During the few decades, computational techniques for simulating heat transfer in complex industrial systems have reached maturity. Combined with increasingly sophisticated modeling of turbulence, chemistry, radiation, phase change, and other physics, powerful computational fluid dynamics (CFD) and computational heat transfer (CHT) solvers have been developed which are beginning to enter the industrial design cycle. In this paper, an overview of emerging simulation needs is first given, and currently-available CFD techniques are evaluated in light of these needs. Emerging computational methods which address some of the failings of current techniques are then reviewed. New research opportunities for computational heat transfer, such as in submicron and multiscale heat transport, are reviewed. As computational techniques and physical models become mature, there is increasing demand for predictive simulation, that is, simulation which is not only verified and validated, but whose uncertainty is also quantified. Current work in the area of sensitivity computation and uncertainty propagation is described.

Issue Section:
Research Papers
Keywords:
Boltzmann equation, computational fluid dynamics, finite volume methods, flow simulation, heat transfer, reviews, turbulence, finite volume, multiscale, sensitivity analysis, immersed boundary, uncertainty quantification, phonons, Boltzmann transport equation
Topics:
Computation, Computational fluid dynamics, Flow (Dynamics), Heat transfer, Phonons, Simulation, Uncertainty, Modeling, Turbulence, Complex systems, Temperature, Finite volume methods, Uncertainty quantification, Electrons, Sensitivity analysis, Algorithms

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