05822cam a2200577 i 4500999001700000001001300017003000600030005001700036006001100053007001500064008004100079015001900120015001900139016001800158020003600176020003300212020001800245020001500263035009600278040019000374050001000564072002500574082001500599100002700614245008500641250001900726264006100745264001200806300002200818336002600840337002600866338003600892504005100928505058800979505058501567505059402152505060102746505057403347520060103921588007604522650003404598650004104632650005904673650009804732650005104830650005904881650006604940776014905006856007605155942001305231  c27457d27457ocn908335721OCoLC20240801165622.0m     o  dcr cnu|||unuuu150504s2015    ne      ob    001 0 eng d  aGBB5528062bnb  aGBB5504772bnb7 a0171661982Uk  a9780128011720q(electronic bk.)  a0128011726q(electronic bk.)  z9780080999951  z0080999956  a(OCoLC)908335721z(OCoLC)908512045z(OCoLC)1066650600z(OCoLC)1129350478z(OCoLC)1228531836  aN$TbengerdaepncN$TdN$TdDG1dUIUdYDXCPdEBLCPdE7BdOCLCOdDEBSZdOCLCFdOCLCOdIDEBKdOCLCOdVGMdNRCdOCLCQdOCLdU3WdD6HdUKMGBdAU@dWYUdOCLCQdVT2dS2HdOCLCOdOCLCQdOCLCO 4aQA911 7aTECx0140002bisacsh04a532.052231 aBlazek, Jiri,eauthor.10aComputational fluid dynamics :bprinciples and applications /cJiri Blazek, PhD.  aThird edition. 1aAmsterdam ;aSan Diego :bButterworth Heinemann,c[2015] 4c�2015  a1 online resource  atextbtxt2rdacontent  acomputerbc2rdamedia  aonline resourcebcr2rdacarrier  aIncludes bibliographical references and index.0 aFront Cover; Computational Fluid Dynamics: Principles and Applications; Copyright; Contents; Acknowledgments; List of Symbols; Abbreviations; Chapter 1: Introduction; Chapter 2: Governing Equations; 2.1 The Flow and Its Mathematical Description; 2.1.1 Finite control volume; 2.2 Conservation Laws; 2.2.1 The continuity equation; 2.2.2 The momentum equation; 2.2.3 The energy equation; 2.3 Viscous Stresses; 2.4 Complete System of the Navier-Stokes Equations; 2.4.1 Formulation for a perfect gas; 2.4.2 Formulation for a real gas; 2.4.3 Simplifications to the Navier-Stokes equations.8 aThin shear layer approximationParabolized Navier-Stokes equations; Euler equations; References; Chapter 3: Principles of Solution of the Governing Equations; 3.1 Spatial Discretization; 3.1.1 Finite-difference method; 3.1.2 Finite-volume method; 3.1.3 Finite-element method; 3.1.4 Other discretization methods; Spectral-element method; Lattice Boltzmann method; Gridless method; 3.1.5 Central and upwind schemes; Central schemes; Upwind schemes; Flux-vector splitting schemes; Flux-difference splitting schemes; TVD Schemes; Fluctuation-splitting schemes; Solution reconstruction.8 aFirst- and second-order schemesENO/WENO Schemes; Central versus upwind schemes; Upwind schemes for real gas flows; 3.2 Temporal Discretization; 3.2.1 Explicit schemes; 3.2.2 Implicit schemes; 3.3 Turbulence Modeling; 3.4 Initial and Boundary Conditions; References; Chapter 4: Structured Finite-Volume Schemes; 4.1 Geometrical Quantities of a Control Volume; 4.1.1 Two-dimensional case; 4.1.2 Three-dimensional case; 4.2 General Discretization Methodologies; 4.2.1 Cell-centered scheme; 4.2.2 Cell-vertex scheme: overlapping control volumes; 4.2.3 Cell-vertex scheme: dual control volumes.8 a4.2.4 Cell-centered versus cell-vertex schemes4.3 Discretization of the Convective Fluxes; 4.3.1 Central scheme with artificial dissipation; Scalar dissipation scheme; Matrix dissipation scheme; 4.3.2 Flux-vector splitting schemes; Van Leer's scheme; AUSM; CUSP scheme; 4.3.3 Flux-difference splitting schemes; Roe upwind scheme; 4.3.4 Total variation diminishing schemes; Upwind TVD scheme; 4.3.5 Limiter functions; Limiter functions for MUSCL interpolation; MUSCL scheme with =0; MUSCL scheme with =1/3; Limiter for CUSP scheme; Limiter for TVD scheme; 4.4 Discretization of the Viscous Fluxes.8 a4.4.1 Cell-centered scheme4.4.2 Cell-vertex scheme; References; Chapter 5: Unstructured Finite-Volume Schemes; 5.1 Geometrical Quantities of a Control Volume; 5.1.1 Two-dimensional case; Triangular element; Quadrilateral element; Element center; 5.1.2 Three-dimensional case; Triangular face; Quadrilateral face; Volume; Cell centroid; 5.2 General Discretization Methodologies; 5.2.1 Cell-centered scheme; 5.2.2 Median-dual cell-vertex scheme; 5.2.3 Cell-centered versus median-dual scheme; Accuracy; Computational work; Memory requirements; Grid generation/adaptation.  aComputational Fluid Dynamics: Principles and Applications, Third Edition presents students, engineers, and scientists with all they need to gain a solid understanding of the numerical methods and principles underlying modern computation techniques in fluid dynamics. By providing complete coverage of the essential knowledge required in order to write codes or understand commercial codes, the book gives the reader an overview of fundamentals and solution strategies in the early chapters before moving on to cover the details of different solution techniques. This updated edition includes new.0 aOnline resource; title from PDF title page (EBSCO, viewed May 5, 2015). 0aComputational fluid dynamics. 0aFluid dynamicsxMathematical models. 6aDynamique des fluides num�erique.0(CaQQLa)000260852 6aDynamique des fluides0(CaQQLa)201-0025811xMod�eles math�ematiques.0(CaQQLa)201-0379082 7aTECHNOLOGY & ENGINEERINGxHydraulics.2bisacsh 7aComputational fluid dynamics2fast0(OCoLC)fst01745072 7aFluid dynamicsxMathematical models2fast0(OCoLC)fst0092798208iPrint version:aBlazek, Jiri.tComputational Fluid Dynamics: Principles and Applications.dBurlington : Elsevier Science, �2015z9780080999951403ScienceDirectuhttps://www.sciencedirect.com/science/book/9780080999951  2ddccEBK