Wendt, GunnarGunnarWendtErbts, PatrickPatrickErbtsDüster, AlexanderAlexanderDüster2020-09-112020-09-112015-11-01Journal of Computational Physics (300): 327-351 (2015-11-01)http://hdl.handle.net/11420/7308This article aims to propose new aspects concerning a partitioned solution strategy for multi-physically coupled fields including the physics of thermal radiation. Particularly, we focus on the partitioned treatment of electro-thermo-mechanical problems with an additional fourth thermal radiation field. One of the main goals is to take advantage of the flexibility of the partitioned approach to enable combinations of different simulation software and solvers. Within the frame of this article, we limit ourselves to the case of nonlinear thermoelasticity at finite strains, using temperature-dependent material parameters. For the thermal radiation field, diffuse radiating surfaces and gray participating media are assumed. Moreover, we present a robust and fast partitioned coupling strategy for the fourth field problem. Stability and efficiency of the implicit coupling algorithm are improved drawing on several methods to stabilize and to accelerate the convergence. To conclude and to review the effectiveness and the advantages of the additional thermal radiation field several numerical examples are considered to study the proposed algorithm. In particular we focus on an industrial application, namely the electro-thermo-mechanical modeling of the field-assisted sintering technology.en1090-2716Journal of computational physics2015327351Convergence accelerationMulti-field problemsPartitioned solution strategyThermal radiationPartitioned coupling strategies for multi-physically coupled radiative heat transfer problemsJournal Article10.1016/j.jcp.2015.07.063Other