatic measurements. The polarity of the output signal of the bridge uniquely determines the direction of regulation of the corresponding variable resistance for each of the four balances.

Claims (1)

 A bridge meter for passive bipolar parameters, containing a pulse generator, two outputs of which are connected to two vertices of the power supply diagonal of the electric bridge, the other diagonal of which is measuring, the first branch of the electric bridge is formed by the first capacitor connected in series, the first output of which forms the first vertex of the power supply diagonal of the measuring bridge, and measurement object, the equivalent circuit of which consists of a series-connected second capacitor, the first resistor RA and the first inductive coil, in parallel with which the second resistor is connected, the second branch of the electric bridge contains a third capacitor connected in series, connected by the first terminal to the first terminals of the first capacitor and the third resistor, and a second inductive coil, the second terminal of the third resistor, connected to the first terminal of the fourth resistor, the second terminal of which is connected to the second terminal of the first inductive coil and forms the second vertex of the diagonal of the power supply of the electric bridge, an equilibrium indicator, first the first input of which is connected to the first vertex of the measuring diagonal of the electric bridge formed by the common output of the first and second capacitors, characterized in that resistors are inserted into it from the fifth to eighth, and a pulse generator of a rectangular, linearly-varying, quadratic pulse sequence is used and cubic forms, with the fifth and sixth resistors connected in series and connected in parallel to the second inductive coil, between the second terminal of which and the common terminal of t the seventh resistor is turned on for the fourth and fourth resistors, the eighth resistor is connected in parallel with the second inductor, the common output of the fifth and sixth resistors forms the second vertex of the measuring diagonal of the electric bridge and is connected to the second input of the equilibrium indicator, the third input of which is connected to the third output of the rectangular pulse generator, linearly changing, quadratic and cubic forms, and the fourth input of the equilibrium indicator is connected to the common bus of the device with which Dinen is also the second peak of the diagonal of the power supply of the electric bridge.