Solution of radiative transfer in a one‐dimensional anisotropic scattering media with different boundary conditions using the DRESOR method

Huang, Zhifeng; Cheng, Qiang; He, Cheng; Zhou, Huaichun

doi:10.1002/htj.20198

Cited by 9 publications

(1 citation statement)

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“…[133] The radiative intensity at any point with high directional resolution can be obtained based on the DRESOR values. The DRESOR method has been successfully used to calculate radiative heat transfer in onedimensional (1D), [134,135] two-dimensional (2D) [136] and threedimensional (3D) [137] systems with the particle media. Zheng et al [138] first combined DRESOR method with SNBCK model to study the radiative heat transfer of gas and soot mixtures in a 1D planar layer, and the SNBCK/DRESOR method showed a better efficiency than the SNBCK/DOM method when considering the wall reflection.…”

Section: Introductionmentioning

confidence: 99%

A Review on the Applications of Non-gray Gas Radiation Models in Multi-dimensional Systems

Zheng¹,

Sui²,

Sun³

et al. 2021

ES Energy Environ.

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Keeping gas radiation is a major way of heat transfer in flames. It affects temperature distributions and hence causes energy transfer in the combustion gaseous as well as subsequent chemical reactions. Accurate and efficient modeling of radiative heat transfer in multi-dimensional combustion systems is challenging, due to the drastic and rapid change of the radiative properties of the reacting gases in the whole spectrum, and the extensive computational cost for solving the radiative transfer equation (RTE) in multi-dimensional space. Several gas radiation models and RTE solution methods have been proposed to treat non-gray radiation heat transfer in combustion systems. In this paper, we first review the development of spectral line databases, gas radiation models and RTE solution methods. Subsequently, the development of radiation model parameters for different gaseous species is discussed. Next, recent simulation investigations are reviewed for one-dimensional, twodimensional and three-dimensional systems involving these state-of-the-art radiation models. In addition, we also discuss machine learning approaches for establishing gas radiation models and solving RTEs in non-gray gas radiative problems, an alternative and flexible way to deal with the complex and dynamic systems. Hopefully, this review will provide an up-to-date knowledge about the numerical calculations of gas radiation heat transfers in combustion systems.

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