Computational elastohydrodynamics, a part of tribology, has existed happily enough for about fifty years without the use of accurate models for the rheology of the liquids used as lubricants. For low molecular weight liquids, such as low viscosity mineral oils, it has been possible to calculate, with precision, the film thickness in a concentrated contact provided that the pressure and temperature are relatively low, even when the pressure variation of viscosity is not accurately modelled in detail. Other successes have been more qualitative in nature, using effective properties which come from the fitting of parameters used in calculations to experimental measurements of the contact behaviour, friction or film thickness.
High Pressure Rheology for Quantitative Elastohydrodynamics is intended to provide a sufficiently accurate framework for the rheology of liquids at elevated pressure that it may be possible for computational elastohydrodynamics to discover the relationships between the behaviour of a lubricated concentrated contact and the measurable properties of the liquid lubricant. The required high-pressure measurement techniques are revealed in detail and data are presented for chemically well-defined liquids that may be used as quantitative reference materials.
* Presents the property relations required for a quantitative calculation of the tribological behaviour of lubricated concentrated contacts.
* Details of high-pressure experimental techniques.
* Complete description of the pressure and temperature dependence of viscosity for high pressures.
* Some little-known limitations on EHL modelling.
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1.2 Concentrated Contact Lubrication
1.3 Full Elastohydrodynamic Lubrication
1.4 Experimental Elastohydrodynamics
Chapter 2. An Introduction to the Rheology of Polymeric Liquids
2.2 The Newtonian Model
2.3 Material Functions for Polymeric Liquids
2.4 Rheological Models
2.5 Time-Temperature-Pressure Superposition
2.6 Liquid Failure
Chapter 3. General High-Pressure Experimental Techniques
3.2 Pressure Containment
3.5 Pressure Generation and Measurement
3.6 Hydrostatic Media and Volume Compensation
Chapter 4. Compressibility and the Equation of State
4.2 PVT Measurement Techniques and Results
4.3 Empirical Equations of State
Chapter 5. The Pressure and Temperature Dependence of the Low-Shear Viscosity
5.2 High-Pressure Viscometers
5.3 General Pressure-Viscosity Response and Results for Pure Organic Liquids and Lubricants
Chapter 6. Models for the Temperature and Pressure Dependence of the Low-Shear Viscosity
6.2 Models for the Temperature-Viscosity Response
6.3 Pressure Fragility and Empirical Models for High Pressure Behavior
6.4 The Pressure-Viscosity Coefficient and Empirical Models for Low Pressure Behavior
6.5 Empirical Models for Large Pressure Intervals
6.6 Models Based on Free Volume Theory
6.7 Generalized Temperature-Pressure-Viscosity Models
6.8 Multi Component Systems
Chapter 7. Measurement Techniques for the Shear Dependence of Viscosity at Elevated Pressure
7.2 Phenomena Producing Behavior Similar to Shear-Thinning
7.3 Rheometers for High Pressure
Chapter 8. The Shear Dependence of Viscosity at Elevated Pressure
8.2 Normal Stress Differences at Elevated Pressures
8.3 The Origin of Non-Newtonian Behavior in Low-Molecular-Weight Liquids at Elevated Pressures
8.4 Time-Temperature-Pressure Superposition
8.5 The Competition between Thermal Softening and Shear-Thinning
8.6 Multi Component Systems
8.7 The Power-Law Exponent and the Second Newtonian Viscosity
Chapter 9. Glass Transition and Related Transitions in Liquids under Pressure
9.1 Measurements of Glass Transition at Elevated Pressure
9.2 Measurements of Dielectric Transition at Elevated Pressure
9.3 The Transitions as Isoviscous States
9.4 The Pressure Variation of Viscosity across the Transition
Chapter 10. Shear Localization, Slip and the Limiting Stress
10.2 Measurements of Rate Independent Shear Stress
10.3 Flow Visualization of Shear Bands
10.4 Mohr-Coulomb Failure Criterion
10.5 Change of Character of the Piezoviscous Navier-Stokes Equations
10.6 Thermal Localization, Adiabatic Shear Bands
10.7 Interfacial Slip
Chapter 11. The Reynolds Equation
11.2 Reynolds Equations for Generalized Newtonian Fluids
Chapter 12. Applications to Elastohydrodynamics
12.2 Film Thickness for Shear Thinning Liquids
12.3 The Calculation of Traction from Material Properties
Scott Bair received his Ph.D. in mechanical engineering and is currently a Principal Research Engineer and Director at the Center for High-Pressure Rheology at the Georgia Institute of Technology, USA. In 2009, he was the recipient of the International Award for the highest honor given by the Society of Tribologists and Lubrication Engineers. His main research areas are tribology, rheology, properties of liquids at high pressure, and machine design.