Thermal insulation. Mass transfer. Physi
β¦ LIBER β¦
π
Mass Transfers and Physical Data Estimation
β Scribed by Benallou, Abdelhanine
- Publisher
- John Wiley & Sons, Incorporated
- Year
- 2019
- Tongue
- English
- Leaves
- 215
- Category
- Library
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β¦ Synopsis
Many practical operations, such as environment depollution, blood dialysis or product purification, require matter transfer. With an emphasis on the aforementioned subjects, this book revisits the founding principles of materials transfer on the basis of Fick's first law, which constitutes the foundation of diffusional phenomena. Additionally, continuity equations translating the macroscopic balances of systems are established. These balances constitute Fick's second law, which can be applied to quantify the fluxes of matter transferred in each situation, provided physical data is available. To this end, Mass Transfers and Physical Data Estimation pays particular attention to methods of data estimation. Methods presented in this book are applied to several practical cases, such as diffusion in catalytic reactions or the reconstitution of cartilage in human bone joints.;Cover; Half-Title Page; Title Page; Copyright Page; Contents; Preface; Introduction; 1. Determination of Physical Data; 1.1. Introduction; 1.2. Estimating critical properties; 1.2.1. Estimating critical temperature; 1.2.2. Estimating critical pressure; 1.2.3. Estimating the critical volume: Benson correlation (Benson, 1948); 1.2.4. Estimating the critical compressibility factor; 1.3. Methods for estimating boiling temperature; 1.4. Methods for estimating density; 1.4.1. Estimating liquid densities; 1.5. Methods for estimating viscosity; 1.5.1. Estimating viscosities of pure liquids
β¦ Table of Contents
Cover
Half-Title Page
Title Page
Copyright Page
Contents
Preface
Introduction
1. Determination of Physical Data
1.1. Introduction
1.2. Estimating critical properties
1.2.1. Estimating critical temperature
1.2.2. Estimating critical pressure
1.2.3. Estimating the critical volume: Benson correlation (Benson, 1948)
1.2.4. Estimating the critical compressibility factor
1.3. Methods for estimating boiling temperature
1.4. Methods for estimating density
1.4.1. Estimating liquid densities
1.5. Methods for estimating viscosity
1.5.1. Estimating viscosities of pure liquids 1.5.2. Correlations for the viscosity of liquid mixtures1.5.3. Estimating gas viscosities
1.6. Methods for estimating specific heat
1.6.1. Heat capacities of petroleum oils
1.6.2. Heat capacities of petroleum vapors
1.6.3. Estimations for anthracite and bituminous coals
1.6.4. Heat capacities for cement, mortar and sand
1.6.5. Heat capacities of organic liquids
1.7. Estimating latent heat of vaporization
1.7.1. Rapid estimations
1.7.2. Calculating latent heat from critical data
1.7.3. Chen correlation
1.7.4. Calculations at different temperatures 1.10.6. Correlation of the Prandtl number1.10.7. Correlation for calculating the expansion coefficient
1.10.8. Correlation for calculating the saturating pressure
1.10.9. Correlation for calculating latent heat
1.11. Physical properties of air
1.11.1. Correlation of density
1.11.2. Heat capacity
1.11.3. Correlation of heat conductivity
1.11.4. Correlation of viscosity
1.11.5. Correlation of thermal diffusivity
1.11.6. Correlation of the Prandtl number
1.11.7. Correlation for calculating the expansion coefficient
2. Determinants and Parameters of Mass Transfer
2.1. Introduction 2.2. Relative transfer velocities2.2.1. Velocity relating to average mass velocity
2.2.2. Velocity relative to average molar velocity
2.3. Amount of matter transferred
2.4. Expressions of flux density
2.4.1. Total flux
2.4.2. Specific fluxes
2.5. Operations on diffusion flux densities
2.5.1. Total density as a function of the specific densities
2.5.2. Sum of mass densities with respect to v
2.5.3. Sum of molar flux densities with respect to v
2.5.4. Sum of mass flux densities with respect to a mobile reference frame at v
2.6. Relations between flux densities fi and ji
β¦ Subjects
Science;SCIENCE--Mechanics--Thermodynamics;Electronic books;SCIENCE -- Mechanics -- Thermodynamics
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