SU1605294A1 - Method of automatic control of electric load - Google Patents

Abstract

The invention relates to power engineering. The purpose of the invention is to increase the efficiency of control of an electrical load of an enterprise. For this period T hours, the peak of the power system is divided into a number of equal periods of time, in each of which the predicted power is calculated, and in case the predicted power exceeds the claimed power, the consumer-regulators of the corresponding power are turned off. At the same time, the sums of the mutually correlated moments of the predicted load graph of the enterprise are calculated with each of the predicted load charts of the consumer-regulators for period T and the first to turn off the consumer-regulator with the maximum modulo sum of the mutually correlation moments and further as this value decreases . 1 il.

Description

signaling the fact of excess load and rd of outputting numerical values of the expected and current load of the plant and the control unit 11 of hardstacks. g The timer outputs 9 are connected to the control inputs of all units.

To the output of the K1 sensor (1, p) of electrical energy are connected an input switch 12.1 (1..p) (for which g can be used an intermediate power supply), to the second input of which is connected the sensor 13.1 (13.p) of the presence of current. the key 12.1 (2, p) is connected | to the block 14.1 (14, p) controlling the frequency of the J5 of the generator 15.1 (15ep). The output of the generator 15.1 (15, p) harmonic signals is connected to the control input of the block 16.1 () of the parametric load, the output of which is connected to the 20 distribution electric network 17 on the low voltage side of power transformers parallel to their main load IS.HlS.n) , connected to the power source 19 of the network. 25 through a power transformer 20.1 (20.p), cable lines 21, measuring the 5el5-shy current transformer 22.

To the secondary winding of the measuring transformer, an instantaneous value controller with an instantaneous value of currents is connected, the output of which is connected to bandpass filters, the number of which is determined by the number of electric power sensors. Each output of the controller 23 in the environment with the block 24.1 (24, p) decoding, which is a frequency demodulator, and the block 25, the presence of signals, is a threshold device. The output of the block 25 availability About Q signals connected to the input of the block 10 of the display and alarm ,; By the output 24.1 (24.p) of decoding, block 26.1 (24.p) of a comparative section is fitted, the second input

the 30-minute power consumption of the enterprise (P) and the history of electrical consumption during the time intervals ut during period T (peak hours of the power system). According to the signals from timer 9, the information on the 30-minute load (P) enters the comparison block, where it is compared with the 30-minute power received from the assignment block 6 of the task (G eBBe). The results of the comparison | a vl - P t ° M is issued in block

10indications and alarms in the case of -i О,

On a signal from timer 9, information on the consumption of electricity for periods of time At during the period T comes from block 3 to forecast block 4, where it is processed according to a predetermined algorithm and the expected 30-minute load is calculated through the time of prediction, where K 1,2,3, ...).

The expected 30-minute load for the next half hour enters the comparison unit 5, where it is compared with the specified value received from block 6. The comparison result is supplied to decision block 7 if P a is P U2 and U 2 0. In this case, the decisive block 7 which also receives information from block 4 on the forecast load graph (GB) of the enterprise and from blocks 8.1-8. on forecast load charts for the PR, selects consumers-regulators, due to which power consumption is reduced. Management co. the corresponding PR carries the block

11 drive control.

The choice of PR in the decision block is carried out according to the optimal combination of the established priority scale.

which is connected to the line 27. 5 (27. n) j d for example on technological cooperation, and the output key; 28.1 (28.p), which can be represented by logic I. The output of the 26.1 (26.p) comparison unit is connected to the input of the B-flip-flop 29, l (29on) s whose output is connected to the input of the signaling unit 10 and the second input key 28, J (28, n) 5 the output of which is connected to the block 3 of the account,

The system works as follows .55

From the electrical energy consumption sensor 1.1, information about the power consumption of the enterprise enters the metering unit 3, where it forms the values with an additional criterion — the 21VKM module value (the sum of the mutual correlation moments).

According to the forecast schedules, the loads of the PR get a VS with the predicted GN of an enterprise for a period T. According to them, with a step of 0.5 h, VKM is calculated and their sums for the entire period T. The consumer-regulator VKM module for which has the greatest value makes the greatest the contribution to the correlation component of the dispersion D (tfs) and its switching off leads to a higher leveling effect on the GN of the remaining load

the 30-minute power consumption of the enterprise (P) and the history of electrical consumption during the time intervals ut during period T (peak hours of the power system). According to the signals from timer 9, the information on the 30-minute load (P) enters the comparison block, where it is compared with the 30-minute power received from the assignment block 6 of the task (G eBBe). The results of the comparison | a vl - P t ° M is issued in block

10indications and alarms in the case of -i О,

On a signal from timer 9, information on the consumption of electricity for periods of time At during the period T comes from block 3 to forecast block 4, where it is processed according to a predetermined algorithm and the expected 30-minute load is calculated through the time of prediction, where K 1,2,3, ...).

The expected 30-minute load for the next half hour enters the comparison unit 5, where it is compared with the specified value received from block 6. The comparison result is supplied to decision block 7 if P a is P U2 and U 2 0. In this case, the decisive block 7 which also receives information from block 4 on the forecast load graph (GB) of the enterprise and from blocks 8.1-8. on forecast load charts for the PR, selects consumers-regulators, due to which power consumption is reduced. Management co. the corresponding PR carries the block

11 drive control.

The choice of PR in the decision block is carried out according to the optimal combination of the established priority scale.

wives with an additional criterion, the modulus of 21VKM (sum of mutually correlation moments).

According to the forecast schedules, the loads of the PR get a VS with the predicted GN of an enterprise for a period T. According to them, VKM and their sums for the entire period T are calculated in increments of 0.5 h. The consumer-regulator, the VKM module for which has the highest value, introduces the greatest the contribution to the correlation component of the dispersion D (tfs) and its disconnection leads to a higher leveling effect on the GN of the rest of the front load. Further, the PR priority for shutdown by this criterion is established as the size of the 21VKM modules decreases.

An example, the adjustment of the enterprise s 3-minute power is carried out by controlling 22 CR. The maximum maximum Rd (, e. 50 MW. Peak hours of the power system (period T) from 9 to 11 h. The previous and current values of power at the onset of the period T (9 h)) receive predictive GN of all OL and predicted GN for the whole period T. Using them, the values of the mutually correlation moments are calculated at the points 9.9-30.10; 10-30.11 h and their sum for each Jth RH. The VKM sums are ranked in module, starting with the highest. In case of exceeding the predicted value of the plant load, for example 57 MW, the difference between LR 57-50 7 MW is calculated. All P P with Rpro-5n 7 MW. And by the size of the module they choose the most effective of them, shutting down which reduces the great power consumption and leveling out the rest of the load for the entire period T. Since the rest of the load has become more uniform, this additionally provides half-hour power reduction due to equalization. The accuracy of the load forecast increases at the end of the next 3010

Claims (1)

The reliability of the enterprise supply chain is increased. Formula from the source. The method of automatic control of the electrical load of the enterprise during a fixed period is not T hours the peak of the power system, with which the power of the enterprise and the user of the regulators is measured, and the period T is divided into a number of equal periods of time. In which of which the value of the direct power is calculated, the obtained values are compared with the rear power, if the value of the predicted power exceeds the claimed power, the consumers-regulators of the corresponding power are given, differing in that In order to increase the control efficiency, at the time of the longest period T of the peak of the energy period, the enterprise’s capacity is predicted for the entire period T, and the projected load schedule is 20 25 thirty when, as well as carry out the power of each consumer-controller, obtaining a forecast schedule for the load of each consumer-controller, calculate the sum of the mutual-corrective moments of the forecast graph of the load of the enterprise with each forecast graphs of the load of consumers-regulators for period t and the first to turn off consumer-reg ..-. -, h “v (-jLJij j, h jiic i xjoii j I JrvrlclnJ 1 IIU i and cUrl G GJl 6 PG minute period. Use of the leader with the highest modulo sum of the proposed method allows to reduce the number and frequency of PR shutdown, than mutually correlation moments and more as this value decreases b 0 The reliability of the power supply of the enterprise is achieved. The formula of the method and the method of automatic control of the electrical load of the enterprise during a fixed period of time T hours is the peak of the power system, according to which the power of the enterprise and consumers-regulators are measured, and the period T is divided into a number of equal segments time, in each of which the predicted power value is calculated, the obtained values are compared with the power behind the power, and if the predicted power value exceeds the claimed power, the consumers-regulators of power, characterized by the fact that, in order to increase the efficiency of control, at the onset of the period T of the peak of the power system, the enterprise’s capacity is predicted for the entire period of T, obtaining a forecast load schedule of five when, as well as carry out a forecast of the power of each consumer-controller, obtaining a forecast load graph of each consumer-controller, calculate the sums of mutual correlation moments of the forecast load graph of the enterprise with each of the forecast load graphs of consumer-regulators for the period T and the first disconnect consumer regulation iic i xjoii j I Jrvrlclnn 1 IIU i and cUrl G GJl 6 PG torus with the highest modulus mutually correlation moments and further as this value decreases. L g   - j tdd bt "vl L. Editor N.Lazarenko . Compiled by K.Fotin Tehred M. Didyk - Proofreader L. Bezkid Order ZA57 Circulation 412 VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35, Raushsk on: b., D. 4/5 Production and Publishing Combine Patent, Uzhgorod, st. Gagarin, 101 Subscription