KR20020035328A - diagnosis system of AVR control equipment - Google Patents

Abstract

PURPOSE: A diagnostic system for an AVR control equipment is provided to perform an on-line diagnosis which stabilizes, maintains, and repairs power generating equipment at low costs. CONSTITUTION: An auto-voltage regulator(3) regulates an alternating voltage generated by a power generator(1) to a constant voltage. An exciter(4) outputs an exciting current and voltage according to a voltage from the auto-voltage regulator(3). A signal processor(5) converts terminal and field voltages from the power generator(1) and real values with respect to effective and reactive powers into voltage/current data of a diagnostic range suitable for a predetermined signal system. A data acquisition section acquires diagnostic data processed by the signal processor(5). A PC assembly(6) stores a virtual mathematical model corresponding to various forms of the exciter(4) and the auto-voltage regulator(3). The PC assembly(6) compares and analyzes the diagnostic data from the acquisition section with a really measured model response by a predetermined diagnostic algorithm and displays it a user.

Description

Diagnosis system of AVR control equipment

The present invention relates to a diagnostic apparatus for AV control equipment, and more particularly, to a diagnostic apparatus for AV control equipment that enables maintenance of the AVR exciter voltage control equipment at an appropriate time.

In general, with the rapid economic growth and the expansion of the use of electric energy, power generation facilities are increasing the demand for technology development on performance evaluation of the power plant and maintenance of diagnostic safety.

Although the lifespan of such power generation equipment is typically 25 to 30 years, the AVR exciter voltage control equipment, which is one of the control measurement equipments, is only about 10 years. There is a difficulty in maintenance, which causes a breakdown of the generator and a performance degradation. And, due to the nature of the power plant can not start / stop frequently, the situation is expensive equipment of hundreds to tens of thousands of won for diagnosis.

In order to solve this problem, the following equipments have been developed. In particular, in recent years, domestic research and development of power plant technology has begun, and the characteristics test and modeling technology of power generation system, localization of generator voltage regulator and voltage supply control system technology, boiler turbine control system technology, etc. It is running or in progress.

For example, research and decision of generator control system modeling for power system stability analysis (1993 ~ 1996; characteristic test and precision modeling technology of generator / control system related to stability analysis of power system), and development and commercialization of automatic voltage regulator for power plant (1991 ~ 1996). 1994; Development of design and production technology of generator AVR, commercial operation at Yeosu thermal power plant), development of digital EXCITER for generators (1994 ~ 1997; development of digital excitation system for thermal power generator, practical installation and testing of Yeosu thermal power plant # 1) Development of diagnostic technology for control equipment (1997 ~ 198; System design for investigation of control system and failure history of domestic generator and performance diagnosis of AVR excitation system and B / T control system), and generator control equipment stabilization device (PSS) ) Development research (1998 ~ 2001; PSS design development and field installation verification test using excitation system).

However, since such equipments must be diagnosed as off-line for the replacement of accessories and maintenance of the control equipment due to the aging of the equipment, there is a danger of emergency stop of the generator, and therefore, frequent start / stop due to the characteristics of the power plant. There is a problem that requires expensive equipment of hundreds to tens of thousands of won for diagnosis.

The present invention has been made to solve the above problems, by integrating a system that performs the functions of measurement, diagnosis, monitoring, etc. without stopping the power plant in one equipment to maintain the power plant as well as stabilization at the lowest cost The aim is to provide a diagnostic system for AV control equipment that enables on-line diagnostics.

1 is a configuration diagram showing a diagnostic system for AV control equipment according to the present invention,

2 is a module circuit diagram showing in detail a signal processor according to the present invention.

Explanation of symbols on the main parts of the drawing

One ; Generator 3; AVR

4 ; Excitation 5; Signal processor

6; PC Assembly

The object is, according to the present invention, in the diagnostic system for AV control equipment for having a generator and for diagnosing the performance change of the AV exciter, which is connected to the generator online, whereby the terminal voltage and the field voltage and A signal processing unit for processing to convert actual values of active power and reactive power into voltage / current data of a diagnostic range suitable for a predetermined signal system, a data acquisition unit for acquiring diagnostic data processed by the signal processing unit, and After storing virtual mathematical models corresponding to various types of exciter and AVR, the model response during actual measurement and the diagnostic data of the data acquisition unit are compared and analyzed with a predetermined diagnostic algorithm (or GUI program) and displayed to the user. A diagnostic system for AV control equipment comprising a PC assembly is achieved.

Here, the signal processing unit preferably includes an interface provided with various resistors, capacitors, and diodes, and a core separation current transformer for impedance matching with the generator.

Hereinafter, with reference to the accompanying drawings will be described in detail the diagnostic system for AV control system according to the present invention. 1 is a configuration diagram showing a diagnostic system for AV control equipment according to the present invention, Figure 2 is a module circuit diagram showing in detail the signal processing unit according to the present invention.

As shown in FIG. 1, the diagnostic system for AV control equipment includes an generator 1 and an AVR (Auto-voltage regulator) that draws out an AC voltage generated from the generator 1 and automatically adjusts to a constant voltage. 3) and an exciter 4 which outputs an excitation current and an excitation voltage according to the voltage output from the AVR 3, and the terminal voltage / current and field voltage / current, load angle, active power and ineffectiveness from the generator 1; Signal processing unit (5) for processing to convert the actual values for power and frequency, that is, from several millivolts / amps to thousands of volts / amps, into voltage / current data in a diagnostic range suitable for a given signaling system. And a data acquisition unit for acquiring voltage / current data from the signal processing unit 5, and the diagnostic data of the data acquisition unit is a predetermined diagnostic algorithm (or GUI program). It has a PC assembly (6) for analyzing the display to the user. In this case, the data acquisition unit has an A / D converter, a D / A converter, and digital I / O to convert the analog signal of the signal processor into a digital signal that can be used by a PC.

Here, the signal processing unit 5 is as shown in Figure 2, is designed so as not to affect the measurement object during the measurement, and converts the actual large voltage into a signal suitable for reading in the PC internal card only the signal It is delivered without loss, a plurality of comparison units for calculating the actual value of the terminal voltage, field voltage, active power and reactive power, that is, a variety of grades ranging from a few millivolts / amps to thousands of volts / amps, It has a processing module that supports these operation algorithms and temporarily stores the change data, and an interface equipped with various resistors, capacitors and diodes for connecting and impedance matching the processing module and the comparison unit. Interface that does not affect the measurement target even when connected) (not shown) and cores Lee-type current transformer (sensor) (not shown) is provided. In addition, the signal processor 5 is designed to have an internal impedance of several MΩ or more in order to solve a problem that may occur when the generator and the exciter are connected.

The PC assembly 6 stores virtual mathematical models corresponding to various types of the exciter 4 and the AVR 3, and then diagnoses the result by comparing the model response with the actual diagnostic response. At this time, the types of AVR can be largely divided into DC excitation method, AC excitation method and stationary excitation method. SCRX and the like.

The operation of the diagnostic system as described above is first assumed to be diagnosed in a state where the starting of the power generation system is stopped. That is, when the signal processing unit 5 outputs diagnostic data corresponding to the output value generated from the generator, the data acquisition unit digitally acquires the diagnostic data. At this time, the PC assembly 6 expresses and displays the diagnostic data as a trend screen in the form of a graph, and analyzes it with a predetermined diagnostic algorithm (or GUI program) and displays it to the user. Here, all the work is performed in real time, the acquired diagnostic data is changed and stored in the form of a specific text file, and is actively compatible with the analysis program owned by the user.

As described above, when displayed through the PC assembly 6, the user can determine the performance degradation and the probability of failure using the analysis program or the displayed screen.

In particular, the diagnostic system reflects user-defined signal components to enable active measurement / analysis rather than passive measurement / analysis. The diagnostic algorithms include waveform diagnosis, harmonic diagnosis, AVR adjustment value diagnosis and overexcitation and underexcitation function diagnosis. For this purpose, various types of virtual mathematical models of the exciter and the AVR are stored in advance and judged using them.

In other words, it shows voltage, current, frequency, active power, reactive power, etc. as a waveform as well as direct figures, and the shape of this waveform is more distorted than the virtual model for standard sine wave and direct current. In particular, since each signal can be superimposed in the same time zone, it can be compared and analyzed by waveform diagnosis.

In addition, the harmonic diagnosis is used to determine how much harmonics included in the above waveforms are included in each harmonic order to determine whether there is an abnormality in the power generation facility. Although it is not clearly stated, experimentally, the total harmonics are based on within a few percent of the fundamental waves, and are automatically calculated and output when the harmonics diagnostic item is selected, and becomes the data of the user's diagnosis.

In addition, AVR tuning value diagnosis applies a step signal of about 5% (up to ± 10%) of the rated voltage when the load is not connected to the response characteristics (response response and vibration characteristics). The model response characteristic is used to diagnose and judge whether the AVR is optimally set up and running, and another method is to observe the frequency response in a system with a frequency generator. Measure again and analyze board diagram to diagnose.

In addition, the over-excitation and under-excitation function diagnosis requires the application of corresponding active power and reactive power conditions, which are diagnosed by analyzing signals whose terminal voltage and current are varied in magnitude and phase.

The present invention can be tested by minimizing the influence on the measurement object by considering the impedance to several MΩ or more so that it can be utilized even in a place that is sensitive to synchronization problems or external interference between the respective equipments, In consideration of the characteristics, data acquisition and analysis is possible during operation, and it solves the phase delay and conversion ratio, which are essential when applying parts such as core-type current transformers, and by simply diagnosing and maintaining the AVR control equipment. It has the effect of improving the reliability of power supply, strengthening power equipment maintenance function, improving the power reserve ratio and improving the electric quality.

Claims (2)

A diagnostic system for an AV control system having a generator, for diagnosing a performance change of an AV exciter; A signal processing unit which is connected to the generator online and processes therefrom to convert the actual values of the terminal voltage, the field voltage, the active power and the reactive power into voltage / current data of a diagnostic range suitable for a predetermined signal system; A data acquisition unit for acquiring the diagnostic data processed by the signal processing unit; After storing the virtual mathematical model corresponding to the various types of exciter and AVR, the model response during actual measurement and the diagnostic data of the data acquisition unit are compared and analyzed with a predetermined diagnostic algorithm (or GUI program), and then the user is compared to the user. Diagnosis system for AV control device comprising a PC assembly for displaying. The method of claim 1; The signal processing unit diagnosis system for AV-AL control equipment, characterized in that the current transformer of the core separation type and the interface provided with various resistors, capacitors and diodes for impedance matching with the generator.