SU1117537A1 - Discrete measuring converter of current - Google Patents

Abstract

A DISCRETE MEASURING CONVERTER, containing a primary analog converter, the output of which is connected to the input of the amplifier-limiter included in the polar indicator, and the input of the integrator, is a time pulse converter with a comparison unit. one of the inputs of which is connected to the output of the integrator, a voltage reference block whose output is connected to another input of the comparison unit, and a trigger, a number-pulse converter, a communication line, characterized in that, in order to improve noise immunity, a polar indicator is entered multivibrator, and during a pulse converter there are two stable time slots and an OR element, the input of the multivibrator is connected to the output of the limiting amplifier, and the output is connected to the inputs of the reference voltage unit and both stable time intervals shapers, the output of the first shaper (L stable time intervals are connected to one of the trigger inputs, the other input of which is connected to the output of the OR element, the inputs of the OR element are connected to the outputs of the second shaper of stable time intervals and the comparison unit, and the number-pulse converter connected to the trigger output via a communication line. cd 00

Description

The invention relates to electrical measuring equipment and is intended for use in the implementation of remote current control of high voltage power lines (OHL) and their protection against short circuits (R.3.).

Known used in the systems of control current and relay protection analog transducers (current transformers), made in the form of primary and secondary windings deposited on a ferromagnetic magnetic core. With a rated voltage of overhead lines up to 35 kV, such measuring transducers are obtained with rather simple and inexpensive G13.

However, the higher the rated voltage of an overhead transmission line, the more cumbersome and expensive the insulation of the primary winding becomes. With a rated voltage of overhead lines of more than 750 kV, electromagnetic transducers are becoming more difficult to implement.

Closest to the invention is a discrete current transducer (discrete current transformer) containing a primary analog transducer, the output of which is connected to the input of a limiting amplifier included in the polar indicator, and to the integrator input, a time transducer with a comparison unit, One of the inputs is connected to the integrator output, a voltage reference block, the input of which is connected to the output of the amplifier-limiter, and the output to another input of the comparison unit, and a trigger The inputs of which are connected to the outputs of the Comparison Unit and: an amplifier-limiter, a pulse-pulse converter, the input of which is connected to the trigger output, and the output is connected to the communication line that goes to the converter load,

In the known device, a transition is made to a discrete form of displaying information on the integral parameters of an overhead line current, in particular, on its effective value and phase, which allows using a cheap but low-power primary analog converter, such as a magnetic current transformer, in the device, and it is possible to build control systems current and decisive protection of overhead lines in which the nodes receiving information are located at a considerable distance (100,200 m) from the installation site of the primary converter 2J .

However, the known device, when transmitting multi-pulse measurement information signals over a communication line, is perceived by individual interfering pulses as signals on the receiving side, which negatively affects the accuracy of current control. Real

The relatively wide bandwidth of the measuring channel, due to the use of the number-pulse form of information display, also contributes to a significant interference effect.

The purpose of the invention is to increase the noise immunity of the converter.

The goal is achieved by T-eKf that, in a discrete current measuring transducer containing a primary analog transducer, the output of which is connected to the input of a limiting amplifier included in the polar indicator, and the integrator input, time pulse converter with a comparison unit, one of the inputs which is connected to the integrator output, a voltage reference block, the output of which is connected to another input of the comparator unit, and a trigger, a number-pulse converter, a communication line, and, in turn, a switch the submitter has two stable time intervals shapers and an OR element, the multivibrator input is connected to the output of the limiter amplifier, and the output is connected to the inputs of the reference voltage unit and both stable time intervals shapers, the output of the first stable time intervals shaper is connected to one of the trigger inputs, the other the input of which is connected to the output of the OR element, the inputs of the OR element are connected to the outputs of the second shaper of stable time intervals and the comparison unit, and the output is a number-pulse A transducer is connected to the trigger output via a communication link.

Fig, 1 shows the functional diagram of the proposed discrete current transducer; in fig. 2 - timing diagrams at the outputs of individual composite nodes, explaining the operation of the device

The device consists of a primary analog converter 1, a polar indicator 2 with an amplifier-limiter 3 and a multivibrator 4, an integrator 5, the time of a pulse converter 6 with a comparison unit 7, a reference voltage unit 8, stable time intervals 9 and 10, an OR element 11 and trigger 12, links 13 and the number of pulses. The output of the primary analog converter. 1 is connected to the inputs of the amplifier limiter 3 and integrator 5, the output of the amplifier limiter 3 is connected to the input of the multivibrator 4, the output of the integrator 5 is connected to the first input of the comparison unit 7, the output of the multivibrator 4 is connected to the input of the reference voltage block 8 and the inputs of the formers 9 and 10 stable 311 time intervals, the output of the reference voltage unit 8 is connected to the third input of the comparison unit 7, the output N of the driver 9 stable time intervals is connected to the first input of the trigger 12, the output of the driver 10 stable times the terminals are connected to the first output of the OR element 11, the output of the comparator unit 7 is connected to the second input of the OR element 11, the output of the OR element 11 is connected to the second input of the trigger 12, the output of the trigger 12 is connected to the beginning of the communication line 13, the end of the communication line 13 is connected to the input of the number-pulse converter 14. The operation of the device is conveniently analyzed by the example of its use in the over-current protection of a zero-sequence overhead line. In this case, the primary analog converter 1 uses a zero-sequence current filter consisting of three magnetic current transformers. When k.z. At the moment t, corresponding to the beginning of the damage, a voltage appears on the output of the primary analog converter 1, and (Fig. 2a) proportional to the current ifl f but shifted relative to it in phase 90 ° in the direction of advance, since the magnetic current transformers operate in the transformer mode. , 1 ° - 1 u) J, (2) i 1 from t is the conversion factor of the primary analog npe generator 1. Polar indicator 2 reproduces the moments of voltage curve transition and through zero value, providing overall coordination of work and tat separate units of the device With the help of the limiting amplifier 3, the sinusoidal voltage is converted into a rectangular voltage DS. (Fig.26) with equal duration of half periods T (+) and (.). Along the fronts of the signals Uj, synchronization of the multivibrator 4 tuned to a frequency of 50 Hz is performed. Thus, the voltage and (Fig. 26) at the output of the multivibrator 4 after time point t | j completely coincides with the nS phase and form with the signals Uj of the amplifier-limiting 3. The presence of the multivibrator 4 provides in some cases a reduction in the dynamic errors of the device and allows, as will be shown, to produce 1-ms control single-pulse signals even in the absence of i, which contributes, to a certain extent, to an increase in the noise immunity of the device and to the implementation of a thorough test of its performance under normal conditions. Noah work overhead. The integrator 5 integrates the voltage U at intervals T (.j. At a sinusoidal current IQ and a constant frequency, the output voltage SC (Fig. 2a) of the integrator 5 each time reaches the value Cly, which is proportional to the current value of current E during the positive half-period : 1 LCH1M-o1) / T 5 om-rFk, K, D where t. and the time points marking the beginning and the end of the interval T (), the conversion factor of the integrator 5. Time pulse converter 6 each period performs a logarithmic transformation of the voltage Uj. in the time interval g,. Using the reference voltage unit 8, controlled by the output signals of the multivibrator 4, the voltage i5- (fig. 2a) is generated per-period, decreasing each time from the maximum value Ug by an exponential law with a constant time 3 reference ms can be implemented, for example, in the form of functionally connected voltage converters, a linear compensating stabilizer, a control key, a capacitor and resistors in the charge and discharge circuits of the capacitor. At times t corresponding to the equality of the voltages U and UQ, both compared voltages are forcibly reduced from zero, and the comparison block 7 generates a pulse that flips trigger 12 through the OR 11 element 11. Trigger 12 returns to its initial state with signals u5 (Fig. 2c) with a duration of 9 ms, generated by the shaper 9 stable time intervals. As a result, k.s. signals 2 (fig.2g) occur on the ground in an overhead line at the output of flip-flop 12, the duration of which corresponds to -G, the Anshytic formula for t is determined by equating to each other the written expressions (3) and (4) for u g, -. Eno -o min min lower limit of the monitored range (at Tg, expressed in milliseconds, .o / iin, 8) Since the trailing edges of the signals are oriented under the influence of a shaper 9 stable time intervals and do not depend on the moment of voltage junction on the location on the time axis C through a zero value with a positive derivative, it is not difficult to verify that the device has a transient error from industrial frequency fluctuations. In the absence of a short circuit, to the ground in BL, that is, in normal mode, the last (diagrams in fig. 2 up to t J, there are also no voltages C, Uj, pulses at the output of the comparison block 7 do not appear, and initial flips of the trigger 12 are carried out with the help of signals (Fig. 2c) with a duration of 8 ms stable time interval shaper 10. However, trigger 12 is reset to its initial state as before with signals Ug from stable time interval shaper output 9. As a result, in normal VL mode, output U at the output of trigger 12 occurs (Fig. 2d), the duration of which corresponds to the time pedestal g - 1 ms. One pulse signal U (normal mode VL) or and, (if the VL is damaged) is sent via the wired communication line 13 (along the wires of the control cable) to the relay protection panel. Directly at the relay protection panel, a number-pulse converter 14 is installed, in which the received signals U, or C, are filled with high-frequency pulses f. In the end, at the output of the number-pulse converter 14, multi-pulse signals are formed and or, and., (Fig. 2d), the number of pulses in each of which corresponds either to the signals and the numerical pedestal W serve, as already noted, to check (ascertain) the health of all device nodes. The signals U, with the number of pulses NJ, are measurement information signals and determine the action or failure of the overhead line relay protection system as a whole. Placing the N-pulse pulse converter 14 next to the information sensing nodes and realizing that the transmission of single-pulse signals with a time pedestal on link 13 provide an increased noise immunity of the proposed discrete current-measuring transducer. This is because the single-pulse signals require significantly less on the order of the bandwidth of the measuring channel than for multipulse signals, and, therefore, it is possible by setting narrowband filters to prevent penetration of high-frequency markings on the receiving side. If there is a time pedestal t, and a numerical pedestal N, it is easy to erase (reset) false information, characterized by W | N. The duration of the most common impulse noise on the territory of a power facility does not exceed one millisecond, i.e. the duration of the selected, temporary pedestal. The proposed discrete measuring current transducer can, in principle, also be of full-wave performance, in which the formation of measurement information signals takes place during each period. The noted structural realization of the device is coupled with the doubling of the majority of component blocks and, as a result, can be used only in those current control systems and relay protections to which especially high speed requirements are imposed. The reduction in the likelihood of improper operation of the relay protection systems under the effect of interference, provided by the practical use of the proposed device, reduces the interruptions in the power supply of consumers.

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Claims (1)

A DISCRETE MEASURING CURRENT TRANSDUCER containing a primary analog converter, the output of which is connected to the input of an amplifier-limiter, which is part of the polar indicator, and to the input of an integrator, a time-pulse converter with a comparison unit, one of the inputs of which is connected to the integrator output, a reference voltage block, the output which is connected to another input of the comparison unit, and a trigger, a pulse-number converter, a communication line, characterized in that, in order to increase noise immunity, in the field the multivibrator is inserted, and during the pulse converter there are two shapers of stable time intervals and an OR element, the input of the multivibrator connected to the output of the limiter amplifier, and the output to the inputs of the reference voltage unit and both shapers of stable time intervals g, the output of the first shaper stable time intervals connected to one of the inputs of the trigger, the other input of which is connected to the output of the OR element, the inputs of the OR element are connected to the outputs of the second driver GOVERNMENTAL time intervals and comparing the block number and the input-pulse converter connected to the output latch via the communication line. SU. ,, 11175