A finite element analysis of thermal convection problems with the Joule heat

被引:0
作者
Tagami Daisuke
Itoh Hajime
机构
[1] Kyushu University,Department of Intelligent Machinery and Systems, Graduate School of Engineering
[2] Asahi Glass Co.,Research Center
[3] Ltd.,undefined
来源
Japan Journal of Industrial and Applied Mathematics | 2003年 / 20卷 / 2期
关键词
thermal convection problem; Joule heat; error estimate; finite element method; electric glass furnace;
D O I
10.1007/BF03170426
中图分类号
学科分类号
摘要
Error estimates are introduced in a finite element approximation to thermal convection problems with the Joule heat. From the Joule heat, a nonlinear source term arises in the convection-diffusion part of problems. The derivation of the estimates is based on the fact that a finite element approximation to the electric potential appearing in such a nonlinear term is uniformly bounded in the cubic summable norm with derivatives up to the first order. The error estimates are optimal, and do not require any stability conditions. Numerical results show that the numerical convergence rates agree well with the theoretical ones, and that phenomena in a simplified electric glass furnace are influenced by the electric potential distributions associated with the location of electrodes.
引用
收藏
相关论文
共 20 条
  • [1] Boland J.(1990)An analysis of the finite element method for natural convection problems Numer. Methods Partial Differential Equations 6 115-126
  • [2] Layton W.(1990)Error analysis for finite element methods for steady natural convection problems Numer. Punct. Anal. Optim. 11 449-483
  • [3] Boland J.(1985)Three-dimensional mathematical model for flow and heat transfer in electric glass furnaces Heat Transfer Eng. 6 55-65
  • [4] Layton W.(1971)Use of mathematical modeling in determining the effects of electrode configuration on convection currents in an electric glass melter IEEE Trans. Ind. Gen. Appl. IGA-7 116-129
  • [5] Choudhary M.(1956)Some observations on the design and operation of an all-electric glass-melting furnace J. Soc. Glass Tech. 40 482-498
  • [6] Curran R.L.(1998)A finite element analysis for a thermal convection problem with the infinite Prandtl number Hiroshima Math. J. 28 555-570
  • [7] Gell P.A.M.(1995)Three-dimensional variable viscosity convection of an infinite Prandtl number Boussinesq fluid in a spherical shell Geophys. Res. Lett. 22 2227-2230
  • [8] Itoh H.(1998)Electric melting of glass: Influence of cathodic currents on the formation of protective layers on molybdenum electrodes Glastech. Ber. 71 6-11
  • [9] Tabata M.(2000)A stabilized finite element method for the Rayleigh-Bénard equations with infinite Prandtl number in a spherical shell Comput. Methods Appl. Mech. Engrg. 190 387-402
  • [10] Ratcliff J.T.(2000)Error estimates for finite element approximations of drag and lift in nonstationary Navier-Stokes flows Japan J. Indust. Appl. Math. 17 371-389
12