KR100964296B1 - A data acquisition and supervisory control system - Google Patents

Abstract

PURPOSE: A data acquisition and monitoring control system is provided to improve user convenience by freely using data through an internet without installing a separate program. CONSTITUTION: A data acquisition part(110) acquires power system data from the facilities of an electric power system. The data acquisition part comprises a data acquisition server and a history data management server. The data acquisition server acquires data from the remote terminal device of a generating station or an electric power substation. The history data management server extracts data selected by a user from a real time database. An electric power system monitoring part(130) indicates an operation state of the electric power system. A remote control part(150) transmits a control signal about the facilities of the electric power system based on the operation state of the electric power system.

Description

Data Acquisition and Supervisory Control System for Power System

The present invention relates to a data acquisition and monitoring control system for acquiring and managing data on various equipments connected to a power system in an energy management system, and performing supervisory control on power system operation using the same. In addition to the data acquisition server directly connected to the facilities of the system, the data linkage server can remove the inefficiency of data acquisition by linking the data already acquired from the SCADA of each regional power supply station. It can send and receive various data with external system, collect power system monitoring and control information from EMS through history data management server and store it for a long time, and also provide and use necessary information from outside. Operator and user can use freely anytime and anywhere through web without installing any program It is possible to increase user convenience by enabling the system, and to filter, group, set priority of alarm data to improve efficiency of power system operation monitoring, and if alarm data is not generated as needed, The present invention relates to a data acquisition and supervisory control system that can maximize the efficiency of power system operation monitoring by eliminating and delaying occurrence.

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 occurred in North America and Europe in 2003 as a result of spreading to all power systems because they could not detect and respond to early small accidents quickly due to the weakness of data acquisition and monitoring control system. As a result, the importance of obtaining data on the overall operating status and remote monitoring and control system for the power system in the energy management system is highlighted.

Conventional data acquisition and supervisory control systems lacked data collection or data linkage for a wide range of power systems. In particular, data linkage in the data collection system for a small regional power supply station is weak, as well as an energy management system. There is not enough system to systematically collect and manage the information of external systems.

In addition, in the case of an alarm provided for monitoring the operating state of a conventional power system, it is merely to recognize when a change in the operating state occurs, and thus an operating state continuously and repeatedly generated by a simple contact failure. Alarm signal is generated indiscriminately even in the operation state change caused by the change or the user's control signal, which causes the reliability of alarm signal and distracts the operator's attention. There is a disadvantage that cannot be prevented.

In addition, there is no system for evaluating whether the automatic power generation control performed by the remote monitoring control in real time.

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

The purpose of the present invention is 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 linking server already acquired from the SCADA (SCADA) of each regional power station Data acquisition and monitoring control to obtain and provide a variety of data for efficient energy management by enabling the transmission and reception of various data to the weather server (WIS) of the Korea Electric Power Exchange. To provide a system.

Another object of the present invention is to collect the power system monitoring, control information, etc. in the EMS through the history data management server to be stored in the long-term and also to provide information required from the outside to be used as the energy management system (EMS) operating data In addition, it is possible to provide a data acquisition and surveillance control system that can increase the user's convenience by allowing the system operator and user to use freely anytime and anywhere through the web without installing a separate program.

Another object of the present invention is not only to generate and display alarm data according to the change in the operation state of the power system uniformly, but also to filter, group, and set the priority of the alarm data so as to increase the efficiency of power system operation monitoring. If the alarm data does not need to be generated as needed, the alarm data can be removed and delayed so that the operator who monitors the operation status of the power system can select the required alarm data from the generated alarm data. It is to provide data acquisition and supervisory control system that can maximize the efficiency of power system operation monitoring by responding quickly.

Another object of the present invention is to prevent damage to the reliability of the alarm signal or distracting operator's attention that occurs when the alarm is generated indiscriminately until a change in the system operating state changed by the control by the user. It is to provide data acquisition and supervisory control system to prevent alarms from changing the power system operation status by control.

Another object of the present invention is to evaluate the implementation level of the automatic power generation control for the generator as well as the monitoring control of the power system, and in particular, to accurately measure and analyze the characteristics of the increase and decrease rate of the generator which is the basis of the automatic power generation control, It is to provide a data acquisition and surveillance control system that can ensure the accuracy and promptness of performance evaluation by excluding intervention as much as possible.

Power system data acquisition and monitoring control system for achieving the above object of the present invention includes the following configuration.

Data acquisition and monitoring control system of the power system according to an embodiment of the present invention is a data acquisition unit for acquiring and storing the power system data from the facilities of the power system; A power system monitoring unit displaying an operating state of the power system based on the data acquired and stored by the data acquisition unit and generating an alarm when the state changes; It includes a remote control unit for transmitting a control signal for the equipment of the power system based on the power system operating state displayed in the power system monitoring unit, wherein the data acquisition unit from a remote terminal device (RTU) installed in the generator or substation Data acquisition server that directly acquires data and stores it in real-time database, data linking server that connects and acquires data from SCADA or external system of each regional power station and stores it in real-time database, among the data stored in the real-time database It includes a history data management server for periodically extracting and storing the data selected by the user to be used as the energy management system (EMS) operating data, the history data management server is a web module for receiving information from the user, and the real-time Data collection to acquire and transmit the data selected by the user from the database A module, a data calculation module for storing data transmitted through the data collection module in a history data database, and generating operator fees according to a calculation condition input by the user, and storing the data stored in the history data database. According to the present invention, a backup module for automatically backing up and a data providing module for inquiring and providing data backed up as well as data stored in the history data database may be included.

According to another embodiment of the present invention, in the data acquisition and monitoring and control system according to the present invention, the power system monitoring unit generates an alarm when the power system operating state changes based on data acquired and stored in the data acquisition unit. The alarm server includes an alarm filtering module that can filter alarms by category, facility type, and region, an alarm limit module that prohibits alarm generation for a specific facility, and is continuously generated by a defective contact or a relay malfunction. Alarm delay module that sets delay time for alarm to prevent alarm within delay time, Alarm grouping module to check and manage alarms caused by the same accident collectively, and Alarm priority It is characterized by including a priority designation module to specify and display by priority The.

According to still another embodiment of the present invention, in the data acquisition and monitoring control system according to the present invention, the remote control unit transmits a control command input from a user to the facilities of the power system and receives a control command response. The control server module includes a control timer module for setting a response time for a control command transmitted, and an alarm signal to be treated as an alarm in the alarm server when the control command response is not received within the response time. A control failure transmission module for transmitting a control failure transmission module for transmitting a control success signal to prevent an alarm from occurring in the power system operating state variation due to control when a control command response is received within a response time; It is characterized by.

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

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, it is possible to transmit and receive various data to the weather server (WIS) of the Korea Electric Power Exchange as an example of other external systems, and has the effect of acquiring and providing various data for efficient energy management.

The present invention collects the power system monitoring, control information, etc. in the EMS through the history data management server to be stored for a long time and also to provide information required from the outside to be used as the energy management system (EMS) operating data Of course, system administrators and users can increase the user's convenience by allowing them to use freely anytime and anywhere through the web without installing a separate program.

The present invention not only generates and displays alarm data according to changes in the operation status of the power system uniformly, but also filters, groupings, and sets priorities for alarm data to increase the efficiency of power system operation monitoring. When the data does not need to be generated, alarm data can be eliminated and delayed so that the operator who monitors the operation status of the power system can select necessary alarm data from countless generated alarm data and respond appropriately. It has the effect of maximizing the efficiency of power monitoring.

The present invention is to control to prevent damage to the reliability of the alarm signal that occurs when the alarm occurs indiscriminately until a change in the system operating state changed by the control by the user or distracting the operator's attention The change of the power system operating state caused by this has the effect that an alarm does not occur.

The present invention can evaluate the implementation level of the automatic power generation control for the generator as well as the supervisory control of the power system, and in particular, accurately measure and analyze the characteristic value of the increase / decrease rate of the generator which is the basis of the automatic power generation control and exclude human intervention as much as possible. This has the effect of ensuring the accuracy and promptness of the performance evaluation.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the data acquisition and monitoring control system of the power system according to the present invention will be described in detail.

1 is a block diagram showing a configuration of a data acquisition and monitoring control system of a power system according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating a redundant structure of data communication in a data acquisition server or a data connection server. 3 is a block diagram showing the detailed configuration of the history data management server of the data acquisition unit, Figure 4 is a block diagram showing the detailed configuration of the power system monitoring unit, Figure 5 is a detailed configuration of the remote control unit 6 is a block diagram showing the detailed configuration of the real-time execution evaluation unit of the remote control unit.

1 to 6, the data acquisition and monitoring control system 10 of the power system according to an embodiment of the present invention is a data acquisition unit 110 for acquiring and managing the power system data from the facilities of the power system ; A power system monitoring unit 130 displaying a power system operating state based on the data acquired and stored by the data acquisition unit 110 and generating an alarm when the state changes; Remote control unit 150 for transmitting a control signal for the facilities of the power system based on the power system operating state displayed on the power system monitoring unit 130;

The data acquisition unit 110 configures a power system to perform functions such as rapid and accurate monitoring and control of the power system on the energy management system (EMS) and optimized automatic power generation control through the data management unit. Various power system facilities, that is, the information about the state of the generator, substation, breaker, and so on, that is, the configuration to enable the acquisition and storage management of the power system data, in particular the data acquisition unit 110 is installed remotely in the generator or substation A data acquisition server 111 that directly acquires data from a terminal (RTU: Remote Terminal Unit, 50) and stores it in a real-time database (310), and SCADA (Supervisory Control and Data Acquisition System, 70) And a data linkage server 113 for acquiring and linking data from an external system 90 and storing the data in the real-time database 310 and storing the data in the real-time database 310. It may include a history data management server 115 for periodically extracting and storing the data selected by the user from the collected data to be used as the energy management system (EMS) operating data. The standard protocol used for data acquisition in the data acquisition unit 110 may be used DNP 3.0, ICCP (ICCP) and the like. Before briefly explaining the detailed configuration of the data acquisition unit 110, a brief look at the structure of the EMS database 30, the EMS database 30 is largely for each generator for real-time monitoring and control of the power system B) Real-time database 310 for storing real-time data indicating the current state of the power system, such as remote measurement devices (RTU) of substations (RTU) 50 or remote measurement values transmitted from each power management station (RCC); Program database 330 for supporting power system equipment modeling and power system connection relationship modeling to support generator and generator control operation programs, and all data related to power system monitoring and control collected and transmitted from EMS. After that, it includes a history data database 350 provided on request.

The data acquisition server 111 is connected to a remote terminal device (RTU) 50 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, requests and receives various status information from the remote terminal device (RTU, 50) installed in the generator or substation and transmits them to the host server or real-time database 310 of the EMS. And, the data communication between the remote terminal device (RTU, 50) and the data acquisition server 111 and the host server or real-time database 310 of the EMS as shown in Figure 2 to improve the communication reliability It is preferable that not only the data acquisition device but also the network or communication line be 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 a remote terminal device (RTU) 50 periodically according to a period set by a user, and the power of the remote terminal device (RTU, 50). When a change occurs in the system data, all of the methods of transmitting it to the data acquisition server 111 may be utilized.

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) 70 or an external system 90 of each regional power supply station, and the data linking server 113. Receives signals such as data requests and control commands from the host server of the EMS, requests and receives various status information from the SCADA (70) or the external system 90 of each regional power supply station. It is transmitted and stored in the database 310, the data communication between the SCADA (70) or the external system 90 and the data connection server 113 and the host server or real-time database 310 of the EMS communication reliability As shown in FIG. 2, it is preferable that the network or communication line as well as the data acquisition device be designed in a redundant structure so as to be improved. 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 Weather information for each location is transmitted and received to the host server of EMS to assist in efficient energy management. 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 70 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 periodically extracts the data selected by the user from the data stored in the real-time database 310 (in the history data database 350) to be used as an energy management system (EMS) operating data. In this configuration, a web module 1151 for receiving information from a user, a data collection module 1152 for acquiring and transmitting data selected by the user from the real-time database 310, and the data collection module 1152. A data operation module 1153 for storing the data transmitted through the data in the history data database 350 and generating operator fees according to the operation conditions input by the user, and the data stored in the history data database 350. Backup module 1154 that automatically backs up according to the storage period, and the data stored in the history data database 350, as well as to query and provide the backed up data It may include a data providing module 1155 to enable.

The web module JAVA 1151 is configured to allow a user to access information on the history data management server 115 through a web server and input information on types, storage cycles, storage formats, etc. of collected data. The information regarding the type, storage cycle, and storage format of the data to be collected by the history data management server 115 through the web module 1151 or the storage cycle related to the backup of the information or data regarding the data calculation conditions is stored. You can enter information about the information provided on other systems or the type, period, and format of the data provided.In particular, you can freely input anytime and anywhere without installing a separate program by accessing a web server, increasing user convenience. You can do it.

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 facilitate the selection of data, information about the power system is extracted from the real-time database 310 to generate a power system schema file (* .XML), and the user is provided with a web screen through the web module 1151. Can increase the convenience. 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 1153 stores the data (* .dat) transmitted through the data collection module 1152 in a table form in the history data database 350 and based on the calculation conditions input by the user based on the data. According to the configuration for generating the operator fee, the user through the data operation module 1153, the summary data (summary data) or statistical data, etc. according to the conditions or cycles desired by the user for the data stored in the history data database 350 (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 the user 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 search and provide the data stored in the history data database 350 (data not stored in the elapsed storage period) as well as backup data. The data providing module 1155 For the user's convenience, the web module 1151 provides a table list of data (data not stored in the storage period) existing on the web screen through the web module 1151 and the table column is clicked when the table name is clicked. Information is provided as a pop-up so that the user can select the table to be searched and search the desired data, and also according to the information related to user-defined data provision (for example, system information to be provided, table information to be provided, etc.) The data stored in the history data database 350 may be provided to another system. 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 the user's PC according to the user's request.

As such, the history data management server 115 collects power system monitoring and control information from the EMS and stores it for a long time and also provides information required from the outside to be used as an energy management system (EMS) operating data. Of course, it is possible to increase the user's convenience by allowing the system operator and the user to use freely anytime and anywhere through the web without installing a separate program.

The power system monitoring unit 130 is configured to display the power system operating state based on the data acquired and stored in the data acquisition unit 110 and to generate an alarm when the state changes, the monitoring display unit 133, which is a general display device. The detailed description thereof will be omitted, and thus the dynamic description of the power system operation status is displayed on the online system diagram and the single line diagram, and the power system based on the data acquired and stored by the data acquisition unit 110. Alarm server 131 that generates an alarm when the operating state changes to enable a more thorough monitoring of the EMS power system operating state.

The alarm server 131 generates alarm data generated through the threshold value check, state change check, and validity check on the data acquired and stored by the data acquisition unit 110 (alarm data includes at least one alarm category ID). It is configured to perform the function of receiving and managing the alarm filtering module 1311 that can filter the alarm by category, facility type, region, and the alarm limit module 1312 for prohibiting the alarm generation for a specific facility, The alarm delay module 1313 sets a delay time for alarms that are continuously generated due to a defective contact or a relay malfunction so that alarms within the delay time are not displayed. An alarm grouping module 1314 and a priority designation module 1315 for assigning priorities of generated alarms to be displayed for each priority. It can be included.

The alarm filtering module 1311 is configured to filter and manage alarms by category, facility type, and region for alarm data transmitted and managed by the alarm server 131, and the alarm filtering module 1311. By using the category ID included in the alarm data is to display only the alarm data corresponding to the category required among each alarm data, or alarm data corresponding to the category that is not needed is not displayed. The alarm filtering module 1311 may filter the alarm data by using a predefined filtering method and a user-defined filtering method. The predefined filtering method may be a time when a graphic page is first created on the monitoring display unit 133 using a graphic builder. That is, the alarm filtering information is defined in advance at the design time, and the user-defined filtering method is a method of filtering a user-defined filtering group by creating a user-defined filtering group in real time.

The alarm limit module 1312 is configured to prohibit the occurrence of an alarm for a specific facility. The alarm limit module 1312 is operated for a corresponding facility due to the fact that replacement and maintenance work or a test are being performed for a particular facility. When there is no need to display a state or generate an alarm, the alarm limit module 1312 does not perform limit value check, state change check, validity check, etc. to generate alarm data for data acquired and stored for the corresponding equipment. Alarm data is generated so that an alarm can be prevented from occurring.

The alarm delay module 1313 is configured to set a delay time for an alarm that is continuously generated due to a contact failure or a relay malfunction so that an alarm within the delay time is not displayed. If flip-flop occurs continuously due to relay malfunction, alarms may be delayed for a certain period of time (time during which replacement and repair of the equipment is in progress) for the part related to the equipment. By setting the delay time, the alarm generated within the delay time is not displayed and only the log is executed so that the attention of the operator who monitors the operation status of the power system can be avoided.

The alarm grouping module 1314 is configured to collectively check and manage alarms caused by the same accident. The alarm grouping module 1314 may be required to collectively manage alarm data due to a specific accident. Through collectively collecting (grouping) the alarm data for a specific category can be displayed to collectively check or delete the grouped alarm data.

The priority designation module 1315 is configured to display the priorities of the alarms generated by specifying the priorities of the alarms, and when only the alarms are sequentially displayed, the operator monitoring the operating state of the power system. The priority designation module 1315 may be modified to prevent such cases from spreading due to inadvertent overlooking or recognizing important alarm data, resulting in a delay in response time and a missed response time. By specifying the priority for each category of the alarm data in advance through, for example, in the case of alarm data corresponding to the highest priority is displayed on the top or important alarm page of the monitoring display unit 133 so as to be immediately recognized. Even before newly generated subordinate alarm data is recognized by the operator To be removed, etc. and the top page of the important alarm monitor display unit 133, or it is possible to prevent pressed. If necessary, the priority designation module 1315 may set different colors for displaying alarm data for each priority or add sound effects.

As such, the alarm server 131 included in the power system monitoring unit 130 not only generates and displays alarm data according to a change in the operating state of the power system, but also improves the efficiency of operating monitoring of the power system. The operator who monitors the operation of the power system by filtering, grouping and setting the priority of alarm data so that it can be increased, and eliminating and delaying the occurrence of alarm data when the alarm data does not need to be generated as needed. It is possible to maximize the efficiency of power system operation monitoring by selecting necessary alarm data from the generated alarm data and responding appropriately.

The remote controller 150 is configured to control the facilities of the power system on the basis of the power system operating state displayed on the power system monitoring unit 130, the control command input from the user equipment of the power system And a control server 151 for receiving the control command response and storing the data in the EMS database 30 as well as the alarm server 131.

The control server 151 transmits a control command to the facilities of the power system and receives a control command response. The control method varies depending on the type of equipment connected to the RTU 50. For example, a method of adjusting a state value (Digital Output), and a generator, etc., may input a real target value such as an output value to adjust an output value (Analog Output). The control server 151 is configured to set a response time for a control command to be transmitted, and if the control command response is not received within the response time, the alarm is regarded as a control failure and the alarm from the alarm server 131. Control failure transmission module 1512 for transmitting an alarm signal to be processed, and if the control command response is received within the response time, the alarm server 131 is controlled so that the alarm does not occur in the power system operating state change by the control It may include a control success transmission module 1513 for transmitting a success signal.

The control timer module 1511 transmits a control command from the control server 151 and sets a response time for each control command. This is the management of the control command after the control command is transmitted. It is set to manage whether the control command is properly transmitted and responded or not received a response signal despite the transmission of the control command, and whether the control command succeeds or fails based on the response time set for each transmitted control command. It can be judged and alarmed.

The control failure transmission module 1512 is configured to transmit an alarm signal to be treated as an alarm in the alarm server 131 when a control command response is not received within a response time, so that the alarm command can be processed. After that, if the response time is exceeded until the response comes, it is immediately transmitted to the alarm server 131 as an alarm signal so that the alarm can be processed so that the operator can respond appropriately. The control command and response time which are regarded as a control failure by the control failure transmission module 1512 and processed as an alarm are deleted from the control command information.

The control success transmission module 1513 is configured to transmit a control success signal so that an alarm does not occur in the alarm server 131 when a control command response is received within a response time. If the alarm is generated indiscriminately from the alarm server 131 to the fluctuation of the system operating state, which is controlled and controlled by the user, it causes damage to the reliability of the alarm signal as well as distracting the operator's attention. The control success transmission module 1513 sends the alarm server 131 when a response is received within the response time after a control command is transmitted so that an alarm does not occur in the alarm system 131 due to a power system operating state change. By transmitting a control success signal,), the alarm does not occur for the change of the operation state.

In addition, according to another embodiment of the present invention, the control server 151 is a real-time implementation evaluation unit 153 that can evaluate in real time whether the automatic power generation control (AGC) for the generators of the power system is actually being implemented It may further include.

Referring to FIG. 6, the real-time execution evaluation unit 153 may include a communication module 1531 that may exchange signals or data with the control server 151; A selection module 15331 for selecting a generator to be tested or a performance evaluation test method among generators 52 connected to the control server 151 through a remote terminal device (RTU) 50, and a target output to be tested; An input module (15332) capable of inputting the generator, and a generator control signal generation module (15334) for generating an output control signal for the generator under test at the beginning of the test and transmitting it through the communication module (1531), and the output A central control unit 1533 including a calculation module 15335 that calculates the increase / decrease rate of the test target generator using the current output and the time data of the test target generator in response to the control signal; A database unit 1535 for storing automatic power generation control-related data about the test target generator acquired from the EMS database 30 connected to the control server 151 and output control signals or data relating to the response output generated in the course of the test; A display unit 1537 for displaying automatic power generation control-related data about the test target generator acquired from the EMS database 30 connected to the control server 151, and output control signals or data relating to the response output generated in the course of the test; It may include.

The communication module 1531 is configured to be an interface for exchanging signals or data with the control server 151, and the real-time execution evaluation unit 153 may be operated by a separate computer (PC) as necessary. Since it can transmit the output control signal of the generator 52 through the control server 151 to the generator 52 and also the data such as the current output of the generator 52 can also be fed back through the control server 151 A configuration such as the communication module 1531 that can exchange signals or data with the control server 151 is further required. As a data acquisition communication protocol applied to the communication module 1531, a communication protocol such as an intersite data (ISD) may be used.

The central control unit 1533 is configured to control the overall operation of the real-time execution evaluation unit 153, the test preparation work before starting the performance evaluation test (that is, the control server 151 through the communication module 1531). When connected to the system, the capacity, current load, and system frequency values are read and updated in real time), starting and ending the test, generating various control signals during the test, and calculating and evaluating using the test data. It is presided over. To this end, a central processing unit (CPU) or the like may be used as the central control unit 1533. The central control unit 1533 selects a generator to be tested from among the generators 52 connected to the control server 151 or conducts an evaluation test. A selection module 15331 for selecting a method, an input module 15332 for inputting a target output to be tested, and an output control signal for the generator under test at the beginning of the test to generate the communication module 1531. Generator control signal generation module (15334) transmitted through the; and a calculation module (15335) for calculating the increase and decrease rate of the generator under test using the current output and the time data of the generator under test in response to the output control signal Can be.

The selection module 15331 performs a function of selecting a generator to be tested or a performance evaluation test method in an automatic mode or a manual mode among the generators 52 connected to the control server 151 before starting the performance evaluation test. When the generator to be tested is selected among the generators 52 connected to the control server 151 through the selection module 15331, the automatic generation control-related characteristic data of the generator, that is, the facility capacity of the generator, the upper limit of the automatic generation control (LFC Limit Max), automatic generation control lower limit value (LFC Limit Min), evaporation rate and deceleration rate, the current output value, etc. from the EMS database 30 linked to the control server 151 to be described after the database unit (1535, More specifically, it is stored in the generator storage module 15351, and is displayed on the display unit 1537 (more specifically, the generator display module 15371) which will be described later. In addition, the selection module 15331 may be used to select whether to perform the performance evaluation test in the automatic mode or the manual mode, in the case of the automatic mode after the test start of 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 15332 is a part capable of inputting a target output to be tested before the performance evaluation test starts, and when the target output is input to the generator under test through the input module 15332, 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 decay test.

In addition, the central control unit 1533 further includes a start stop module 15333 for selecting start and end points of the test (if the start stop module 15333 is not included separately in the selection module 15331). Charge)), the start stop module 15333 is completed through the preparation of the test, such as the selection of the generator under test, the selection of the test method, the input of the target output through the selection module 15331 and the input module (15332) 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 15334 generates an output control signal for the generator under test at the beginning of the test and transmits the generated control signal through the communication module 1531. The performance evaluation of the real-time execution evaluation unit 153 is performed. Before the test is performed, the automatic power generation control (AGC) of the energy management system (EMS) generates and transmits a control signal for the generator, but when the performance evaluation test is started, the test is performed by the real-time performance evaluation unit 153. The generator generates and controls an output control signal, and the generator control signal generation module 15334 is responsible for this. The generator control signal generation module 15334 compares the current output of the generator under test and the target output input through the input module 15332 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, the first output control signal at the start of the test is calculated and transmitted to the current output value just before the start of the test of the generator under test. This is to enable stable output control of generator by starting from output value.

The calculation module 15335 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 15334 is transmitted to the generator under test through the control server 151, and the response output of the generator under test is also controlled. It is stored in the database unit 1535 (more specifically, the test data storage module 15352) to be fed back through the server 151 and described later, and displayed on the display unit 1537 (more specifically, the test state display module 15372). In the arithmetic module 15335, the response output and time are stored in the database unit 1535, more specifically, the test data storage module 15352. Using the emitter is increased or decreased balyul the operation of the test target generators. In this case, the formula for increasing / decreasing rate utilized by the calculation module 15335 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 153 does not simply calculate all the response outputs fed back at the start of the test by the calculation module 15335 to calculate the increase / deceleration rate, 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 15335 evaluates the performance of the automatic generator control assistance service of the generator under test based on the calculated increase / decrease rate. If 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 15335 can accurately calculate the increase / decrease rate of the generator to be tested to evaluate the implementation level so as to ensure fair power market operation.

The database unit 1535 stores data related to automatic power generation control related to the generator to be tested obtained from the EMS database 30 linked to the control server 151 and output control signals or response outputs generated in the course of the test. In such a configuration as to store a memory (RAM) or a disk storage device, the database unit 1535 stores the automatic power generation control-related data about the generator under test obtained from the EMS database 30 linked to the control server 151. Generator storage module 15351 for storing, and a test data storage module 15352 for storing data relating to the output control signal or the response output generated in the course of the test.

As described above, when the generator storage module 15351 is connected to the control server 151 through the communication module 1531, data of the supply capacity, the current load, and the system frequency related to the automatic power generation control are updated in real time. When the generator under test is selected through the selection module 15331, the automatic power generation control-related characteristic data for the generator, which is also stored in the EMS database 30 linked to the control server 151, that is, the generator The facility capacity, 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, and the like are read and stored from the EMS database 30. In particular, the generator storage module 15351 accurately records and stores the current output value of the generator under test just before the test start and provides the generator control signal generation module 15334.

As described above, the test data storage module 15352 has an output control signal and a control server 151 which are generated by the generator control signal generation module 15334 and transmitted to the generator under test through the control server 151 when the test is started. The current output of the generator under test, that is, the response output and the time data, responding to the output control signal fed back from the NF) is stored in real time. In particular, the test data storage module 15352 has a response output (MW ₁₀ ), time data (T ₁₀ ), and a response output of 90% of the target output when the generator's test output reaches 10% of the target output. The response output (MW ₉₀ ) and the time data (T ₉₀ ) at the time of reaching the level are accurately recorded and stored and provided to the calculation module 15335.

The display unit 1537 displays data related to the automatic power generation control related to the generator to be tested obtained from the EMS database 30 linked to the control server 151 and output control signals or response outputs generated in the course of the test. In the same configuration as the display device displayed on the screen, for this purpose, the display unit 1537 displays a generator for displaying automatic power generation control-related data about the test target generator acquired from the EMS database 30 linked to the control server 151. The module 15371 may include a test state display module 15372 that displays data related to output control signals or response outputs generated in the course of the test.

As described above, when the generator display module 15371 is connected to the control server 151 through the communication module 1531, data of the supply capacity, the current load, the system frequency, etc. related to the automatic power generation control is updated in real time. When the generator under test is selected through the selection module 15331, the automatic power generation control-related characteristic data for the generator, which is also stored in the EMS database 30 linked to the control server 151, that is, the generator The facility capacity, 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, and the like are read from the EMS database 30 and displayed.

As described above, the test state display module 15372 includes an output control signal and a control server 151 generated by the generator control signal generation module 15334 and transmitted to the generator under test through the control server 151 when the test is started. The current output of the generator under test in response to the output control signal fed back), i.e., the response output and the time data, is displayed in real time.

In addition, the real-time execution evaluation unit 153 further includes a report generation module 15153 in which the central control unit 1533 prepares a report on a test result, and the database unit 1535 includes the report generation module ( 15336) can additionally include a report storage module (15353) for storing the report generated, through which the results of the performance evaluation test in the form of a separate report can be prepared, stored and printed to ensure long-term preservation and evidence of the test results. It is possible to increase the usability as.

The report generation module 15153 is a part which summarizes the results of the performance evaluation test by the real-time performance evaluation unit 153 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 15153 is a part for storing a report on a test result generated through the report generation module 15153, 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 153 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 data acquisition and monitoring control system of a power system according to an embodiment of the present invention;

2 is a reference diagram showing a redundant structure of data communication in a data acquisition server or a data connection server;

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

4 is a block diagram showing the detailed configuration of the power system monitoring unit;

5 is a block diagram showing a detailed configuration of a remote control unit;

6 is a block diagram showing the detailed configuration of the real-time execution evaluation unit of the remote control unit;

* Explanation of the main symbols used in the drawings

10: data acquisition and supervisory control system

110: data acquisition unit, 130: power system monitoring unit, 150: remote control unit

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

1151: web module, 1152: data collection module, 1153: data operation module

1154: backup module, 1155: data providing module

131: alarm server, 1311: alarm filtering module, 1312: alarm limit module,

1313: alarm delay module, 1314: alarm grouping module, 1315: priority assignment module

133: monitoring display

151: control server, 1511: control timer module, 1512: control failure transmission module

1513: control success transmission module, 153: real-time performance evaluation unit

1531: communication module, 1533: central control unit, 1535: database unit, 1537: display unit

15331: Select module, 15332: Input module, 15333: Start stop module,

15334: generator control signal generation module, 15335: calculation module, 15336: report generation module

15351: generator storage module, 15352: test data storage module, 15353: report storage module

15371: generator display module, 15372: test status display module

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

50: RTU, 51: substation, 52: generator, 70: local power station, 90: external system

Claims (3)

A data acquisition unit for acquiring and storing power system data from facilities of the power system; A power system monitoring unit displaying an operating state of the power system based on the data acquired and stored by the data acquisition unit and generating an alarm when the state changes; And a remote control unit which transmits a control signal for facilities of the power system based on the power system operating state displayed in the power system monitoring unit. 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. It includes a data linking server to store in the database, and a history data management server to periodically extract and store the data selected by the user from the data stored in the real-time database to be used as the energy management system (EMS) operating data, The power system monitoring unit comprises an alarm server for generating an alarm when the power system operating state changes based on the data acquired and stored in the data acquisition unit, The alarm server includes an alarm filtering module that can filter alarms by category, facility type, and region, an alarm limit module that prohibits alarm generation for a specific facility, and alarms that are continuously generated due to contact failure or relay malfunction. Alarm delay module to set delay time so that alarms within delay time are not displayed, Alarm grouping module to check and manage alarms caused by the same accident collectively, Priority by designating priority of generated alarms Data acquisition and monitoring control system of the power system, characterized in that it comprises a priority designation module to be displayed separately. delete The method of claim 1, wherein the remote control unit It includes a control server for transmitting a control command input from the user to the facilities of the power system and receives the control command response, The control server is a control timer module for setting a response time for the control command to be transmitted, and if the control command response is not received within the response time to consider the control failure to transmit an alarm signal so that the alarm can be processed in the alarm server And a control failure transmission module for transmitting a control success signal so that an alarm does not occur in the alarm server when a control failure transmission module and a control command response are received within a response time. Data acquisition and monitoring and control system of power system.

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