Description |
1 online resource (xiii, 660 pages) : illustrations |
Contents |
Cover -- Contents -- Preface -- Acknowledgments -- 1. INTRODUCTION -- 1.1 GENERAL INFORMATION -- 1.2 VISCOSITY UNITS AND CONVERSION -- 1.3 FLUID FLOW AND VISCOSITY -- 2. VISCOMETERS -- 2.1 CAPILLARY VISCOMETERS -- 2.1.1 THEORY -- 2.1.2 OSTWALD VISCOMETER -- 2.1.3 MODIFIED OSTWALD VISCOMETERS -- 2.1.4 SUSPENDED LEVEL VISCOMETERS FOR TRANSPARENT LIQUID -- 2.1.5 REVERSE FLOW VISCOMETERS -- 2.2 ORIFICE VISCOMETERS -- 2.2.1 RED WOOD VISCOMETER -- 2.2.2 ENGLER VISCOMETER -- 2.2.3 SAYBOLT VISCOMETER -- 2.2.4 FORD VISCOSITY CUP VISCOMETER -- 2.2.5 ZAHN VISCOSITY CUP -- 2.2.6 SHELL VISCOSITY CUP -- 2.3 HIGH TEMPERATURE, HIGH SHEAR RATE VISCOMETERS -- 2.4 ROTATIONAL VISCOMETERS -- 2.4.1 COAXIAL-CYLINDER VISCOMETER -- 2.4.2 CONE AND PLATE VISCOMETERS -- 2.4.3 CONI-CYLINDER VISCOMETER -- 2.4.4 ROTATING/PARALLEL DISK VISCOMETERS -- 2.5 FALLING BALL VISCOMETERS -- 2.5.1 FALLING SPHERE VISCOMETER FOR OPAQUE LIQUIDS -- 2.5.2 ROLLING BALL VISCOMETERS -- 2.5.3 FALLING CYLINDER VISCOMETERS -- 2.5.4 FALLING NEEDLE VISCOMETER -- 2.6 VIBRATIONAL VISCOMETERS -- 2.6.1 TUNING FORK TECHNOLOGY -- 2.6.2 OSCILLATING SPHERE -- 2.6.3 VIBRATING ROD -- 2.7 ULTRASONIC VISCOMETERS -- 2.8 SUMMARY -- 3. THEORIES OF VISCOSITY -- 3.1 THEORIES OF GAS VISCOSITY -- 3.2 THEORIES OF DENSE-GAS VISCOSITY -- 3.3 GAS AND LIQUID VISCOSITY THEORIES -- 3.4 PURE-LIQUID VISCOSITY THEORIES -- 3.4.1 THEORIES PROPOSED -- 3.4.2 SEMI-THEORETICAL MODELS -- 3.4.3 EMPIRICAL METHODS -- 3.5 SUMMARY -- 4. CORRELATIONS AND ESTIMATION OF PURE LIQUID VISCOSITY -- 4.1 EFFECT OF PRESSURE ON VISCOSITY OF LIQUIDS -- 4.1.1 LUCAS METHOD FOR THE EFFECT OF PRESSURE -- 4.1.2 NEURAL NETWORK APPROACHES FOR THE EFFECT OF PRESSURE -- 4.2 VISCOSITY AT SELECTED REFERENCE POINTS -- 4.2.1 LIQUID VISCOSITY AT THE CRITICAL POINT -- 4.2.2 LIQUID VISCOSITY AT THE NORMAL BOILING POINT -- 4.3 EFFECT OF TEMPERATURE -- 4.3.1 CORRELATION METHODS -- 4.3.2 ESTIMATION METHODS -- 4.4 COMPARISON OF SELECTED PREDICTION METHODS -- 4.4.1 COMPARISON OF PREDICTION CAPABILITIES OF SELECTED METHODS -- 4.4.2 INPUT REQUIREMENTS AND OTHER DETAILS OF THE SELECTED PREDICTION METHODS -- 4.5 SUMMARY -- 5. VISCOSITIES OF SOLUTIONS AND MIXTURES -- 5.1 VISCOSITIES OF SOLUTIONS -- 5.1.1 FALKENHAGEN RELATIONS -- 5.1.2 KERN RULE -- 5.1.3 DAVIS METHOD -- 5.1.4 DUHRING PLOT -- 5.1.5 SOLVATION/ASSOCIATION PRONE SOLUTIONS -- 5.2 VISCOSITIES OF FLUID MIXTURES -- 5.2.1 LEAN MIXTURE VISCOSITY -- 5.2.2 DENSE FLUID MIXTURE VISCOSITY -- 5.2.3 GAS AND LIQUID MIXTURE VISCOSITY -- 5.2.4 LIQUID MIXTURE VISCOSITY -- 5.3 ARTIFICIAL NEURAL NET APPROACH FOR POLAR LIQUID MIXTURES -- 5.4 LIQUID MIXTURE VISCOSITIES BY EMPIRICAL METHODS -- 5.4.1 KENDALL AND MONROE RELATION -- 5.4.2 ARRHENIUS EQUATION -- 5.4.3 PANCHENKOV EQUATION -- 5.4.4 ANALOGY WITH VAPOR-LIQUID EQUILIBRIA -- REIK METHOD -- 5.4.5 GRUNBERG -- NISSAN EQUATION --T$817 |
Summary |
Brings together viscosity data, experimental methods, theoretical, and correlation and predictive procedures. This book provides an understanding of why various methods are used for measuring viscosity of different types of liquids and why an experimental method is dependent on fluid characteristics, such as Newtonian or non-Newtonian fluids |
Bibliography |
Includes bibliographical references and indexes |
Notes |
Print version record |
In |
Springer e-books |
Subject |
Viscosity.
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Fluids.
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Viscosity
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viscosity.
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SCIENCE -- Mechanics -- Fluids.
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Ingénierie.
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Fluids
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Viscosity
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Form |
Electronic book
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ISBN |
9781402054822 |
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1402054823 |
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1402054815 |
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9781402054815 |
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1280817208 |
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9781280817205 |
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6610817200 |
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9786610817207 |
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