Pulsed energy drives a wide range of high-energy applications, from particle acceleration to fusion research and electromagnetic pulse (EMP) simulation. Marx generators play a critical role in generating those high-voltage pulses by amplifying lower voltage DC inputs.
In this paper, to obtain a higher amplitude, higher energy transfer efficiency and better waveform quality of pulse current, a pulsed power supply that has time delay effect of the secondary side and the structure of inductive and capacitive hybrid energy storage is presented.
High Voltage Nanosecond Pulse Generator based on Inductive Energy Storage With Adjustable Pulse Width Published in: 2022 IEEE International Conference on High Voltage Engineering and Applications (ICHVE)
Even students exploring energy storage trends will find gold here. Why Simulate High Voltage Pulse Systems? Imagine trying to tame lightning in a lab. That''s essentially what managing high-voltage pulses feels like. Simulation tools let us test theories without frying expensive equipment.
To develop a compact and lightweight high-voltage pulse generator, this work proposed a new modular pulse forming topology with high voltage gain and a reduced number of energy storage capacitors.
This paper presents the design, simulation, and implementation of a modular and versatile high-voltage pulse power supply used in microwave device characterization and testing.
To have a reliable high-voltage pulse generator, a technique of capacitor discharge was employed. Four units of capacitor rated 100 μ F 1.2 kV were connected in series to produce 25 μ F 4.8 kV which were used to store the energy of approximately 200 J.
To have a reliable high-voltage pulse generator, a technique of capacitor discharge was employed. Four units of capacitor rated 100 μ F 1.2 kV were connected in series to produce 25 μ F 4.8 kV which were used to store
This paper presents a design, simulation, and analysis of an advanced negative high voltage nanosecond pulse generator (NSPG) utilizing a boost-based multi-stage Marx generator with solid-state SiC-MOSFET switches.
LTDs use low- inductance, capacitive energy storage circuits (known as bricks) arranged in parallel to produce a high-peak current directly from the primary energy store.
Abstract cting linear accelerator TESLA. They produce rectangular high voltage pulses of up to 120 kV. The electrical power during the pulse is typically 15 W and can maximally be 16.8 MW. The pulse length is 1.6 ms with a repetition rate of 5 Hz, for
