RU2475763C1 - Bridge measuring device of bipole parameters - Google Patents

Abstract

FIELD: testing equipment.SUBSTANCE: bridge measuring device of bipole parameters includes in-series connected generator of pulses with variation of voltage during their duration as per exponential function law, bridge electric chain and zero indicator. Pulse generator includes power amplifier, synchronisation unit, shapers of linearly varying square and rectangular voltage pulses. Bridge chain includes two branches, to the first one of which a single capacitor and bipole with balancing elements are connected in series, and to the second one of which a single capacitor of the second arm of the ratio, as well as terminals for connection of a measuring object are connected. Bipole with balancing elements represents a series connection of capacitor, resistor and inductance coil. A new feature of bridge measuring device of bipole parameters is introduction of three additional capacitors to bridge chain, the first one of which is connected between the first output of pulse generator and common output of available capacitor and resistor of the first branch of the bridge, the second additional capacitor is connected between the first output of pulse generator and common output of available resistor and inductance coil of the first branch of the bridge, the third additional capacitor is connected between available resistor and grounded terminal for connection of bipole of the measuring object of the second branch of the bridge; electric chain is made of in-series connected inductance coil, resistor and the third additional capacitor in the second branch of the bridge and forms a bipole of the measuring object.EFFECT: improving reliability of the bridge and reducing intensity of the bridge failures.1 dwg

Description

The invention relates to information-measuring equipment, automation and industrial electronics and can be used to control and determine the parameters of the measurement objects, as well as physical quantities by means of parametric sensors.

A well-known bridge meter of the parameters of multi-element passive two-terminal devices (USSR AS No. 1157467, G01R 17/10, BI No. 19, 1985), containing a series-connected pulse generator with voltage change over their duration according to the law of power functions, a bridge electrical circuit and a zero indicator.

Its disadvantage is the lack of the ability to balance the bridge circuit only with the same type of balancing adjustable elements in the form of adjustable capacitors of variable capacitance. Adjustable capacitors do not have rubbing contacts. They are promising and preferred in those practical cases where smooth (not discrete) adjustment is required and it is undesirable to use adjustable variable resistance resistors, since they have a rubbing contact. Such a contact wears out relatively quickly and reduces the service life of the element or product with its use, during regulation the resistance in the rubbing contact is unstable, it also changes during the service life and with temperature, sparks and, consequently, interference occur when moving the rubbing contact. These factors reduce reliability, increase the failure rate and reduce the service life of adjustable resistors and, accordingly, bridge circuits and devices using them. The absence of rubbing contacts eliminates the adjustable capacitors of variable capacitance from the above disadvantages.

Known electric bridge (USSR AS No. 983552, G01R 17/10, BI No. 47, 1982), containing a series-connected pulse generator of complex shape, a bridge electrical circuit and an equilibrium indicator.

Its disadvantage is the inability to determine the parameters of two-terminal measuring objects with heterogeneous reactive elements, i.e. R-L-C bipolar parameters.

The closest in technical essence and the achieved result is an electric bridge selected as a prototype (USSR AS No. 920532, G01R 17/10, BI No. 14, 1982), containing a series-connected pulse generator of complex shape, a bridge electrical circuit and an equilibrium indicator (prototype) .

Its disadvantage is the inability to balance the bridge with only the same type of balancing elements in the form of adjustable capacitors of variable capacitance when determining the parameters of two-terminal devices with heterogeneous reactive elements (R-L-C two-terminal devices).

The problem to which the invention is directed is to increase the reliability and reduce the failure rate of the bridge when determining the parameters of two-terminal devices with heterogeneous reactive elements through the use of only the same type of balancing adjustable elements in the form of adjustable capacitors of variable capacitance.

This is achieved by the fact that in a bridge meter of two-terminal parameters, it contains a pulse generator, which consists of pulse shapers with voltage changes over their duration according to the law K ₀ t ⁰ , K ₁ t ¹ , K ₂ t ² , where K _i are constant coefficients and t is the time from the switch, the inputs of which are connected to the outputs of the pulse shapers, and the output is connected to a power amplifier, the output of which forms the first output of the pulse generator, from the synchronization block, the output of which is connected to the synchronization inputs of the pulse shapers It also forms the second output (synchronization output) of the pulse generator, the common bus of the pulse generators is “grounded”, and its first output is connected to the input of the bridge circuit; the bridge consists of two branches connected in parallel, the first of which includes a single capacitor of the first shoulder connected in series to the bridge relationship and a two-terminal device with balancing elements, which consists of a series capacitor, resistor and inductive coil, the free output of a single capacitor is connected to the first output of the pulse generator , the free output of the inductive coil is “grounded”, the common output of two capacitors forms the first output of the bridge circuit output, the second branch of the bridge includes a single capacitor of the second shoulder of the bridge relationship and two terminals for connecting the two-terminal of the measurement object, the free output of the single capacitor is connected to the first output of the pulse generator, one of the terminals for connecting the two-terminal of the measurement object is “grounded”, the common output of the other and the single capacitor forms the second output of the bridge circuit output, a circuit from a series-connected inductive coil and resistor is connected to an ungrounded terminal, they enter a bipolar IR measurement object; a null indicator, to the first input of which (differential input) two outputs of the bridge circuit output are connected, the second output of the pulse generator is connected to the second input (synchronization input), the common bus of the null indicator is “grounded”, three additional capacitors are introduced, the first additional capacitor is turned on between the first output of the pulse generator and the common output of the capacitor and resistor of the first branch of the bridge circuit, the second additional capacitor is connected between the first output of the pulse generator and the common output of the resistor and the inductive coil of the first branch of the bridge circuit, the third additional capacitor is connected between the free terminal of the resistor and the grounded terminal for connecting the two-terminal object of the measurement of the second branch of the bridge circuit, the circuit of the inductive coil, resistor and third additional capacitor in the second branch of the bridge forms the two-terminal of the measurement object.

The invention is illustrated in the drawing (figure 1).

The bridge two-terminal parameter meter contains a pulse generator 1, which includes a square wave voltage generator 2 K ₀ t ⁰ , where hereinafter K _i are constant coefficients, t is time, a linear voltage generator 3 pulse generator K ₁ t ¹ and a shaper 4 pulses of a quadratic form K ₂ t ² . The outputs of each shaper are connected to the inputs of the switch 5, the output of which is connected to the input of the power amplifier 6. Its output forms the first output of the pulse generator. The output of the synchronization unit 7 is connected to the inputs (synchronization inputs) of each pulse shaper, and also forms the second output of the pulse generator (synchronization output). The common bus of the generator 1 is grounded.

The first output of the pulse generator is connected to the input of the bridge circuit, which consists of two branches connected in parallel. The first branch of the bridge consists of a series-connected capacitor 8 (C8), a capacitor 9 (C9), a resistor 10 (R10) and an inductive coil 11 (L11). It also includes a capacitor 12 (C12) connected between the first output of the generator 1 and the common output of the capacitor 9 and the resistor 10, and a capacitor 13 (C13) connected between the first output of the generator and the common output of the resistor 10 and inductive coil 11. Free output a capacitor 8 is connected to the first output of the generator 1. The common output of the capacitors 8 and 9 forms the first output of the bridge circuit output. The free terminal of the inductive coil 11 is grounded.

The second branch of the bridge consists of a series-connected capacitor 14 (C14) and two terminals for connecting the two-terminal device of the measurement object. One of the terminals is grounded. The common terminal of the other terminal and capacitor 14 forms the second terminal of the bridge circuit output. The measurement object connected to the two terminals contains a series-connected inductive coil 15 (L15), a resistor 16 (R16) and a capacitor 17 (C17).

Both outputs of the bridge circuit output are connected to the first input (differential input) of the zero indicator 18. Its second input (synchronization input) is connected to the second output of the pulse generator 1. The common bus of the zero indicator is grounded.

A bridge meter for the parameters of bipolar operates as follows. In the initial state, all reactive elements of the bridge circuit are free of electrical energy reserves, the voltage at the input and output of the bridge is zero. Using the switch 5 from the first output of the generator 1, we will apply to the bridge a pulse train of a rectangular shape. Under the influence of the next pulse in the steady state, the pulse of the bridge output voltage has a flat peak in the time interval from the end of the transient process to the end of the pulse. By a single adjustment of the value of the capacitance of the capacitor 9 (this is an element of balancing) we bring the voltage of the flat top to zero and thereby fulfill the first equilibrium condition

Here and in the future, we note the equilibrium of the bridge by the zero indicator 18 (for example, an oscilloscope). The synchronization signal from the second output of the generator 1 to the second input of the zero indicator 18 ensures the stability of the readings of the latter.

Next, through the switch 5 from the first output of the generator 1, we feed the bridge with a pulse train of a ramp voltage. When the next such pulse is applied, at the bridge output after the end of the transient process, a pulse nonequilibrium signal with a flat top is established. By a single adjustment of the capacitance value of the capacitor 12 (balancing element) we bring the voltage of this flat peak to zero, i.e. we fulfill the second condition of equilibrium of the bridge

Moreover, the first condition (1) is not violated, because Parameter 12 adjustable here is not included.

After that, through the switch 5 from the output of the generator 1, we feed a quadratic pulse train to the bridge. Under the influence of the next pulse at the output of the bridge after the end of the transition process there is a voltage with a flat top. This voltage by a single adjustment of the capacitance of the capacitor 13 (balancing element) is brought to zero, thereby fulfilling the third condition for the equilibrium of the bridge

The first two equilibrium conditions (1), (2) are not violated from this, because adjustable parameter 13 is not included in them.

From the above it follows that the bridge circuit has a separate dependent balancing and it should be carried out in the above sequence of 9, 12 and 13. The values of the parameters of the elements 8, 10, 11 and 14 are constant and known, the values of the parameters 9, 12 and 13 are adjustable and also known, the values of the two-terminal parameters of the measurement object 15, 16 and 17 are unknown. They are determined from equilibrium conditions (1) - (3), in fact, from three equations.

Thus, the bipolar bridge meter measures the reliability and reduces the failure rate of the bridge when determining the parameters of bipolar with heterogeneous reactive elements through the use of adjustable elements only in the form of capacitors of variable capacitance. It lacks adjustable elements with rubbing contacts. The bridge chain in it retained the property of separate balancing.

Information sources

1. A.S. USSR 1157467. IPC G01R. Bridge meter of parameters of multi-element passive two-terminal devices. - Publ. 05/23/1985. Bull. No. 19.

2. A.S. USSR 93552. IPC G01R. Electric bridge. - Publ. 12/23/1982. Bull. No. 47.

3. A.S. USSR No. 920532. IPC G01R. Electric bridge. - Publ. 04/15/1982. Bull. No. 14 (prototype).

Claims (1)

A bridge meter of two-terminal parameters, containing a pulse generator, which consists of pulse shapers with voltage changes over their duration according to the law K ₀ t ⁰ , K ₁ t ¹ , K ₂ t ² , where K _i are constant coefficients and t is time, from a switch, the inputs of which are connected to the outputs of the pulse shapers, and the output is connected to a power amplifier, the output of which forms the first output of the pulse generator, from the synchronization unit, the output of which is connected to the synchronization inputs of the pulse shapers, and also forms swarm yield (yield sync) pulse generator common bus pulse "grounded" generators, and a first output connected to the input of the bridge circuit; the bridge consists of two branches connected in parallel, the first of which includes a single capacitor of the first shoulder connected in series to the bridge relationship and a two-terminal device with balancing elements, which consists of a series capacitor, resistor and inductive coil, the free output of a single capacitor is connected to the first output of the pulse generator , the free output of the inductive coil is “grounded”, the common output of two capacitors forms the first output of the bridge circuit output, the second branch of the bridge includes a single capacitor of the second shoulder of the bridge relationship and two terminals for connecting the two-terminal of the measurement object, the free output of the single capacitor is connected to the first output of the pulse generator, one of the terminals for connecting the two-terminal of the measurement object is “grounded”, the common output of the other and the single capacitor forms the second output of the bridge circuit output, a circuit from a series-connected inductive coil and resistor is connected to an ungrounded terminal, they enter a bipolar IR measurement object; a null indicator, to the first input of which (differential input) two outputs of the bridge circuit output are connected, the second output of the pulse generator is connected to the second input (synchronization input), the common bus of the null indicator is “grounded”, characterized in that three additional capacitors are introduced, the first additional capacitor is connected between the first output of the pulse generator and the common output of the capacitor and resistor of the first branch of the bridge circuit, the second additional capacitor is connected between the first output of the pulse generator and general output of the resistor and inductive coil of the first branch of the bridge circuit, the third additional capacitor is connected between the free output of the resistor and the grounded terminal for connecting the two-terminal object of the measurement of the second branch of the bridge circuit, the circuit of the inductive coil, resistor and third additional capacitor in the second branch of the bridge forms a two-terminal object .