RU2813851C1 - Method and device for seasonal reduction of electric energy losses and increase of reliability in electric network - Google Patents

Abstract

FIELD: electric networks.

SUBSTANCE: at transformer substation, powered by one supply line, transformers of different power are installed, wherein power of each of them is less than power required for power supply at maximum load of substation, and their total power is equal to or greater than the maximum power, providing the conditions for parallel operation of transformers, setting and counting the first group of time intervals in accordance with the season of the year, wherein intervals are set per second, during which the load connected to the transformer substation is less than the power of one of the two installed transformers. In addition, a second group of time intervals is set and counted in accordance with the season of the year, during which the load connected to the transformer substation is less than the power of the second of the two installed transformers, the third group of time intervals is set and counted in accordance with the season of the year, during which the load of the transformer substation is greater than the power of each of the two transformers separately, but less than the total power of the two installed transformers, connected in parallel, during counting of the first group of intervals, the switched on state of the first transformer is provided and the load of the transformer substation is supplied from it, the switched off state of the second transformer is provided. At the beginning of the second group of intervals, the second transformer is automatically switched to parallel operation with the first transformer, after which the first transformer is automatically disconnected and the on state of the second transformer is provided and the load of the transformer substation is supplied from it. At the beginning of the third group of time intervals, the second transformer is automatically switched to parallel operation with the operating transformer, providing the connected state of two transformers for parallel operation and power supply from them to the load of the transformer substation, controlling the load of the transformer substation, nominal load values and permissible operating time with overload are set for each of the transformers, if during the counting of the first or second group of time intervals the load will exceed the rated value for the corresponding transformer, permissible overload time of the transformer switched on at this time is counted, if after the end of the permissible overload time count it is not eliminated, second transformer is automatically switched to parallel operation, if during the first or second time interval the connected transformer is damaged, it is automatically switched off and the second installed transformer is switched on.

EFFECT: reduction of losses in electric network due to reduction of no-load losses in power transformers and increase of reliability due to possibility of redundancy of power transformers, as well as automatic switching of transformers taking into account seasonality of electric loads in case of damage of one of transformers.

2 cl, 1 dwg

Description

The invention relates to the automation of electrical networks and is intended to seasonally reduce electrical energy losses and increase reliability in the electrical network.

There is a known method for preserving the resource of power transformers of a two-transformer substation (Patent No. 2740396 Russian Federation, IPC H02H 5/04, H02J 3/46, H02J 13/00., publ. 01/14/2021, Bulletin No. 2).

The closest in technical essence to the proposed invention is a method for reducing electricity losses at a two-transformer substation (Khorolsky V. Ya. et al. Organizational measures to reduce technical losses of electricity in rural electrical networks // Energy Security. - 2017. - P. 199-206 ), which consists in turning off one of the transformers during low load.

A device for implementing a method for preserving the life of a power transformer is known (Patent No. 2408123 Russian Federation MPK51 H02J 13/00 H01F 41/00 G01R31/34., publ. 12/24/2010. Bulletin No. 36).

The closest in technical essence to the proposed invention is a device for implementing a method for preserving the resource of power transformers of a two-transformer substation (Patent No. 2740396 Russian Federation, IPC H02H 5/04, H02J 3/46, H02J 13/00., publ. 01/14/2021, Bull. No. 2), including power transformers, switches, power sensors.

The disadvantage of the known methods and devices is the lack of functionality due to the fact that the method and device do not involve automatic switching of transformers taking into account the seasonality of electrical loads, if one of the transformers is damaged, they are applicable only for two-transformer substations powered by two lines.

The technical objective of the proposed invention is to expand the functionality by automatically switching transformers taking into account the seasonality of electrical loads, if one of the transformers is damaged, the applicability of the method and device for transformer substations powered from a single line.

The above technical result is achieved by the fact that in the proposed method for seasonally reducing electrical energy losses and increasing reliability in the electrical network, which consists of seasonally shutting down one of the two transformers of the transformer substation at low loads, according to the invention, the Method for seasonally reducing electrical energy losses and increasing reliability in electrical network, which consists in the seasonal shutdown of one of the two transformers of the transformer substation at low loads, characterized in that at the transformer substation, powered by one supply line, transformers of different powers are installed, and the power of each of them is less than the power required to supply power at maximum load substations, and their total power is equal to or greater than the maximum power, provide conditions for parallel operation of transformers, set and count the first group of time intervals in accordance with the season of the year, and the intervals are set per second, during which the load connected to the transformer substation is less than the power of one of two installed transformers, set and count the second group of time intervals in accordance with the season of the year, during which the load connected to the transformer substation is less than the power of the second of the two installed transformers, set and count the third group of time intervals in accordance with the season of the year, during which the load of the transformer substation is greater than the power of each of the two transformers separately, but less than the total power of the two installed transformers connected in parallel; during the countdown of the first group of intervals, the first transformer is switched on and the load of the transformer substation is powered from it; the switched off state of the second transformer is reduced, thus Thus, the no-load losses of the transformer substation compared to the use of one more powerful transformer, at the beginning of the countdown of the second group of intervals, the second transformer is automatically switched to parallel operation with the first transformer, after which the first transformer is automatically turned off and the second transformer is switched on and the load is powered from it transformer substation, thus reducing the no-load losses of the transformer substation compared to using one more powerful transformer; at the beginning of the countdown of the third group of time intervals, the second transformer is automatically switched to parallel operation with the operating transformer; the two transformers are switched on for parallel operation and power supply from them the load of the transformer substation, control the load of the transformer substation, set the rated load values and the permissible operating time with overload for each of the transformers, if during the counting of the first or second group of time intervals the load exceeds the rated value for the corresponding transformer, the permissible overload time is counted of the transformer turned on at this time, if after the end of the countdown of the permissible overload time it is not eliminated, the second transformer is automatically switched to parallel operation, if during the first or second time interval the turned on transformer is damaged, it is automatically turned off and the second installed transformer is put into operation, thus increasing the reliability of the electrical network, information about the results of switching, about damage to power transformers is transmitted to the electrical network dispatcher; when remote control commands are received from the electrical network dispatcher, these commands are processed and executed, producing the necessary switchings.

The technical result is also achieved by the fact that the proposed device for seasonal reduction of electrical energy losses and increasing reliability in the electrical network, including two power transformers, outgoing lines and buses, according to the invention, is equipped with a supply line connected through high voltage buses to high voltage circuits for connecting power transformers , low voltage buses connected to the outgoing line and low voltage circuits connecting power transformers, two controlled switching devices of high voltage inputs installed in the high voltage circuit of power transformers, two controlled switching devices of low voltage inputs installed in the low voltage circuit of power transformers, switching a device installed in the outgoing line, a load of the transformer substation connected to the outgoing line, a load sensor of the transformer substation connected to the outgoing line, connected to the low voltage circuits for connecting power transformers behind the switching devices of the low voltage inputs and connected to the information processing and control unit, block information processing and control, connected to controlled switching devices of high and low voltage inputs, connected to connection circuits of power transformers in front of switching devices of low voltage inputs, connected to a load sensor of the transformer substation, a data receiving and transmitting device connected to an information processing and control unit.

The essence of the proposed method is illustrated by a drawing that shows a block diagram of a device for seasonally reducing electrical energy losses and increasing reliability in the electrical network.

The block diagram of the device contains a power transformer T1, a power transformer T2, a supply line PL3, high voltage buses SHVN4 connected to the supply line and high voltage circuits for connecting power transformers, an outgoing line OL5, a switching device for the outgoing line KAOL6 installed in the outgoing line, buses low voltage SHNN7, connected to the outgoing line and low voltage circuits connecting power transformers, load of the NTP8 transformer substation connected to the outgoing line, controlled low voltage input switching device UKAVNN9, installed in the low voltage circuit connecting the power transformer T1, controlled low voltage input switching device UKAVNN10, installed in the low voltage connection circuit of power transformer T2, controlled high voltage input switching device UKAVVN11, installed in the high voltage connection circuit of power transformer T1, controlled high voltage input switching device UKAVVN12, installed in the high voltage connection circuit of power transformer T2, load sensor transformer substation DNTP13, connected to the outgoing line, low voltage circuits for connecting power transformers and an information processing and control unit, information processing and control unit BOIiU14, data reception and transmission device UPPD15, connected to an information processing and control unit BOIiU14, connected to controlled switching devices high and low voltage inputs, outgoing line, power transformer connection circuits, transformer substation load sensor, data reception and transmission device, high voltage connection circuit for power transformer TsVNPT16, high voltage connection circuit for power transformer TsVNPT17, low voltage connection circuit for power transformer TsNNPT18, circuit low voltage connection of the power transformer TsNNPT19.

Power transformers T1 and T2 serve to convert electrical energy with one parameters into electrical energy with other parameters, in particular, voltage conversion, supply line PL3 serves to supply high voltage to transformers T1 and T2, high voltage buses ShVN4 serve to transmit electricity from supply line in the high voltage circuit for connecting power transformers, the outgoing line OL5 serves to supply voltage to the load of the transformer substation, the switching device of the outgoing line KAOL6, installed in the outgoing line, serves for its switching, low voltage buses ShNN7, connected to the outgoing line and low voltage circuits connection voltage of power transformers, used to transfer electricity from low voltage circuits connecting power transformers to the outgoing line, the load of the NTP8 transformer substation connected to the outgoing line consumes electricity, controlled low voltage input switching device UKAVNN9, installed in the low voltage connection circuit of power transformer T1 , serves for its manual, automatic, or remote switching, a controlled low voltage input switching device UKAVNN10, installed in the low voltage connection circuit of the power transformer T2, serves for its manual, automatic, or remote switching, a controlled high voltage input switching device UKAVVN11, installed in the high voltage connection circuit of power transformer T1, serves for its manual, automatic, or remote switching, controlled high voltage input switching device UKAVVN12, installed in the high voltage connection circuit of power transformer T2, serves for its manual, automatic, or remote switching, sensor load of the transformer substation DNTP13, connected to the outgoing line, low-voltage circuits for connecting power transformers and an information processing and control unit, serves to control the parameters of the operating modes of the outgoing line, low-voltage circuits for connecting power transformers, determining the load of the transformer substation powered from T1, T2, or from T1 and T2 simultaneously, transmitted via an outgoing line to NTP8, information processing and control unit BOIiU14, data reception and transmission device UPPD15, connected to information processing and control unit BOIiU14, connected to controlled switching devices of high and low voltage inputs, outgoing line , circuits for connecting power transformers, a load sensor of a transformer substation, a device for receiving and transmitting data, used to receive information from DNTP13, control parameters of operating modes of the outgoing line, low voltage circuits for connecting power transformers, counting groups of time intervals of the seasons, receiving commands from UPPD15, generation and transmission of commands for turning on and off UKAVVN11, UKAVVN12, UKAVNN9, UKAVNN10, transmission of information to UPPD15. The high voltage circuit connecting the power transformer TsVNPT16 and the low voltage circuit connecting the power transformer TsNNPT18 are used to connect T1, the high voltage circuit connecting the power transformer TsVNPT17 and the low voltage circuit connecting the power transformer TsNNPT19 are used to connect T2.

The method is implemented as follows. For existing transformer substations fed by one supply line (PL3), the transformer at a single-transformer substation is replaced with two transformers of the same or different power T1 and T2, each of which has less power than the previously installed transformer, but the total power of which is equal, or more power of the previously installed transformer. For new transformer substations, two transformers of the same or different power T1 and T2 are installed. Provide conditions for parallel operation of transformers T1 and T2. In BOIiU14, the first group of time intervals is set and with its help counted in accordance with the season of the year, during which the NTP8 load, connected to the transformer substation via OL5, can be powered from the first of the installed transformers, for example, T1, and the intervals are set per second, reducing, thus, no-load losses of the transformer compared to the use of one more powerful transformer that was installed previously (for existing substations), or which would have been installed in the case of a substation with a single transformer.

In BOIiU14 the second group of time intervals is set and with its help counted in accordance with the season of the year, during which the load connected to the transformer substation can be powered from the second of the installed transformers (T2), and the intervals are set per second, thus reducing no-load losses transformer stroke compared to using one more powerful transformer.

In BOIiU14, the third group of time intervals is set and with its help counted in accordance with the season of the year, during which the load of the transformer substation must be powered from two installed transformers T1 and T2, connected in parallel.

Using DNTP13, they control the value of the load connected to the transformer substation, including separately to each of the transformers, and transmit this data to BOIiU14. This makes it possible to determine the operating parameters of each transformer, the degree of their load, including for estimating electricity losses. During the counting of the first group of intervals, the first transformer T1 is turned on and NTP8 is powered from it (UKAVVN11, UKAVNN9, KAOL6 are turned on, UKAVVN12 and UKAVNN10 are turned off). At the beginning of the countdown of the second group of intervals, the second installed transformer T2 is automatically connected to parallel operation with the operating transformer T1, issuing a command from BOIIU14 to turn on UKAVVN12 and UKAVNN10, after which the first transformer T1 is automatically turned off, turning off UKAVNN9 and UKAVVN11 in series. They ensure the on state of the second transformer T2 and power supply from it to the load of the NTP8 transformer substation.

At the beginning of the countdown of the third group of time intervals, transformer T1 is automatically connected to parallel operation with the operating transformer T2 by turning on UKAVVN11 and UKAVNN9, ensuring the on state of two transformers T1 and T2 for parallel operation and powering the load of the NTP8 transformer substation from them.

Using DNTP13, the load of the transformer substation is monitored, including separately for each of the transformers, determining the degree of its load, identifying possible overloads, setting in BOIiU14 the permissible operating time with overload for each of the transformers, if during the countdown of the first or second group of time intervals the load will exceed the rated value, the permissible overload time of the transformer turned on at this time is counted, if after the end of the countdown of the permissible overload time it is not eliminated, the second transformer is automatically switched on for parallel operation.

If during the first or second time interval the transformer that is turned on at that time is damaged, it is automatically turned off by turning off UKAVVN11 or UKAVVN12 and the second installed transformer is put into operation, thus increasing the reliability of the electrical network.

Information about the results of switching, about damage to power transformers is transmitted from BOIiU14 to UPPD15 and through it to the electrical network dispatcher. When remote control commands are received (enable, disable UKAVVN11, UKAVNN9, UKAVVN12, UKAVNN10) from the electrical network manager via UPPD15, these commands are processed and executed by transmission from BOIiU14 to the corresponding controlled switching devices.

The use of the proposed method and device makes it possible to expand the functionality by automatically switching transformers taking into account the seasonality of electrical loads, if one of the transformers is damaged, apply the method and device to transformer substations powered from one line. This reduces losses in the electrical network by reducing no-load losses in power transformers and increases reliability due to the possibility of redundancy of power transformers.

Claims (2)

1. A method for seasonally reducing electrical energy losses and increasing reliability in the electrical network, which consists of seasonally shutting down one of the two transformers of a transformer substation at low loads, characterized in that transformers of the same or different power are installed at the transformer substation, powered by one supply line, in this case, the power of each of them is less than the power required to supply power at the maximum load of the substation, and their total power is equal to or greater than the maximum power, ensure conditions for parallel operation of transformers, set and count the first group of time intervals in accordance with the season of the year, and the intervals are set per second , during which the load connected to the transformer substation is less than the power of one of the two installed transformers, the second group of time intervals is set and counted in accordance with the season of the year, during which the load connected to the transformer substation is less than the power of the second of the two installed transformers, the third group of time intervals is set and counted in accordance with the season of the year, during which the load of the transformer substation is greater than the power of each of the two transformers separately, but less than the total power of the two installed transformers connected in parallel; during the counting of the first group of intervals, the first transformer is turned on and supplying the load of the transformer substation from it, the disconnected state of the second transformer, thus reduces the no-load losses of the transformer substation compared to using one more powerful transformer; at the beginning of the countdown of the second group of intervals, the second transformer is automatically switched to parallel operation with the first transformer, after which automatically turns off the first transformer and ensures the on state of the second transformer and power supply from it to the load of the transformer substation, thus reducing the no-load losses of the transformer substation compared to using one more powerful transformer; at the beginning of the countdown of the third group of time intervals, they automatically switch to parallel operation with a working transformer, the second transformer, ensure the on state of two transformers for parallel operation and power supply from them to the load of the transformer substation, control the load of the transformer substation, set the rated load values and the permissible operating time with overload for each of the transformers, if during the countdown of the first or second group time intervals, the load will exceed the rated value for the corresponding transformer, the permissible overload time of the transformer turned on at this time is counted, if after the end of the countdown of the permissible overload time it is not eliminated, the second transformer is automatically switched to parallel operation if damage occurs during the first or second time interval switched on transformer, it is automatically turned off and the second installed transformer is put into operation, thus increasing the reliability of the electrical network, information about the results of switching, about damage to power transformers is transmitted to the electrical network manager, when remote control commands are received from the electrical network manager, these commands are processed and carry them out, making the necessary switches. 2. A device for seasonal reduction of electrical energy losses and increasing reliability in the electrical network, including two power transformers, an outgoing line and buses, characterized in that it is equipped with a supply line connected by high voltage buses to high voltage circuits connecting power transformers, low voltage buses, connected to the outgoing line and low voltage circuits connecting power transformers, two controlled switching devices of high voltage inputs installed in the high voltage circuit of power transformers, two controlled switching devices of low voltage inputs installed in the low voltage circuit of power transformers, a switching device installed in the outgoing line, the load of the transformer substation connected to the outgoing line, the load sensor of the transformer substation connected to the outgoing line, low voltage circuits for connecting power transformers and an information processing and control unit, an information processing and control unit connected to controlled switching devices of high and low voltage inputs outgoing line, connection circuits for power transformers, load sensor of the transformer substation, data receiving and transmitting device connected to the information processing and control unit.

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