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A Method to design composite insulation structures based on reliability for pulsed power systems

Published online by Cambridge University Press:  14 February 2014

Liang Zhao*
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Jian-Cang Su
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Xi-Bo Zhang
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Ya-Feng Pan
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Rui Li
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Bo Zeng
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Jie Cheng
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Bin-Xiong Yu
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
Xiao-Long Wu
Affiliation:
Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, Xi'an, Shaanxi, China
*
Address correspondence and reprint requests to: Liang Zhao, Science and Technology on High Power Microwave Laboratory, Northwest Institute of Nuclear Technology, No. 28, Pingyu Lu, Baqiao Qu, Xi'an, Shaanxi, 710024, China. E-mail: [email protected]

Abstract

A method to design the composite insulation structures in pulsed power systems is proposed in this paper. The theoretical bases for this method include the Weibull statistical distribution and the empirical insulation formula. A uniform formula to describe the reliability (R) for different insulation media such as solid, liquid, gas, vacuum, and vacuum surface is derived. The dependence curves of the normalized applied field on R are also obtained. These curves show that the normalized applied field decreases rapidly as R increases but the declining rates corresponding to different insulation media are different. In addition, if R is required to be higher than a given level, the normalized applied field should be smaller than a certain value. In practical design, the common range of the applied fields for different insulation media should be chosen to meet a global reliability requirement. In the end, the proposed method is demonstrated with a specific coaxial high-voltage vacuum insulator.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2014 

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References

REFERENCES

Adler, M.S. & Temple, V.A.K. (1978). Maximum surface and bulk electric-fields at breakdown for planar an beveled devices. IEEE Trans. Electron Dev. 25, 12661270.Google Scholar
Bluhm, H. (2006). Pulsed Power Systems. Karlsruhe: Springer.Google Scholar
Chantrenne, S. & Sincerny, P. (1999). Update of the lifetime performance of dependence vacuum insulator coating. Proc. 12th IEEE Int. Pulsed Power Conf., pp. 1403–1407. Monterey, California.Google Scholar
Cheng, X.B., Liu, J.L., Zhang, H.B., Hong, Z.Q. & Qian, B.L. (2012). Output voltage waveform analysis of an intense electron beam accelerator based on strip spiral Blumlein line. Laser Part. Beams 30, 379385.Google Scholar
Dissado, L.A. & Fothergill, J.C. (1992). Electrical Degradation and Breakdown in Polymers. London: The Institution of Engineering and Technology.Google Scholar
Dissado, L.A., Fothergill, J.C., Wolfe, S.V. & Hill, R.M. (1984). Weibull Statistics in Dielectric Breakdown: Theoretical Basis, Applications and Implications. IEEE Trans. Electr. Insul. EI-19, 227233.Google Scholar
Kiricov, A.V., Belomyttsev, S.Y., Ryzhov, V.V., Turchanovsky, I.Y. & Tarakanov, V.P. (2003). Condition for magnetic insulation of the electron beam in a rod-pinch diode. Laser Part. Beams 21, 273277.Google Scholar
Liu, J.L., Zhang, H.B., Fan, Y.W., Hong, Z.Q. & Feng, J.H. (2012). Study of low impedance intense electron-beam accelerator based on magnetic core Tesla transformer. Laser Part. Beams 30, 299305.CrossRefGoogle Scholar
Mankowski, J. (1997). High voltage subnanosecond dilelectric breakdown. Dissertation for the Ph. Degree: Texas Ttech University.Google Scholar
Martin, J.C. (1992). Nanosecond pulse techniques. Proc. IEEE 80, 934945.Google Scholar
Martin, T.H. (1985). Pulsed charged gas breakdown. Proc. 5th IEEE Int. Pulsed Power Conf., pp. 74–83. Arlington, Virginia.Google Scholar
Martin, T.H. (1989). An empirical formula for gas switch breakdown. Proc. 7th IEEE Int. Pulsed Power Conf., pp. 73–79. Monterey, Canada.CrossRefGoogle Scholar
Martin, T.H., Seamen, J.F., Jobe, D.O. & Pena, G.E. (1991). Gaseous prebreakdown process: that are important for pulsed power switching. Proc. 8th IEEE Int. Pulsed Power Conf., pp. 323–327. San Diego, California.Google Scholar
Martin, T.H., Guenther, A.H., & Kristiansen, M. (1996). J. C. Martin on Pulsed Power. New York: Plenum Publishers.Google Scholar
Miller, H.C. (1989). Surface flashover of insulators. IEEE Trans. Electr. Insul. 24, 765786.CrossRefGoogle Scholar
Miller, H.C. (1993). Flashover of insulators in vacuum: review of the phenomena and techniques to improved holdoff voltage. IEEE Trans. Electr. Insul. 28, 512527.Google Scholar
Milton, O. (1972). Pulsed flashover of insulators in vacuum. IEEE Trans. Electr. Insul. EI-7, 911.Google Scholar
Pai, S.T. & Zhang, Q. (1995). Introduction to High Power Pulse Technology. Singapore: World Scientific.Google Scholar
Peng, J.C., Liu, G.Z., Song, X.X. & Su, J.C. (2011). A high repetitive rate intense electron beam accelerator based on high coupling Tesla transformer. Laser Part. Beams 29, 5560.Google Scholar
Roth, I.S., Sincerny, P.S., Mandelcorn, L., Mendelsohn Smith, M.D., Engel, T.G., Schlitt, L. & Cooke, C.M. (1997). Vacuum insulator coating development. Proc. 11th IEEE Int. Pulsed Power Conf., pp. 537–542. Baltimore, Maryland.Google Scholar
Shao, T., Sun, G.S., Yan, P., Wang, J., Yuan, W.Q.Sun, H.Y. & Zhang, S.C. (2006). An experimental investigation of repetitive nanosecond-pulse breakdown in air. J. Phys. D: Appl. Phys. 39, 21922197.Google Scholar
Shao, T., Sun, G.S., Yan, P. & Zhang, S.C. (2007). Breakdown phenomena in nitrogen uue to repetitive nanosecond-pulses. IEEE Trans. Dielectr. Electr. Insul. 14, 813819.CrossRefGoogle Scholar
Shao, T., Tarasenko, V.F., Zhang, C., Baksht, E.K., Yan, P. & Shut'Ko, Y.V. (2012). Repetitive nanosecond-pulse discharge in a highly nonuniform electric field in atmospheric air: X-ray emission and runaway electron generation. Laser Part. Beams 30, 369378.CrossRefGoogle Scholar
Stygar, W.A., Spielman, R.B., Anderson, R.A., Clark, R.E., Douglas, J.W., Gilliland, T.L., Horry, M.L., Hughes, T.P., Ives, H.C., Long, F.W., Martin, T.H., McDaniel, D.H., Milton, O., Mostrom, M.A., Seamen, J.F., Shoup, R.W., Smith, J.W., Struve, K.W., Vogtlin, G.E., Wagoner, T.C. & Yamamoto, O. (1999). Operation of a Five-stage 40000-cm2 Area Inaulator Stack at 158 kV/cm, pp. 454–456. Proc. 11th IEEE Int. Pulsed Power Conf.Google Scholar
Vitkovitsky, I. (1987). High Power Switches. New York: Van Nostrand Reinhold Inc.Google Scholar
Wang, M. (2006). Reach of Multi-Stage Vacuum Insulator Stack Flashover Probability Analysis Methods. Ph.D. Thesis. Mianyang, China: China Academy of Engineering Physics.Google Scholar
Wang, X.S., Du, H.C. & Hu, B.T. (2012). Electron acceleration in vacuum with two overlapping linearly polarized laser pulses. Laser Part. Beams 30, 421425.Google Scholar
Wang, X.X., Hu, Y. & Song, X.H. (2005). Gas discharge in a gas peaking switch. Laser Part. Beams 23, 553558.Google Scholar
Xiao, R.Z., Zhang, X.W., Zhang, L.J., Li, X.Z., Zhang, L.G., Song, W., Hu, Y.M., Sun, J., Huo, S.F., Chen, C.H., Zhang, Q.Y. & Liu, G.Z. (2010). Efficient generation of multi-gigawatt power by a klystron-like relativistic backward wave oscillator. Laser Part. Beams 28, 505511.Google Scholar
Xun, T., Yang, H.W., Zhang, J.D., Liu, Z.X., Wang, Y. & Zhao, Y.S. (2008). A ceramic radial insulation structure for a relativistic electron beam vacuum diode. Rev. Sci. Instrum. 79, 063303.Google Scholar
Zhang, Y., Liu, J.L., Wang, S.W., Fan, X.L., Zhang, H.B. & Feng, J.H. (2012). Effects of dielectric discontinuity on the dispersion characteristics of the tape helix slow-wave structure with two metal shields. Laser Part. Beams 30, 329339.Google Scholar
Zhang, Y. & Liu, J.L. (2012). Impedance matching condition analysis of the multi-filar tape-helix Blumlein PFL with discontinuous dielectrics. Laser Part. Beams 30: 639650.Google Scholar
Zhao, L., Liu, G.Z., Su, J.C., Pan, Y.F. & Zhang, X.B. (2011). Investigation of thickness effect on electric breakdown strength of polymers under nanosecond pulses. IEEE Trans. Plasma Sci. 39, 16131618.Google Scholar
Zhao, L., Peng, J.C., Pan, Y.F., Zhang, X.B. & Su, J.C. (2010). Insulation Analysis of a Coaxial High-Voltage Vacuum Insulator. IEEE Trans. Plasma Sci. 38, 13691374.Google Scholar
Zhao, L., Su, J.C., Zhang, X.B. & Pan, Y.F. (2012). Experimental Investigation on the Role of Electrodes in Solid Dielectric Breakdown under Nanosecond Pulses. IEEE Trans. Dielectr. Electr. Insul. 19, 11011107.Google Scholar
Zhao, L., Pan, Y.F., Su, J.C., Zhang, X.B., Wang, L.M., Fang, J.P.Sun, X. & Li, R. (2013 a). A Tesla-type repetitive nanosecond pulse generator for solid dielectric breakdown research. Rev. Sci. Instrum. 84, 105114.CrossRefGoogle ScholarPubMed
Zhao, L., Su, J.C., Zhang, X.B., Pan, Y.F., Wang, L.M., Fang, J.P.Sun, X. & Li, R. (2013 b). An investigation into the cumulative breakdown process of polymethylmethacrylate in quasi-uniform electric field under nanosecond pulses. Phys. Plasma 20, 082119.Google Scholar
Zhao, L., Su, J.C., Zhang, X.B., Pan, Y.F., Wang, L.M., Sun, X., Li, R., Zeng, B. & Cheng, J. (2013 c). An experimental and theoretical Investigation into the ‘worm-hole’ effect. J. Appl. Phys. 114: 063306.Google Scholar
Zhao, L., Su, J.C., Zhang, X.B., Pan, Y.F., Wang, L.M., Sun, X. & Li, R. (2013 d). Research on Reliability and Lifetime of Solid Insulation Structures in Pulsed Power Systems. IEEE Trans. Plasma Sci. 41, 165172.Google Scholar