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1. Fundamentals of fluid mechanics [2013]
 Munson, Bruce Roy, 1940
 7th edition.  Hoboken, NJ : John Wiley & Sons, Inc., [2013]
 Description
 Book — 1 volume various pagings : ill. ; 29 cm.
 Summary

 Introduction
 1 Learning Objectives
 1 1.1 Some Characteristics of Fluids
 3 1.2 Dimensions, Dimensional Homogeneity, and Units
 4 1.2.1 Systems of Units
 7 1.3 Analysis of Fluid Behavior
 11 1.4 Measures of Fluid Mass and Weight
 11 1.5 Ideal Gas Law
 12 1.6 Viscosity
 14 1.7 Compressibility of Fluids
 20 1.8 Vapor Pressure
 23 1.9 Surface Tension
 24 1.10 A Brief Look Back in History
 27 1.11 Chapter Summary and Study Guide
 29 References
 30 Review Problems
 31 Conceptual Questions
 31 Problems
 31
 2 Fluid Statics
 40 Learning Objectives
 40 2.1 Pressure at a Point
 40 2.2 Basic Equation for Pressure Field
 42 2.3 Pressure Variation in a Fluid at Rest
 43 2.4 Standard Atmosphere
 49 2.5 Measurement of Pressure
 50 2.6 Manometry
 52 2.7 Mechanical and Electronic PressureMeasuring Devices
 57 2.8 Hydrostatic Force on a Plane Surface
 59 2.9 Pressure Prism
 65 2.10 Hydrostatic Force on a Curved Surface
 68 2.11 Buoyancy, Flotation, and Stability
 70 2.12 Pressure Variation in a Fluid with RigidBody Motion
 74 2.13 Chapter Summary and Study Guide
 79 References
 80 Review Problems
 80 Conceptual Questions
 81 Problems
 81
 3 Elementary Fluid DynamicsThe Bernoulli Equation
 101 Learning Objectives
 101 3.1 Newton's Second Law
 101 3.2 F  ma along a Streamline
 104 3.3 F  ma Normal to a Streamline
 108 3.4 Physical Interpretation
 110 3.5 Static, Stagnation, Dynamic, and Total Pressure
 113 3.6 Examples of Use of the Bernoulli Equation
 117 3.7 The Energy Line and the Hydraulic Grade Line
 131 3.8 Restrictions on Use of the Bernoulli Equation
 134 3.9 Chapter Summary and Study Guide
 139 References
 141 Review Problems
 141 Conceptual Questions
 141 Problems
 141
 4 Fluid Kinematics
 157 Learning Objectives
 157 4.1 The Velocity Field
 157 4.2 The Acceleration Field
 166 4.3 Control Volume and System Representations
 175 4.4 The Reynolds Transport Theorem
 176 4.5 Chapter Summary and Study Guide
 188 References
 189 Review Problems
 189 Conceptual Questions
 189 Problems
 190
 5 Finite Control Volume Analysis
 199 Learning Objectives
 199 5.1 Conservation of MassThe Continuity Equation
 200 5.2 Newton's Second LawThe Linear Momentum and MomentofMomentum Equations
 213 5.3 First Law of ThermodynamicsThe Energy Equation
 236 5.4 Second Law of ThermodynamicsIrreversible Flow
 253 5.5 Chapter Summary and Study Guide
 253 References
 254 Review Problems
 255 Conceptual Questions
 255 Problems
 255
 6 Differential Analysis of Fluid Flow
 276 Learning Objectives
 276 6.1 Fluid Element Kinematics
 277 6.2 Conservation of Mass
 282 6.3 Conservation of Linear Momentum
 288 6.4 Inviscid Flow
 292 6.5 Some Basic, Plane Potential Flows
 286 6.5.1 Uniform Flow
 300 6.5.2 Source and Sink
 301 6.5.3 Vortex
 303 6.5.4 Doublet
 306 6.6 Superposition of Basic, Plane Potential Flows
 308 6.7 Other Aspects of Potential Flow Analysis
 318 6.8 Viscous Flow
 319 6.9 Some Simple Solutions for Viscous, Incompressible Fluids
 321 6.10 Other Aspects of Differential Analysis
 331 6.11 Chapter Summary and Study Guide
 332 References
 333 Review Problems
 334 Conceptual Questions
 334 Problems
 334
 7 Dimensional Analysis, Similitude, and Modeling
 346 Learning Objectives
 346 7.1 Dimensional Analysis
 347 7.2 Buckingham Pi Theorem
 349 7.3 Determination of Pi Terms
 350 7.4 Some Additional Comments About Dimensional Analysis
 355 7.5 Determination of Pi Terms by Inspection
 359 7.6 Common Dimensionless Groups in Fluid Mechanics
 360 7.7 Correlation of Experimental Data
 364 7.8 Modeling and Similitude
 368 7.9 Some Typical Model Studies
 374 7.10 Similitude Based on Governing Differential Equations
 384 7.11 Chapter Summary and Study Guide
 387 References
 388 Review Problems
 388 Conceptual Questions
 389 Problems
 389
 8 Viscous Flow in Pipes
 400 Learning Objectives
 400 8.1 General Characteristics of Pipe Flow
 401 Developed Flow
 405 8.2 Fully Developed Laminar Flow
 407 8.3 Fully Developed Turbulent Flow
 416 8.4 Dimensional Analysis of Pipe Flow
 426 8.5 Pipe Flow Examples
 445 8.6 Pipe Flowrate Measurement
 459 8.7 Chapter Summary and Study Guide
 465 References
 467 Review Problems
 468 Conceptual Questions
 468 Problems
 468
 9 Flow Over Immersed Bodies
 480 Learning Objectives
 480 9.1 General External Flow Characteristics
 481 9.2 Boundary Layer Characteristics
 489 9.3 Drag
 512 9.3.1 Friction Drag
 513 9.4 Lift
 528 9.5 Chapter Summary and Study Guide
 541 References
 542 Review Problems
 543 Conceptual Questions
 543 Problems
 544
 10 OpenChannel Flow
 554 Learning Objectives
 554 10.1 General Characteristics of OpenChannel Flow
 555 10.2 Surface Waves
 556 10.3 Energy Considerations
 561 10.4 Uniform Depth Channel Flow
 566 10.5 Gradually Varied Flow
 575 10.6 Rapidly Varied Flow
 576 10.7 Chapter Summary and Study Guide
 589 References
 590 Review Problems
 591 Conceptual Questions
 591 Problems
 591
 11 Compressible Flow
 601 Learning Objectives
 601 11.1 Ideal Gas Relationships
 602 11.2 Mach Number and Speed of Sound
 607 11.3 Categories of Compressible Flow
 610 11.4 Isentropic Flow of an Ideal Gas
 614 11.5 Nonisentropic Flow of an Ideal Gas
 631 11.6 Analogy between Compressible and OpenChannel Flows
 655 11.7 TwoDimensional Compressible Flow
 657 11.8 Chapter Summary and Study Guide
 658 References
 661 Review Problems
 662 Conceptual Questions
 662 Problems
 662
 12 Turbomachines
 667 Learning Objectives
 667 12.1 Introduction
 668 12.2 Basic Energy Considerations
 669 12.3 Basic Angular Momentum Considerations
 673 12.4 The Centrifugal Pump
 675 12.5 Dimensionless Parameters and Similarity Laws
 688 12.6 AxialFlow and MixedFlow Pumps
 693 12.7 Fans
 695 12.8 Turbines
 695 12.9 Compressible Flow Turbomachines
 707 12.10 Chapter Summary and Study Guide
 713 References
 715 Review Problems
 715 Conceptual Questions
 715 Problems
 716 A Computational fluid dynamics
 725 B Physical Properties of Fluids
 737 C Properties of the U.S. Standard Atmosphere
 742 D Compressible Flow graphs For an Ideal Gas (k  1.4)
 744 Answers ANS1 Index I1 Video Index 000.
 (source: Nielsen Book Data)
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TA357 .M86 2013  Unknown 
2. Fundamentals of fluid mechanics [2009]
 6th ed.  Hoboken, NJ : Wiley, c2009.
 Description
 Book — 1 v. (various pagings) : ill. (some col.) ; 27 cm.
 Summary

The number one text in its field, "Fundamentals of Fluid Mechanics" is respected by professors and students alike for its comprehensive topical coverage, its varied examples and homework problems, its application of the visual component of fluid mechanics, and its strong focus on learning. The authors have designed their presentation to allow for the gradual development of student confidence in problem solving. Each important concept is introduced in simple and easytounderstand terms before more complicated examples are discussed.
(source: Nielsen Book Data)
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TA357 .M86 2009  Unknown 
 Fundamentals of fluid mechanics
 Munson, Bruce Roy, 1940 author.
 Eighth edition.  Hoboken, NJ : Wiley, [2016]
 Description
 Book — xxii, 777, 11 pages : illustrations ; 28 cm
 Summary

 Approximate Physical Properties of Some Common Liquids (BG Units)
 Introduction
 Fluid Statics
 Elementary Fluid DynamicsThe Bernoulli Equation
 Fluid Kinematics
 Finite Control Volume Analysis
 Differential Analysis of Fluid Flow
 Dimensional Analysis, Similitude, and Modeling
 Viscous Flow in Pipes
 Flow over Immersed Bodies
 OpenChannel Flow
 Compressible Flow
 Turbomachines
 Appendix A: Computational Fluid Dynamics
 Appendix B: Physical Properties of Fluids
 Appendix C: Properties of the U.S. Standard Atmosphere
 Appendix D: Compressible Flow Functions for an Ideal Gas
 Appendix E: Comprehensive Table of Conversion Factors
 Answers to Selected Homework Problems
 Index
 Figure 8.20 Friction factor as a function of Reynolds number and relative roughness for round pipesthe Moody chart.
 Online
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On order  
(no call number)  Unavailable On order Request 
 Chhabra, R. P.
 2nd ed.  Boca Raton, FL : CRC Taylor & Francis, c2007.
 Description
 Book — 771 p. : ill. ; 24 cm.
 Online
Science Library (Li and Ma)
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QC189.5 .C55 2007  Unknown 
 Barenblatt, G. I., author.
 Cambridge : Cambridge University Press, 2014.
 Description
 Book — xix, 255 pages : illustrations (some color) ; 26 cm.
 Summary

 Foreword Alexandre J. Chorin Preface Introduction
 1. Idealized continuous media: the basic concepts
 2. Dimensional analysis and physical similitude
 3. The ideal incompressible fluid approximation. General concepts and relations
 4. The ideal incompressible fluid approximation. Analysis and applications
 5. The approximation of a linear elastic solid. Basic equations and boundary value problems of linear theory of elasticity
 6. Approximation of a linear elastic body. Applications: brittle and quasibrittle fracture, strength of structures
 7. The approximation of Newtonian viscous fluids: general comments and basic relations
 8. Approximation of a Newtonian viscous fluid: the boundary layer
 9. Advanced similarity methods: complete and incomplete similarity
 10. The ideal gas approximation. Sound waves. Shock waves
 11. Turbulence. Generalities. Scaling laws for shear flows
 12. Turbulence. Mathematical models of turbulent shear flows and of the local structure of turbulent flows at very large Reynolds numbers Bibliography Index.
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Science Library (Li and Ma)
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QA901 .B37 2014  Unknown 
 Pert, G. J. (Geoffrey J.)
 Chichester, West Sussex, United Kingdom : John Wiley & Sons Ltd., [2013]
 Description
 Book — xx, 468 pages : illustrations ; 26 cm
 Summary

 Preface xvii
 1 Introduction
 1
 2 Flow of Ideal Fluids
 25
 3 Viscous Fluids
 75
 4 Waves and Instabilities in Fluids
 93
 5 Turbulent Flow
 117
 6 Boundary Layer Flow
 139
 7 Convective Heat Transfer
 175
 8 Compressible Flow and Sound Waves
 209
 9 Characteristics and Rarefactions
 219
 10 Shock Waves
 241
 11 Aerofoils in LowSpeed Incompressible Flow
 295
 12 Aerofoils in HighSpeed Compressible Fluid Flow
 341
 13 Deflagrations and Detonations
 363
 14 Selfsimilar Methods in Compressible Gas Flow and Intermediate Asymptotics
 383 Problems
 417 Solutions
 427 Bibliography
 455 Index 463.
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 Online
Engineering Library (Terman)
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QC145.2 .P47 2013  Unknown 
 Leal, L. Gary.
 Cambridge ; New York : Cambridge University Press, 2007.
 Description
 Book — xix, 912 p. : ill.
 Leal, L. Gary.
 Cambridge ; New York : Cambridge University Press, 2007.
 Description
 Book — xix, 912 p. : ill. ; 27 cm.
 Summary

 1. A preview
 2. Basic principles
 3. Unidirectional and onedimensional flow and heat transfer processes
 4. An introduction to asymptotic approximations
 5. The thin gap approximation  lubrication problems
 6. The thin gap approximation  films with a free surface
 7. Creeping flow  general properties and solutions for 2D and axisymmetric problems
 8. Creeping flow  3D problems
 9. Convection effects and heat transfer for viscous flows
 10. Boundary layer theory for laminar flows
 11. Heat and mass transfer at large Reynolds number
 12. Hydrodynamic stability Appendix A. Governing equations and vector operations in cartesian, cylindrical and spherical coordinate systems Appendix B. Cartesian component notation.
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Science Library (Li and Ma)
Science Library (Li and Ma)  Status 

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QC145.2 .L43 2007  Unknown 
9. HydroUmformung [electronic resource] [2008]
 Berlin : Springer, 2008.
 Description
 Book — xiv, 312 p. : ill.
10. Advanced fluid mechanics [2007]
 Graebel, W. P.
 Burlington, MA : Academic Press, ©2007.
 Description
 Book — 1 online resource (xv, 362 pages) : illustrations
 Summary

 Chapter 1 Fundamentals
 Chapter 2 Inviscid Irrotational Flows
 Chapter 3 Irrotational TwoDimensional Flows
 Chapter 4 Surface and Interfacial Waves
 Chapter 5 Exact Solutiona of the NavierStokes Equations
 Chapter 6 The Boundary Layer Approximation
 Chapter 7 Thermal Effects
 Chapter 8 Low Reynolds Number Flows
 Chapter 9 Flow Stability
 Chapter 10 Turbulence and Transition to Turbulance
 Chapter 11 An Introduction to Computational Fluid Dynamics
 Chapter 12 Numerical Solution of Partial Differential Equations Appendix Mathematical Aids References Index.
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(source: Nielsen Book Data)
11. Hydrodynamique : problèmes corrigés [2010]
 Leblanc, Stéphane.
 Les Ulis : EDP Sciences, ©2010.
 Description
 Book — 1 online resource (x, 100 pages) : illustrations.
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