Fault detection and prediction with application to rotating machinery

Halligan, Gary

January 2009

Thesis (M.S.)--Missouri University of Science and Technology, 2009. / Vita. The entire thesis text is included in file. Title from title screen of thesis/dissertation PDF file (viewed November 25, 2009) Includes bibliographical references.

Plant-wide monitoring of processes under closed-loop control

Valle-Cervantes, Sergio.

January 2001

Thesis (Ph. D.)--University of Texas at Austin, 2001. / Vita. Includes bibliographical references. Available also from UMI/Dissertation Abstracts International.

Distributed intelligent system for on-line fault section estimation of large-scale power networks /

Bi, Tianshu.

January 2002

Thesis (Ph. D.)--University of Hong Kong, 2002. / Includes bibliographical references (leaves 112-126).

Distribution fault location using short-circuit fault current profile approach

Das, Swagata

09 July 2012

Popularly used impedance-based methods need voltage and current waveform as well as line impedance per unit length to estimate distance to fault location. For a non-homogenous system with different line configuration, these methods assume that the system is homogenous and use the line impedance of the most frequently occurring line configuration. Load present in the system before fault is an important parameter which affects fault location accuracy. Impedance-based methods like Takagi and positive-sequence method assume that the load is lumped beyond the fault point which may not be true for a typical distribution system. As a result, accuracy of the impedance-based methods in estimating distance to fault is affected. Another short-coming of impedance-based methods are that they are unable to identify the branch in which the fault may be located. To minimize these errors, this thesis proposes a short-circuit fault current profile approach to complement impedance-based algorithms. In the short-circuit fault current profile approach, circuit model of the distribution feeder is used to place faults at every bus and the corresponding short-circuit fault current is plotted against reactance or distance to fault. When a fault occurs in the distribution feeder, fault current recorded by relay is extrapolated on the current profile to get location estimates. Since the circuit model is directly used in building the current profile, this approach takes into account load and non-uniform line impedance. Using the estimates from short-circuit fault current profile approach and impedance-based methods, the path on which the fault is located is identified. Next to improve fault location estimates, a median value of the estimates is computed. The median is a more robust estimate since it is not affected by outliers. The strategy developed above is tested using modified IEEE 34 Node Test Feeder and validated against field data provided by utilities. For the IEEE 34 Node Test Feeder, it is observed that the median estimate computed from impedance-based methods and the short-circuit fault current profile approach is very close to the actual fault location. Error in estimation is within 0.58 miles. It was also observed that if a 0.6 mile radius is built around the median estimate, the fault will lie within that range. Now the IEEE 34 Node Test Feeder represents a typical distribution feeder and has also been modeled to represent the worst case scenario, i.e. load current is around 51% of the fault current for the farthest bus. Hence the 0.6 mile radius around the median estimate will hold true for most distribution feeders and will be used when computing the fault range for field case events. For the field events, it was seen that the actual faults indeed lie within the 0.6 mile radius built around the median estimate and the path of the fault location has also been accurately estimated. For certain events, voltage waveform was not useful for analysis. In such situations, short-circuit fault current profile alone could be used to estimate fault location. Error in estimation is within 0.1 miles, provided the circuit model closely represents the distribution feeder. / text

Fault location

Fault current

Power distribution faults

Short-circuit current

Development and analysis of current limiting technology for extending the life span of a power transformer.

Madiba, Tshimbalanga.

04 September 2012

M. Tech. Electrical Engineering. / In this work, the Current Limiter Technologies lifetime of a power transformer is developed and analysed. The general overview of the different techniques of limiting fault currents in an electric power system have been analysed, with an emphasis being placed on the research regarding two types of current limiters: one based on passive magnetic, and the other on high temperature, superconducting materials.

Dissertations, Academic -- South Africa.

Electric substations.

Electric fault location.

Plant-wide monitoring of processes under closed-loop control

Valle-Cervantes, Sergio

07 April 2011

Not available / text

Principal components analysis

Fault location (Engineering)

Automatic control

High impedance fault detection and overvoltage protection in low voltage power systems

袁綺珊, Yuen, Yee-shan, Cherry.

January 1998

published_or_final_version / Electrical and Electronic Engineering / Master / Master of Philosophy

Neural networks (Computer science)

Electric fault location.

Low voltage systems.

FAULT-TEST GENERATION FOR SEQUENTIAL CIRCUITS DESCRIBED IN AHPL

Carter, Ernest Aubert, 1942-

January 1973

No description available.

SCIRTSS (Computer program)

Digital integrated circuits -- Testing.

Electric fault location.

A programmed test sequence generation to detect and distinguish failures in a combinational circuit

Huang, George Huang-Liang, 1938-

January 1973

No description available.

Electric fault location.

Digital integrated circuits -- Testing.

Logic circuits -- Testing.

Spatial analysis of thermal aging of overhead power transmission lines

Bhuiyan, Md. Mafijul Islam

Unknown Date

No description available.

Powerline ampacity

Spatial analysis (Statistics)