A Pulsed Power Supply Based on an Optimized SFPFN Scheme Producing Large Currents With a Flat Top on a Heavily Inductive Load

A Pulsed Power Supply Based on an Optimized SFPFN Scheme Producing Large Currents With a Flat Top on a Heavily Inductive Load

A power supply able to generate a pulsed large current (∼26 kA) with a flattop period > 10 ms for a heavily inductive load was designed based on the sequentially fired pulse forming network (SFPFN) scheme with high-energy-transfer efficiency. To overcome the high voltage stress on switching devic...

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Veröffentlicht in:IEEE transactions on power electronics 2021-10, Vol.36 (10), p.11221-11233
Hauptverfasser: E, Peng, Ling, Wenbin, Mao, Aaohua, Guan, Jian, Ma, Xun, Li, Hongtao, Yu, Zhiguo, Ding, Mingjun
Format: Artikel
Sprache:eng
Schlagworte:
Capacitors
Circuits
Crowbar branch
Electric power supplies
Energy exchange
Energy transfer
flattop current
Power supplies
Power supply
pulse-forming unit (PFU)
pulsed power supply
Resistors
sequentially fired pulse forming network (SFPFN)
Stress
Switches
Switching
Thyristors
Topology
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Zusammenfassung:A power supply able to generate a pulsed large current (∼26 kA) with a flattop period > 10 ms for a heavily inductive load was designed based on the sequentially fired pulse forming network (SFPFN) scheme with high-energy-transfer efficiency. To overcome the high voltage stress on switching devices due to the SFPFN scheme, a novel electrical circuit topology was developed. In particular, the current changing rate ( di/dt ) on switching devices is limited by new designs of crowbar branch and pulse-forming unit (PFU). The assembled power supply is shown to provide an output current of a flattop of 26 kA and 12 ms on a load of 40 μ H and 4.24 mΩ with the predicted improvement in energy transfer efficiency.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2021.3068984