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005 | 20240206090526.0 | ||
008 | 750407s1975 maua b 001 0 eng | ||
020 | _a0395186072 | ||
040 |
_aBUL _cBUL _dBUL _bEng _erda |
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082 | 0 | 0 |
_a620.106 _222 _bROB |
100 | 1 | _aRoberson, John A. | |
245 | 1 | 0 |
_aEngineering fluid mechanics / _cJohn A. Roberson and Clayton T. Crowe. |
260 |
_aBoston : _bHoughton Mifflin, _c[1975] |
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300 |
_ax, 520 p. : _bill.; _c24 cm. |
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500 | _aCONTENT CHAPTER ONE: INTRODUCTION 1.1 Fluids 1.2 Flow Classification 1.3 Historical Note 1.4 Significance of Fluid Mechanics CHAPTER TWO: FLUID PROPERTIES 2.1 Basic Units 2.2 System, Extensive, and Intensive Properties 2.3 Properties Involving the Mass or Weight of the Fluid 2.4 Properties Involving the Flow of Heat 2.5 Viscosity Etc. CHAPTER THREE: FLUID STATICS 3.1 Pressure 3.2 Pressure Variation with Elevation 3.3 Pressure Measurements 3.4 Hydrostatic Force on Plane Surface 3.5 Hydrostatic on Curved Surfaces Etc. CHAPTER FOUR: FLUIDS IN MOTION 4.1 Velocity and Flow Visualization 4.2 Rate of Flow 4.3 Acceleration 4.4 Basic Control-Volume Approach 4.5 Continuity Equation Etc. CHAPTER FIVE: PRESSURE VARIATION IN FLOWING FLUID 5.1 Basic Causes of Pressure Variation in a Flowing Fluid 5.2 Examples of Pressure Variation Resulting From Acceleration 5.3 The Bernoulli Equation 5.4 Application oif the Bernoulli Equation 5.5 Separation and Its Effect on Pressure Variation Etc. CHAPTER SIX: MOMENTUM PRINCIPLE 6.1 The Momentum Equation 6.2 Applications of the Momentum Equation 6.3 Moment-of- Momentum Equation CHAPTER SEVEN: ENERGY PRINCIPLE 7.1 Derivation of the Energy Equation 7.2 Discussion of the Energy Equation 7.3 Simplified Forms of the Energy Equation 7.4 Application of the Energy, Momentum, and Continuity Equations in Combination 7.5 Concept of the Hydraulic and Energy Grade Lines Etc. CHAPTER EIGHT: DIMENSIONAL ANALYSIS AND SIMILTUDE 8.1 The Need for Dimensional Analysis 8.2 Dimensions and Equations 8.3 The Buckingham II Theorem 8.4 Dimensional Analysis 8.5 Standard Dimensionless Numbers Etc. CHAPTER NINE: SURFACE RESISTANCE 9.1 Introduction 9.2 Surface Resistance with Uniform Laminar Flow 9.3 Qualitative Description of the Boundary Layer 9.4 Qualitative Relations for the Laminar Boundary Layer 9.5 Qualitative Relations for the Turbulent Boundary Layer CHAPTER TEN: FLOW IN CONDUCTS 10.1 Shear Stress Distribution Across a Pipe Section 10.2 Laminar Flow in Pipes 10.3 Criterion for Laminar or Tubulent Flow in Pipes 10.4 Turbulent Flow in Pipes 10.5 Flow at Pipe Inlets and Losses from Fittings Etc. CHAPTER 11: DRAG AND LIFT 11.1 Basic Considerations 11.2 Drag of Two-Dimensional Bodies 11.3 Vortex Shedding from Cylindrical Bodies 11.4 Effects of Streamlining 11.5 Drag of Axisymmetric and Three- Dimensional Bodies Etc. CHAPTER TWELVE: COMPRESSIBLE FLOW 12.1 Wave Propagation in Compressible Fluids 12.2 Mach-Number Relationships 12.3 Normal Shock Waves 12.4 Isentropic Compressible Flow Through a Duct with Varying Area 12.5 Compressible Flow in a Pipe with Friction CHAPTER THIRTEEN: FLOW MEASUREMENT 13.1 Instrument for the Measurement of Velocity and Pressure 13.2 Instruments and Procedures for Measurement of Flow Rate 13.3 Measurement in Compressible Flow CHAPTER FOURTEEN: TURBOMACHINERY 14.1 Propeller Theory 14.2 Axial-Flow Pumps 14.3 Radial- and Mixed-Flow Machines 14.4 Specific Speed 14.5 Suction Limitations of Pumps Etc. CHAPTER Fifteen: VARIED FLOW IN OPEN CHANNELS 15.1 Energy Relations in Op[en Channels 15.2 The Hydraulic Jump 15.3 Surge or Tidal Bore 15.4 Gradually Varied Flow in Open Channels | ||
504 | _aIncludes bibliographies and index p. 515-520 | ||
650 | 0 | _aFluid mechanics. | |
700 | 1 | _aCrowe, Clayton T. | |
942 |
_2ddc _cBO _h620.106 _i1 _kROB _m620.106 ROB |
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_c2133 _d2133 |