多孔質体における混相流 Essentials of Multiphase Flow in Porous Media

多孔質体における混相流<br>Essentials of Multiphase Flow in Porous Media

個数：

多孔質体における混相流
Essentials of Multiphase Flow in Porous Media

Pinder, George F./ Gray, William G.

ウェブストア価格 ¥33,382（本体¥30,348）
Wiley-Interscience（2008/08発売）
外貨定価 US$ 166.95
ポイント 303pt

提携先の海外書籍取次会社に在庫がございます。通常3週間で発送いたします。
【重要ご説明事項】
1. 納期遅延や、ご入手不能となる場合が若干ございます。
2. 複数冊ご注文の場合は、ご注文数量が揃ってからまとめて発送いたします。
3. 美品のご指定は承りかねます。

●3Dセキュア導入とクレジットカードによるお支払いについて

【入荷遅延について】
世界情勢の影響により、海外からお取り寄せとなる洋書・洋古書の入荷が、表示している標準的な納期よりも遅延する場合がございます。
おそれいりますが、あらかじめご了承くださいますようお願い申し上げます。

◆画像の表紙や帯等は実物とは異なる場合があります。

◆ウェブストアでの洋書販売価格は、弊社店舗等での販売価格とは異なります。
また、洋書販売価格は、ご注文確定時点での日本円価格となります。
ご注文確定後に、同じ洋書の販売価格が変動しても、それは反映されません。

製本 Hardcover:ハードカバー版／ページ数 257 p.
言語 ENG
商品コード 9780470317624
DDC分類 624.1513

Full Description

Learn the fundamental concepts that underlie the physics of multiphase flow and transport in porous media with the information in Essentials of Multiphase Flow in Porous Media, which demonstrates the mathematical-physical ways to express and address multiphase flow problems. Find a logical, step-by-step introduction to everything from the simple concepts to the advanced equations useful for addressing real-world problems like infiltration, groundwater contamination, and movement of non-aqueous phase liquids. Discover and apply the governing equations for application to these and other problems in light of the physics that influence system behavior.

1. Setting the Stage. 1.1 Introduction.

1.2 Phases and Porousmedia.

1.3 Grain and Pore Size Distributions.

1.4 The Concept of Saturation.

1.5 The Concept of Pressure.

1.6 Surface Tension Considerations.

1.7 Concept of Concentration.

1.8 Summary.

1.9 Exercises.

2. Mass Conservation Equations.

2.1 Introduction.

2.2 Microscalemass Conservation.

2.3 Integral Forms Ofmass Conservation.

2.4 Integral Theorems.

2.4.1 Divergence Theorem.

2.4.2 Transport Theorem.

2.5 Point Forms Ofmass Conservation.

2.6 Themacroscale Perspective.

2.6.1 The Representative Elementary Volume.

2.6.2 Global and Local Coordinate Systems.

2.6.3 Macroscopic Variables.

2.6.4 Definitions Of Macroscale Quantities.

2.6.5 Summary Of Macroscale Quantities.

2.7 The Averaging Theorems.

2.7.1 Spatial Averaging Theorem.

2.7.2 Temporal Averaging Theorem.

2.8 Macroscalemass Conservation.

2.8.1 Macroscale Point Forms.

2.8.2 Integral Forms.

2.9 Applications.

2.9.1 Integral Analysis.

2.9.2 Point Analysis.

2.10 Summary.

2.11 Exercises.

3. Flow Equations.

3.1 Introduction.

3.2 Darcy'S Experiments.

3.3 Fluid Properties.

3.4 Equations of State for Fluids.

3.4.1 Mass Fraction.

3.4.2 Mass Density and Pressure.

3.4.3 Fluid Viscosity.

3.5 Hydraulic Potential.

3.5.1 Hydrostatic Force and Hydraulic Head.

3.5.2 Derivatives of Hydraulic Head.

3.6 Single Phase Fluid Flow.

3.6.1 Darcy'S Law.

3.6.2 Hydraulic Conductivity and Permeability.

3.6.3 Derivation of Groundwater Flow Equation.

3.6.4 Recapitulation of the Derivation.

3.6.5 Initial and Boundary Conditions.

3.6.6 Two-Dimensional Flow.

3.7 Two-Phase Immiscible Flow.

3.7.1 Derivation of Flowequations.

3.7.2 Observations on the Pc - Sw Relationship.

3.7.3 Formulas for The Pc - Sw Relationship.

3.7.4 Observations of the Kà Rel - Sw Relationship.

3.7.5 Formulas for the Kà Rel - Sw Relation.

3.7.6 Special Cases of Multiphase Flow.

3.8 The Buckley-Leverett Analysis.

3.8.1 Fractional Flow.

3.8.2 Derivation of the Buckley-Leverett Equation.

3.8.3 Solution of the Buckley-Leverett Equation.

3.9 Summary.

3.10 Exercises.

4. Mass Transport Equations.

4.1 Introduction.

4.2 Velocity in the Species Transport Equations.

4.2.1 Direct Approach.

4.2.2 Rigorous Approach.

4.2.3 Distribution Approach.

4.2.4 Summary.

4.3 Closure Relations for the Dispersion Vector.

4.4 Chemical Reaction Rates.

4.5 Interphase Transfer Terms.

4.5.1 Kinetic Formulation.

4.5.2 Equilibriumformulation.

4.5.3 Summary: Kinetic Vs. Equilibrium Formulations.

4.6 Initial and Boundary Conditions.

4.7 Conclusion.

4.8 Exercises.

5. Simulation.

5.1 1-D Simulation of Air-Water Flow.

5.1.1 Drainage in a Homogeneous Soil.

5.1.2 Drainage in a Heterogeneous Soil.

5.1.3 Imbibition in Homogeneous Soil.

5.2 1-D Simulation of Dnapl-Water Flow.

5.2.1 Primary Dnapl Imbibition In Homogeneous Soil.

5.2.2 Density Effect.

5.2.3 Dnapl Drainage in Homogeneous Soil.

5.2.4 Secondary Imbibition of Dnapl in Homogeneous Soil.

5.2.5 Secondary Drainage in Homogeneous Soil.

5.2.6 Primary Imbibition in Heterogeneous Soil.

5.3 2-D Simulation of Dnapl-Water Flow.

5.3.1 Dnapl Descent into a Water-Saturated Reservoir.

5.4 Simulation Of Multiphase Flow And Transport.

5.4.1 1-D Two-Phase Flow and Transport.

5.4.2 2-D Two-Phase Flow and Transport.

5.5 2-D Single-Phase Flow and Transport.

5.5.1 Base-Case.

5.5.2 Effect of Inflow.

5.5.3 Impactofwell Discharge.

5.5.4 Effect of Adsorption.

5.5.5 Effect of a Low Transmissivity Region.

5.5.6 Effect of a High Transmissivity Region.

5.5.7 Effect of Rate of Reaction.

5.6 3-D Single-Phase Flow and Transport.

5.7 2-D Three-Phase Flow.

5.8 Summary.

6. Select Symbols.