THE DEVELOPMENT AND APPLICATION OF THE TECHNIQUE OF CALCULATION OF THERMAL BREAKDOWN VOLTAGE IN THE HIGH-FREQUENCY STRUCTURES


Cite item

Full Text

Abstract

The paper deals with the description of a new technique of calculations of the heat release processes at the high and ultra-high frequencies associated with the losses in composite materials (CM) what may cause the destruction of radio components. The study of thermal breakdown is necessary to determine the mechanism and nature of change of dielectric properties. Thermal breakdown influences destructively the composite material radio components or even causes their failure. The heating phenomena are rather complex and the calculation of its origination mechanism, as well as the stages of the origination and development of thermal effect and composite material aging, are scientifically and practically attractive.

The goal of the study is the development of a technique for calculation of heat removal and thermal breakdown voltage in the high-frequency structures both for a structure cooled from the one side and for a structure cooled from two sides.

The author got the formulas for calculation of the thermal breakdown voltage of the small-size insulators both in the cases when the electric field is uniform and in the cases when it is non-uniform.

It is experimentally proved that when increasing the temperature of the environment, the value of thermal overload decreases for the composite dielectric materials. When increasing the frequency, the temperature differential increases; at the high frequencies, large temperature differentials occur in the structures made of composite dielectric materials that cause the destruction.

The calculation technique proposed by the author ensures the calculation accuracy sufficiently high for the practical purpose. The study of the breakdown of the discoid components made of a composite containing titanium dioxide shows that in the interval of frequencies f from 0.5 to 1.5 MHz, the temperature and frequency dependencies of thermal breakdown voltage are compliant with the calculations according to the proposed technique.

About the authors

E. M. Volokobinsky

Bonch-Bruevich Saint-Petersburg State University of Telecommunications

Author for correspondence.
Email: fake@neicon.ru

engineer of Chair of Designing and Technology of Production of Radioelectronic Facilities

Russian Federation

References

  1. Poberezhskiy L.P. Oscillography of internal insulation currents in the layer of the insulation in the presence of interference. Vestnik elektropromyshlennosti, 1961, no. 12, pp. 50–51.
  2. Dulnev G.N., Semyashkin E.M. Teploobmen v radioelektronnykh apparatakh [Heat transfer in electronic devices]. Moscow, Energiya Publ., 1968. 492 p.
  3. Braude E.V. Determination of the electrical strength of the of installational ceramic insulators in high-power radio transmitting devices. Voprosy radioelektroniki. Seriya X: Tekhnika radiosvyazi, 1960, no. 2, pp. 82–116.
  4. Puchkovskiy V.V., Myakinin E.G. Thermal breakdown of a two-layer dielectric. Inzhenerno-fizicheskiy zhurnal, 1962, vol. 5, no. 9, pp. 33–37.
  5. Afanasev A.M., Podgornyy V.V., Siplivyy B.N., Yatsyshen V.V. Calculation of the thermal effects of microwave radiation on flat water-containing objects of a layered structure. Fizika voln, protsessov i radiotekhnicheskoy sistemy, 1998, vol. 1, no. 2, pp. 83–90.
  6. Sergeeva E.A., Adbullin I.Sh. Activation of the high modulus high molecular polyethylene fibres by activeted by nonequilibrium low-temperature plasma. Nanotekhnika, 2009, no. 2, pp. 12–15.
  7. Skvortsov A.A., Kalenkov S.G., Koryachko M.V. Phase transformations in the systems of metallization with non-stationary thermal effects. Pisma v zhurnal tekhnicheskoy fiziki, 2014, vol. 40, no. 18, pp. 24–32.
  8. Burya A.I., Tkachenko E.V., Chigvintseva O.P. Polyamide composites: properties and applications. Kompozitsionnye materialy, 2009, vol. 3, no. 1, pp. 4–21.
  9. Emelyanov O.A., Ivanov I.O. Fast electromigration crack in nanoscale aluminum film. Journal of Applied Physics, 2014, vol. 116, no. 6, pp. 1–4.
  10. Komarov V.V. The error of linearization of the solution of the joint boundary value problem of electrodynamics and heat conduction for dissipative dielectrics. Radiotekhnika, 2006, no. 12, pp. 78–82.
  11. Makdessi M., Sari A., Vente P. Metallized polymer film capacitors ageing law based on capacitance degradation. Microelectronics Reliability, 2014, vol. 54, no. 9, pp. 1823–1829.
  12. Kazanskiy L.S., Minkin M.A. On the modification of the generalized equivalent circuit method. Vestnik Samarskogo otraslevogo nauchnogo issledovatelskogo instituta radio, 2004, no. 2, pp. 54–57.
  13. Gradshteyn N.S., Ryzhik I.M. Tablitsy integralov, summ, ryadov i proizvedeniy [Tables of integrals, sums, series and products]. Moscow, Fizmatgiz Publ., 1963. 1100 p.
  14. Serebrov R.A., Fridman B.E., Martynenko V.A., Khapugin A.A. Design and testing of heavy pulse current switches based on photothyristors. Russian Electrical Engineering, 2016, vol. 87, no. 7, pp. 395–402.
  15. Jow T.R., MacDougall F.W., Ennis J.B., Yang X.H., Schneider M.A., Scozzie C.J., White J., Macdonald J.R., Schalnat M.C., Cooper R.A., Yen S.P.S. Pulsed Power Capacitor Development and Outlook. IEEE Pulse Power Conference. Switzerland, IEEE Publ., 2015, pp. 1–7.
  16. Kazanskiy L.S., Minkin M.A., Yudin V.V. Calculation of symmetric radiating systems by the method of a generalized equivalent circuit. Radiotekhnika, 2005, no. 1, pp. 73–75.
  17. Buzova M.A., Yudin B.B. Proektirovanie provolochnykh antenn na osnove integralnykh uravneniy [Design of wire antennas on the basis of integral equations]. Moscow, Radio i svyaz Publ., 2005. 172 p.
  18. Buzova M.A., Yudin V.V. Integral equation of the second kind for a linear vibrator. Vestnik Samarskogo otraslevogo nauchnogo issledovatelskogo instituta radio, 2003, no. 1, pp. 22–27.
  19. Belko V.O., Emelyanov O.A. Self-healing in segmented metallized film capacitors: Experimental and theoretical investigations for engineering design. Journal of Applied Physics, 2016, vol. 119, no. 2, pp. 1–7.
  20. Karnakov B.M., Mur V.D., Popruzhenko S.V., Popov V.S. Current progress in developing the nonlinear ionization theory of atoms and ions. Physics-Uspekhi, 2015, vol. 58, no. 1, pp. 3–32.
  21. Minkin M.A. Analysis of the parametric sensitivity of radiating structures based on the method of a generalized equivalent circuit. Radiotekhnika, 2001, no. 11, pp. 86–89.
  22. Matveev V.I., Makarov D.N., Kapustin S.N. Dimensions of neutral clusters and processes of their fragmentation during ionic sputtering of a solid. Pisma v zhurnal tekhnicheskoy fiziki, 2015, vol. 41, no. 16, pp. 15–20.
  23. Liang Y. Transient temperature analysis and short-term ampacity calculation of power cables in tunnel using SUPG finite element method. 2013 IEEE Industry Applications Society Annual Meeting. Switzerland, IEEE Publ., 2013, pp. 1–4.
  24. Skvortsov A.A., Zuev S.M., Koryachko M.V. Electrothermal degradation of systems of metallization at non-stationary current influences. International Conference on Actual Problems of Electron Devices Engineering. Saratov, TUS im. Yuriy Gagarin Publ., 2014, pp. 340–343.

Supplementary files

Supplementary Files
Action
1. JATS XML

Copyright (c)



This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies