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100   $a20090423d2009      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aConvective heat transfer $esolved problems /$fMichel Favre-Marinet, Sedat Tardu
210   $aHoboken, NJ $cISTE/John Wiley and Sons$d2009
215   $a1 online resource (393 p.)
225 1 $aISTE ;$vv.148
300   $aDescription based upon print version of record.
311 08$a9781848211193 
311 08$a1848211198 
320   $aIncludes bibliographical references and index.
327   $aConvective Heat Transfer; Table of Contents; Foreword; Preface; Chapter 1. Fundamental Equations, Dimensionless Numbers; 1.1. Fundamental equations; 1.1.1. Local equations; 1.1.2. Integral conservation equations; 1.1.3. Boundary conditions; 1.1.4. Heat-transfer coefficient; 1.2. Dimensionless numbers; 1.3. Flows with variable physical properties: heat transfer in a laminar Couette flow; 1.3.1. Description of the problem; 1.3.2. Guidelines; 1.3.3. Solution; 1.4. Flows with dissipation; 1.4.1. Description of the problem; 1.4.2. Guidelines; 1.4.3. Solution; 1.5. Cooling of a sphere by a gas flow
327   $a1.5.1. Description of the problem1.5.2. Guidelines; 1.5.3. Solution; Chapter 2. Laminar Fully Developed Forced Convection in Ducts; 2.1. Hydrodynamics; 2.1.1. Characteristic parameters; 2.1.2. Flow regions; 2.2. Heat transfer; 2.2.1. Thermal boundary conditions; 2.2.2. Bulk temperature; 2.2.3. Heat-transfer coefficient; 2.2.4. Fully developed thermal region; 2.3. Heat transfer in a parallel-plate channel with uniform wall heat flux; 2.3.1. Description of the problem; 2.3.2. Guidelines; 2.3.3. Solution
327   $a2.4. Flow in a plane channel insulated on one side and heated at uniform temperature on the opposite side2.4.1. Description of the problem; 2.4.2. Guidelines; 2.4.3. Solution; Chapter 3. Forced Convection in Boundary Layer Flows; 3.1. Hydrodynamics; 3.1.1. Prandtl equations; 3.1.2. Classic results; 3.2. Heat transfer; 3.2.1. Equations of the thermal boundary layer; 3.2.2. Scale analysis; 3.2.3. Similarity temperature profiles; 3.3. Integral method; 3.3.1. Integral equations; 3.3.2. Principle of resolution using the integral method; 3.4. Heated jet nozzle; 3.4.1. Description of the problem
327   $a3.4.2. Solution3.5. Asymptotic behavior of thermal boundary layers; 3.5.1. Description of the problem; 3.5.2. Guidelines; 3.5.3. Solution; 3.6. Protection of a wall by a film of insulating material; 3.6.1. Description of the problem; 3.6.2. Guidelines; 3.6.3. Solution; 3.7. Cooling of a moving sheet; 3.7.1. Description of the problem; 3.7.2. Guidelines; 3.7.3. Solution; 3.8. Heat transfer near a rotating disk; 3.8.1. Description of the problem; 3.8.2. Guidelines; 3.8.3. Solution; 3.9. Thermal loss in a duct; 3.9.1. Description of the problem; 3.9.2. Guidelines; 3.9.3. Solution
327   $a3.10. Temperature profile for heat transfer with blowing3.10.1. Description of the problem; 3.10.2. Solution; Chapter 4. Forced Convection Around Obstacles; 4.1. Description of the flow; 4.2. Local heat-transfer coefficient for a circular cylinder; 4.3. Average heat-transfer coefficient for a circular cylinder; 4.4. Other obstacles; 4.5. Heat transfer for a rectangular plate in cross-flow; 4.5.1. Description of the problem; 4.5.2. Solution; 4.6. Heat transfer in a stagnation plane flow. Uniform temperature heating; 4.6.1. Description of the problem; 4.6.2. Guidelines; 4.6.3. Solution
327   $a4.7. Heat transfer in a stagnation plane flow. Step-wise heating at uniform flux
330   $aEach chapter begins with a brief yet complete presentation of the related topic. This is followed by a series of solved problems. The latter are scrupulously detailed and complete the synthetic presentation given at the beginning of each chapter. There are about 50 solved problems, which are mostly original with gradual degree of complexity including those related to recent findings in convective heat transfer phenomena. Each problem is associated with clear indications to help the reader to handle independently the solution. The book contains nine chapters including laminar external and inter
410  0$aISTE
606   $aHeat$xConvection
606   $aHeat$xTransmission
615  0$aHeat$xConvection.
615  0$aHeat$xTransmission.
676   $a536.25
676   $a621.402/25
700   $aFavre-Marinet$b Michel$f1947-$01839255
701   $aTardu$b Sedat$f1959-$01691466
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911019914003321
996   $aConvective heat transfer$94418427
997   $aUNINA