KR100964300B1 - A dispatcher training simulation system - Google Patents

Abstract

PURPOSE: A training simulation system for quickly and accurately evaluating AGC in a training simulation process is provided to evaluate the capability of dispatcher by performing a simulation training under a same condition of an actual power system state. CONSTITUTION: A DTS(Dispatcher Training Simulation) operator(510) acquires data required for simulation. The DTS operator relays the interval of a simulation unit(530) and the dispatcher and controls the simulation situation. The simulation unit practices the dispatcher training simulation. A simulation manager(550) manages the simulation by control signal. A DTS database(570) stores data created in the simulation process.

Description

Dispatcher Training Simulation System

The present invention relates to a training simulation system for training a power supply for operating a power system. More specifically, the power supply can be simulated similarly to changes in a real power system under the same conditions as a real power system state. In addition to the data acquisition server that can directly evaluate and train the capability of the system, the data acquired from SCADA of each regional power supply station in addition to the data acquisition server directly connected to the facilities of the power system can be used in conjunction with the data. It is possible to eliminate the inefficiency of overlapping acquisition of data, and to transmit and receive various data to the weather server (WIS) of KEPCO, for example, to acquire and manage various and accurate data related to power system. It is possible to connect various training scenarios and events to the training instructor's setting conditions. It can be easily created, and the power supply and training instructors participating in the training can be freely connected and used anytime and anywhere through the web without installing a separate program, thereby increasing user convenience, and in the training simulation process. The present invention relates to a dispatcher training simulation system that can accurately and quickly evaluate the implementation level for automatic power generation control (AGC) and be used as future operational data.

As the national economic growth and the standard of living improve, the power consumption, which is the driver of convenience and the national economic growth, continues to increase, and the increase in electric power demand has complicated, diversified, and increased the power system. However, large-scale blackout accidents in North America and Europe in 2003 were not only due to the weakness of data acquisition and monitoring and control of the power system, but also spreading to all power systems because they could not detect and respond to small-scale initial accidents quickly. As a result, the importance of simulating training for emergency supply in charge of power system operation in the energy management system is highlighted.

However, the systematic development of the conventional power supply training simulation system has not been progressed, and the local parts such as the simulation system for analyzing the power system and the OTS (Operator Training System) for the SCADA operator Only a mock training system has been utilized, and there is a lack of development of a training simulation system for power supply, which is in charge of power system operation for the entire energy management system (EMS).

In addition, in the case of the existing simulation training system, since the training model in which the simulation is performed differs from the actual power system, there is a limit in evaluating the power supply capability or deriving the results of the training. Acquisition and management system also had the problem of operating inefficiently.

In addition, since there is no system for evaluating the control in the training simulation process of power supply, in particular, the implementation of AGC, it can be provided as an operation data of the future power system. The usability could also be extremely limited.

The present invention has been made to solve the above problems,

SUMMARY OF THE INVENTION An object of the present invention is to provide a power supply training simulation system capable of accurately evaluating and training power supply capability by performing simulation training similar to changes in an actual power system under the same conditions as the actual power system state. .

Another object of the present invention is the data acquisition server directly connected to the facilities of the power system, in addition to the data acquisition server through the data linking server for the data already acquired in the SCADA (SCADA) of each regional power station by using this in conjunction with the ratio of duplicate acquisition of data Efficiency can be eliminated, and other external systems, for example, can transmit and receive various kinds of data to the weather server (WIS) of KEPCO, so that it can acquire, manage and utilize various accurate data related to power system. To provide a simulation system.

Still another object of the present invention is to provide a power supply training simulation system that can provide the same training environment conditions as the actual power system state by utilizing the connection with the acquisition management database for EMS.

Still another object of the present invention is to provide a power supply training simulation system that can easily generate various scenarios and events to be used in the training simulation in connection with the setting conditions of the trainer.

Another object of the present invention is to provide a power supply training simulation system that can increase the user convenience by allowing the power supply and training instructors to participate in the training can be freely connected and used anywhere, anytime, without a separate program installation. It is.

It is another object of the present invention to evaluate the implementation level of the automatic power generation control (AGC) in the training simulation process, and in particular, to accurately measure and analyze the characteristics of the increase / decrease rate of the generator, which is the basis of the automatic power generation control, and to engage in human behavior. It is to provide a power supply training simulation system that can be used as future operation data by ensuring the accuracy and promptness of the performance evaluation by excluding as much as possible.

The power supply training simulation system for achieving the above object of the present invention includes the following configuration.

The power supply training simulation system according to an embodiment of the present invention obtains the data necessary for the simulation from the EMS database in connection with the data acquisition unit, relays the power supply and simulation unit participating in the training, and monitors and controls the simulation situation. ; A simulation unit that executes a power supply training simulation; A simulation management unit for generating scenarios and events required for simulation and managing the simulation situation by a control signal input from a training instructor; And a DTS database for storing data acquired from an EMS database and data generated in a simulation process, wherein the DTS operation unit controls a second communication module for allowing a power supply to be accessed through a web server, and overall operation of the DTS operation unit. A central processing module, and a display module for displaying a simulation situation executed in the simulation unit, wherein the simulation management unit includes a third communication module for allowing a trainer to access the web server, scenarios necessary for simulation, It includes a scenario generation module for generating an event, a training management module for progressively managing a simulation situation by a control signal input from a web server, and a real-time execution evaluation unit for evaluating the control results in the training simulation.

According to another embodiment of the present invention, in the power supply training simulation system according to the present invention, the data acquisition unit directly acquires data from a remote terminal device (RTU) installed in a generator or substation and stores it in a real-time database; Data linking server which acquires data from SCADA or external system of each regional power supply station and stores them in real time database, and periodically extracts and selects data selected by user from data stored in real time database as EMS operation data. It includes a history data management server that can be utilized, the history data management server is a first communication module for receiving information from the user through a web server, and the data collection to obtain and transmit the data selected by the user from the real-time database Module and data transmitted through the data collection module A data operation module for storing operator data based on a calculation condition input by the user based on the data stored in a history data database, a backup module for automatically backing up data stored in the history data database according to a storage cycle, and the history data It is characterized by including a data providing module for querying and providing the data stored in the database as well as the backed up data.

According to another embodiment of the present invention, in the power supply training simulation system according to the present invention, the real-time performance evaluation unit communication module for transmitting and receiving a signal or data with the history data management server; A selection module for selecting a test generator or a performance evaluation test method among the generators connected through the history data management server, an input module for inputting a target output to be tested, and a test generator with the start of the test. A generator control signal generation module for generating an output control signal for and transmitting through the communication module, and using the current output and time data of the generator under test in response to the output control signal to calculate the increase and decrease rate of the generator under test A central control unit including a calculation module; A database unit for storing automatic power generation control-related data about the test target generator acquired from the EMS database connected through the history data management server and output control signals or data relating to the response output generated in the course of the test; And a display unit for displaying the automatic power generation control-related data about the test target generator acquired from the EMS database connected through the history data management server and the output control signal or the data relating to the response output generated in the course of the test. In the calculation module, the absolute value of the difference between the 10% reaching time of the target output and the 90% reaching time of the target output is divided by the absolute value of the difference between the 10% reaching time of the target output and the 90% reaching time of the target output. By calculating the increase and decrease rate, it is possible to accurately calculate the increase and decrease rate of the generator to evaluate the implementation level of the automatic power generation control.

The present invention can achieve the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention can simulate the change in the actual power system under the same conditions as the actual power system state can have an effect that can accurately evaluate and train the power supply.

The present invention removes the inefficiency of data acquisition by using the data acquisition server directly connected to the facilities of the power system, in addition to the data acquisition server through the data connection server for the data already acquired in the SCADA of each regional power station. In addition, other external systems, for example, can transmit and receive various data to the weather server (WIS) of the Korea Power Exchange, etc., which has the effect of acquiring, managing and utilizing various accurate data related to the power system.

The present invention has the effect of providing the same training environment conditions as the actual power system state by utilizing them in conjunction with the database managed for the EMS.

The present invention has an effect that can be easily generated in connection with the set conditions of the training instructor various scenarios and events to be used in the training simulation.

The present invention has the effect that the power supply and training instructors participating in the training can be freely connected and used anytime and anywhere through the web without installing a separate program to increase user convenience.

The present invention can evaluate the implementation level of the automatic generation control (AGC) in the training simulation process, and in particular, by accurately measuring and analyzing the characteristics of the increase and decrease rate of the generator, which is the basis of the automatic generation control, It has the effect of ensuring the accuracy and promptness of the performance evaluation so that it can be used as future operation data.

Hereinafter, preferred embodiments of the dispatcher training simulation (DTS) system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of a power supply training simulation system according to an embodiment of the present invention, Figure 2 is a block diagram showing the configuration of the history data management server of the data acquisition unit, Figure 3 is a simulation management unit It is a block diagram showing the detailed configuration of the real-time implementation evaluation unit.

1 to 3, the power supply training simulation system according to an embodiment of the present invention, in conjunction with the data acquisition unit 110 to acquire the data necessary for the simulation from the EMS database 30, and participate in the training A DTS operation unit 510 for relaying a power supply and a simulation unit 530 and monitoring and controlling a simulation situation; A simulation unit 530 on which power supply training simulation is executed; A simulation management unit 550 for generating scenarios and events necessary for simulation and managing the simulation situation by a control signal input from a training instructor; And a DTS database 570 for storing data acquired from the EMS database 30 and data generated in the simulation process.

One of the main features of the power supply training simulation system according to the present invention is the actual power by receiving and using a database that is acquired, stored, and managed in relation to the power system for an energy management system (EMS). The power supply training simulation can be performed in the same environment as the system. For this purpose, the configuration of the data acquisition unit 110 for collecting data related to the power system and the EMS database 30 for storing and managing the data will be described first. do.

The data acquisition unit 110 includes a variety of power system facilities constituting the power system to perform a function such as fast and accurate monitoring and control of the power system and the optimized automatic power generation control through the EMS, that is, generator, Information about the state of the substation, breaker, etc., that is, the configuration to enable the acquisition and storage management of the power system data, in particular the data acquisition unit 110 is a remote terminal unit (RTU: Remote Terminal Unit, installed in the generator or substation, Data acquisition server 111, which acquires data directly from 70) and stores it in real-time database 310, and data from SCADA (SCADA: Supervisory Control and Data Acquisition System, 80) or external system (90). The data linking server 113 for acquiring and storing the data in the real time database 310 and the data selected by the user among the data stored in the real time database 310. It may include a history data management server 115 to be periodically extracted, stored, managed to be utilized as EMS operation data and the like. The standard protocol used for data acquisition by the data acquisition unit 110 may be used DNP 3.0, ICCP, Web module, and the like. Before describing the detailed configuration of the data acquisition unit 110, a brief look at the structure of the EMS database 30 for storing and managing the EMS-related data for reference, EMS database 30 is a large-scale real-time monitoring of the power system And a real-time database 310 for storing real-time data indicating the current state of the power system, such as a remote measurement value transmitted from a remote terminal device (RTU) of each generator or substation or a remote control unit (RCC) for control. , A program database 330 for supporting power system installation modeling and power system connection relation modeling to support system application programs and generator control operation programs of the EMS, and power system monitoring and control collected and transmitted from the EMS. It includes a history data database 350 that stores and backs up all data and provides them upon request.

The data acquisition server 111 is connected to a remote terminal device (RTU, 70) installed in a generator or substation, and directly obtains data therefrom and stores the data in the real-time database 310. The data acquisition server 111 is Receives signals such as data requests and control commands from the host server of the EMS, and requests and receives various status information from the remote terminal device (RTU) 70 installed in the generator or substation. The data communication between the remote terminal device (RTU) 70 and the data acquisition server 111 and the host server or real time database 310 of the EMS is performed so as to improve communication reliability. (B) It is preferable that the communication line is designed in a redundant structure. The method of acquiring data in the data acquisition server 111 may be a method of acquiring and requesting data from the remote terminal device RTU 70 periodically according to a period set by a user, and the power of the remote terminal device RTU 70. When a change occurs in the system data, a method of transmitting it to the data acquisition server 111 and a method of acquiring a user request signal may be used.

The data linking server 113 is configured to store data in the real-time database 310 by acquiring and linking data from a SCADA (SCADA, 80) or an external system 90 of each regional power station, and the data linking server 113 Receives data requests, control commands, etc. from the host server of the EMS, requests and receives various status information from the SCADA (80) or the external system 90 of each regional power supply station. It is transmitted and stored in the database 310, etc., the data communication between the SCADA (80) or the external system 90 and the data connection server 113 and the host server or real-time database 310 of the EMS communication communication reliability In order to improve, it is preferable that not only the data acquisition device but also the network or communication line be designed in a redundant structure. In particular, the data linking server 113 can be connected to the external system 90 to transmit and receive external data, for example from the weather server (WIS) of the Korea Power Exchange through the data linking server 113 By providing weather information for each branch and providing it to the host server of EMS, it can assist in efficient energy management with reference to it. As such, in addition to the data acquisition server 111, the data can be acquired through the data linking server 113, so that data already acquired from the SCADA (SCADA, 80) of each regional power station is duplicated by using the linkage. The inefficiency of the acquisition can be eliminated, and other external systems 90, for example, can transmit and receive various types of data with the meteorological server (WIS) of the Korea Electric Power Exchange, so as to acquire various data for efficient energy management. You get the effect you can provide.

The history data management server 115 may be periodically used to extract the data selected by the user from the data stored in the real-time database 310, (stored in the history data database 350) to be used as EMS operation data, etc. Of course, the data stored and managed in the EMS database 30 is provided to be utilized in another server or another system, and as shown in FIG. 1 a communication module 1151, a data collection module 1152 for acquiring and transmitting data selected by a user from the real-time database 310, and data transmitted through the data collection module 1152; a history data database 350 And a data operation module 1557 for generating an operator fee according to a calculation condition input by the user, and the data stored in the history data database 350. Backup module 1154 for automatically backing up according to the storage period, and the data providing module to query and provide the data of the EMS database 30, including the data stored or backed up in the history data database 350 (1155).

The first communication module 1151 allows a user to access the history data management server 115 through a web server and input information on the type, storage cycle, storage format, etc. of collected data, or other server or other system. This is a configuration for linking signals or data in conjunction with the standard, and uses the standard protocol for data transmission and reception described above. The user may store information related to the type of data to be collected by the history data management server 115 through the first communication module 1151, the storage cycle, information about a storage format, or information about data calculation conditions or data backup; You can enter information about the storage location or the type, period, and format of the data provided to other systems. Especially, you can freely input anytime and anywhere without installing a separate program by accessing the web server. User convenience can be increased. In addition, the process of requesting and receiving data related to the power system from another server or another system is also performed through the first communication module 1151.

The data collection module 1152 is configured to acquire and transmit data selected by a user from the real-time database 310, and the data collection module 1152 is to be collected when the user inputs collection information about data to be collected. In order to easily select data, information about the power system is extracted from the real-time database 310, and a power system schema file (* .XML) is generated and provided as a web screen through the first communication module 1151. By doing so, the user's convenience can be increased. When the user inputs information about the type of data to be collected, the storage cycle, and the storage format, the config file in which the collection information is defined is transferred to the data collection module 1152, and the data collection module 1152 is called through an API call. The relevant data is requested to the real-time database 310 and the response data is created and transmitted in a '* .dat' file.

The data operation module 1557 stores the data (* .dat) transmitted through the data collection module 1152 in the history data database 350 in a table form and based on the calculation condition input by the user. In accordance with the configuration for generating the operator fee, the user through the data operation module (1557) for the data stored in the history data database 350 according to the user's desired condition or cycle, such as summary data (summary data) or statistical data, etc. (This is called 'calculated data') so that the data can be easily utilized. The operation conditions input to generate the operator fee include the table information (a table with data to be used for calculation) and operation There are periodic information (period of data to be grouped), work information (work cycle, active date and time), and formula.

The backup module 1154 is a configuration for automatically backing up the data stored in the history data database 350 according to the storage cycle, the storage cycle is the history so that the collected and stored data can be immediately inquired by the user's request The data in which the storage period has elapsed as a period of time remaining in the memory on the data database 350 is backed up by the SAN method to the space of the disk designated by the backup module 1154, so that It will increase the usability and operation efficiency. At this time, the backup module 1154 stores the metadata related to the backup operation in the history data database 350 so that a user or the like can inquire about the data whose storage period has elapsed. In addition, the backup module 1154 may move the backed up file to another medium (Optical Disk, etc.).

The data providing module 1155 is configured to inquire and provide data of the EMS database 30 including data stored in the history data database 350 (data not stored in the elapsed storage period) or backed up data. When the data providing module 1155 provides a table list of data existing in the EMS database 30 on a web screen through the first communication module 1151 for the convenience of a user, and the like, when the table name is clicked, By providing table column information as a popup, users can select the table they want to search and search the desired data.In addition, information related to providing user-defined data (for example, system information to be provided, table information to be provided) Etc.) may provide data stored in the EMS database 30 to other systems. The data providing module 1155 also enables inquiry or provision of data already backed up by the backup module 1154 after a storage cycle has elapsed, which is described in detail above. It is based on the stored meta information, and the inquired data can be saved as an Excel file on a PC or other storage device such as a user according to a user's request.

As described above, the history data management server 115 (to data acquisition unit 110) collects data related to power system monitoring, control information, etc. in the EMS and stores the data for a long time and also provides information required from the outside of the EMS. In addition to being used as operating data or other data for power management, system operators and users can freely use anytime, anywhere through the web without installing a separate program, thereby increasing user convenience.

The DTS operator 510 acquires the data necessary for the simulation from the EMS database 30 in connection with the data acquisition unit 110, relays the power supply and the simulation unit 530 participating in the training, and monitors and monitors the simulation situation. In this configuration, the DTS operation unit 510 may transmit and receive a signal or data in association with the data acquisition unit 110 and the power supply (corresponding to the 'trainer' of the training simulation) can be accessed through the web server. Display module 515 for displaying the second communication module 511, the central processing module 513 to control the overall operation of the DTS operation unit 510, and the simulation situation to be executed in the simulation unit 530 to be described later ) May be included.

The second communication module 511 may be connected with the data acquisition unit 110 to transmit and receive a signal or data, and the power supply (corresponding to the 'trainer' of the training simulation) to be connected through a web server. In this case, the standard protocol for data transmission and reception described above is used. Since one of the main features of the present invention is to receive the database that is acquired, stored, and managed in relation to the power system for the EMS as it is to use it to proceed the power supply training simulation in the same environment as the actual power system, The second communication module 511 receives the various data related to the power system stored in the EMS database 30 through the data acquisition unit 110 and the DTS database 570 which will be described later. It is stored in the database (571) and can be utilized in the simulation unit 530 which will be described later. In addition, the trainee that is the training target of the training simulation, that is, the power supply is transmitted to the simulation progress status from the simulation unit 530 to be described later through the second communication module 511 and accordingly system operation, automatic power generation control, failure It is possible to participate in the training simulation by sending and receiving necessary signals and data during the simulation process, such as inputting control signals related to recovery, etc. In particular, it is possible to freely send and receive anytime and anywhere without installing a separate program by accessing using a web server. Can be increased.

The central processing module 513 is a part for controlling the overall operation of the DTS operation unit 510, and a simulation unit 530 or a DTS database (described later) to describe various signals or data transmitted and received through the second communication module 511. 570 may be controlled to be distributed and stored or may be displayed through the display module 515 to be described later. As the central processing module 513, a central processing unit (CPU) or the like may be utilized.

The display module 515 may display a situation related to a power system state acquired through the second communication module 511 through a screen or display a simulation progress situation, a result, etc., which are executed by the simulation unit 530. As a part to be displayed through, it may be referred to as a graphic processing module that can be displayed on the screen by the graphic processing the data managed by the DTS operation unit 510. The screen displayed through the display module 515 can also check the trainer, that is, the power supply through the web server.

The simulation unit 530 is a portion in which the power supply training simulation process is actually executed, that is, a training simulation program is driven, and data related to the actual power system acquired from the EMS database 30 through the DTS operation unit 510. Based on the modeling work for the power system is carried out, the training scenario or event transmitted through the simulation management unit 550 to be described later is executed, the trainee input through the DTS operation unit 510, that is the input of the power supply The simulation process is performed according to the signal to verify and train the trainer's power system operation and control, and the ability to deal with the situation in an environment similar to the real power system. In the simulation unit 530, various applications related to the operation and control of the power system should be able to be driven in the same manner as in the real world, so that the EMS database 30 linked through the DTS operation unit 510, in particular, the program database 330 In)), a database of systematic models that can be commonly used for various applications is obtained and used.

The simulation management unit 550 generates scenarios and events necessary for simulation, and proceeds to manage the simulation situation by a control signal input from a training instructor. For this purpose, the simulation management unit 550 is the simulation unit 530. And a third communication module 551 for transmitting and receiving a signal or data related to a training simulation situation and allowing a trainer to access and transmit a control signal through a web server, and to generate scenarios and events necessary for simulation. Scenario generation module 553, a training management module 555 for managing the progress of the simulation by the control signal input from the web server, and a real-time implementation evaluation unit 557 for evaluating the control results in the training simulation Can be.

The third communication module 551 may be connected to the simulation unit 530 to transmit and receive a signal or data related to the training simulation situation, and to allow a training instructor to access a web server to transmit a control signal. Use the standard protocol for data transmission and reception described above. The simulation management unit 550 receives the information on the training simulation situation in progress in the simulation unit 530 through the third communication module 551 and the control signal of the training instructor periodically or transmitted through a web server By transmitting the training scenarios and events generated and managed in the scenario generation module 553, which will be described later, it is managed to proceed with the training simulation process. In addition, the training instructor to proceed and manage the training simulation is received through the third communication module 551 to the simulation progress status from the simulation unit 530 to be described later, according to the signal or data necessary in the simulation progress process accordingly It also manages and supervises the training simulation process by sending and receiving control signals such as simulation progress speed, event insertion time and change, scenario change, and simulation stop. This makes it possible to increase user convenience.

The scenario generation module 553 is a part for generating scenarios and events required for simulation. Training scenarios can be categorized into steady state, abnormal state, and fault recovery situation.The steady state scenarios include economic dispatch, automatic power generation control, remote control, power distribution planning, load tracking, and voltage control under normal power system conditions. And training scenarios for training processes such as reactive power feeding, communication with substation and power plant operators, tidal current calculations, and optimal algal calculations, and abnormal situation scenarios in which power system problems occur, namely power failure, It is related to training scenarios that enable training of various types of failures, load interruptions, communication failures, generator trips, unplanned relay operations, etc.The failure recovery scenarios include recovery procedures after a power outage and generator system. It relates to training scenarios that enable the training of reintervention and system analysis during restoration. Generating a training scenario consists of editing various events or event groups to be described later in accordance with a training purpose. The scenario generating module 553 can edit various events, and store and call a scenario. Etc., so that a scenario can be easily generated. An event is a component of a scenario, and its definition refers to an accident and a specific event used in training. It can be categorized into actionable relay action event and request event that instructor can arbitrarily occur. The designated event is an event generated by the instructor after determining the event occurrence time and the event generating device. The designated event may be selectively used or selected to be released when the scenario is generated. The condition event is set by the trainer. This event is generated when one condition is satisfied, and then the instructor decides various execution conditions and contents and then creates an edit based on this. The relay operation event is also edited and generated based on the specific relay and the specific operation specified by the trainer, and the request event is edited accordingly when the trainer defines a newly defined event that is not added to the existing event list.

The training management module 555 is a part that manages the simulation situation by the training scenario or a control signal (training instructor) input through a web server, by the training scenario generated by the scenario generation module 553 or The control signal input by the training instructor connected through the web server starts and ends the training simulation in the simulation unit 530, the simulation execution speed, the change of the scenario, the control of the cycle or the power supply to perform the automatic power generation control It manages the overall progress such as setting the time when the signal is transmitted and stopping and restarting the training simulation. As the training management module 555, a central processing unit (CPU) or the like may be utilized.

The real-time execution evaluation unit 557 is a part for evaluating the control result in the training simulation, for the automatic power generation control, remote control, system operation, etc. performed by the power supply in the training simulation carried out through the simulation unit 530. The training results are evaluated based on a predetermined evaluation standard, and the results are transmitted to the DTS operation unit 510 and stored in the DTS database 570. In particular, the real-time implementation evaluation unit 557 can accurately evaluate in real time whether the implementation by the automatic power generation control (AGC), a detailed description thereof will be described later.

The DTS database 570 is configured to store and manage data acquired from the EMS database 30 through the DTS operation unit 510 and data generated in the simulation process. An operating database 571 which stores and manages data related to the power system acquired from the EMS database 30 through the DTS operation unit 510 so that the simulation can proceed in the same situation, and data and training generated during the training simulation process. It may include a simulation database 573 that stores and manages the results and evaluation data of the simulation.

The operation database 571 is a part for storing and managing data related to the power system acquired from the EMS database 30 through the DTS operation unit 510 so that the simulation can proceed in the same situation as the actual power system. Since the simulation unit 530 should be able to perform the simulation in the same environment as the actual power system, the operation database 571 is added to the operation database 571 as needed based on data related to the power system acquired from the EMS database 30. This is done by adding a new list in parallel to an existing database table.

The simulation database 573 stores and manages data generated during a training simulation process, results of training simulations, and evaluation data, and the like, and results of modeling work on a power system performed by the simulation unit 530. It saves and manages the data related to the entire training simulation process such as the scenario used in the process, the control signal input by the power supply, the training progress and results, and the training evaluation result, so that it can be used as future operation data.

According to another embodiment of the present invention, the real-time implementation evaluation unit 557 may evaluate in real time whether the implementation of the automatic generation control (AGC: Auto Generation Control) for the power system in particular during the training simulation process for the power supply To this end, the real-time implementation evaluation unit 557 is a fourth communication module (5571) that can send and receive signals or data with the history data management server 115, as shown in Figure 3; A selection module 55731 for selecting a generator to be tested or a performance evaluation test method among generators 72 connected through the history data management server 115 and a remote terminal device (RTU) 70 and a target to be tested. An input module 55732 capable of inputting an output, and a generator control signal generation module 55734 for generating an output control signal for the generator under test at the beginning of the test and transmitting it through the fourth communication module 5571; A central control unit 5573 including a calculation module 55735 that calculates the increase / decrease rate of the test target generator using the current output and time data of the test target generator corresponding to the output control signal; Database unit for storing automatic power generation control-related data about the test target generator obtained from the EMS database 30 linked through the history data management server 115 and output control signals or data relating to the response output generated in the course of the test. (5575); Display unit for displaying the automatic power generation control data related to the generator under test obtained from the EMS database 30 linked through the history data management server 115 and the output control signal or the response output data generated in the course of the test (5577); may include.

The fourth communication module 5571 is configured to be an interface for transmitting and receiving a signal or data with the history data management server 115, and the real-time performance evaluation unit 557 is a separate computer (PC) as necessary. Because it can be operated in the history data management server 115 through the output control signal of the generator 72 to the generator 72 and also data such as the current output of the generator 72 also history data management server ( In order to receive the feedback through the 115, the configuration such as the fourth communication module 5571 capable of exchanging signals or data with the history data management server 115 may be further required. As a data acquisition communication protocol applied to the fourth communication module 5571, a communication protocol such as an intersite data (ISD) may be used.

The central control unit 5573 is configured to control the overall operation of the real-time execution evaluation unit 557, the test preparation work before starting the performance evaluation test (that is, history data management through the fourth communication module 5571) When connected to the server 115, the supply capacity, the current load and grid frequency values are read and updated in real time), the start and end of the test, the generation of various control signals during the test process and the calculation and evaluation using the test data. The operation of the first half is governed. To this end, a central processing unit (CPU) or the like may be used as the central controller 5573. The central controller 5573 may select a generator to be tested from a generator 72 connected through a history data management server 115, or the like. A selection module 55731 for selecting a performance evaluation test method, an input module 55732 for inputting a target output to be tested, and an output control signal for the generator under test at the beginning of the test, 4 A generator module for calculating the increase / deceleration rate of the generator under test using the generator control signal generation module 55734 transmitted through the communication module 5571 and the current output and time data of the generator under test responding to the output control signal. (55735) may be included.

The selection module 55731 has a function of selecting a generator to be tested from among the generators 72 connected through the historical data management server 115 or selecting a performance evaluation test method in an automatic mode or a manual mode before starting the performance evaluation test. As a part of performing, selecting a generator to be tested from among the generators 72 connected through the historical data management server 115 through the selection module 55731, that is, automatic generator control-related characteristic data of the generator, that is, the facilities of the generator Capacity, automatic power generation control upper limit value (LFC Limit Max), automatic power generation control lower limit value (LFC Limit Min), evaporation rate and deceleration rate, current output value, etc. are read from the EMS database 30 linked to the history data management server 115 and described later. In the database unit 5475, more specifically, the generator storage module 54751, which is to be described later, is displayed on the display unit 5577 (more specifically, the generator display module 55771) to be described later. It becomes. In addition, the selection module 55731 may select whether to perform the performance evaluation test in the automatic mode or in the manual mode. In the automatic mode, after the test starts, the generator's response output (output control signal transmitted to the generator) When the current output of the responding generator is referred to as 'response output' below 90% of the target output (a detailed description will be described later), the transmission of the output control signal is automatically stopped and the test is terminated. In this case, even after the generator's response output reaches 90% of the target output, the test can be terminated as soon as the operator's test stop signal is transmitted, allowing the test to run flexibly depending on the situation.

The input module 55732 is a part capable of inputting a target output to be tested before starting the performance evaluation test. When the target output is input to the generator under test through the input module 55732, the target output is tested. If the value is larger than the current output before the start of the test generator, the evaporation test is automatically recognized. If the value is smaller than the current output of the test generator, it is automatically recognized as the desensitization test.

In addition, the central control unit 5573 further includes a start stop module 55733 for selecting the start and end points of the test (if the start stop module 55733 is not included separately, the selection module 55731 includes: Charge)), the start stop module (55733) through the selection module (55731) and the input module (55732) the test preparation work, such as the selection of the generator under test, the selection of the test method, input of the target output is completed Thereafter, it becomes possible to selectively control the time when the performance evaluation test is started, that is, when the output control signal is transmitted to the generator under test, and when the test is stopped (especially required in the manual mode). .

The generator control signal generation module 55734 generates an output control signal for the generator under test at the beginning of the test and transmits the generated control signal through the fourth communication module 5571. Before the performance evaluation test is performed, the control signal for the generator is generated and transmitted in the automatic generation control (AGC) of EMS or the training simulation of the simulation unit 530. However, when the performance evaluation test starts, the real-time execution is performed. The evaluation unit 557 generates and controls an output control signal for the generator under test, and the generator control signal generation module 55734 is responsible for this. The generator control signal generation module 55734 compares the current output of the generator under test with the target output input through the input module 55732 to recognize whether it is an evaporation test or a deceleration test and outputs an output control signal accordingly. The output control signal can be generated according to the following equation.

TatgetMW _t = TatgetMW _{t -1} ± ΔMW _{Ramp Rate , 4 sec}

(ΔMW _{Ramp Rate , 4 sec} = (MW _{Ramp Rate , 1 Min} ) / 15

TatgetMW _t : control target value of current cycle, TatgetMW _{t -1} : control target value of previous cycle,

ΔMW _{Ramp Rate , 4 sec} : _ramp rate per 4 seconds, MW _{Ramp Rate , 1 Min} : Change rate per minute)

That is, the output control signal is the same as that of the automatic power generation control (AGC) control signal transmitted every 4 seconds. The control target value of the current cycle is calculated by adding or subtracting. In this case, in particular, the first output control signal at the start of the test is calculated and transmitted to the current output value immediately before the start of the test of the generator under test, which prevents the instability of the generator due to sudden changes in the control target value and at the same time output control. This is to enable stable output control of generator by starting from output value.

The calculation module 55735 calculates the increase / deceleration rate of the test target generator by using the current output of the test target generator corresponding to the output control signal, that is, the response output and the time data. When the performance evaluation test is started by the start signal, the output control signal generated from the generator control signal generation module 55734 is transmitted to the generator under test through the history data management server 115, and the response output of the generator under test is also transmitted. The history data management server 115 is fed back through the database unit 5475 (more specifically, the test data storage module 5475), which will be described later, and stored in the display unit 5577 (more specifically, the test state display module 55772). ), Which is stored in the database unit 5475 (more specifically, the test data storage module 5475). Dynamic power and time data are used to calculate the rate of increase and decrease of the generator under test. In this case, in particular, the increase / decrease rate calculation formula utilized by the calculation module 55735 is as follows.

RR _test = │MW ₉₀ -MW ₁₀ │ / │T ₉₀ -T ₁₀ │

(However, RR _test : measured increase and decrease rate [MW / MIN],

T ₁₀ : 10% reach time of target output [MIN], T ₉₀ : 90% reach time of target output [MIN],

MW ₁₀ : T ₁₀ time point output [MW], MW ₉₀ : T ₉₀ time point output [MW])

That is, the real-time execution evaluation unit 557 does not simply calculate the increase / deceleration rate by simply calculating all the response outputs fed back at the start of the test by the calculation module 55735, but the response output is considered in consideration of the response delay time of the generator. By extracting only the data from 10% of the target output to 90% of the target output and using it to calculate the increase and decrease rate, the generator increases and decreases in the section following the output control signal after starting to respond to the output control signal. It is possible to calculate the evaporation rate so that the increase and decrease characteristics of the generator under test can be calculated accurately. The calculation module 55735 evaluates the performance of the automatic generator control assistance service of the generator under test based on the calculated increase / deceleration rate. When the calculated increase / decrease rate is less than 80% of the reported increase / decrease rate, automatic generation control failure occurs. Will be judged. As described above, the calculation module 55735 accurately calculates the increase / decrease rate of the generator to be tested to evaluate the implementation level, thereby ensuring a fair power market operation.

The database unit 5475 may be configured to output data related to automatic power generation control related to the generator to be tested obtained from the EMS database 30 linked through the history data management server 115 and output control signals or response outputs generated in the course of the test. In the configuration such as a memory (RAM) or a disk storage device for storing the data related to this, the database unit (5575) to the test target generator obtained from the EMS database 30 linked through the history data management server 115 Generator storage module (55751) for storing the automatic power generation control-related data, and a test data storage module (55752) for storing data about the output control signal or the response output generated in the course of the test.

As described above, when the generator storage module 55751 is connected to the history data management server 115 through the fourth communication module 5571, data such as supply capacity, current load, and grid frequency related to automatic power generation control are stored. If the test target generator is selected through the selection module 55731, it is updated and stored in real time. The automatic power generation for the corresponding generator stored in the EMS database 30 linked through the history data management server 115 is also performed. Control-related characteristic data, that is, the capacity of the generator, the automatic power generation control upper limit value (LFC Limit Max), the automatic power generation control lower limit value (LFC Limit Min), evaporation rate and deceleration rate, the current output value, etc. are read from the EMS database 30 and stored. Will be. In particular, the generator storage module (55751) accurately stores and stores the current output value of the generator under test immediately before the test start to provide to the generator control signal generation module (55734).

As described above, when the test is started, the test data storage module 54752 is generated by the generator control signal generation module 55734 and output control signal and history data transmitted to the generator under test through the history data management server 115. The current output of the generator under test, that is, the response output and the time data corresponding to the output control signal fed back through the management server 115 is stored in real time. In particular, the test data storage module 54752 has a response output (MW ₁₀ ), time data (T ₁₀ ), and a response output of 90% of the target output when the response output of the target generator reaches the 10% level of the target output. The response output (MW ₉₀ ) and the time data (T ₉₀ ) at the point of arrival are accurately recorded and stored and provided to the calculation module 55735.

The display unit 5577 is configured to output data related to automatic power generation control related to the generator under test acquired from the EMS database 30 linked through the history data management server 115 and output control signals or response outputs generated in the course of the test. In the same configuration as the display device for displaying the relevant data on the screen, the display unit 5577 is associated with the automatic power generation control for the generator under test obtained from the EMS database 30 linked through the history data management server 115 Generator display module (55771) for displaying data, and a test state display module (55772) for displaying data relating to the output control signal or the response output generated in the course of the test.

As described above, when the generator display module 55771 is connected to the history data management server 115 through the fourth communication module 5571, data such as supply capacity, current load, and grid frequency related to automatic power generation control are stored. If the test target generator is selected through the selection module 55731, it is displayed in real time and is automatically generated for the corresponding generator stored in the EMS database 30 linked through the history data management server 115. The control-related characteristic data, that is, the capacity of the generator, the automatic power generation control upper limit value (LFC Limit Max), the automatic power generation control lower limit value (LFC Limit Min), the evaporation rate and the deceleration rate, the current output value, etc. are read and displayed from the EMS database 30. Done.

The test state display module 55772 has an output control signal and history data generated by the generator control signal generation module 55734 and transmitted to the test target generator through the history data management server 115 when the test is started as described above. The current output of the generator under test in response to the output control signal fed back through the management server 115, i.e., the response output and the time data, is displayed in real time.

The real-time performance evaluation unit 557 further includes a report generation module 55736 in which the central controller 5573 prepares a report on a test result, and the database unit 5575 includes the report generation module (5). 55736) can additionally include a report storage module (55753) for storing the report generated through this, it is possible to create, store and output the results of the performance evaluation test in a separate report form, so that long-term preservation and evidence of the test results It is possible to increase the usability as.

The report creation module 55736 is a part which summarizes the results of the performance evaluation test by the real-time performance evaluation unit 557 in a report form, and includes the name of the generator to be tested, the date and time of the test, the rate of increase and decrease of the generator, and the target output. In this regard, the report is prepared by briefly arranging the response output and time during the test process, the increase and decrease rate calculated from the test result, and the evaluation result.

The report storage module 54753 is a part for storing a report on a test result generated through the report preparation module 55736, so that the report, which is a test result, can be stored for a long time and used as evidence or various data.

As described above, the real-time execution evaluation unit 557 accurately evaluates and analyzes the characteristics of the generator's increase / decrease rate, which is the basis of the automatic power generation control, to evaluate the implementation level of the automatic power generation control of the generator as well as exclude human intervention. This ensures the accuracy and promptness of the performance evaluation.

In the above, the Applicant has described preferred embodiments of the present invention, but these embodiments are merely one embodiment for implementing the technical idea of the present invention, and any changes or modifications may be made as long as the technical idea of the present invention is implemented. Should be interpreted as being within the scope.

1 is a block diagram showing the configuration of a power supply training simulation system according to an embodiment of the present invention.

2 is a block diagram showing the configuration of a history data management server of a data acquisition unit;

3 is a block diagram showing the detailed configuration of the real-time implementation evaluation unit of the simulation management unit;

* Explanation of the main symbols used in the drawings

110: data acquisition unit, 111: data acquisition server, 113: data connection server, 115: history data management server

30: EMS database, 310: real time DB, 330: program DB, 350: history DB

510: DTS operation unit, 511: second communication module, 513: central processing module, 515: display module

530: simulation unit

550: simulation management unit, 551: third communication module, 553: scenario generation module, 555: training management module, 557: real-time performance evaluation unit

5571: communication module, 5573: central control unit, 5575: database unit, 5577: display unit

55731: selection module, 55732: input module, 55733: start stop module,

55734: Generator control signal generation module, 55735: operation module, 55736: report generation module

55751: generator storage module, 55752: test data storage module, 55753: report storage module

55771: generator display module, 55772: test status display module

570: DTS database, 571: operational DB, 573: simulation DB

70: RTU, 71: substation, 72: power plant, 80: regional power station, 90: external system

Claims (3)

A DTS operation unit which acquires data necessary for simulation from the EMS database in connection with the data acquisition unit, relays the power supply and simulation unit participating in the training, and monitors and controls the simulation situation; A simulation unit that executes a power supply training simulation; A simulation management unit for generating scenarios and events required for simulation and managing the simulation situation by a control signal input from a training instructor; It includes; DTS database for storing the data obtained from the EMS database and the data generated during the simulation process, The data acquisition unit obtains data directly from a remote terminal device (RTU) installed in a generator or substation and stores the data in a real-time database, and acquires data from a SCADA or an external system of each regional power supply station in real time. Data linking server to store in the database, and history data management server for extracting and storing the data selected by the user periodically from the data stored in the real-time database to be used as operational data, The simulation management unit includes a real-time performance evaluation unit for evaluating the control results in the training simulation, The real-time performance evaluation unit communication module for transmitting and receiving a signal or data with the history data management server; A selection module for selecting a test generator or a performance evaluation test method among the generators connected through the history data management server, an input module for inputting a target output to be tested, and a test generator with the start of the test. A generator control signal generation module for generating an output control signal for and transmitting through the communication module, and using the current output and time data of the generator under test in response to the output control signal to calculate the increase and decrease rate of the generator under test A central control unit including a calculation module; A database unit for storing automatic power generation control-related data about the test target generator acquired from the EMS database connected through the history data management server and output control signals or data relating to the response output generated in the course of the test; And a display unit for displaying automatic power generation control-related data about the test target generator acquired from the EMS database connected through the history data management server and output control signals or data relating to the response output generated in the course of the test. In the calculation module, the absolute value of the difference between the 10% reaching time of the target output and the 90% reaching time of the target output is the absolute value of the difference between the 10% reaching time of the target output and the 90% reaching time of the target output. A power supply training simulation system, characterized by calculating the increase and decrease rate of the generator by dividing the increase and decrease rate by dividing, to evaluate the automatic power generation control transition level. The method of claim 1, The history data management server includes a first communication module for receiving information from a user through a web server, a data collection module for acquiring and transmitting data selected by the user from the real-time database, and data transmitted through the data collection module. A data operation module for storing operator data based on a calculation condition input by the user based on the data stored in a history data database, a backup module for automatically backing up data stored in the history data database according to a storage cycle, and the history data Power supply training simulation system comprising a data providing module for querying and providing data stored in the database as well as backed up data. delete

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