SU789766A1 - A.c. compensation bridge - Google Patents

Description

(54) AC PAYMENT BRIDGE

one

The invention relates to electrical measuring equipment and is intended to measure the components of the impedance using ac bridges. five

It is known a device comprising a generator, a power transformer, a bridge measuring circuit, a matching device, logic elements, an equilibrium unit, and a pulse shaping system, in which a control action is formed for separate equilibration over the measured component of the impedance when using only supply voltage and unbalance voltage 1.

This device has a significant disadvantage - a narrow measurement range of the component 20 of the impedance, due to the fact that the formed element located in the branch, containing the measured complex resistance, is used as balances of the entire element.

A compensating bridge of alternating current, a generator of sinusoidal voltage, is known, the output of which is connected to the primary 30

winding transformer power, pavement measuring circuit, one branch% of which is composed of series-connected impedance. and a model element that is uniform in the measured component of the impedance, and the second branch is composed of consecutively included model elements, one uniformly measured component of the complex impedance, and the other is homogeneous in character and not measurable. both exemplary elements that are uniform in terms of the measured component of the impedance of the impedance included in the adjacent shoulders: the branches of the bridge measuring circuit form one of the vertices of the diagonals supplying the branches containing and not containing the measurable impedance, connected to the beginning of the unregulated secondary winding and to the second output of the second matching device, the second vertex of the power supply of the branch not containing the measured impedance, is connected to the end of the specified secondary winding and to the first input the second matching device, the second vertex of the supply diagonal containing the measured impedance is connected to the end of the secondary control winding, the beginning of which is Disconnected with the end of the unregulated secondary winding, the top of the measured diagonal, not adjacent to the measured complex resistance, connected to the common bus, the top of the measuring diagonal, adjacent to the measured complex resistance, is connected through the first matching device in parallel to the first input of the pulse former and to the first inputs of both phase shifters, the output of the second matching device is connected in parallel with the second inputs of both phase shifters and drivers pulse body, the output of which is connected in parallel to the prohibitive input of the first element of the Ban and to the direct input of the second element of the Ban, the outputs of the first and second phase-time converters are connected to the direct and inverse inputs of the Zapra elements, respectively, the outputs of the Overturn elements are connected to the inputs of the OR element , the output of which is connected to the input of the display unit 2 through a balance unit. The disadvantage of this digital ac bridge is the slow response due to the successor Due to the timeliness of the operation of selection, the limit and balancing of the measured component, as well as the low accuracy of the component measurement due to the achievement of only the state of quasi-equilibrium. The purpose of the invention is to increase accuracy and speed. The goal is achieved by the fact that in a known alternating current bridge containing a sinusoidal voltage generator whose output is connected to the primary winding of a parametric transformer, a pavement measuring circuit, one branch of which is composed of successively connected measured impedance and a sample element that is uniform I one of the components of the measured complex resistance, and the second branch is composed of successively included model elements, one and which is homogenous to one component of the measured complex resistance, and the second to its other component, both of which are exemplary elements that are homogeneous to one of the components of the measured complex resistance, located in the adjacent arms of the branches of the bridge measuring circuit, are interconnected and form one of the vertices power diagonals of the branches containing and not containing the measurable - complex resistance, connected to the beginning of the Unregulated secondary winding of a parametric transformer and parallel to The second and third matching devices, the second vertex of the power diagonal of the branch containing the measured impedance, are connected to the end of the unregulated secondary winding of the parametric transformer, to the end of the switched secondary winding of the parametric transformer, which is located on the core rotated ± 90 ° relative to the core, where the non-switched secondary winding is located, and to the second input of the second matching device, the output of which is connected to the first input of the phase sense A rectifier, the second vertex of the power supply diagonal of the branch that does not contain the measured impedance, is connected to the beginning of the switched secondary winding of the parametric transformer and to the second input of the third matching device, the top of the measuring diagonal, adjacent to the measured impedance, is connected to the common bus, the second vertex of the measuring diagonal is connected through the first matching device to the second input of the phase-sensitive rectifier and through the pulse shaper to the control inputs of both comparison units, the first input of the first comparison unit is connected to the output of the phase-sensing rectifier, and the output to the first equilibration unit, the output of the second comparison unit through the second equilibration unit is connected to the input of the subscription unit, and an amplitude converter is inserted the output of the first matching device is connected via an amplitude converter to the first input of the second comparison unit, the second input of which is connected to the output of the third matching device, the output of the second read out apparatus is connected to the second input of the first comparator unit. FIG. Figure 1 shows a typographic diagram of the process of balancing a compensating alternating current bridge; in fig. 2 - scheme of the AC bridge. The following notation is accepted in the drawing: (f is the angle whose tangent carries information about the ratio of the active and reactive components of the measured impedance; аb is the supply voltage of the compensatory-bridge measuring circuit containing the measured impedance; af is the voltage power supply of the compensation bridge measuring circuit that does not contain the measured impedance; the phase angle between the voltage supply vectors of the branches that contain and does not contain the measured complex the initial positions of the potential points c, d (top of the compensation-bridge measuring circuit) corresponding to the state of underbalance of the compensation-bridge circuit along both components of the measured complex resistance; the position of the potential points c and d corresponding to the state of full balance of compensation a measuring circuit; april of unbalance of a compensation-bridge measuring circuit; right along which the potential point d moves while balancing a compensation Stovo measuring circuit in tg (f (Q); dd, etc - equilibration circumferences of the branches containing and not containing the measured impedance. The process of balancing the complex-bridge measuring circuit over tg (5 (Q)) consists in changing the supply voltage of the branches not containing the measured impedance by switching the secondary coil winding of a parametric transformer located on a core rotated by ± 90 ° relative to the core on which the primary and non-switched secondary winding is located. The moment of quasi-equilibrium is compensatory the bridge measuring circuit along tg d (Q) can be fixed by completing the following equality: cd - af sin f U U) Blocking (resetting) all changes of the adjustable element, turns of the switched secondary winding of the parametric transformer, resulting in cd inequality afsin (2) and dropping (blocking), for example, changes in an adjustable element, switchable secondary winding of a parametric transformer, leading to cd-afsln 50 inequality (3) This allows one to achieve a quasi-equilibrium compensation-bridge measurement chain of tg d (Q). As the points c and d, t, e approach each other, and when approaching a state of complete equilibrium, the measurement accuracy tgrf (Cl) increases and the moment the point c emerges to pin 1 about switching db can be fixed by completing the following equation H - eh cos O Bloku (dropping), for example, all changes to an adjustable element (RS.), Leading to inequality (R2.), Leading to the inequality ab S in P - ab 70 (b), you can achieve the exit point c to the switch line db. In addition, when the equilibrium of the compensation-bridge measuring circuit is reached, a reading can also be made on the reactive component of the measured impedance. A reading of the loss tangent of the measured impedance can be obtained as follows. tgd tg V (7) Relation (7) can be expressed in terms of the ratio of turns in the secondary winding of the parametric transformer | formator. Thus, knowing the values of tg (f (Q) can be determined.; 1, model element 2 (resistance R2), serving to select measurement limits, active element 3 (with resistance R) and reactive element 4 (with capacity) of measured impedance, capacitor 5, resistor b, sinusoidal voltage generator 7, transformer 8 food, primary about the coil 9 of the power transformer with the number of turns WQ, secondary non-switched, located on one core with the primary winding, the winding 10 of the power transformer with the number of turns W, additional secondary: switched winding 11 of the power transformer located on the core turned on i 90 relative to core, on which is located the primary winding, with the number of turns Wj, matching devices 12,13 and 14, phase-sensitive transmitter 12, shaper 16 pulses, amplitude converter 17, blocks 18 and 19 comparison, blocks 20 and 21 equilibrium Hanging unit 22 display.

The device works as follows.

The unbalance voltage V. j, taken directly from the diagonal of the measuring circuit 1, through the matching device 12 is fed simultaneously to the reference input of the phase-sensitive rectifier 15, to the input of the pulse former 16 and the amplitude converter 17. The power supply of the branch containing the measured impedance through matching device 13 arrives at the information input of the phase-sensitive rectifier 15 and at one of the inputs of the comparison unit 18. And the supply voltage of the branch that does not contain the measured impedance Udi through the matching device 14 is fed to one of the inputs of the comparison unit 19. A signal from the output of the phase-sensitive rectifier 15, equal in magnitude to cos ch., Is supplied to the second input of the comparison unit 18. From the output of the pulse shaper 16, a narrow pulse generated at the time of the transition voltage U (-d through zero is fed to the control inputs of the 18 and Comparison 19. The signal from the output of the amplitude converter 17, equal to Vcd, is fed to the first input of the comparator unit 19. Depending on the sign of the voltage level at the output of the comparator unit 18, the equilibration unit 20 blocks or resets all changes of the reference elec cient 2 (R2), depending on the sign of the comparison signal at the output of block 19, block 21 resets the equilibration or block changes the controlled element 11 and the display unit 22 displays the value of the measured parameter.

The use of the proposed AC compensation bridge allows to increase the speed and accuracy of measurement of ASTP impedance components, in which technological process changes are judged by changes in the impedance parameter. The introduction of the amplitude converter and new connections allows the operation of selecting the limit and balancing the measured component at the same time, as a result of which the response speed and the measurement accuracy are increased due to the achievement of complete equilibrium. Invention Formula

An alternating current compensation bridge containing a sinusoidal voltage generator, the output of which is connected to the primary winding of a parametric transformer, is a bridge measuring circuit, one branch of which is composed of a series-connected measuring impedance and a sample element that is uniform to one of the components of the measured impedance the second branch is composed of successively included model elements, one of which is one component of the measured complex the second, its other component, and both model elements, homogeneous to one of the components of the measured impedance, located in the adjacent arms of the branches of the bridge measuring circuit, are connected by honey to form one of the vertices of the diagonals of the branches that contain and not containing the measured complex - resistance, connected to the beginning of the unregulated secondary winding of the parametric transformer and in parallel to the first inputs of the second and third matching devices, the second the top of the power diagonal of the branch, containing the measured impedance, is connected to the end of the unregulated secondary winding of the parametric transformer, to the end of the switched secondary winding of the parametric transformer, which is located on the core rotated i: 90 relative to the core, on which the non-switched secondary winding is located, and the second input of the second matching device, the output of which is connected to the first input of the phase-sensitive rectifier, the second vertex of the power supply diagonal vi, which does not contain the measured impedance, is connected to the beginning of the switched secondary winding of the parametric transformer and to the second input of the third matching device, the top of the measuring diagonal adjacent to the measured impedance is connected to the common bus, the second top of the measuring diagonal is connected to the second input of the phase-sensitive rectifier and through the pulse shaper with the control inputs of both comparison units, the first input the first comparator unit is connected to the output of the phase-sensitive rectifier and the output is connected to the first equilibration unit; The output of the first matching device is connected via an amplitude converter to the first input of the second block of the comparison, the second input of which is connected to the output of the third matching device, Exit second matching

The connecting device is connected to the second input of the first comparison unit.

Sources of information taken into account in the examination

1. Authors certificate of the USSR 491285, cl. G 01 R 17/10, 16.01.73.

2. USSR author's certificate on application 2385167/21, 08/15/76

Claims (1)

Claim Compensating AC bridge containing a sinusoidal voltage generator, the output of which is connected to the primary winding of a parametric transformer, a bridge measuring circuit, one branch of which is composed of series-connected measured complex resistance and a reference element homogeneous to one of the components of the measured complex resistance, and the second branch is composed of series-connected reference elements, one of which is one component of the measured complex resistance, and the second - its other component. Moreover, both model elements, homogeneous to one of the components of the measured complex resistance, located in the adjacent shoulders of the branches of the bridge measuring circuit, are interconnected and form one of the vertices of the power supply diagonals of the branches containing and not containing the measured complex resistance connected to the beginning of the unregulated secondary winding of the parametric transformer and parallel to the first inputs of the second and third matching devices, the second peak the diagonal of the power supply of the branch containing the measured complex resistance is connected to the end of the unregulated secondary winding of the parametric transformer, to the end of the switched secondary winding of the parametric transformer, which is located on the core rotated ± 90 ° relative to the core on which the non-switched secondary winding is located, and to the second input the second matching device, the output of which is connected to the first input of the phase-sensitive rectifier, the second vertex of the branch diagonal power supply, not containing measuring the measured complex resistance, connected to the beginning of the switched secondary winding of the parametric transformer and to the second input of the third matching device, the top of the measuring diagonal adjacent to the measured complex resistance is connected to a common bus, the second top of the measuring diagonal is connected through the first matching device to the second input of the phase-sensitive rectifier and through the pulse shaper with control inputs of both comparison blocks, the first input of the first block cp the output is connected to the output of the phase-sensitive rectifier, and the output is connected to the first balancing unit, the output of the second comparison unit through the second balancing unit is connected to the input of the indexing unit, characterized in that, in order to improve accuracy and speed, an amplitude converter is inserted into it, moreover, the output of the first matching device is connected through an amplitude converter to the first input of the second comparison unit, the second input of which is connected to the output of the third matching device, the output of the second bitch present apparatus is connected to the second input of the first comparator unit.