KR101734151B1 - Power System Management Method For Transmission Line Overload Mitigation - Google Patents

Abstract

The present invention relates to a power system management system and a method for managing congestion on the entire power system by solving a problem of an overload generated on a power transmission line due to the occurrence of a contingency accident or a sudden increase in a load on the power system. In order to alleviate the overload of the transmission line, the present invention reduces the generated power of a generator, supplies energy from an energy storage device to the transmission line, or mixes the mentioned two schemes. The present invention proposes a method for quantitatively calculating a reduction amount of generated power of the generator for solving an overload problem of a transmission line and a power to be supplied to the transmission line from the energy storage device.

Description

TECHNICAL FIELD [0001] The present invention relates to a power system management method for a transmission line overload mitigation,

The present invention relates to a power system management system and method for managing congestion on an overall power system by eliminating an overload generated in a power transmission line due to an occurrence of an assumed accident or a sudden load on the power system. More particularly, the system collects at least one of operation setting information from an energy management system (EMS), transmission line related information from a transmission line monitoring device, battery status information from an energy storage system (EMS) And more particularly, to a power system management system and method that can reliably and efficiently manage an entire power system by eliminating an overload of a power transmission line based on information.

Recently, due to the increase in income due to economic development, power consumption for providing various services has surged, but there has been a large-scale power outage due to a lack of power reserve ratio corresponding thereto. In order to solve this power shortage problem, it is necessary to expand electric power supply, power demand management, and renewable energy supply in the long term. In order to level the electric load with a large variation in time, By operating the system, it is expected to seek ways to respond effectively to power usage peak and major power outage.

The Energy Management System (EMS), which performs functions such as comprehensive monitoring and control of the electric power system, economic dispatch and automatic power control, power system analysis, data recording and storage, and emergency power simulation training, Control of power generation output to generators, operation status of over-154kV transmission line, operation status of system protection facilities such as circuit breaker, abnormal state of power system, occurrence of fault, voltage and frequency.

The power system in Korea is composed of a large load area mainly in Yeongnam and west coast areas and the metropolitan area. In order to provide smooth power supply between these areas, large-scale power transmission is performed over a long distance. As described above, since the power consumption is steadily increasing, the construction of the power plant and the expansion of the transmission line must be concurrently carried out in order to smoothly supply the power. However, since it is difficult to construct a power plant and a transmission line near the load center, Related stability problems and overload problems are likely to occur more frequently, and in case of an accident, line overload may occur frequently, so it is necessary to prepare countermeasures.

In addition, in a power system in which a transmission / distribution line is intertwined with a plurality of generators and a plurality of loads, it is not easy to determine how much power to be generated by a generator should be reduced when an overload occurs in a transmission line. It is not easy to determine how much power should be supplied from the energy storage device in order to reduce the power of an overloaded transmission line to an appropriate amount.

Patent Publication No. 2016-0035509

SUMMARY OF THE INVENTION It is an object of the present invention to provide a system and method for managing congestion of an entire power system by eliminating an overload of a transmission line that may occur due to an assumed incident in a power system or a sudden fluctuation in power demand.

An object of the present invention is to efficiently overload the transmission line by providing a method of calculating a production power reduction amount of the generator required to overcome the overload of the transmission line.

An object of the present invention is to efficiently overload the transmission line by providing a method of calculating the power supply amount of the energy storage device necessary for overcoming the overload of the transmission line.

According to an aspect of the present invention, there is provided an energy storage device, comprising: an energy storage device connected to a power transmission line for receiving power from the power transmission line or supplying power to a load connected to the power transmission line; (Transmission line power) that is received from the transmission line monitoring apparatus 300 and calculates the power (transmission line power) flowing through the transmission line. If the transmission line power is equal to or higher than the set value, And a power management system for congestion control (110) for controlling the energy storage device (120) to supply power (supply power) calculated according to a desired amount of reduction (desired reduction amount) from the energy storage device (120) to the load The congestion management system 100 of FIG.

The calculation of the power (supply power) to be supplied from the energy storage device 120 to the load according to the desired reduction amount of the transmission line power specifies the load (maximum influence load) having the greatest influence on the transmission line, (Reduction ratio of load to transmission line) between the load and the transmission line power is calculated according to Equation 1 below and the supply power is calculated using the load-transmission line reduction ratio and the transmission line power reduction amount according to Equation 2 below .

Equation 1:

Equation 2:

The energy storage device 120 may include a plurality of energy storage devices using various protocols and may communicate with a plurality of energy storage devices 120 using the various protocols and may collect And provides the congestion control power management system 110 with the standardized information.

The network matching device 130 may perform PRP (Parallel Redundancy Protocol) communication with the congestion control power management system 110 and the energy storage device 120.

The network matching apparatus 130 collects the information collected by the plurality of energy storage devices 120 and converts the information into the same address space and a predetermined scale to provide the information to the power management system 110 for congestion control .

The congestion control power management system 110 includes a communication duplexer 111 for communicating with the network matching device 130; A data storage device 113 for storing data; And a mixed control arithmetic processing unit 114 for calculating the transmission line power and the supply power.

The energy storage device 120 includes a communication duplexer 121 for communicating with the network matching device 130; A battery 123 for storing energy; And a power conversion device 122 for converting energy between the power transmission line and the battery 123 and transferring the converted energy.

According to another aspect of the present invention, there is provided a congestion management system (100) in accordance with the aforementioned invention; The transmission line monitoring apparatus 300 for monitoring the state of the transmission line and providing the monitoring to the congestion management system 100; And an energy management system (200) for receiving information on the power supply from the congestion management system (100) and controlling an amount of power generation of the generator connected to the power transmission line.

Another aspect of the present invention is a transmission line overload management method performed by a congestion management system 100 including an energy storage device 120. The transmission line overload management method includes the steps of receiving first information from the transmission line monitoring device 300 step; A second step of calculating power (transmission line power) flowing through the transmission line; A third step of calculating power (supply power) to be supplied to the load connected to the transmission line according to a transmission line power amount (a desired reduction amount of the transmission line power) to be determined as an overload when the transmission line power is not less than a set value; And a fourth step of controlling the energy storage device (120) so that the energy storage device (120) supplies the calculated supply power to the load.

 The third step of calculating the supply power in accordance with the desired reduction amount of the transmission line power specifies a load (maximum influence load) having the greatest influence on the transmission line and determines a reduction rate between the maximum influence load and the transmission line power The transmission power reduction rate and the transmission line power reduction amount may be calculated according to Equation (2) below, or the supply power may be estimated using the load-transmission line reduction ratio and the transmission line power reduction amount.

Equation 1:

Equation 2:

The congestion management system (100) includes: a plurality of energy storage devices (120) connected to transmission lines for receiving and storing power from the transmission lines or supplying power to the loads; And a power management system for congestion control 110 for calculating the supply power and for controlling the energy storage device 120 to supply the supply power to the load.

The congestion management system 100 communicates with the plurality of energy storage devices 120 using various protocols and standardizes information collected from the plurality of energy storage devices 120 to control the congestion control power management system 110 (Not shown).

The network matching device 130 may perform PRP (Parallel Redundancy Protocol) communication with the congestion control power management system 110 and the energy storage device 120.

The congestion control power management system 110 includes a communication duplexer 111 for communicating with the network matching device 130; A data storage device 113 for storing data; And a mixed control arithmetic processing unit 114 for calculating the transmission line power and the supply power.

The energy storage device 120 includes a communication duplexer 121 for communicating with the network matching device 130; A battery 123 for storing energy; And a power conversion device 122 for converting energy between the power transmission line and the battery and transmitting the energy.

Another aspect of the present invention is a congestion management system 100 that receives information on a transmission line from a transmission line monitoring apparatus 300 and provides information on power (transmission line power) supplied through the transmission line to the energy management system 200 ); And an energy management system (200) for controlling the generation of electric power of the generator linked to the transmission line by the calculated power amount calculated according to the amount of electric power to be reduced at the transmission line (transmission line power reduction amount A) when the transmission line is overloaded And the power system management system.

The calculation of the deceleration power according to the transmission line power desired decrease amount A is performed by specifying a generator (maximum influence generator) having the greatest influence on the transmission line, and calculating a generator- transmission line reduction ratio between the maximum influence generator and the transmission line by the following equation 3, and the generated power can be calculated using the generator-transmission line reduction ratio and the transmission line power reduction amount A according to Equation (4) below.

Equation (3)

Equation 4:

The transmission line power desired decrease amount A may be equal to the difference (excess power) between the transmission line power and the proper power amount set value.

The calculation of the decay power may be performed by the energy management system 200.

The congestion management system 100 may calculate the transmission line power, determine whether the transmission line power is overloaded, calculate the transmission power, and provide the information to the energy management system 200.

The congestion management system (100) includes an energy storage device (120) connected to the power transmission line and storing power supplied from the power transmission line or supplying power to a load connected to the power transmission line; And a control unit for receiving the information on the transmission line from the transmission line monitoring apparatus 300 to calculate the transmission line power, and if the transmission line power is equal to or higher than a set value, And to control the energy storage device 120 to supply it from the storage device 120 to the load.

The calculation of the supply power to be supplied from the energy storage device 120 to the load according to the transmission line power desired decrease amount B specifies the load (maximum influence load) having the greatest influence on the transmission line, The supply power can be calculated using the load-transmission line reduction ratio and the transmission line power desired decrease amount B according to the following equation (2) after calculating the reduction rate (load-transmission line reduction ratio) between the transmission line power .

Equation 1:

Equation 2:

It is possible to set the sum of the transmission line power desired decrease amount A and the transmission line power desired decrease amount B to be the difference (excess power) between the transmission line power and the appropriate power amount set value.

According to another aspect of the present invention, there is provided a power system management method performed by a power system management system, comprising: a first step of receiving information on a transmission line from a transmission line monitoring device 300; A second step of calculating power (transmission line power) flowing through the transmission line; A third step of calculating a transmission line power amount (transmission line power reduction amount A) to be determined to be overloaded if the transmission line power is equal to or higher than a set value and calculating the transmission power of the generator connected to the transmission line according to the transmission line power reduction amount A ; And a fourth step of controlling power generation of the generator by the generated power.

The calculation of the deceleration power according to the transmission line power desired decrease amount A is performed by specifying a generator (maximum influence generator) having the greatest influence on the transmission line, and calculating a generator- transmission line reduction ratio between the maximum influence generator and the transmission line by the following equation 3, and the generated power can be calculated using the generator-transmission line reduction ratio and the transmission line power reduction amount A according to Equation (4) below.

Equation (3)

Equation 4:

The third step further includes calculating a desired transmission power reduction amount B and calculating power (supply power) to be supplied from the energy storage device 120 to the load connected to the transmission line according to the desired transmission power reduction amount B, The fourth step may further include controlling the energy storage device 120 to supply the calculated supply power to the transmission line.

The calculation of the supply power in accordance with the transmission line power desired reduction amount B may be performed by specifying a load (maximum influence load) having the greatest influence on the transmission line and determining a reduction rate (load-transmission line reduction ratio) between the maximum influence load and the transmission line power, Is calculated according to Equation (1) below, and then the supply power is calculated using the load-transmission line reduction ratio and the transmission line power desired decrease amount B according to Equation (2) below.

Equation 1:

Equation 2:

It is possible to set the sum of the transmission line power desired decrease amount A and the transmission line power desired decrease amount B to be the difference (excess power) between the transmission line power and the set value.

According to the present invention, when a power line overload occurs due to an assumed incident or a sudden increase in power load, by supplying power to the system load using an energy storage device or reducing the amount of power generated by the generator connected to an overloaded transmission line, It can reduce the economic and social costs by eliminating overload quickly, effectively managing the power flow to the entire transmission and distribution line, and quickly responding to transient overloads, reducing the need for additional construction of power generation and transmission and distribution facilities for peak power supply.

According to the present invention, when the power transmission line is overloaded, the power to be supplied from the energy storage device to the load is calculated using the reduction ratio between the load having the greatest influence on the transmission line and the transmission line power, The overload can be eliminated by quickly adjusting the power of the overhead transmission line to an appropriate amount.

According to the present invention, when the transmission line is overloaded, the reduction rate between the power of the generator that has the greatest influence on the transmission line and the transmission line power is applied to calculate the amount to control the production power of the generator, The overload can be eliminated by quickly adjusting the power of the overhead transmission line to an appropriate amount.

FIG. 1 is a diagram illustrating an exemplary configuration of a power system management system 10 according to an embodiment of the present invention.
2 is a block diagram illustrating a power system management system 10 according to an embodiment of the present invention.
3 is a block diagram illustrating the configuration of the congestion control power management system 110 of FIG.
4 is a block diagram illustrating the configuration of the energy storage device 120 of FIG.
5 is a block diagram illustrating the configuration of the network matching apparatus 130 of FIG.
6 is a block diagram illustrating an association structure of the energy storage device 120 and the network matching device 130. As shown in FIG.
7 is a block diagram illustrating a configuration of a connection between the congestion control power management system 110 and the network matching apparatus 130. As shown in FIG.
8 illustrates a transmission line overload removal procedure according to a method of supplying power stored in the energy storage device 120 to an overloaded transmission line.
9 illustrates a procedure for eliminating an overload of a transmission line in a manner of reducing power generation of a generator 500 connected to an overloaded transmission line.
Fig. 10 illustrates a procedure for solving an overload of a transmission line using the method of Fig. 8 and the method of Fig. 9 together.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a block diagram of a power system management system 10 according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a power system management system 10 according to an embodiment of the present invention.

1 and 2, a power system management system 10 according to an embodiment of the present invention includes a congestion management system (CMS) 100, an energy management system (EMS) 200, And may include a transmission line monitoring device 300.

The congestion management system 100 is connected to the energy management system 200 and the transmission line monitoring apparatus 300 through a communication line to exchange information necessary for management of the power system. The congestion management system 100 may be connected to a plurality of generators 500 and the system load 400 via a transmission line to supply power to the transmission line or receive power from the transmission line.

The energy management system 200 may be an upper management system of the congestion management system 100, for example, an energy management system at a power exchange. The energy management system 200 can collectively monitor and control the power system and perform functions such as economic dispatch and automatic power control, power system analysis, data recording and storage, and emergency power simulation training. The generator output target value for each power generation resource is calculated with respect to the power generation output control and the frequency monitoring control function of the energy management system 200 and is controlled through an automatic generation control signal, Can be managed.

The energy management system 200 receives information on the power supplied from the congestion management system 100 to the transmission line by the energy storage device 120 managed by the congestion management system 100 according to the embodiment of the present invention, And the power generation amount of the generator connected to the control unit.

The transmission line monitoring apparatus 300 measures the voltage, current, phase, and temperature of the transmission line using a PT, a CT, a MOF, and various sensors To the congestion management system 100 via a communication line.

The system load 400 is scattered globally in the load region. In order to balance the overall power supply and demand when users temporarily increase the amount of electricity used to increase the load, the generator 500 can increase the power generation and supply electric power In this case, an overload may occur in the transmission line connected to the surge system load 400.

2, the congestion management system 100 may include a power management system 110 for congestion control, one or more energy storage devices 120, and a network matching device 130.

The network matching device 130 communicates with the energy management system 200, the transmission line monitoring device 300 and the energy storage device 120 and transmits and receives information required for power system management to the energy management system 200, Collects power line information such as voltage, current, power and phase from the monitoring device 300 and collects status information of the power conversion device 122 and the battery 123 from the energy storage device 120, (110). The network matching device 130 communicates with a plurality of energy storage devices 120 using various protocols and standardizes and stores the collected information from the plurality of energy storage devices 120 or provides them to the power management system 110 for congestion control can do.

The congestion control power management system 110 calculates the power to be supplied to the energy storage device 120 from the transmission line or the power to be supplied from the energy storage device 120 to the load based on the collected information, Or discharge command to charge the energy storage device 120 or to discharge the power of the energy storage device 120 to overcome the overload of the transmission line.

The congestion control power management system 110 periodically collects information on the voltage, current, phase, and temperature of the transmission line from the transmission line monitoring device 300 through the network matching device 130 and transmits power (transmission line power) And determines whether or not an overload is occurring by determining whether or not the transmission line power is equal to or higher than a set value set at an appropriate power amount. If the power exceeds a set value, it is recognized as an overload state.

The congestion control power management system 110 calculates the power to be supplied from the energy storage device 120 to the load so that the energy storage device 120 can supply power when the transmission line is recognized as an overloaded state, Or by calculating the power of the generator connected to the overhead transmission line and transmitting the information to the energy management system 200, it is possible to perform a function for overloading the transmission line.

The energy storage device 120 is connected to a power transmission line and receives power from the power transmission line and stores or supplies power to the load. A plurality of energy storage devices 120 may be provided, and each energy storage device 120 may be connected between the transmission line and the system load 400 and may be connected to the transmission line to which the overload occurs when an overload occurs in the transmission line to which the energy storage device 120 is connected It is possible to perform a function of supplying power to the load and solving the overload of the transmission line. The plurality of energy storage devices 120 may use various protocols. The network matching device 130 collects and standardizes information while communicating with the energy storage devices 120 using various protocols. Can be performed.

3 is a block diagram illustrating the detailed configuration of the power management system 110 for congestion control of FIG. 3, the congestion control power management system 110 includes a communication duplexer 111, an operational HMI 112, a data storage device 113, and at least one congestion control calculation processing device 114, 115 can do.

The communication duplexer 111 may use general communication means that is not redundant, but preferably it can improve the availability of the entire system by providing stable communication between the devices using a PRP (Parallel Redundancy Protocol) protocol . The PRP is a redundancy protocol recommended by the International Electrotechnical Commission (IEC) 61850 standard and defined in IEC 62439-3 Clause 4. When constructing a network using a general protocol, it takes tens of milliseconds (ms) to tens of seconds (s) to recover not only packet loss due to link disconnection but also recovery. On the other hand, when a redundant network is constructed using PRP , Normal communication is continuously provided without packet loss due to link disconnection, thereby enhancing the stability of the system.

The operating HMI 112 is an interface between the driver and the apparatus (Human-Machine Interface), and performs an interface function necessary for the driver to control the operation of the power management system 110 for congestion control.

The data storage device 113 stores various data necessary for the operation of the power management system 110 for congestion control.

The congestion control calculation processing units 114 and 115 take charge of the calculation functions performed by the power management system 110 for congestion control. One of the congestion control calculation processing units 114 and 115 may be used, but it is more preferable to use two of them in order to secure redundancy and ensure stable operation like the communication duplexing apparatus.

4 is a block diagram illustrating the configuration of the energy storage device 120 of FIG. 4, the energy storage device 120 may include a communication duplication device 121, a power conversion device 122, and a battery 123. [

The communication duplexer 121 performs a communication function in the same manner as the communication duplexer 111 included in the congestion control power management system 110 described above.

The power conversion device 122 is connected to the battery 123 via a DC power line and receives electric power from the electric power management system for congestion control 110 to supply power to the electric power transmission line, Function. The power conversion device 122 and the battery 123 receive information such as the operating state, voltage, current, power, temperature, and state of charge (SOC) of the power conditioning system PCS, To the network matching device 130. [

5 is a block diagram illustrating the configuration of the network matching apparatus 130 of FIG. The network matching apparatus 130 may include an information concentrating apparatus 131, an Ethernet switch A 132, and an Ethernet switch B 133. [

 The information centralization unit 131 collects the information of the power conversion device 122 and the battery 123 belonging to the energy storage device 120 and converts the information into the same address space and a predetermined scale, And transmits the result to the power management system 110 for congestion control. If you build an entire system, you may not be able to configure it with the same equipment. In addition, when the system is firstly built and thereafter the secondary configuration is additionally configured as needed, the system may be constructed by a third party. In this case, information addresses and scales for different types of equipment may be different from each other, so that it is necessary to standardize them in a unified structure. The information centralizing unit 131 is used for this purpose. The information centralizing unit 131 may implement functions in a separate hardware device, but may be implemented in software in a general computer system.

It is preferable that the Ethernet switches 132 and 133 are configured to be redundant in order to increase the stability and high availability of the entire network by using the PRP protocol described above. However, the Ethernet switches 132 and 133 may be used without redundancy of general communication means.

6 is a block diagram illustrating an example of a configuration of an association between the energy storage device 120 and the network matching device 130. FIG 7 is a diagram illustrating a connection configuration of the power management system 110 for congestion control and the network matching device 130 Block diagram. 6 and 7, the network matching device 130, the power management system for congestion control 110, and the energy storage device 120 are connected to each other through the redundant communication means to exchange information and perform the functions described above .

Next, a method of solving an overload of a transmission line using the power system management system 10 according to an embodiment of the present invention will be described. The overload reduction of the transmission line according to the present invention can be performed by three methods. The first method is to supply the power stored in the energy storage device 120 to a load having the greatest influence on the overloaded power transmission line. The second method is to reduce the power generation of the generator 500 connected to the overloaded power transmission line And the third is to use the two methods together.

First, a method of supplying power stored in the energy storage device 120 to a load (hereinafter, referred to as a maximum impact load) which has the greatest influence on an overloaded transmission line will be described.

This method utilizes the principle of reducing the power flowing to the transmission line when the system load is reduced. When the energy storage device 120 disposed between the overloaded transmission line and the maximum influence load supplies power to the maximum influence load, The load is reduced in the amount of power supplied from the transmission line, so that the overload of the transmission line can be reduced.

8 illustrates a transmission line overload resolution procedure according to a method of supplying power stored in the energy storage device 120 to a maximum influence load of an overloaded transmission line. 8, a congestion control power management system 110 receives information on a transmission line from the transmission line monitoring device 300. The power management system 110 for congestion control transmits power (transmission line power The power management system for congestion control 110 determines whether or not an overload is caused based on whether the transmission line power is equal to or higher than a predetermined value and determines whether or not the power to be supplied to the transmission line according to the transmission line power amount (Power supply) of the energy storage device 120, and a third step of the energy storage device 120 to supply the calculated supply power to the maximum influence load. Step < / RTI >

In the case of the method of FIG. 8, it may be a matter of how much power should be supplied to the transmission line from the energy storage device 120 to overcome the overload of the transmission line. If too little power is supplied, there is a problem that the overload is not solved. If too much power is supplied, unnecessary energy transfer between the energy storage device 120 and the power transmission line is accompanied and the overall power system inefficiency problem may occur , It is preferable to supply an appropriate amount for overload relief. However, it is not easy to accurately calculate the proper amount to be supplied from the energy storage device 120 because a plurality of generators and a plurality of loads are intricately intertwined through a large number of transmission and distribution lines.

The embodiment of the present invention defines and uses a load-transmission line reduction rate to calculate an appropriate amount for overload relief. (Load-transmission line reduction ratio) between the maximum influence load and the transmission line power is obtained in advance or in real time according to the following equation (1), and the following mathematical expression The supply power to be supplied from the energy storage device 120 to the maximum influence load is calculated using the load-transmission line reduction ratio and the desired reduction amount of the transmission line power (the amount of power to be reduced among the power flowing through the transmission line) The load-to-transmission line reduction rate can be analyzed and calculated using commercial software used for the power grid transmission and outlook design.

Equation 1:

Equation 2:

According to this method, by using the load-transmission line reduction rate, the power fluctuation amount of the transmission line due to the variation of the load is quantitatively reflected, so that the power required for overloading the overloaded transmission line can be more accurately calculated.

In this method, if the desired reduction amount of the transmission line power is equal to the excess power (the difference between the overdrive transmission line power and the predetermined set amount of the proper amount of power), it is preferable since it is possible to supply an appropriate amount necessary for overloading the transmission line.

When this method is used, the congestion management system 100 is connected to the transmission line adjacent to the system load 400 between the transmission line and the system load 400. When the system 100 is connected to the transmission line adjacent to the system load 400, It is preferable because it can cope efficiently when an overload occurs.

According to this method, it is preferable from the viewpoint of the overall power supply and demand that the energy storage device 120 supplies electric power to overcome the overload of the overhead transmission line, so that the power generation power of the generator connected to the transmission line is reduced so much. To this end, the congestion management system 100 may provide information on the power supplied to the transmission line to the energy management system 200, and may control the power generation of the generators in the energy management system 200.

Second, how to overcome the overload of the transmission line by reducing the power generation of the generator 500 connected to the overloaded transmission line will be explained.

This method is based on the principle that when the power generation of the generator is reduced, the power flowing through the associated transmission line is also reduced. If the power generation of the generator, which has the greatest influence on the overloaded transmission line, is reduced, the power flowing through the overloaded transmission line Can be efficiently reduced. In this case, the power generation amount of the generator, which has the greatest influence on the overloaded transmission line, is reduced. In the energy management system 200, it is possible to increase the power generation amount of other generators to maintain the balance of power supply and demand of the entire power system, Load shedding, and demand response (Demand Response).

9 illustrates a procedure for eliminating an overload of a transmission line in a manner of reducing power generation of a generator 500 connected to an overloaded transmission line. 9, the congestion management system 100 includes a first step of receiving information on a transmission line from the transmission line monitoring apparatus 300, a first step in which the congestion management system 100 calculates a power (transmission line power) flowing through the transmission line If the transmission line power is greater than the set value, the congestion management system 100 determines that the congestion management system 100 is overloaded, calculates the transmission line power amount (transmission line power reduction amount A) A third step of calculating the generated power to be reduced (the amount of generated power to be reduced), and a fourth step of controlling the energy management system 200 to reduce the power generation of the generator by the induced power. In the above description, the congestion management system 100 is illustrated as performing the third step, but it may be performed by the energy management system 200. When the congestion management system 100 performs the third step, the congestion management system 100 may transmit information about the calculated power to the energy management system 200. [

In this method, it may be a problem to reduce the power generation amount of the generator 500 to overcome the overload of the transmission line in order to overcome the overload of the transmission line. If the generated power of the generator 500 is too small, there is a problem that the overload is not solved. If the generated power is too large, the unbalance and inefficiency of the energy supply and demand of the entire power system may occur. Needs to be. However, as mentioned above, it is not easy to accurately calculate the appropriate discharge power because the power system is intertwined with many generators and many loads through many transmission and distribution lines.

Embodiments of the present invention utilize the generator-transmission line reduction rate to calculate the appropriate power required for overload relief. (Maximum influence generator) that has the greatest effect on the overhead transmission line is determined, and the reduction rate of the generator-transmission line between the maximum influence generator and the overhead transmission line is calculated according to the following equation (3) - Calculate the decay power using the reduction rate of the transmission line and the desired decrease amount A of the transmission line power. Then the maximum impact generator controls the power generation to be reduced by the calculated power. Generator-transmission line reduction rates can be analyzed and calculated using commercially available software used for power grid transmission design.

Equation (3)

Equation 4:

According to this method, the power fluctuation amount of the transmission line due to the fluctuation of the power generation amount of the generator can be quantitatively reflected by using the generator-transmission line reduction rate, so that the required power for overloading the overloaded transmission line can be more accurately calculated.

It is preferable that the power reduction amount A of the transmission line power is made equal to the difference (excess power) between the transmission line power overloaded and the set value, because the generator can reduce the necessary amount for overloading the transmission line.

Third, a method of supplying power stored in the energy storage device 120 to a load connected to an overloaded transmission line and a method of using a method of reducing the power generation of the generator 500 connected to the overloaded transmission line together Explain.

This method considers the difference (excess power) between the power of the transmission line overloaded and the preset appropriate power setting value so that the desired reduction amount A of the transmission line power desired to be reduced by the generation of the generator 500, To the load connected to the transmission line, and then calculates the deceleration power and the supply power by using the above-mentioned Equations 1 to 4, A method of reducing the power generation of the generator by the generated power and a method of supplying the power from the energy storage device 120 to the load connected to the transmission line by the calculated supply power is used at the same time to overcome the overload of the transmission line. In this method, if the sum of the transmission line power desired reduction amount A and the transmission line power desired reduction amount B is equal to the excess power, the transmission line power can be approximated to an appropriate power setting value.

Fig. 10 illustrates a procedure for solving an overload of a transmission line using the method of Fig. 8 and the method of Fig. 9 together. 10, the congestion management system 100 includes a first step of receiving information on a transmission line from the transmission line monitoring device 300, a first step in which the congestion management system 100 calculates the power (transmission line power) flowing through the transmission line If the transmission line power is equal to or greater than the predetermined value, it is determined that the congestion management system 100 determines that the congestion management system 100 is overloaded, and the reduction amount A of the transmission line power desired to be reduced through the detection of the generator, And then calculates the deceleration power of the generator connected to the transmission line according to the desired reduction amount A of the transmission line power using the above Equations 3 and 4. Then, (Power supply) to be supplied from the energy storage device 120 to the load connected to the transmission line according to the transmission line power desired reduction amount B using Equation 2, The congestion management system 100 controls the energy storage device 120 so that the energy storage device 120 supplies the calculated power supply to the power transmission line and provides information about the calculated power consumption to the energy management system 200 And a fourth step of controlling the energy management system 200 so as to reduce the power generation of the corresponding generator by the deceleration power.

According to this method, by using the reduction rate of the generator-transmission line and the load-transmission line reduction rate simultaneously, it is possible to quantitatively reflect the power fluctuation amount of the transmission line according to the power reduction amount of the transmission line due to the decrease of the load and the power generation amount of the generator, It is possible to more accurately calculate required power to be supplied to the power transmission line from the power supply 120 and the required power. Also, considering the residual energy of the energy supply device 120, it is possible to appropriately adjust the transmission line power desired reduction amount A and the transmission line power desired reduction amount B, so that the overload can be efficiently solved.

While the invention has been shown and described with reference to certain embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined only by the appended claims.

100: Congestion management system
110: Power management system for congestion control
111: communication duplexer
112: Operating HMI
113: Data storage device
114: Congestion control calculation processor (A)
115: Congestion control processor (B)
120: Energy storage device
121: communication duplexer
122: power converter
123: Battery
130: Network matching device
131: Information centralizing device
132: Ethernet switch (A)
133: Ethernet switch (B)
200: Energy Management System (EMS)
300: Transmission line monitoring device
400: System load
500: generator

Claims (5)

A power system management method performed by a power system management system,
A first step of receiving information on a transmission line from the transmission line monitoring device 300;
A second step of calculating power (transmission line power) flowing through the transmission line;
A third step of calculating a transmission line power amount (transmission line power reduction amount A) to be determined to be overloaded if the transmission line power is equal to or greater than a set value and calculating a transmission power of the generator connected to the transmission line according to the transmission line power reduction amount A ; And
And a fourth step of controlling the power generation of the generator to be reduced by the deceleration power,
The calculation of the deceleration power according to the transmission line power desired decrease amount A is performed by specifying a generator (maximum influence generator) having the greatest influence on the transmission line, and calculating a generator- transmission line reduction ratio between the maximum influence generator and the transmission line, 3, and calculates the deceleration power using the generator-transmission line reduction ratio and the transmission line power reduction amount A according to Equation (4) below,
Equation (3)

Equation 4:

The third step further includes calculating a desired transmission power reduction amount B and calculating power (supply power) to be supplied from the energy storage device 120 to the load connected to the transmission line according to the transmission line power desired reduction amount B,
Wherein the fourth step further comprises controlling the energy storage device (120) to supply the calculated supply power to the transmission line. delete delete The method of claim 1, wherein calculating the supply power according to the desired transmission line power reduction amount B comprises:
(Load-transmission line reduction ratio) between the maximum influence load and the transmission line power is calculated according to the following equation (1), and the load And calculates the supply power by using the load-transmission line reduction rate and the transmission line power desired decrease amount (B).
Equation 1:

Equation 2:

The power system management method according to claim 4, wherein the sum of the transmission line power reduction amount A and the transmission line power reduction amount B is set to be a difference (excess power) between the transmission line power and the set value.

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