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BL
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| Record Number
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841493
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| Main Entry
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Kleinstreuer, C.
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| Title & Author
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Modern fluid dynamics /\ Clement Kleinstreuer.
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| Edition Statement
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Second edition.
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| Publication Statement
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Boca Raton :: CRC Press,, 2018.
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, ©2018
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| Page. NO
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1 online resource
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| ISBN
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1138198102
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: 1315226278
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: 135184962X
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: 1351849638
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: 1351849646
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: 1523118202
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: 9781138198104
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: 9781315226279
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: 9781351849623
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: 9781351849630
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: 9781351849647
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: 9781523118205
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| Bibliographies/Indexes
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Includes bibliographical references and index.
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| Contents
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Cover; Half-Title; Copyright; Title; Dedication; Contents; Preface; Author Bio; Section A Fluid Dynamics Fundamentals with Applications; 1 Review of Basic Concepts; 1.1â#x80;#x82;The Continuum Mechanics Hypothesis; 1.2â#x80;#x82;Definitions, Fluid Properties, and Constitutive Equations; 1.2.1â#x80;#x82;Definitions; 1.2.2â#x80;#x82;Thermodynamic Properties; 1.2.3â#x80;#x82;Constitutive Equations; 1.2.4â#x80;#x82;Stress Tensors and Stress Vectors; 1.2.5â#x80;#x82;Flux Vectors; 1.3â#x80;#x82;Derivation and Modeling Approaches; 1.3.1â#x80;#x82;Approaches to Problem Solving; 1.3.2â#x80;#x82;Derivation Techniques.
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1.3.3â#x80;#x82;Basic Flow Assumptions and their Mathematical Statements1.3.4â#x80;#x82;Closed versus Open Systems and Associated Flow Descriptions; 1.3.5â#x80;#x82;Material (or Stokes) Derivative; 1.4â#x80;#x82;Scale Analysis and Dimensionless Groups; 1.4.1â#x80;#x82;Examples of Scaling; 1.4.1.1â#x80;#x82;A Note on the Reynolds Number; 1.4.2â#x80;#x82;Non-Dimensionalization of Equations; 1.5â#x80;#x82;Homework Assignments; 1.5.1â#x80;#x82;Physical Insight; 1.5.2â#x80;#x82;Engineering Problems; 2 Conservation Laws with Illustrative Examples; 2.1â#x80;#x82;The Reynolds Transport Theorem; 2.1.1â#x80;#x82;Extended Cases; 2.1.2â#x80;#x82;Setting up the Reynolds Transport Theorem.
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2.2â#x80;#x82;Fluid-Mass Conservation: The Continuity Equation2.2.1â#x80;#x82;Fluid-Mass Conservation in Integral Form; 2.2.2â#x80;#x82;Continuity in Differential Form; 2.2.2.1â#x80;#x82;Differential Mass Balance; 2.3â#x80;#x82;Momentum Conservation Equations: Linear Momentum Transfer and Vorticity Transport; 2.3.1â#x80;#x82;The Momentum Equation in Integral Form; 2.3.2â#x80;#x82;Momentum Conservation in Differential Form; 2.3.2.1â#x80;#x82;The Equation of Motion; 2.3.2.2â#x80;#x82;Force Balance Derivation; 2.3.3â#x80;#x82;Special Cases of the Equation of Motion; 2.3.3.1â#x80;#x82;The Navierâ#x80;#x93;Stokes Equation; 2.3.3.2â#x80;#x82;Prandtlâ#x80;#x99;s Boundary-Layer Equations.
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2.3.3.3â#x80;#x82;Stokes Equation2.3.3.4â#x80;#x82;Euler Equation; 2.3.3.5â#x80;#x82;Bernoulli Equation; 2.3.3.5.1â#x80;#x82;Notes on Bernoulliâ#x80;#x99;s Equation; 2.3.4â#x80;#x82;Basic Examples of Linear Momentum Transfer; 2.3.5â#x80;#x82;Vorticity Dynamics; 2.3.5.1â#x80;#x82;Vorticity Vector and Fluid Circulation; 2.3.5.2â#x80;#x82;Vorticity Transport Equation; 2.3.5.3â#x80;#x82;Vortex-Line Straining; 2.3.5.4â#x80;#x82;Vorticity Diffusion; 2.3.5.5â#x80;#x82;Helicity; 2.4â#x80;#x82;Scalar Transport Equations: Energy and Species-Mass Conservation; 2.4.1â#x80;#x82;Macro-Scale Energy Balance; 2.4.2â#x80;#x82;The Convection-Diffusion Equation for Heat Transfer; 2.4.3â#x80;#x82;The Species Convection-Diffusion Equation.
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2.5â#x80;#x82;Homework Assignments2.5.1â#x80;#x82;Physical Insight; 2.5.2â#x80;#x82;Engineering Problems; 3 Incompressible Viscous Fluid Flow Applications; 3.1â#x80;#x82;Internal Laminar Flows; 3.1.1â#x80;#x82;Steady Fullyâ#x80;#x91;Developed Flows; 3.1.2â#x80;#x82;Near-Parallel Flows; 3.1.3â#x80;#x82;Forced Convection Heat Transfer; 3.1.3.1â#x80;#x82;Convection Heat Transfer Coefficient; 3.1.3.2â#x80;#x82;The Nusselt Number; 3.1.3.3â#x80;#x82;The Reynolds-Colburn Analogy; 3.1.4â#x80;#x82;Transient One-Dimensional Flows; 3.1.4.1â#x80;#x82;Stokesâ#x80;#x99; First Problem: Thin Shear-Layer Development; 3.1.4.2â#x80;#x82;Transient Pipe Flow; 3.2â#x80;#x82;External Laminar Flows; 3.2.1â#x80;#x82;Momentum Boundary-Layer Flow.
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3.2.1.1â#x80;#x82;Solution Methods for Flat-Plate Boundary-Layer Flows.
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| Abstract
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"Modern Fluid Dynamics, Second Edition provides up-to-date coverage of intermediate and advanced fluids topics. The text emphasizes fundamentals and applications, supported by worked examples and case studies. Scale analysis, non-Newtonian fluid flow, surface coating, convection heat transfer, lubrication, fluid-particle dynamics, microfluidics, entropy generation, and fluid-structure interactions are among the topics covered. Part A presents fluids principles, and prepares readers for the applications of fluid dynamics covered in Part B, which includes computer simulations and project writing. A review of the engineering math needed for fluid dynamics is included in an appendix."--Provided by publisher.
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| Subject
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Fluid dynamics.
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Fluid dynamics.
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| Subject
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TECHNOLOGY ENGINEERING-- Engineering (General)
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TECHNOLOGY ENGINEERING-- Reference.
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| Dewey Classification
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620.1/064
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| LC Classification
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TA357.K576 2018
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