SU1014085A2 - Frequency relay - Google Patents

Abstract

RELAY FREQUENCY by aut. St. No. 498682, characterized in that, in order to increase functionality, by varying the response frequency depending on the time, a delay line j is inserted in the match circuit j and the AND element, the first inputs of which are connected via the delay line to the output of the reset unit startup, clock pulse generator, clock pulse counter, the counting input of which is connected to the clock pulse generator, the setup input is well. the left state — with the output of the element I, and the output — with the second input of the coincidence circuit; pulses, and the output is connected to the second input of the element I.

Description

The invention relates to electrical engineering and is intended for automatic frequency unloading (AChR) of power systems in the event of a shortage of active power by switching off low-power consumers by combining the functions of regular AChR-1 and AChR-2. BASIC Tue St. N 98682 a frequency relay is known which contains a generator-reference frequency, a pulse counter, the counting input of which is connected to the output of the reference frequency generator, a decoder for the response setpoint, a decoder for the counter, and a trigger, whose inputs through the decoder for the setpoint and decoder for the counter. the counters are connected to the outputs of the pulse counter, and the output is connected to the first input of the element I, the reset unit, the shaper of short pulses and the shaper of rectangular pulses with the network frequency, the output of which is connected to the inputs of the reset unit and the short pulse shaper, the output of the short pulse shaper is connected to the second input of the element I, and the output of the reset unit to the zero state setting inputs of the pulse counter trigger jl The disadvantage of the known device used as a frequency-sensitive organ of the next ACH is that, in order to ensure the selective operation of the AChR queues, it is necessary in conjunction with the above mentioned ones — the frequency relays use time delay bodies that have either fixed or dependent the frequency of the voltage controlled network actuation setpoint. Such an AChR queue structure cannot ensure the timely selective and reasonable disconnection of consumers in all possible variants of the flow of systems. Partial accidents associated with the occurrence of an active power deficit, especially in frequency recovery. The purpose of the invention is to increase the functionality by varying the frequency of operation as a function of time. This goal is achieved by additionally introducing a delay line, a coincidence circuit and an AND element, the first inputs of which are connected via a delay line to an output reset block, a start frequency decoder, a clock generator, a clock counter, the counting input of which is connected to the known device. with a clock pulse generator, the zero state input input — with the output of the element I, and the output — with the second input of the coincidence circuit, and the output of the coincidence circuit i is not connected to the input of the installation in the unit state rigger pulse counter trigger inputs of which run through the decoder and decoder frequency fill counter connected to the outputs of the pulse counter, and an output connected to the second input element I. In FIG. 1 is a block diagram. proposed frequency relay; in fig. 2 and 3 are characteristics of the device response frequency versus time. The device contains a separation transformer 1, a shaper of 2 rectangular pulses consisting of an amplitude limiter and a null organ, a reset unit 3, a shaper of short pulses of measuring the controlled voltage period, a reference frequency generator 5, a pulse counter b, a decoder of the response frequency setpoint 7, the decoder 8 fill the counter, trigger 9, element I 10, trigger 11, power amplifier 12, output actuator relay 13, decoder I start frequency, trigger 15, element And 16, counter 17 clock pulses, 18 clock pulse generator, delay line. 19, coincidence circuit 20, the voltage of the monitored network through the isolation. The transformer is fed to the input of the former 2 rectangular pulses following the voltage frequency of the controlled network and arriving at the inputs of the reset unit 3 and the former k short pulses. At the end of each period of monitored voltage, the driver generates a pulse, which, acting on the element 10, transfers information about the state of the trigger 9 to the trigger 11, the output of which is converted by the power amplifier 12 to two levels sufficient to control the output executive relay 13. The zero state of the trigger 11 triggers the output of the executive relay 13. The reset unit 3 at the beginning of the period, the monitored voltage produces a short pulse spaced in time with the output pulse It is the driver 4. This ensures that the triggers of the counter 6 are set to the zero state only after reading the information at the end of the period. The output signal of the delay line 19, separated in time with the output signal of the reset unit 3, which sets the triggers of the counter 6 to the zero state, records the number stored in the triggers of the counter 17, into the triggers of the counter 6, last, through the coincidence 20, into one a state if the corresponding triggers of the counter 17 are in a single state. Circuit 20 generates an output signal when i matches two single signals at its input. Thus, the response frequency of the device, which is set on the decoder 9 set, varies: the response frequency. During the period of monitored voltage, the meter is repeatedly filled with 6 pulses that are generated by this 5-frequency oscillator. At the same time, multiple triggers 9 and 15 are set by the output signals of the decoder 7 of the response frequency set and the decoder 1 4acTotb (start to zero state and return them to one state by the output signal of the decoder 8 counter. If the input signal frequency exceeds the value the trigger frequency settings set on the decoder 7 and the trigger frequency on the decoder 14, the triggers 9 and 15 will be in the unit state at the end of the period of the monitored voltage. the voltage exceeds the trigger frequency specified on decoder 14, then at the beginning of each period the single output signals of the trigger 15 and the delay line 19 add up at the inputs of the element. AND 16, will set the triggers of the counter 17 to the zero state. At the beginning of each measurement cycle, the duration of the period of monitored voltage, the triggers of counter 6 will also be set to the zero state, and the device response frequency will be determined by the decoder 7 of the frequency setting. When the frequency of the input voltage drops below the start frequency specified on the decoder 14, the triggers of the clock counter 17 stop at the beginning of each period of the monitored voltage stop. The state of the trigger trigger counter 17 6-. The details correspond to the number of clock pulses received by its counting input from generator 18 from the moment when the frequency of the monitored voltage is lower than the starting frequency. If the counter 17 performs the summing of clock pulses, the response frequency of the device will increase (Fig. 2), and if the counter 17 performs subtraction, then the response frequency fcpqp will decrease (Fig. 3). If it is necessary for the device to operate when the frequency of the input signal rises above the trigger frequency, then the output signals of the EY 15 flip-flops should use the voltage of their inverse outputs. The rate of change of the frequency of operation of the proposed device, i.e. the slope of the response characteristic (Fig. 2 and 3) can be adjusted by changing the frequency of the 18 clock pulse generator. The introduction of additional elements into the well-known relays made it possible to change the setpoint of the frequency of operation as a function of time, which made it possible to combine the functions of the AChR-1 and AChR-2 queues in one device. The response characteristics of the proposed frequency relay (Figs. 2 and 3) allow for fast drops in frequency to disconnect consumers without a time delay, when a frequency hangs below a start frequency, to disconnect consumers with time delays that guarantee the selectivity (specified sequence) of the shutdown, and restoring the frequency of the power system at a rate exceeding the rate of increase in the setpoint frequency of the operation of the proposed device is to stop further disconnection of consumers. The application of the proposed device in the AChR circuits will ensure the timely shutdown of the optimally 5UOUT3

GB load volume at different power capacities, i.e. will increase the occurrence of systemic accidents on the pipeline, the reliability of the power system in the case of scarce scrap.

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Claims (1)

FREQUENCY RELAY St. No. 498682, characterized in that, with the goal of increasing functionality by changing the response frequency depending on time, a delay line, a matching circuit, and an And element are introduced into it, the first inputs of which are connected to the output of the reset unit through a delay line, and a trigger frequency decoder , a clock generator, a clock counter, the counting input of which is connected to a clock generator, the installation input is well. the left state — with the output of the And element, and the output — with the second input of the coincidence circuit, and the output of the coincidence circuit connected to the unit's input state to the triggers of the pulse counter, a trigger whose inputs are connected to the outputs of the pulse counter through the start frequency decoder and the fill fill decoder, and the output is connected to the second input of element I. 1 1014085