000			02106aab a2200241 4500
008			240122b19901990|||mr||| |||| 00| 0 eng d
022			_a0017-9310
100			_aZhang, L. _9167966
100			_aSoufiani, A. _9869048
100			_aPetit, J.P. _9880080
100			_aTaine, J. _9869049
245			_aCoupled Radiation and Laminar Mixed Convection in an Absorbing and Emitting Real Gas Mixture along a Vertical Plate
300			_a319-329 p.
520			_aThe radiation transfer part is treated by the application of a random statistical narrow-band model and the Curtis-Godson approximation. An implicit finite-difference technique, developed for this study is used to solve the mass, momentum and energy conservation equations in a coupled manner. Excellent agreement between our finite-difference solutions and those of other authors are obtained for pure natural convection, pure forced convection and mixed convection without radiation. The investigation of the boundary conditions at infinity shows that the radiation penetration length at atmospheric pressure is of the order of one pure H2O equivalent metre, which is one order of magnitude larger than the boundary layer thickness for mixed convection without fluid radiation. Comparison of results with and without radiation in various conditions shows that fluid radiation enhances the effect of buoyancy forces, increases temperature, velocity, and conductive heat transfer at the wall, but decreases the wall radiative heat flux. A dimensionless parameter R is introduced in order to enable a crude estimation of wall conductive flux enhancement due to radiation.
650			_aCoupled Radiation _9880081
650			_aLaminar Mixed Convection _9865139
650			_aAbsorbing _9875173
650			_aEmitting Real Gas Mixture _9880082
650			_aVertical Plate _9682605
773	0		_dNew York, U.S.A : Pergamon Subsidiary of Elsevier Science & Technology _x00179310 _tInternational Journal of Heat and Mass Transfer
856			_uhttps://www.sciencedirect.com/science/article/pii/001793109090101Y
942			_2ddc _n0 _cART _o14993 _pMr. Muhammad Rafique Al Haj Rajab Ali (Late)
999			_c814761 _d814761