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2020-01-21 14:49 來源：京東作者：京東

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內容簡介:　　《油氣井工程多相流動（英文版）》為油氣鉆采井筒中的復雜多相流動分析和計算難題提供了解決方案，闡述了多相流計算中所涉及的流型轉化機理、流型判別準則、多相流動模型等。通過《油氣井工程多相流動（英文版）》七個部分的學習，讀者可以逐步認識考慮油一氣以及水合物相變的多相流動模型，了解該模型在陸地和海洋鉆井井簡壓力控制水力參數(shù)設計和計算中的應用情況。另外，多相流動模型在欠平衡鉆井（主要包括氣體鉆井、環(huán)空注氣鉆井、立管充氣鉆井、低密度鉆井液鉆井等）中的應用也在本書中有所討論。
　　●針對鉆井中酸性氣體氣侵和水合物的相變等問題給出了新的研究結果。
　　●完善了多相流動理論，改進了油氣鉆采過程中復雜多相流動計算模型，展現(xiàn)了石油工程基礎理論研究一個熱點方向的新成果。
　　●本書作者是書中多相流動模型和氣液流型轉化機理的主要完成人。

作者簡介:

目錄:Preface
Chapter 1 Introduction
1．1 Multiphase Flow in the Well
1．2 Methods
1．2．1 Theoretical Analysis
1．2．2 Experimental Study
1．2．3 Numerical Simulation
1．3 Parameters
1．4 Multiphase Flow Patterns
1．4．1 Flow Patterns of Gas-Liquid Flow
1．4．2 Gas-Liquid Flow Pattern of Acid Gas Under Supercritical Condition
1．5 Multiphase Flow Models
1．5．1 Homogeneous Flow Model
1．5．2 Separated Flow Model
1．5．3 Drift-Flux Model
1．5．4 Statistical Average Model

Chapter 2 The Void Fraction Wave and Flow Regime Transition
2．1 Introduction
2．1．1 Bubble Coalescence and Flow Regime Transition
2．1．2 Void Fraction Wave and Flow Regime Transition
2．2 Experimental Setup and Methods
2．2．1 Experimental Setup
2．2．2 Observation and Determination of Flow Regimes
2．2．3 Flow Resistance Measurement
2．2．4 Flow Rate and Void Fraction Wave Measurement
2．2．5 Data Processing
2．3 Formation Mechanism of Slug Flow with Low Continuous Phase Velocity
2．3．1 Flow Regime Transition
2．3．2 Analytical Method
2．3．3 Experimental Results
2．3．4 Discussion on the Instability of Void Fraction Wave and Formation Mechanism of Taylor Bubble
2．3．5 Propagation Velocity of Void Fraction Wave
2．4 Gas-Liquid Flow Regime Transition with High Continuous Phase Velocity
2．4．1 Flow Regime Transition
2．4．2 Experimental Results and Discussions
2．4．3 Mechanism of Losing Stability for Bubbly Flow
2．4．4 Velocity of Void Fraction Wave
2．4．5 Non-Linear Properties of the Void Fraction Wave

Chapter 3 Mnltiphase Flow Model for Well Drilling
3．1 Continuity Equation
3．1．1 Continuity Equation in the Annulus
3．1．2 Continuity Equation in the Drilling Stem
3．2 Momentum Equation
3．2．1 Momentum Equation in the Annulus
3．2．2 Momentum Equation in the Drilling Stem
3．3 Energy Equation
3．3．1 Energy Equation in the Annulus
3．3．2 Energy Equation in the Drilling Stem
3．4 Applications of the Model
3．4．1 Underbalanced Drilling
3．4．2 Kicking and Killing
3．4．3 Kicking and Killing Afier Acid Gas Influx
3．4．4 Kicking and Killing for Deepwater Drilling

Chapter 4 Mnltiphase Flow During Underbalanced Drilling
4．1 Flow Model
4．1．1 Flow-Governing Equations in the Annulus
4．1．2 Flow-Governing Equations in the Drilling Stem
4．1．3 Energy Equations
4．1．4 Auxiliary Equations
4．2 Solving Processing
4．2．1 Definite Conditions
4．2．2 Discretization of the Model
4．2．3 Algorithms
4．3 Case Study
4．3．1 Gas Drilling
4．3．2 Drill Pipe Injection-Aerated Drilling
4．3．3 Annulus Injection-Aerated Drilling

Chapter 5 Multiphase Flow During Kicking and Killing
5．1 Common Killing Method
5．1．1 Killing Parameters of Driller's Method and Wait and Weight Method
5．1．2 The Circulate-and-Weight Method
5．2 Multiphase Flow Model
5．2．1 Governing Equations for Killing
5．2．2 Governing Equation for Kicking
5．2．3 Auxiliary Equations
5．3 Solving Process
5．3．1 Definite Conditions
5．3．2 Discretization of the Model
5．3．3 Algorithms
5．4 Case Study
5．4．1 Basic Parameters of the Well
5．4．2 Simulations of Overflow
5．4．3 Hydraulic Parameters for Killing

Chapter 6 Multiphase Flow During Kicking and Killing with Acid Gas
6．1 Flow Model
6．1．1 Flow Governing Equations for Killing Acid Gas Kicking
6．1．2 Flow Governing Equations for Acid Gas Kicking
6．1．3 Auxiliary Equations
6．2 The Solving Process
6．2．1 Definite Conditions
6．2．2 Algorithms
6．3 Simulations and Case Study
6．3．1 Basic Parameters of the Well
6．3．2 Acid Gas Compressibility and Density in the Wellbore
6．3．3 Acid Gas Solubility in the Wellbore
6．3．4 Acid Gas Expansion in the Wellbore
6．3．5 Impact on the Pit Gain

Chapter 7 Multiphase Flow During Kicking and Killing in Deepwater Drilling
7．1 Common Deepwater Killing Method
7．1．1 Dynamic Killing Method
7．1．2 Advanced Driller's Method
7．1．3 Additional Flow Rate Method
7．2 Flow Model
7．2．1 Governing Equations for Deepwater Well Killing
7．2．2 Governing Equations for Kicking
7．2．3 Auxiliary Equations
7．3 The Solving Process
7．3．1 Definite Conditions
7．3．2 Algorithms
7．4 Case Study
7．4．1 Basic Parameters of the Well
7．4．2 Simulations of Kicks and Blowout
7．4．3 Simulation of the Killing Process
References
Author Index
Subject Index

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