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Development and testing of a three-section pulse-forming network and its application to Marx circuit

Published online by Cambridge University Press:  02 October 2019

Falun Song*
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Beizhen Zhang
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Chunxia Li
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Fei Li
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Ganping Wang
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Haitao Gong
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Yanqing Gan
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
Xiao Jin
Affiliation:
Science and Technology on High Power Microwave Laboratory, Institute of Applied Electronics, China Academy of Engineering Physics, Mianyang621900, China
*
Author for correspondence: Falun Song, Institute of Applied Electronics, China Academy of Engineering Physics No. 64, Mianshan Road, Mianyang621900, China. E-mail: songfalun@caep.cn

Abstract

A three-section pulse forming network (PFN) based on Guillemin type-C circuit was developed to meet the challenge of a compact design, high withstand voltage, and high-quality output waveform with fast rise time, flat-top duration, and 100-ns pulse width. A simplified pulse forming circuit was proposed and studied that includes only three LC-sections connected in parallel, with each section containing an inductor and a capacitor connected in series. The effect of the capacitance deviation on the output waveform was investigated. The simulation results show that when the capacitance deviation exceeds +3%, both the flat top and fall time of the output waveform of single PFN module deteriorate greatly. Fortunately, in a multi-stage PFN-Marx circuit, even if the capacitance deviation exceeds +10%, when the average capacitance of the same LC sections is close to the theoretical value, the output waveform maintains a good quality and is in good agreement with the theoretical prediction. The compact three-section PFN developed during this project has a size of only 360 mm × 342 mm × 65 mm, and a maximum withstand voltage of 120 kV. Sixteen PFN stages were assembled to form a Marx generator with design parameters to provide of an output peak power of 12 GW and a maximum peak current of 15 kA. The tested output waveform agrees well with the theoretical results, having a rise time of 31 ns, a flat-top of 104 ns, and a pulse with of 164 ns.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2019

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References

Adler, RJ, Gilbrech, JA and Price, DT (2009) A modular PFN Marx with a unique charging system and feedthrough. IEEE Pulsed Power Conference, Jun 28, 2009 – Jul 2, 2009, Washington, DC, USA, IEEE Xplore, pp. 1201–1206.Google Scholar
Benford, J, Swegle, JA and Schamiloglu, E (2007) High Power Microwaves. Boca Raton, FL: Taylor & Francis.CrossRefGoogle Scholar
Clementson, J, Rahbarnia, K, Grulke, O and Klinger, T (2014) Design of A, B, and C pulse forming networks using the VINPFN application. IEEE Transactions on Power Electronics 29, 56735679.CrossRefGoogle Scholar
Cook, EG (1975) Pulse Forming Network Investigation (M.S. thesis). Texas Tech University, Lubbock, Texas, USA.Google Scholar
Gaudet, JA, Barker, RJ, Buchenauer, CJ, Christodoulou, C, Dickens, J, Gundersen, MA, Joshi, RP, Krompholz, HG, Kolb, JF, Kuthi, A, Laroussi, M, Neuber, A, Nunnally, W, Schamiloglu, E, Schoenbach, KH, Tyo, JS and Vidmar, RJ (2004) Research issues in developing compact pulsed power for high peak power applications on mobile platforms. Proceedings of the IEEE 92, 11441165.CrossRefGoogle Scholar
Glasoe, GN and Lebacqz, JV (1948) Pulse Generators. New York, NY: McGraw-Hill, pp. 189207.Google Scholar
Jiang, PJ, Zhang, YY, Xie, HQ and Li, ZH (2018) Phase-locked high-power microwave generator driven by kW level RF power. High Power Laser and Particle Beams 30, 083006.Google Scholar
Korovin, SD, Rostov, VV, Polevin, SD, Pegel, IV, Schamiloglu, E, Fuks, MI and Barker, RJ (2004) Pulsed power-driven high- power microwave sources. Proceedings of the IEEE 92, 10821095.CrossRefGoogle Scholar
Lassalle, F, Morell, A, Loyen, A, Chanconie, T, Roques, B, Toury, M and Vezinet, R (2018) Development and test of a 400-kV PFN Marx with compactness and rise time optimization. IEEE Transactions on Plasma Science 46, 33133319.CrossRefGoogle Scholar
Li, HT, Ryoo, HJ, Kim, JS, Rim, GH, Kim, YB and Deng, JJ (2009) Development of rectangle-pulse Marx generator based on PFN. IEEE Transactions on Plasma Science 37, 190194.CrossRefGoogle Scholar
Li, W, Li, ZQ, Sun, XL and Zhang, J (2015) A reliable, compact, and repetitive-rate high power microwave generation system. Review of Scientific Instruments 86, 114704.CrossRefGoogle ScholarPubMed
Li, F, Song, FL, Zhu, MD, Jin, X, Gan, YQ and Gong, HT (2018) A compact high-voltage pulse forming module with hundreds of nanoseconds quasi-squared output pulse. Review of Scientific Instruments 89, 104706.CrossRefGoogle ScholarPubMed
Liu, HW, Xie, WP, Yuan, JQ, Wang, LY, Ma, X and Jiang, P (2016) Design of compact Marx module with square pulse output. Review of Scientific Instruments 87, 074706.CrossRefGoogle ScholarPubMed
Maenchen, J, Cooperstein, G, O'Malley, J and Smith, I (2004) Advances in pulsed power-driven radiography systems. Proceedings of the IEEE 92, 10211042.CrossRefGoogle Scholar
Mead, MJ, Moncho-Banuls, S, Pottier, S and Brasile, JP (2009) Pulsed power system for the Orion high power laser. Acta Physica Polonica-Series A General Physics 115, 978979.CrossRefGoogle Scholar
Pan, ZL, Yang, JH and Cheng, XB (2016) Research of the anti-resonance pulse forming network and its application in the Marx generator. Laser and Particle Beams 34, 675686.CrossRefGoogle Scholar
Rathod, PJ, Anitha, VP, Sholapurwala, ZH and Saxena, YC (2014) A Guillemin type E pulse forming network as the driver for a pulsed, high density plasma source. Review of Scientific Instruments 85, 063503.CrossRefGoogle Scholar
Song, FL, Li, F, Zhang, BZ, Gong, HT, Gan, YQ and Jin, X (2019 a) A compact low jitter high power repetitive long-pulse relativistic electron beam source. Nuclear Instruments and Methods in Physics Research Section A 919, 5663.CrossRefGoogle Scholar
Song, FL, Li, F, Zhang, BZ, Zhu, MD, Li, CX, Wang, GP, Gong, HT, Gan, YQ and Jin, X (2019 b) Recent advances in compact repetitive high-power Marx generators. Laser and Particle Beams 37, 110121.CrossRefGoogle Scholar
Tewari, SV, Umbarkar, SB, Agarwal, R, Saroj, PC, Sharma, A, Mittal, KC and Mangalvedekar, HA (2013) Development and analysis of PFN based compact Marx generator using finite integration technique for an antenna load. IEEE Transactions on Plasma Science 41, 26842690.CrossRefGoogle Scholar
Wu, QL, Cui, YC, Gao, JM, Li, S and Yang, HW (2019) A High-voltage pulse generator based on PFN and varistors. IEEE Transactions on Plasma Science 47, 512517.CrossRefGoogle Scholar
Zhang, HB, Yang, JH, Lin, JJ and Yang, X (2013) A compact bipolar pulse-forming network-Marx generator based on pulse transformers. Review of Scientific Instruments 84, 114705.CrossRefGoogle ScholarPubMed
Zhang, JD, Ge, XJ, Zhang, J, Zhang, JT, Fan, YW, Li, ZQ, Jin, ZX, Gao, L, Ling, JP and Qi, ZM (2016) Research progresses on Cherenkov and transit-time high-power microwave sources at NUDT. Matter and Radiation at Extremes 1, 163178.CrossRefGoogle Scholar