An advanced level examination of the latest developments in power transformer protection This book addresses the technical challenges of transformer malfunction analysis as well as protection. One of the current research directions is the malfunction mechanism analysis due to nonlinearity of transformer core and comprehensive countermeasures on improving the performance of transformer differential protection. Here, the authors summarize their research outcomes and present a set of recent research advances in the electromagnetic transient analysis, the application on power transformer…mehr
An advanced level examination of the latest developments in power transformer protection
This book addresses the technical challenges of transformer malfunction analysis as well as protection. One of the current research directions is the malfunction mechanism analysis due to nonlinearity of transformer core and comprehensive countermeasures on improving the performance of transformer differential protection. Here, the authors summarize their research outcomes and present a set of recent research advances in the electromagnetic transient analysis, the application on power transformer protections, and present a more systematic investigation and review in this field. This research area is still progressing, especially with the fast development of Smart Grid. This book is an important addition to the literature and will enhance significant advancement in research. It is a good reference book for researchers in power transformer protection research and a good text book for graduate and undergraduate students in electrical engineering.
Chapter headings include: Transformer differential protection principle and existing problem analysis; Malfunction mechanism analysis due to nonlinearity of transformer core; Novel analysis tools on operating characteristics of Transformer differential protection; Novel magnetizing inrush identification schemes; Comprehensive countermeasures on improving the performance of transformer differential protection An advanced level examination of the latest developments in power transformer protection Presents a new and systematic view of power transformer protection, enabling readers to design new models and consider fresher design approaches Offers a set of approaches to optimize the power system from a microeconomic point of viewHinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Xiangning Lin, Professor, College of Electrical and Electronic Engineering, Huazhong University of Science and Technology, China. Prof. Lin was the first to discover the ultra-saturation phenomenon of power transformer and he designed operating characteristics analysis planes to make clear the advantages and disadvantages of existing differential protection of power transformer. He invented a variety of novel protection algorithms for the main protection of the power transformer. A series of papers were published in journals including IEEE Transactions on Power Systems and IEEE Transactions on Power Delivery. The work has been widely acknowledged and cited by international peers. He also pioneers the introduction of modern signal processing techniques to design the protection criteria for power transformer. He was the winner of the 2nd Class National Natural Science Award in 2009. He has published nearly 200 papers and books (in Chinese), he also owns over 15 patents. Jing Ma, Associate Professor, School of Electrical and Electronic Engineering, North China Electric Power University, Beijing, China. Prof. Ma was the first to apply the two-terminal network algorithm to the areas of power system protection. The work has been widely acknowledged and cited by international peers. He also proposed an approach based on grille fractal to solve the TA saturation problem, and the related paper has been published in the IEEE Transactions on Power Delivery. The research results were used in many practical engineering projects. Dr. Qing Tian, Senior Engineer with the Maintenance and Test Center of EHV Transmission Co. Ltd, Southern Power Grid, Guangzhou, China. Dr. Hanli Weng, Senior Engineer with Three-Gorge Hydropower Plant, China Yangtze Power Co., Ltd. Both have been working in this area since 1995. Their main research fields include power system operation analysis and control, voltage and reactive power optimization, power system reliability and risk assessment and power system energy saving assessment and planning.
Inhaltsangabe
1 Introduction: Transformer differential protection principle and existing problem analysis
1.1 Introduction
1.2 Fundamentals of transformer differential protection
1.3 Some problems about power transformer main protection
1.4 Analysis of Electromagnetic Transient and Adaptability of Second Harmonic Restraint Based Differential Protection of UHV Power Transformer
1.5 Study on comparisons among some waveform symmetry principle based transformer differential protection
1.6 Summary
2 Malfunction mechanism analysis due to nonlinearity of transformer core
2.1 Introduction
2.2 The ultra-saturation phenomenon of loaded transformer energization and its impacts on differential protection
2.3 Studies on the unusual maloperation of transformer differential protection during the nonlinear load switch-in
2.4 Analysis of a sort of unusual mal-operation of transformer differential protection due to removal of external fault
2.5 Analysis and countermeasure of abnormal operation behaviors of the differential protection of converter transformer
2.6 Summary
3 Novel analysis tools on operating characteristics of Transformer differential protection
3.1 Introduction
3.2 Studies on the operation behavior of differential protection during a loaded transformer energization
3.3 The Comparative investigation on current differential criteria between the one using phase current and the one using phase-phase current difference for the transformer using Y-delta connection
3.4 Comparative analysis on current percentage differential protections using a novel reliability evaluation criterion
3.5 Comparative studies on percentage differential criteria using phase current and superimposed phase current
3.6 A novel analysis methodology of differential protection operation behaviour
3.7 Summary
4 Novel magnetizing inrush identification schemes
4.1 Introduction
4.2 Studies for identification of the inrush based on improved correlation algorithm
4.3 A novel method for discrimination of internal faults and inrush currents by using waveform singularity factor
4.4 A new principle of discrimination between inrush current and internal fault current of transformer based on self-correlation function
4.5 Identifying inrush current using sinusoidal proximity factor
4.6 A wavelet transform based sheme for power transformer inrush identification
4.7 A novel adaptive scheme of discrimination between internal faults and inrush currents of transformer using mathematical Morphology
4.8 Identifying transformer inrush current based on normalized grille curve
4.9 A novel algorithm for discrimination between inrush currents and internal faults based on equivalent instantaneous leakage inductance
4.10 A two terminal network-based method for discrimination between internal faults and inrush currents
4.11 Summary
5 Comprehensive countermeasures on improving the performance of transformer differential protection
5.1 Introduction
5.2 A method to eliminate the magnetizing inrush current of energized transformers
5.3 Identification of cross-country fault of power transformer for fast unblocking of differential protection
5.4 Adaptive scheme in the transformer main protection
5.5 A Series Multi-resolution Morphological Gradient based Criterion to Identify CT Saturation
5.6 A new adaptive method to identify CT saturation using grille fractal
1 Introduction: Transformer differential protection principle and existing problem analysis
1.1 Introduction
1.2 Fundamentals of transformer differential protection
1.3 Some problems about power transformer main protection
1.4 Analysis of Electromagnetic Transient and Adaptability of Second Harmonic Restraint Based Differential Protection of UHV Power Transformer
1.5 Study on comparisons among some waveform symmetry principle based transformer differential protection
1.6 Summary
2 Malfunction mechanism analysis due to nonlinearity of transformer core
2.1 Introduction
2.2 The ultra-saturation phenomenon of loaded transformer energization and its impacts on differential protection
2.3 Studies on the unusual maloperation of transformer differential protection during the nonlinear load switch-in
2.4 Analysis of a sort of unusual mal-operation of transformer differential protection due to removal of external fault
2.5 Analysis and countermeasure of abnormal operation behaviors of the differential protection of converter transformer
2.6 Summary
3 Novel analysis tools on operating characteristics of Transformer differential protection
3.1 Introduction
3.2 Studies on the operation behavior of differential protection during a loaded transformer energization
3.3 The Comparative investigation on current differential criteria between the one using phase current and the one using phase-phase current difference for the transformer using Y-delta connection
3.4 Comparative analysis on current percentage differential protections using a novel reliability evaluation criterion
3.5 Comparative studies on percentage differential criteria using phase current and superimposed phase current
3.6 A novel analysis methodology of differential protection operation behaviour
3.7 Summary
4 Novel magnetizing inrush identification schemes
4.1 Introduction
4.2 Studies for identification of the inrush based on improved correlation algorithm
4.3 A novel method for discrimination of internal faults and inrush currents by using waveform singularity factor
4.4 A new principle of discrimination between inrush current and internal fault current of transformer based on self-correlation function
4.5 Identifying inrush current using sinusoidal proximity factor
4.6 A wavelet transform based sheme for power transformer inrush identification
4.7 A novel adaptive scheme of discrimination between internal faults and inrush currents of transformer using mathematical Morphology
4.8 Identifying transformer inrush current based on normalized grille curve
4.9 A novel algorithm for discrimination between inrush currents and internal faults based on equivalent instantaneous leakage inductance
4.10 A two terminal network-based method for discrimination between internal faults and inrush currents
4.11 Summary
5 Comprehensive countermeasures on improving the performance of transformer differential protection
5.1 Introduction
5.2 A method to eliminate the magnetizing inrush current of energized transformers
5.3 Identification of cross-country fault of power transformer for fast unblocking of differential protection
5.4 Adaptive scheme in the transformer main protection
5.5 A Series Multi-resolution Morphological Gradient based Criterion to Identify CT Saturation
5.6 A new adaptive method to identify CT saturation using grille fractal
5.7 Summary
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