use of phasors for fault location presenter: armando maldonado instructor: dr. mladen kezunovic...
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![Page 1: Use of Phasors for Fault Location Presenter: Armando Maldonado Instructor: Dr. Mladen Kezunovic Ph.D. Course: ECEN 679 Computer Relays](https://reader036.vdocument.in/reader036/viewer/2022082506/5697bfc81a28abf838ca8866/html5/thumbnails/1.jpg)
Use of Phasors for Fault Location
Presenter: Armando Maldonado
Instructor: Dr. Mladen Kezunovic Ph.D.
Course: ECEN 679 Computer Relays
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Single Ended ProtectionRelay Protection, voltage and current inputs at one end of transmission line.
• Fault type must be determined prior to fault location algorithm
• Algorithm calculates inductance from relay location to fault
• Fault Impedance = errors
• Load flow = errors
• Zero Sequence mutual coupling = errors
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Single Ended ProtectionReduce the effect of fault resistance and load flow to combat errors.
• Voltage/Current phasors computed by Discrete Fourier Transforms
• Separate into real and imaginary components
• Multiply equations with
• Subtract real from imaginary equations and solve for “n”
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Single Ended ProtectionVoltage and current phasors determined by fault type to properly solve for “n”
• AG Faults
• LL Faults
ZR1 = positive sequence impedance of the transmission line
ZR0 = zero sequence impedance of the transmission line
K0 = ratio of zero sequence impedance to positive sequence impedance of the line.
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Two Ended ProtectionData needed for calculation of fault location
• Voltages
• Currents
• Time Stamps = Communication to central location for analysis
Method for location based on negative-sequence voltage profile along transmission line
k = line section
L or R = left or right junction
X or Y = terminal
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Two Ended Protection Negative Sequence Voltage Magnitudes
• Voltage magnitudes indicate faulted line section
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Two Ended Protection Algorithm estimates the distance to the fault on the homogenous line section.
• Use the equivalent negative sequence voltages and
• Voltage magnitudes at the fault location calculated form the two junctions should equal
• Algorithm solves “m” = distance to the fault
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Comparisons Single Ended Fault LocationPros
• Only needs access to 1 terminal’s voltage and current values
• No communication to other terminals
Cons
• Nonhomogeneous systems
• Subject to errors from load flow mutual coupling
• Fault location approximation accuracy
Two Ended Fault LocationPros
• Algorithm not affected by fault resistance, load or zero sequence mutual coupling.
• Accurate fault locations
• Nonhomogeneous systems
Cons
• Communication to other terminals
• Needs accurate time stamps
• Data at both ends gathered at one location for analysis
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References• J.M. Kennedy, General Electric, “Evaluation of a Phasor-Based Fault Location
Algorithm,”GE Protection and Controls, GER-3963.
• Yanfeng Gong, Mangapathirao Mynam, Armando Guzmin and Gabriel Benmouyal, Schweitzer Engineering Laboratories, “Automated Fault Location System for Nonhomogeneous Transmission Networks,” Boris Schulim, Orange and Rockland Utilities, 2012.
• Abdolhamid Rahideh, Mohsen Gitizadeh, Sirus Mohammadi, “A Fault Location Technique for Transmission Lines Using Phasor Measurements,” International Journal of Engineering and Advance Technology (IJEAT), ISSN: 2249-8958, Volume-2,Issue-1, October 2013
• IEEE Guide for Determining Fault Location on AC Transmission and Distribution Lines, IEEE Standard C37.114, 2004.
• S.M. Brahma, “New Fault Location Method for a Single Multi-Terminal Transmission Line Using Synchronized Phasor Measurements,” IEEE Trans. Power Delivery, Vol. 21-3, pp. 1148-1153, July 2006.
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Thank you
Questions?