Design of Transient Protection Systems
Including Supercapacitor Based Design Approaches for Surge Protectors
- 1st Edition - December 7, 2018
- Latest edition
- Authors: Nihal Kularatna, Alistair Steyn Ross, Jayathu Fernando, Sisira James
- Language: English
Design of Transient Protection Systems: Including Supercapacitor Based Design Approaches for Surge Protectors is the only reference to consider surge protection for end-user… Read more
Design of Transient Protection Systems: Including Supercapacitor Based Design Approaches for Surge Protectors is the only reference to consider surge protection for end-user equipment. This book fills the gap between academia and industry, presenting new product development approaches, such as the supercapacitor assisted surge absorber (SCASA) technique. It discusses protecting gear for modern electronic systems and consumer electronics, while also addressing the chain of design, development, implementation, recent theory and practice of developing transient surge protection systems. In addition, it considers all relevant technical aspects of testing commercial surge protectors, advances in surge protection products, components, and the abilities of commercial supercapacitors.
- Provides unique, patented techniques for transient protectors based on supercapacitors
- Includes recent advances in surge protection
- Links scattered information from within academia and industry with new product development approaches on surge protection for end-user equipment
Electrical and Electronic engineers, industry engineers, product designers, researchers working in power quality, and technicians in test and transient surge protection systems
Chapter 1: Power Quality in an End User Perspective
1.1 Introduction
1.2 Power line disturbances
1.3 Power quality issues
Chapter 2: Surge protection essentials
2.1 Levels of surge protection
2.2 Surge protection standards and practices
2.3 Circuit concepts used in surge protection
Chapter 3: Components used in surge protection circuits
3.1 Metal oxide varistors
3.2 TVS diodes and thyristors
3.3 Gas discharge tubes
Chapter 4: Designing of surge protection systems
4.1 Understanding transient equations and their solution
4.2 Surge absorbent device characterisation
4.3 Surge propagation in linear systems
4.4 Surge propagation through a TVSS system
Chapter 5: Applications of surge protection systems
5.1 SPDs for the service entrance
5.2 SPDs for point-of-use protection
Chapter 6: Supercapacitor based circuits for transient absorption
6.1 Supercapacitors and their ability to absorb transient surges
6.2 Extending the simple RC circuit theory – to resistor-supercapacitor circuits
6.3 Abilities of commercial supercapacitors to absorb transient surges
6.4 Supercapacitor assisted surge absorber (SCASA) technique
Chapter 7: Test gear for transient testing
7.1 Lightning surge simulators (LSS)
7.2 Internal circuit blocks of a LSS
7.3 Test techniques using LSS
1.1 Introduction
1.2 Power line disturbances
1.3 Power quality issues
Chapter 2: Surge protection essentials
2.1 Levels of surge protection
2.2 Surge protection standards and practices
2.3 Circuit concepts used in surge protection
Chapter 3: Components used in surge protection circuits
3.1 Metal oxide varistors
3.2 TVS diodes and thyristors
3.3 Gas discharge tubes
Chapter 4: Designing of surge protection systems
4.1 Understanding transient equations and their solution
4.2 Surge absorbent device characterisation
4.3 Surge propagation in linear systems
4.4 Surge propagation through a TVSS system
Chapter 5: Applications of surge protection systems
5.1 SPDs for the service entrance
5.2 SPDs for point-of-use protection
Chapter 6: Supercapacitor based circuits for transient absorption
6.1 Supercapacitors and their ability to absorb transient surges
6.2 Extending the simple RC circuit theory – to resistor-supercapacitor circuits
6.3 Abilities of commercial supercapacitors to absorb transient surges
6.4 Supercapacitor assisted surge absorber (SCASA) technique
Chapter 7: Test gear for transient testing
7.1 Lightning surge simulators (LSS)
7.2 Internal circuit blocks of a LSS
7.3 Test techniques using LSS
- Edition: 1
- Latest edition
- Published: December 7, 2018
- Language: English
NK
Nihal Kularatna
Nihal Kularatna is an Associate Professor in the School of Engineering at the University of Waikato, New Zealand. He won the New Zealand Innovator of the Year Award (2013). His electronic engineering career spans 45 years and he is currently active in research in supercapacitor applications, power converter topologies, and power conditioning. He has contributed to over 160 papers and authored nine books. Multiple patents were granted for his supercapacitor assisted (SCA) circuit topologies. Before migrating to New Zealand in 2002, he was the CEO of the Arthur C Clarke Institute in Sri Lanka.
Affiliations and expertise
Associate Professor in Electronic Engineering, The University of Waikato, New ZealandAR
Alistair Steyn Ross
His 100 research contributions include papers in satellite remote sensing physics, computational neurodynamics, general anesthesia, EEG signal processing, supercapacitor applications, surge suppression, and rechargeable battery modeling. With Moira Steyn-Ross, he edited the 2010 Springer volume "Modeling Phase Transitions in the Brain." He has been an active researcher for 30 years, with particular interest in the physics and mathematics of nonlinear threshold phenomena.
Affiliations and expertise
Computational Physicist and Associate Professor, School of Engineering, University of Waikato, New ZealandJF
Jayathu Fernando
He has served Arthur C Clarke Institute for Modern Technologies for 10 years in different capacities, and he is a contributor to several patents on supercapacitor assisted techniques such as supercapacitor assisted low dropout regulator (SCALDO) and supercapacitor assisted surge absorber (SCASA).
He is currently a PhD student at University of Waikato, working on the implementation aspects of SCASA technique, which is currently licenced to an Australian power quality products company. Jayathu Fernando holds BSc and MSc degrees from University of Colombo, and University of Moratuwa, respectively.
Affiliations and expertise
BSc and MSc degrees from University of Colombo and University of Moratuwa, respectivelySJ
Sisira James
He holds BE, MSc and PhD degrees from Bangalore University, University of Aberdeen, and University of Waikato, respectively. His PhD thesis was on Surge Propagation studies under the supervision of the first two authors of this work, and his MSc thesis was on Computer Simulation of DC-DC Switching Converter Systems. He has developed mathematical models for nonlinear surge protection devices and employed MATLAB-based numerical simulations to predict the incipient failure of electronics in transient voltage suppressor systems (TVSSs). He has also validated the numerical simulations experimentally using a lightning surge simulator. Sisira James has served Sri Lanka Telecom PLC as a senior telecommunications professional for more than 11 years.
Affiliations and expertise
BE, MSc and PhD degrees from Bangalore University, University of Aberdeen and University of Waikato respectively.Read Design of Transient Protection Systems on ScienceDirect