Title :
Numerical Computation of Surface Melting at Imperfect Electrical Contact between Rough Surfaces
Author :
Kim, Wansik ; Wang, Q. Jane
Author_Institution :
Dept. of Mech. Eng., Northwestern Univ., Evanston, IL
Abstract :
This paper presents a surface melting model by means of numerical simulation of three-dimensional imperfect electrical contact (ImPEC) between rough surfaces in a high electrical current application. The continuous convolution and fast Fourier transform (CC-FFT) and discrete convolution and fast Fourier transform (DC-FFT) algorithms with the conjugated gradient method (CGM) for pressure iteration are applied to solve the surface melting problem under thermo-electro- mechanically coupled ImPEC conditions. The computational result suggests that asperity melting by Joule heating of electron tunneling through a surface oxide film layer may be initiated in a very short time interval if the apparent current density is extremely high. Averaged asperity melting speeds at molten contact asperities are also predicted by means of simulated asperity melting heights.
Keywords :
conjugate gradient methods; electrical contacts; fast Fourier transforms; melting; rough surfaces; tunnelling; Joule heating; asperity melting; conjugated gradient method; discrete convolution; electron tunneling; fast Fourier transform; high electrical current application; pressure iteration; rough surfaces; surface melting; three-dimensional imperfect electrical contact; Contacts; Convolution; Electrons; Fast Fourier transforms; Gradient methods; Heating; Numerical simulation; Rough surfaces; Surface roughness; User-generated content; CC-FFT; DC-FFT; ImPEC; asperity melting heights and speeds; surface melting;
Conference_Titel :
Electrical contacts - 2006, proceedings of the fifty-second ieee holm conference on
Conference_Location :
Montreal, QC
Print_ISBN :
1-4244-0581-5
DOI :
10.1109/HOLM.2006.284069
