This lecture provides the generation, diagnostics, and applications of high power electrical pulses. A wide range of pulsed power technology will be discussed, including fundamental as well as advanced concept. Topics covered are high-voltage generators, energy storage devices and circuits, high power switches, pulse forming networks, pulse forming lines, magnetic pulse compression circuits, and the electromagnetic and optical diagnostics of pulsed power systems. Applications of pulsed power technology for lasers, non-thermal plasma, and environmental and medical applications will be discussed. Students are required to simulate typical pulsed power circuits and gas breakdown.
The students will comprehensively understand pulsed power technologies, which have been widely used in industry, through the generation, diagnostics, and applications of high power electrical pulses.
Upon completion of this lecture students should be able to design pulsed power circuits including high-power switches, pulse forming networks/lines with discharge loads, using LTSpice circuit simulator or MATLAB software to solve various pulsed power circuits and gas breakdown. They should also be able to choose appropriate methods of measuring, grounding and shielding techniques for pulsed large currents and high voltages, and understand the applications of pulsed power technology.
Pulsed power, high voltage, large current, breakdown phenomena
|Intercultural skills||Communication skills||✔ Specialist skills||✔ Critical thinking skills||✔ Practical and/or problem-solving skills|
Lessons contain not only a lecture but also tactical exercises and oral presentations.
|Course schedule||Required learning|
|Class 1||Basic concept and applications of pulsed power systems, fundamental knowledge of electromagnetic theory, simulation tool (LTSpice), and project guidance||Understand the basic concept and applications of pulsed power systems.|
|Class 2||Capacitive energy storage and LCR circuit||Understand capacitive energy storage and explain the behavior of an LCR circuit.|
|Class 3||Inductive energy storage and opening switch||Understand inductive energy storage and explain the behavior of circuits with opening switches.|
|Class 4||Charge transfer circuit: CLC and high voltage capacitors||Explain the behavior of a charge transfer circuit with high voltage capacitors.|
|Class 5||Circuit components for pulsed power circuit||Explain circuit components for pulsed power circuits.|
|Class 6||High voltage DC generator, pulsed generator: Marx circuit||Understand the operating principles of high voltage DC generators and pulsed generators.|
|Class 7||High voltage and fast switches and their modeling||Understand the characteristics of high voltage and fast switches and the method for modeling.|
|Class 8||Midterm evaluation||Pulsed power circuit analysis with LTspice.|
|Class 9||Gas, liquid and solid breakdown||Explain gas, liquid and solid breakdown phenomena.|
|Class 10||Rate equation, simulation tool (Matlab), Gas discharge characteristics and modeling||Understand the characteristics of gas discharges and the method for modeling using rate equations.|
|Class 11||Pulse forming network||Explain the behavior of a pulse forming network.|
|Class 12||Pulse forming line||Explain the behavior of a pulse forming line.|
|Class 13||Magnetic pulse compression circuit||Explain the behavior of a magnetic pulse compression circuit.|
|Class 14||Pulsed high voltage and pulsed large current diagnostics, grounding and shielding techniques||Explain diagnostics of pulsed high voltage and pulsed large current and techniques of grounding and shielding.|
|Class 15||Pulsed power applications||Examples of industrial pulsed power applications.|
None are required. Lectures will be made up of power point presentations and notes written on the board.
Pulsed Power Systems, Bluhm, Hansjoachim, Springer-Verlag GmbH,
Transient electronics -Pulsed Circuit Technology, Paul W. Smith, Wiley
Transient circuit and operation analyses of Pulsed power circuit using LTspice or MATLAB: Midterm examination 50%,
term-end examination 50%.
Students should have an experience of high-voltage experiments and knowledge of basic electromagnetic theory and transient analysis of circuits.