RU2398338C1 - Method for automatic load transfer (versions) and device for its realisation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method consists in measurement of positive-phase-sequence voltage of redundant power supply sources buses, linear voltages in buses of the main power supply source, angle between vectors of positive-phase-sequence voltages of the main and redundant power supply sources, separate measurement of the following for each of three phases at the input to the main source - value of existing current in phase and value of angle between vector of complex existing current in the same phase and vector sum of complex existing voltage between two other phases on buses of the main source and accepted as equal to 0-50% of share in identical complex existing voltage in buses of redundant source, measurement of angle between vectors of positive-phase-sequence voltages in the main and redundant sources in specified time gap and switching supply of main source buses to redundant one as any of measured voltages reduces in buses of main source below specified value or as angle increases between vectors of positive-phase-sequence voltages in buses of the main and redundant sources over specified value or as angle changes between vectors of positive-phase-sequence voltages in buses of the main and redundant sources in specified time gap over specified value, when simultaneously value of existing current in any phase at the input of the main supply source and value of angle between vector of complex existing current in the same phase and above specified vector sum reach specified area of values, and positive-phase-sequence voltage on buses of redundant supply source exceeds specified value.

EFFECT: improved efficiency.

4 cl, 2 dwg

Description

Technical field

The invention relates to electrical engineering, in particular to emergency control devices for electrical substations and distribution devices of low, medium and high voltage, and can be used to detect power failure of consumers of the main power source for any type of damage in the power supply network section of the switchgear and the implementation of high-speed switching to a backup power source.

State of the art

A known method of automatically turning on backup power supply to consumers (AS USSR No. 1728927, class H02J 9/06, 1990), which consists in measuring the voltage of the direct sequence of buses of the main and backup power sources, the angle between the voltage vectors of the direct sequence of buses of the main sequence of the buses of the main and backup sources power supply, determining the direction of active power on the input busbars of the main power supply, switching the main power supply bus to the backup power supply while reducing the voltage of the direct bus line sequence a new source below a predetermined or exceeding the angle between the direct sequence voltage vectors is greater than the specified one and when the active power is directed from the buses to the main power source, the direction and value of the reactive component of the direct sequence current at the input of the main source buses, the voltage of the reverse sequence voltage of the main source buses and when the direction of the reactive current component of the direct sequence from the tires to the main source and exceeding the last and the voltage of the reverse sequence of tires of the main source of the set values also switch the buses of the main source to the backup power source, and simultaneously with switching in all cases, the excitation of synchronous motors is forced.

The disadvantages of this method include the impossibility of detecting single-phase, two-phase and two-phase to ground short circuits in the consumer power circuit, due to the fact that in these modes the direction of the active power at the input of the substation does not change and its consumption continues with the connected power consumers. For any short circuits in the power circuit, the direction of the reactive component of the direct sequence current does not change in the absence of motor load on the sections.

This invention is the closest technical solution to the claimed invention, i.e. prototype. Disclosure of invention

The objective of the invention is the implementation of the ability to quickly respond to any disturbances in the normal power supply of consumers occurring in the circuit of their main power source and include all types of short circuits with subsequent switching of consumers to a backup power source. The method allows you to quickly respond to power outages on switchgears with and without electric motor load, as well as powered from unsynchronized power sources.

The specified technical result according to option 1 is achieved by creating a method for automatically turning on the backup power supply of consumers, in which the direct sequence voltage is measured on the buses of the backup power source, instead of directing the active power at the input of the main power source for each of its three phases, the value of the current in phase and the value are measured the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between two other phases on the buses of the main power supply and an equal to 0% to 50% share of the complex active voltage of the same name on the tires of the backup power supply, instead of the direct sequence voltage on the buses of the main power supply, measure the line voltages on the same buses and issue a command to switch the power supply of the buses of the main source on standby when any of the measured voltages on the tires of the main power source decreases below a predetermined value, when at the same time the value of the effective current in l any of the phases at the input of the main power source and the value of the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between the two other phases on the buses of the main power source and taken from 0 to 50% of the share of the same complex effective voltage on the tires the redundant power supply reaches a predetermined range of values and the voltage of the direct sequence on the tires of the redundant power supply exceeds a predetermined value.

Also, the specified technical result according to option 2 is achieved by creating a method for automatically turning on the backup power supply to consumers, in which direct voltage is measured on the buses of the backup power source, the angle between the voltage vectors of the direct sequence of the buses of the main and backup power sources, instead of directing the active power to the input of the main power source for each of its three phases, the value of the effective current in the phase and the value of the angle between the vector current rms in the same phase and the vector sum of the complex rms voltage between the two other phases on the buses of the main power source and taken equal to from 0 to 50% of the share of the same complex rms voltage on the buses of the backup power source and give the command to switch the bus voltage of the main source to backup when increasing the angle between the voltage vectors of the direct sequence of buses of the main and backup power sources above a specified value, when at the same time e of the effective current in any of the phases at the input of the main power source and the value of the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between the two other phases on the buses of the main power source and taken from 0 to 50% of the share of the same complex the effective voltage on the tires of the backup power source reaches a predetermined range of values and the voltage of the direct sequence on the tires of the backup power source exceeds the specified value.

The specified technical result according to option 3 is achieved by creating a method for automatically turning on the backup power supply of consumers, in which the direct sequence voltage is measured on the buses of the backup power source, instead of directing the active power at the input of the main power source for each of its three phases, the current value in phase and the value are measured the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between two other phases on the buses of the main power supply and an equal to 0 to 50% share of the complex active voltage of the same name on the buses of the backup power supply, additionally measure the change in the angle between the voltage vectors of the direct sequence of the buses of the main and backup power supplies for a given period of time and give a command to switch power busbars of the main source to the standby when changing the angle between the voltage vectors of the direct sequence of buses of the main and standby power sources for a given period of time above a specified value, when at the same time the value of the effective current in any phase at the input of the main power source and the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between two other phases on the buses of the main source power supply and assumed equal to from 0 to 50% of the share of the same complex effective voltage on the tires of the backup power source reach a predetermined range of values and direct voltage Sequences on the buses of the redundant power supply exceed the set value.

The specified technical result is achieved by creating a device for automatically turning on the backup power supply of consumers, containing the main and backup power supplies, input switches of the main and backup power supplies, a section switch, buses of the main and backup power supplies, a set of measuring current transformers at the input of the main power supply, measuring kits voltage transformers on the tires of the main and backup power supplies, auto starter a reserve switching unit comprising a third phase current recovery unit, equipped with three output channels an analog-to-digital current converter, the input of which is connected to the output of a set of measuring current transformers through a third phase current recovery unit, equipped with three output channels of an analog-to-digital voltage converters, the inputs of which are connected with outputs of sets of measuring voltage transformers on the buses of the main and backup power sources, voltage detection units direct sequence voltage on the buses of the main and backup power supplies, the inputs of which are connected to the output channels of analog-to-digital voltage converters on the buses of the main and backup power supplies, respectively, the maximum voltage relay unit, the input of which is connected to the output of the direct sequence voltage detecting unit on the buses of the backup source power supply, relay block for determining the angle between the direct sequence voltage vectors on the buses of the main and backup sources power supply, the inputs of which are connected to direct sequence voltage detection units on the buses of the main and backup power sources, a device that switches to the backup power source with the main contacts of the section switch closed at the time close to common mode, between the same voltage on the buses of the main and backup sources power, activated upon receipt of a command to turn on the reserve from the starting device, while the starting device for automatically turning on Zrava contains blocks of special relay organs for phase-by-phase control of the current direction, each of which is respectively connected to one of the three output channels of the analog-to-digital current converter, which is the current channel in one of the phases of the main power source, one of the three output channels of the analog-to-digital voltage converter tires of the main power source, which is the voltage channel on the buses of the main source between two other phases, and one of the three output channels of the analog-to-digital converter voltage on the tires of the backup power source, which is the voltage channel on the tires of the backup source between the same phases as on the tires of the main source, the relay unit of the minimum voltage of three, the inputs of which are connected to the output channels of the analog-to-digital voltage converter on the tires of the main power source, relay unit for determining the change in angle over a fixed time interval between the direct sequence voltage vectors on the buses of the main and backup power sources, corresponding the inputs of which are connected to direct sequence voltage detection units on the buses of the main and backup power sources, the “AND-NOT” logical element, the corresponding inputs of which are connected to the outputs of the blocks of special relay organs for phase-by-phase control of the current direction, the “AND” logic element, the corresponding inputs of which are connected with the outputs of the undervoltage relay block of three, the overvoltage relay block and the AND-NOT logic element, the second AND element, the corresponding inputs to of which are connected to the outputs of the relay block of the maximum voltage, the relay block of determining the angle between the voltage vectors of the direct sequence on the buses of the main and backup power sources, the logical element "NAND", the third logical element "AND", the inputs of which are connected to the outputs of the relay block of the maximum voltage , relay block for determining the change in angle over a fixed time interval between the voltage sequence vectors of the direct sequence on the buses of the main and backup power sources, of the “AND-NOT” element, the “OR” logic element, the corresponding inputs of which are connected to the outputs of the three “AND” logic elements, the output unit, the input of which is connected to the output of the “OR” logic element, and the output - with the input switch of the main power supply on the circuit-breaker opening channel and with the sectional on-off channel on the channel of its inclusion through the device for selecting the conditions for switching to the backup power source, which is activated when the reserve enable command is received from the starting device.

Brief Description of the Drawings

Figure 1 shows a single-line circuit of a switchgear, including input and sectional switches, measuring current and voltage transformers, a block diagram of the operation of a microprocessor-based starter for automatic automatic switching of a reserve and an intermediate control device for switches.

Figure 2 presents an illustration of the operation of the unit of a special relay body for phase monitoring of the direction of the current on the complex plane.

The invention is as follows.

,

,

аналого-цифровой преобразователь токов 14, вход которого соединен с выходом комплекта измерительных трансформаторов тока 8 через блок восстановления третьего фазного тока 13; снабженные тремя выходными каналами

,

,

и

,

,

аналого-цифровые преобразователи напряжений 15 и 16, входы которых соединены с выходами комплектов измерительных трансформаторов напряжения на шинах основного и резервного источников питания 9 и 10 соответственно; блоки определения напряжений прямой последовательности 17 и 18 на шинах основного и резервного источников питания 6 и 7, входы которых соединены с выходными каналами аналого-цифровых преобразователей напряжений 15 (

,

,

) и 16 (

,

,

) соответственно; блоки особых релейных органов пофазного контроля направления тока 19, 20, 21, каждый из которых соответственно контролирует один из трех выходных каналов

,

,

аналого-цифрового преобразователя токов 14 (значение тока в одной из фаз основного источника питания), один из трех выходных каналов

,

,

аналого-цифрового преобразователя напряжений 15 (значение напряжения на шинах основного источника между двумя другими фазами) и один из трех выходных каналов

,

,

аналого-цифрового преобразователя напряжений 16 (значение напряжения на шинах резервного источника между теми же фазами, что и на шинах основного источника); релейный блок минимального напряжения из трех 22, входы которого контролируют выходные каналы

,

,

аналого-цифрового преобразователя напряжений 15; релейный блок максимального напряжения 23, вход которого соединен с выходом блока определения напряжения прямой последовательности 18 на шинах резервного источника питания 7; релейный блок 24 определения угла между векторами напряжений прямой последовательности на шинах основного и резервного источников питания 6 и 7, входы которого соединены с блоками определения напряжений прямой последовательности 17, 18 на шинах основного и резервного источников питания 6 и 7 соответственно; релейный блок 25 определения изменения угла за фиксированный интервал времени между векторами напряжений прямой последовательности на шинах основного и резервного источников питания 6 и 7, входы которого соединены с блоками определения напряжений прямой последовательности 17, 18 на шинах основного и резервного источников питания 6 и 7 соответственно; логический элемент «И-НЕ» 26, входы которого соединены с выходами блоков особых релейных органов пофазного контроля направления тока 19, 20, 21; логический элемент «И» 27, входы которого соединены с выходами релейного блока минимального напряжения из трех 22, релейного блока максимального напряжения 23 и логического элемента «И-НЕ» 26; логический элемент «И» 28, входы которого соединены с выходами релейного блока максимального напряжения 23, релейного блока 24 определения угла между векторами напряжений прямой последовательности на шинах основного и резервного источников питания 6 и 7, логического элемента «И-НЕ» 26; логический элемент «И» 29, входы которого соединены с выходами релейного блока максимального напряжения 23, релейного блока 25 определения изменения угла за фиксированный интервал времени между векторами напряжений прямой последовательности на шинах основного и резервного источников питания 6 и 7, логического элемента «И-НЕ» 26; логический элемент «ИЛИ» 30, входы которого соединены с выходами логических элементов «И» 27, 28, 29; выходной блок 31, вход которого соединен с выходом логического элемента «ИЛИ» 30, а выход с вводным выключателем основного источника питания 3 по каналу отключения выключателя и с секционным выключателем 5 по каналу его включения через устройство 12 выбора условий (момента) осуществления переключения на резервный 2 источник питания, активирующееся при поступлении от микропроцессорного пускового устройства 11 команды быстродействующего включения резерва.A device designed to implement this method of high-speed automatic inclusion of backup power consumers (figure 1), contains the main 1 and backup 2 power sources; introduction switches of the main and reserve power supplies 3 and 4; section switch 5; main and backup power supply buses 6 and 7; a set of measuring current transformers 8 at the input of the main power source 1 (including two or three transformers); sets of measuring voltage transformers 9 and 10 on the buses of the main and backup power supplies 6 and 7 (including three transformers); microprocessor starting device for high-speed automatic inclusion of a reserve 11; a device 12 that switches to the backup 2 power source (closing the main contacts of the sectional switch 5) at a point in time close to the common-mode voltage between the same voltage on the buses of the main and backup power supplies 6 and 7, which is activated upon receipt of a fast turn-on command from the microprocessor starting device 11 reserve. The starting device for high-speed automatic inclusion of the reserve 11 contains a recovery unit for the third phase current 13 (necessary if there are only two transformers in the set of measuring current transformers 8); equipped with three output channels

,

,

analog-to-digital current converter 14, the input of which is connected to the output of the set of measuring current transformers 8 through the recovery unit of the third phase current 13; equipped with three output channels

,

,

and

,

,

analog-to-digital voltage converters 15 and 16, the inputs of which are connected to the outputs of the sets of voltage measuring transformers on the buses of the main and backup power supplies 9 and 10, respectively; direct sequence voltage detection blocks 17 and 18 on the buses of the main and backup power supplies 6 and 7, the inputs of which are connected to the output channels of analog-to-digital voltage converters 15 (

,

,

) and 16 (

,

,

) respectively; blocks of special relay organs for phase-by-phase control of the current direction 19, 20, 21, each of which respectively controls one of the three output channels

,

,

analog-to-digital current converter 14 (current value in one of the phases of the main power source), one of the three output channels

,

,

analog-to-digital voltage converter 15 (voltage value on the buses of the main source between two other phases) and one of the three output channels

,

,

analog-to-digital voltage converter 16 (voltage value on the buses of the backup source between the same phases as on the buses of the main source); relay block of the minimum voltage of three 22, the inputs of which control the output channels

,

,

analog-to-digital voltage converter 15; maximum voltage relay unit 23, the input of which is connected to the output of the direct sequence voltage detecting unit 18 on the buses of the backup power supply 7; the relay unit 24 for determining the angle between the direct sequence voltage vectors on the buses of the main and standby power supplies 6 and 7, the inputs of which are connected to the direct sequence voltage determination units 17, 18 on the buses of the main and standby power supplies 6 and 7, respectively; a relay unit 25 for determining a change in angle over a fixed time interval between the direct sequence voltage vectors on the buses of the main and backup power supplies 6 and 7, the inputs of which are connected to the direct sequence voltage determination units 17, 18 on the buses of the main and backup power supplies 6 and 7, respectively; the logical element "AND-NOT" 26, the inputs of which are connected to the outputs of the blocks of special relay organs for phase-by-phase control of the current direction 19, 20, 21; the logical element "And" 27, the inputs of which are connected to the outputs of the relay block of the minimum voltage of three 22, the relay block of the maximum voltage 23 and the logical element "AND NOT"26; the logical element "And" 28, the inputs of which are connected to the outputs of the relay block of the maximum voltage 23, the relay block 24 determine the angle between the voltage vectors of the direct sequence on the buses of the main and backup power supplies 6 and 7, the logical element "AND NOT"26; the logical element "And" 29, the inputs of which are connected to the outputs of the relay block of the maximum voltage 23, the relay block 25 determine the change in the angle for a fixed time interval between the voltage vectors of the direct sequence on the buses of the main and backup power supplies 6 and 7, the logical element "AND NOT "26; logical element "OR" 30, the inputs of which are connected to the outputs of the logical elements "AND" 27, 28, 29; the output unit 31, the input of which is connected to the output of the OR gate 30, and the output with the input switch of the main power source 3 through the circuit breaker channel and with the sectional switch 5 through its channel through the device 12 for selecting the conditions (moment) for switching to the backup 2, a power source that is activated upon receipt of a quick-turn-on reserve command from a microprocessor-based starting device 11.

- вектор, соответствующий комплексному действующему значению тока

в фазе «А» на вводе основного источника питания 1;

- вектор, соответствующий комплексному действующему значению напряжения между фазами «В» и «С» на шинах основного источника питания 6;

- вектор, соответствующий произведению комплексного действующего значения напряжения

между фазами «В» и «С» на шинах резервного источника питания 7 и коэффициента k_П - заданной в блоке 19 уставки коэффициента подпитки от шин резервного источника питания 7;

- вектор суммы

; φ_уст - заданная в блоке 19 уставка угла между перпендикуляром к границе зоны срабатывания (см. далее) и вектором

; I_уст - заданная в блоке 19 уставка тока; зона срабатывания - область, при попадании конца вектора

в которую, считается, что переток мощности в фазе «А» направлен от источника питания к нагрузке.Figure 2 shows the complex plane and are indicated:

is the vector corresponding to the complex effective current value

in phase "A" at the input of the main power source 1;

- a vector corresponding to the complex effective value of the voltage between the phases "B" and "C" on the buses of the main power source 6;

is the vector corresponding to the product of the complex effective voltage value

between phases “B” and “C” on the buses of the backup power supply 7 and the coefficient k _P - specified in block 19 of the setting of the charge coefficient from the tires of the backup power supply 7;

- sum vector

; φ _mouth - the angle setting specified in block 19 between the perpendicular to the boundary of the response zone (see below) and the vector

; I _set - the current set in block 19; response zone - the area when the end of the vector hits

into which it is believed that the power flow in phase "A" is directed from the power source to the load.

,

,

) и комплексных действующих значений напряжений на шинах основного 6 (

,

,

) и резервного 7 (

,

,

) источников питания. В блоках 17 и 18 соответственно происходит преобразование комплексных действующих значений напряжений

,

,

и

,

,

в комплексные действующие напряжения прямой последовательности

на шинах основного источника питания 6 и

на шинах резервного источника питания 7. Дальнейшая работа микропроцессорного пускового устройства осуществляется за счет математической и логической обработки результатов измерений.Using the sets of measuring voltage transformers 9 and 10, the starting device controls the instantaneous values of the linear voltages on the buses of the main power supply 6 (u _ab1 , u _bc1 , u _ca1 ) and backup 7 (u _ab2 , u _bc2 , u _ca2 ). Using a set of measuring current transformers 8, the starting device controls the instantaneous values of phase currents at the input of the main power source 1 (i _a1 , i _b1 , i _c1 or i _a1 , i _c1 if there are only two measuring current transformers). The measurement results are sent to the blocks of analog-to-digital converters 14, 15 and 16 (if the set of measuring current transformers consists of two transformers, the current channel passes through the third phase current recovery unit 13, the value of the third phase current is determined as i _b = -i _a -i _c ), where the instantaneous values of currents and voltages are converted into series of complex effective values of currents at the input of the main power source 1 (

,

,

) and the complex effective values of voltages on the tires of the main 6 (

,

,

) and backup 7 (

,

,

) power sources. In blocks 17 and 18, respectively, the conversion of complex effective voltage values occurs

,

,

and

,

,

into complex acting direct sequence voltages

on the tires of the main power supply 6 and

on the tires of the backup power source 7. Further operation of the microprocessor starting device is carried out due to the mathematical and logical processing of the measurement results.

Prohibiting blocks for the operation of the device are blocks of special relay organs for phase-by-phase control of the current direction 19, 20, 21. If the conditions are met

,

,

- комплексные действующие значения напряжений на шинах основного источника питания 6;

,

,

- комплексные действующие значения напряжений на шинах резервного источника питания 7;

,

,

- комплексные числа, соответственно сопряженные комплексным действующим значениям токов

,

,

на вводе основного источника питания 1; φ_уст - заданная уставка угла; I_уст - заданная уставка тока; k_П - заданная уставка коэффициента подпитки от шин резервного источника питания 7; то на выходе соответствующих блоков особых релейных органов пофазного контроля направления тока 19, 20, 21 сигнал равен логической «I»; если хотя бы одно из этих условий не выполняется - выходной сигнал соответствующего блока особого релейного органа пофазного контроля направления тока становится равен логическому «0», и таким образом считается, что переток мощности в соответствующей фазе направлен от нагрузки к источнику питания, и происходит разблокировка работы микропроцессорного пускового устройства 11.Where

,

,

- complex current voltage values on the tires of the main power source 6;

,

,

- complex current voltage values on the tires of the backup power source 7;

,

,

- complex numbers, respectively conjugate to the complex current values of the currents

,

,

at the input of the main power source 1; φ _mouth - setpoint angle; I _set - set current setting; k _P - the specified setting of the coefficient of recharge from the tires of the backup power source 7; then at the output of the corresponding blocks of special relay organs for phase-by-phase control of the current direction 19, 20, 21, the signal is equal to logical “I”; if at least one of these conditions is not fulfilled, the output signal of the corresponding unit of the special relay body for phase-by-phase monitoring of the current direction becomes equal to logical “0”, and thus it is considered that the power flow in the corresponding phase is directed from the load to the power source, and operation is unlocked microprocessor starting device 11.

в зону срабатывания, считается, что переток мощности в фазе «А» направлен от источника питания к нагрузке, при этом на выходе особого релейного органа пофазного контроля направления тока 19 сигнал становится равным логической «I», при выходе конца вектора

из зоны срабатывания выходной сигнал блока 19 становится равным логическому «0».An illustration of the operation of block 19 on a complex plane is shown in FIG. 2, the operation algorithm of blocks 20, 21 is similar with a corresponding change in input signals. When the end of the vector hits

into the actuation zone, it is believed that the power flow in phase “A” is directed from the power source to the load, while at the output of a special relay body for phase-by-phase control of the current direction 19, the signal becomes equal to logical “I” when the end of the vector

from the operation zone, the output signal of block 19 becomes equal to the logical "0".

When the power in each phase at the input of the main power source 1, the overflow of which is determined according to the above algorithm, is directed from the power source to the load, the starting device 11 does not work, no matter what happens in the power supply system. In normal mode, the signals at the input of block 26 block through blocks 27, 28, 29 the signal to turn off the input switch of the main power source 3 and turn on the section switch 5, the bus of the main and backup power sources 6 and 7 work separately.

For registration of asymmetric and three-phase short circuits in the power circuit, a relay block of the minimum voltage of three 22 is used, to register the shutdown of the head switch at the power substation, the relay block 24 for determining the angle between the direct sequence voltage vectors on the buses of the main and backup power supplies 6 and 7 is used, relay block 25 for determining the change in the angle for a fixed time interval between the voltage vectors of the direct sequence on the buses of the main and backup power sources I 6 and 7. To control the normal voltage on the buses of the backup power source, the maximum voltage relay unit 23 is used. The signals for the operation of the device are generated using the “AND-NOT” logic elements (block 26), “I” (blocks 27, 28, 29 ), “OR” (block 30) and enter the output block 31, which controls the input switch of the main power source 3 and the sectional switch 5 through the device 12 for selecting the conditions (moment) for switching to the backup 2 power source that is activated upon receipt of a microprocessor start th device 11 commands a high-speed switches.

,

,

) снижается ниже уставки релейного блока минимального напряжения из трех 22 U_{уст.мин} и, если на шинах резервного источника питания 7 напряжение

больше уставки релейного блока максимального напряжения 23 U_{уст.макс}, пусковое устройство 11 подает сигналы на отключение выключателя основного источника питания 3 и на включение секционного выключателя 5 через устройство 12.According to option 1, in the event of a power outage in the form of asymmetric or three-phase short circuits in the power supply circuit, one or more blocks of special relay organs for phase-by-phase control of the current direction 19, 20, 21 goes (-at) to its initial state and to its (their) output (s) the signal becomes equal to the logical "0", the minimum voltage min (

,

,

) decreases below the setting of the relay block of the minimum voltage of three 22 U _setmin and, if the voltage on the tires of the backup power source 7

greater than the setting of the relay block of the maximum voltage 23 U _set.max , the starting device 11 sends signals to turn off the switch of the main power source 3 and to turn on the section switch 5 through the device 12.

и шинах резервного источника питания

, равный

удовлетворяет условию δ₁₂>δ_уст релейного блока 24 определения угла между векторами напряжений прямой последовательности на шинах основного и резервного источников питания 6 и 7 и, если на шинах резервного источника питания 7 напряжение

больше уставки релейного блока максимального напряжения 23 U_{уст.макс}, пусковое устройство 11 подает сигналы на отключение выключателя основного источника питания 3 и на включение секционного выключателя 5 через устройство 12.According to option 2, in the event of other power outages, for example, when the head switch is turned off due to improper actions of the on-duty personnel, one or more blocks of special relay organs for phase-by-phase monitoring of the current direction 19, 20, 21 will go (-yat) to the initial state and to its (their) output (s), the signal becomes equal to the logical "0", the angle δ ₁₂ between the direct sequence voltage vectors on the buses of the main power source

and power supply busbars

equal to

₁₂ satisfies δ> δ _mouth relay unit 24 determining the angle between the vectors of the positive sequence voltage on the buses of the main and backup power sources 6 and 7 and, if a backup power source voltage and tire 7

greater than the setting of the relay block of the maximum voltage 23 U _set.max , the starting device 11 sends signals to turn off the switch of the main power source 3 and to turn on the section switch 5 through the device 12.

и шинах резервного источника питания

за фиксированный интервал времени Δt_уст, равное Δδ₁₂=δ₁₂ ⁽²⁾-δ₁₂ ⁽¹⁾, где δ₁₂ ⁽¹⁾, δ₁₂ ⁽²⁾ - значения угла между векторами напряжений прямой последовательности на шинах основного источника питания

и шинах резервного источника питания

соответственно в начале и конце интервала времени Δt_уст, удовлетворяет условию Δδ₁₂>Δδ_уст релейного блока 25 определения изменения угла за фиксированный интервал времени между векторами напряжений прямой последовательности на шинах основного и резервного источников питания 6 и 7 и, если на шинах резервного источника питания 7 напряжение

больше уставки релейного блока максимального напряжения 23 U_{уст.макс}, пусковое устройство 11 подает сигналы на отключение выключателя основного источника питания 3 и на включение секционного выключателя 5 через устройство 12.According to option 3, in the event of the same power supply disturbances (see option 2), one or more blocks of special relay organs for phase-by-phase control of the current direction 19, 20, 21 will go (-s) to the initial state and its output (s) ) the signal becomes equal to the logical "0", the value of the change in the angle Δδ ₁₂ between the direct sequence voltage vectors on the buses of the main power source

and power supply busbars

for a fixed time interval Δt _mouth equal to Δδ ₁₂ = δ ₁₂ ⁽²⁾ -δ ₁₂ ⁽¹⁾ , where δ ₁₂ ⁽¹⁾ , δ ₁₂ ⁽²⁾ are the values of the angle between the direct sequence voltage vectors on the buses of the main power source

and power supply busbars

respectively at the beginning and end of the time Δt _mouth interval satisfies Δδ _12> Δδ _mouth relay unit 25 determining the angle change over a fixed time interval between the voltage vectors direct sequence busbar primary and backup power sources 6 and 7 and, if a backup power source and tire 7 voltage

greater than the setting of the relay block of the maximum voltage 23 U _set.max , the starting device 11 sends signals to turn off the switch of the main power source 3 and to turn on the section switch 5 through the device 12.

Thus, the application of the claimed method makes it possible to quickly respond to any disturbance in the normal power supply of consumers occurring in the circuit of their main power source and including all types of short circuits with subsequent switching of consumers to a backup power source, also allows you to quickly respond to power outages on switchgears with electromotive load and without it, as well as powered by unsynchronized power sources.

Industrial applicability

The method of high-speed automatic switching on of the backup power supply of consumers and a device for its implementation can be used to detect violations of power supply to consumers of the main power source for any type of damage in the power supply network of the switchgear section and to quickly switch to the backup power source.

Claims (4)

1. A method for automatically turning on the backup power supply of consumers, in which the direct sequence voltage is measured on the tires of the backup power source, characterized in that the value of the effective current in phase and the angle between the vector of the complex effective current are measured at the input of the main power source for each of its three phases in the same phase and the vector sum of the complex effective voltage between the two other phases on the buses of the main power source and taken equal to from 0 to 50% share of one the complex nominal effective voltage on the buses of the backup power supply, measure the linear voltages on the buses of the main power supply and give a command to switch the power supply of the buses of the main power supply to the standby when any of the measured voltages on the tires of the main power supply drops below a specified value, when at the same time the value of the current current in any phase at the input of the main power source and the value of the angle between the vector of the complex effective current in the same phase and the vector sum ompleksnogo rms voltage between two phases on the other tire main power source and received at from 0 to 50% share the same name integrated RMS voltage busbar backup power source reaches a predetermined range of values, and positive sequence voltage on the standby power source tires exceeds a predetermined value. 2. A method for automatically turning on the backup power supply of consumers, in which the direct sequence voltage is measured on the buses of the backup power source, the angle between the voltage vectors of the direct sequence voltage of the main and backup power supply buses, characterized in that the input of the main power supply for each of its three phases is measured the value of the effective current in the phase and the value of the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between two other phases on the buses of the main power source and an equal to 0 to 50% share of the complex active voltage of the same name on the buses of the backup power supply and give the command to switch the power supply of the buses of the main source to the backup when the angle between the voltage vectors of the direct sequence of the buses of the main and reserve power sources are higher than the set value, when at the same time the value of the effective current in any phase at the input of the main power source and the value of the angle between with the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between the two other phases on the buses of the main power source and taken equal to from 0 to 50% of the share of the same complex effective voltage on the tires of the backup power source reach a given range of values, and the direct voltage Sequences on the buses of the redundant power supply exceed the set value. 3. A method for automatically turning on the backup power supply of consumers, in which the direct sequence voltage is measured on the buses of the backup power source, characterized in that the value of the effective current in phase and the angle between the vector of the complex effective current are measured at the input of the main power source for each of its three phases in the same phase and the vector sum of the complex effective voltage between the two other phases on the buses of the main power source and taken equal to from 0 to 50% share of one the complex nominal effective voltage on the tires of the backup power supply, additionally measure the change in the angle between the voltage vectors of the direct sequence voltage of the main and backup power supplies for a given period of time and give a command to switch the power supply of the buses of the main source to the backup when the angle between the voltage vectors of the direct sequence of the main bus voltage and backup power sources for a given period of time above a given value, when at the same time the value of the effective current in any phase at the input of the main power source and the value of the angle between the vector of the complex effective current in the same phase and the vector sum of the complex effective voltage between the other two phases on the buses of the main power source and taken equal to 0 to 50% of the share of the same complex the effective voltage on the buses of the backup power source reaches a predetermined range of values, and the voltage of the direct sequence on the tires of the backup power source exceeds a predetermined value nie. 4. A device for automatically turning on the backup power supply of consumers, containing the main and backup power supplies, input switches of the main and backup power supplies, a section switch, buses of the main and backup power supplies, a set of measuring current transformers at the input of the main power supply, sets of voltage measuring transformers for tires of the main and backup power sources, a starting device for automatically switching on the reserve, containing the recovery unit the third phase current, equipped with three output channels an analog-to-digital current converter, the input of which is connected to the output of the set of measuring current transformers through the recovery unit of the third phase current, equipped with three output channels, analog-to-digital voltage converters, the inputs of which are connected to the outputs of the sets of voltage measuring transformers on the buses of the main and backup power supplies, direct sequence voltage detection units on the buses of the main and auxiliary power supply sources, the inputs of which are connected to the output channels of analog-to-digital voltage converters on the buses of the main and backup power sources, respectively, the maximum voltage relay unit, the input of which is connected to the output of the direct sequence voltage detecting unit on the buses of the backup power source, the relay unit for determining the angle between direct sequence voltage vectors on the buses of the main and backup power supplies, the inputs of which are connected to the blocks I direct voltage voltages on the buses of the main and backup power sources, a device that switches to the backup power source with the main contacts of the section switch closed at the moment close to common mode between the same voltage on the buses of the main and backup power sources, activated upon receipt from the starting device reserve switching commands, characterized in that the starting device for automatically switching on the reserve contains blocks of special relay bodies phase-by-phase control of the current direction, each of which is respectively connected to one of the three output channels of the analog-to-digital current converter, which is the current channel in one of the phases of the main power source, one of the three output channels of the analog-to-digital voltage converter on the buses of the main power source, which is the voltage channel on the buses of the main source between two other phases, and one of the three output channels of the analog-to-digital voltage converter on the buses of the backup power source which is a voltage channel on the buses of the backup source between the same phases as on the buses of the main source, the relay of the minimum voltage of three, the inputs of which are connected to the output channels of the analog-to-digital voltage converter on the buses of the main power source, the relay block for determining the change in angle for a fixed time interval between direct sequence voltage vectors on the buses of the main and backup power supplies, the corresponding inputs of which are connected to the blocks direct voltage voltages on the buses of the main and backup power sources, the “AND-NOT” logic element, the corresponding inputs of which are connected to the outputs of the blocks of special relay organs for phase-by-phase control of the current direction, the “AND” logic element, the corresponding inputs of which are connected to the outputs of the minimum relay unit voltage of three, the relay block of the maximum voltage and the logic element "AND NOT", the second logic element "AND", the corresponding inputs of which are connected to the outputs of the relay block and the maximum voltage of the relay unit for determining the angle between the direct sequence voltage vectors on the buses of the main and backup power sources, the “AND” logic element, the third AND element, the inputs of which are connected to the outputs of the maximum voltage relay unit, the change detection relay unit angle for a fixed time interval between the direct sequence voltage vectors on the buses of the main and backup power sources, the AND-NOT logical element, the logical element OR ”, the corresponding inputs of which are connected to the outputs of the three logical elements“ AND ”, the output unit, the input of which is connected to the output of the logic element“ OR ”, and the output - with the input switch of the main power source through the circuit breaker channel and with the sectional switch through its channel switching on through the device for selecting the conditions for switching to the backup power source, which is activated when the reserve enable command is received from the starting device.

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