Oosthuizen, Patrick H.
Natural Convective Heat Transfer from Horizontal and Near Horizontal Surfaces [electronic resource] / by Patrick H. Oosthuizen, Abdulrahim Y. Kalendar. - 1st ed. 2018. - XII, 121 p. 146 illus., 11 illus. in color. online resource. - SpringerBriefs in Thermal Engineering and Applied Science, 2193-2549 . - SpringerBriefs in Thermal Engineering and Applied Science, .
Introduction -- Natural Convective Heat Transfer from Upward Facing Horizontal Isothermal Circular, Square, Two-Dimensional, and Rectangular Shaped Surfaces -- Natural Convective Heat Transfer from Upward Facing Horizontal Plane Surfaces of Complex Shape -- Recessed and Protruding Heated Horizontal Surfaces -- Inclined and Adjacent Square Isothermal Heated Surfaces -- Natural Convective Heat Transfer from Horizontal Two-Sided Circular Plates -- Effect of a Parallel Adiabatic Covering Surface on the Natural Convective Heat Transfer from Horizontal Upward Facing Heated Surfaces.
This book deals with a natural convective heat transfer situation of significant practical importance that has not been adequately dealt with in existing texts or widely available review papers: natural convective heat transfer from horizontal and near horizontal surfaces. The aim is to provide the reader with an understanding of past studies of natural convective heat transfer from horizontal surfaces and a more detailed review of contemporary studies. The more recent work deals with heat transfer from surfaces that have more complex shapes than previously considered, with heat transfer in situations in which laminar, transitional, and turbulent flow occur; in situations where the surface is inclined at a relatively small angle to the horizontal; and in situations where there is a covering surface above the heated surface. The authors further present methods for predicting heat transfer rates in all of the situations.
9783319787503
10.1007/978-3-319-78750-3 doi
Thermodynamics.
Heat engineering.
Heat transfer.
Mass transfer.
Fluid mechanics.
Engineering Thermodynamics, Heat and Mass Transfer.
Engineering Fluid Dynamics.
Thermodynamics.
TJ265 TP156.M3
621.4021
Natural Convective Heat Transfer from Horizontal and Near Horizontal Surfaces [electronic resource] / by Patrick H. Oosthuizen, Abdulrahim Y. Kalendar. - 1st ed. 2018. - XII, 121 p. 146 illus., 11 illus. in color. online resource. - SpringerBriefs in Thermal Engineering and Applied Science, 2193-2549 . - SpringerBriefs in Thermal Engineering and Applied Science, .
Introduction -- Natural Convective Heat Transfer from Upward Facing Horizontal Isothermal Circular, Square, Two-Dimensional, and Rectangular Shaped Surfaces -- Natural Convective Heat Transfer from Upward Facing Horizontal Plane Surfaces of Complex Shape -- Recessed and Protruding Heated Horizontal Surfaces -- Inclined and Adjacent Square Isothermal Heated Surfaces -- Natural Convective Heat Transfer from Horizontal Two-Sided Circular Plates -- Effect of a Parallel Adiabatic Covering Surface on the Natural Convective Heat Transfer from Horizontal Upward Facing Heated Surfaces.
This book deals with a natural convective heat transfer situation of significant practical importance that has not been adequately dealt with in existing texts or widely available review papers: natural convective heat transfer from horizontal and near horizontal surfaces. The aim is to provide the reader with an understanding of past studies of natural convective heat transfer from horizontal surfaces and a more detailed review of contemporary studies. The more recent work deals with heat transfer from surfaces that have more complex shapes than previously considered, with heat transfer in situations in which laminar, transitional, and turbulent flow occur; in situations where the surface is inclined at a relatively small angle to the horizontal; and in situations where there is a covering surface above the heated surface. The authors further present methods for predicting heat transfer rates in all of the situations.
9783319787503
10.1007/978-3-319-78750-3 doi
Thermodynamics.
Heat engineering.
Heat transfer.
Mass transfer.
Fluid mechanics.
Engineering Thermodynamics, Heat and Mass Transfer.
Engineering Fluid Dynamics.
Thermodynamics.
TJ265 TP156.M3
621.4021