SU611268A2 - Frequency relay - Google Patents

Description

(54) FREQUENCY RELAY

FIG. 1 shows a diagram of the described relay; in fig. 2 - voltage diagrams.

It contains a shaper of I rectangular pulses, consisting of an amplitude limiter and a zero organ, a block 2 for generating a counter reset pulse to "O, a shaper of 3 short pulses measuring the period of the network frequency, a master oscillator 4 of the reference frequency, 5 counters of pulses, a decoder 6 response frequency settings, decoder 7 filling counter 5, trigger 8, element 9, trigger 10, frequency divider 11, element 12, pulse counter 13, power amplifier 14, response body 15. Shaper 1 rectangular pulse connection n through a reset unit 2 with a counter of 5 pulses, the master oscillator 4 is connected to the input of counter 5, the output of which through decoders 6 and 7 is connected to two inputs of the trigger 8. The output of trigger 8 is connected to one of the inputs of the AND 9 element, the second input of which is connected with the driver 3 short pulses, and the output of the element And 9 is connected to the input of the second trigger 10. Simultaneously, the output of the trigger 8 is connected to the input of the frequency divider J1, and the input of the installation of the divider 11 to “O is connected to the output of the unit 2. element and 12, sec second input of which is connected to the output of the master oscillator 4. At the output of AND gate 12 are enabled counter 13 pulses, the amplifier 14 output and responsive actuator 15, and set input 13 of the counter at 0 is connected to the output of flip-flop 10.

A controlled voltage of alternating current is applied to the input of the relay, which is converted by the pulse shaper to square pulses; the duration of the pulses corresponds to a positive half-period, and the pause to a negative one. The imaging unit 3 issues short pulses at the end of the period, and the reset unit 2 outputs a short pulse at the beginning of the period, spaced in time with the impulse at the output of the imaging unit 3 on the 10th ISS. This ensures that the triggers of the counter 5 are set to "0" only after reading the information at the end of the period.

The settings of the relay frequency settings are made by the decoder 6 according to the state of the triggers of the counter 5 at the end of the period at a given network frequency. Additional decoder 7 provides a reset information from the trigger 8 with each filling of the counter. This eliminates information about the part of the period that does not change in a given range of adjustment settings.

If at the end of the period at the moment of appearance of a pulse at the output of the driver 3, the signal at the output of trigger 8 is equal to "1, the signal at the output of element And 9 is absent, the state of trigger 10 does not change, and at its inverse output the signal is" O. If at the end of the period of resetting information from trigger 8, there was no signal at its output "O, then

ps) YE) A signal “O from the output of the mold 3 appears at the output of the el (.-meit I 9 and the state of the trigger 10 changes. At its output appears the signal“ 1 that occurs only at the network frequency equal to or less than the frequency of the lowering relay. In the STOM Cm, the counter no longer stops and is ready for counting the pulses arriving at its input.

Consequently, when the frequency decreases in j of the network below the setpoint frequency, due to an increase in the duration of the period between the appearance of the last signal O at the output of the trigger 8 and the signal at the output of the generator 3, a time interval appears that increases with a further decrease in frequency. In order to exclude information about a part of the period that does not change in the range of possible frequency reduction from 50 to 45 Hz, a frequency divider is turned on at the output of trigger 8. Since the number of fillings of the counter 5 at a frequency of 49.5 Hz is equal to 5 5, and at a frequency of 45 Hz is equal to 5 5.5, the signal at the output of the divider I appears only after 5 pulses are received at the input of its input. Only after the occurrence of pulses "1 at the output of the divider 11 through the element 12 and 12, inputs 5 of the counter 13 begin to receive pulses with a frequency of generator 4. At the beginning of each period, the pulse from block 2 counters 5 and the divider 1 I are set to" O. In this case, the arrival of pulses at the input of the counter 13 is stopped until the next filling of the frequency divider 11.

The number of high frequency pulses, which is fed to the input of the counter 13 for each period depends on the duration of the period. Consequently, when the frequency is deeply reduced, the counter is filled quickly, and at a frequency equal to the relay trigger frequency, one pulse per pulse is sent to the counter, and the relay response time is maximum.

When the duration of the voltage period in the controlled network is equal to it, the frequency below the response setpoint corresponds to it. At this frequency, the signals at the output of the flip-flops 8 and 10, respectively, Hi and Hs, and at the output of the divider 11, the signal From. It is the duration of the voltage pulse From that determines the number of voltage pulses AND, coming through the element 12 to the input of the counter 13 for one period. The range of variation of the time delay for triggering in a given range of frequency variation in the energy system is set by the required minimum; by selecting the frequency of the generator 4 and the capacity of the counter 13. Thus, with a frequency of the master oscillator 63.4 kHz, the minimum time delay is triggered5. 0.2 seconds at 45 Hz to the input of the counter 13 for one period receives 128 pulses when the charter. ke act. When the frequency in the monitored network rises above the trigger setpoint frequency, the output of the trigger 10 shows the signal "O, which is off. 3 from 0 clearing the information from the counter 13. 1ln. This was in the activated state, then it returns. If the relay does not have time to work, then after the reset, it does not work. The circuit of the described frequency relay with inverse time delay provides a much larger range of time delay with frequency change than the known frequency relay with time delay, and also allows to obtain greater stability and accuracy of the response characteristics. The latter is determined by the fact that the relay is filled with both counters by pulses from a quartz oscillator at the same frequency. Formula // Lobregenk Relay frequency auth. St. No. 498682, st. To / to, that, in order to increase reliability by ensuring that the response time is inversely dependent upon a frequency change below the response setpoint, the series divider, the And element and the second pulse counter are additionally entered, the frequency divider input connected to the output of the first trigger relay, and the installation of the frequency divider to zero is connected to the output of the reset unit, the second input element And is connected to the output of the master oscillator, the input setting the second counter to zero with one with the output of the second latch relay, and the output of the second counter is connected to the input of amplifier MOUIHOCTH.

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