Synopses & Reviews
The mechanics of fluid flow is one of the most important fundamental engineering disciplines explaining both natural phenomena and human-induced processes. A group of some of the best-known petroleum engineers in the world give a thorough understanding of this important field, central to the operations of the oil and gas industry.
The mechanics of fluid flow, specifically gas, oil, and water, is a fundamental engineering discipline explaining various natural phenomena and human-induced processes. It is of utmost importance in aviation, shipbuilding, petroleum industries, thermodynamics, meteorology, and chemical engineering. This basic applied scientific discipline enables one to understand and describe mathematically the movement of fluids (gas, oil, water) in various media: channels, subsurface formations, pipelines, etc. To describe various phenomena and applications associated with fluid dynamics, the writers used the unified systematic approach based on the continuity and conservation laws of continuum mechanics.
There have been many books written on the basics of fluid flow or fluid mechanics, but this volume, written by some of the most well-respected engineers and scientists in the oil and gas industry, is the first of its kind to apply these fundamental concepts to problems encountered in the petroleum industry at this level of detail.
Mathematical description of specific applied problems and their solutions are presented in the book, as well as the concepts behind them, both traditional and newly conceived ideas that will be of use to scientists and students alike. This book can be used as a textbook by the university student, or as a handbook for the engineer or scientist in the field.
This groundbreaking new volume includes:
- More efficient oil & gas production for the petroleum engineer and petroleum geologist
- More accurate forecasting for the environmental engineer
- Real-world examples for the engineering student
- Valuable new information not available anywhere else
The mechanics of fluid flow is a fundamental engineering discipline explaining both natural phenomena and human-induced processes, and a thorough understanding of it is central to the operations of the oil and gas industry. This book, written by some of the world’s best-known and respected petroleum engineers, covers the concepts, theories, and applications of the mechanics of fluid flow for the veteran engineer working in the field and the student, alike. It is a must-have for any engineer working in the oil and gas industry.
About the Author
Kaplan S. Basniev, PhD,
is a well-known specialist in the oil and gas industry with over 50 years of experience. He has held numerous high-level positions in the field throughout his career, including heading the Oil and Gas Section of the Russian Academy of Natural Sciences for 15 years. He has 240 publications, 15 monographs, and numerous medals and awards to his name.
Nikolay M. Dmitriev, PhD, is a specialist in the area of fluid flow with many years of experience and publications under his belt. He is the head of the Department of International Education and Cooperation at the Ministry of Education and Science of the Russian Federation.
George V. Chilingar, PhD, is an Emeritus Professor of Engineering at the University of Southern California, Los Angeles. He is one of the most well-known petroleum geologists in the world and the founder of several prestigious journals in the oil and gas industry. He has published over 70 books and 500 articles and has received over 100 awards over his career.
Table of Contents
Part I. Fundamentals of the Mechanics of Continua 15
I. Basic Concepts of the Mechanics of Continua 15
II. Conservation Laws. Integral and Differential Equations of Continuous Medium 27
III. Continuous Medium Deformation Rate 45
IV. Liquids 57
V. Basics of the Dimensionality and Conformity Theory 73
Part II. Hydromechanics 91
VI. Hydrostatics 91
VII. Flow of Ideal Fluid 105
VIII. Parallel-Plane Flows of Ideal Incompressible Fluid 135
IX. Flow of Viscous Incompressible Fluid in Prismatic Tubes 153
X. Turbulent Flow of Fluids in Pipes 165
XI. Hydraulic Calculation for Pipelines 179
XII. Fluid’s Outflow from Orifices and Nozzles 191
XIII. Non-Stationary Flow of Viscous Fluid in Tubes 201
XIV. Laminar Boundary Layer 233
XV. Unidimensional Gas Flows 243
XVI. Laminar Flow of Non-Newtonian Fluids 277
XVII. Two-Phase Flow in Pipes 299
Part III. Oil and Gas Subsurface Hydromechanics 317
XVIII. Main Definitions and Concepts of Fluid and Gas Flow, Darcy’s Law and Experiment 317
XIX. Mathematical Models of Uniphase Filtration 345
XX. Unidimensional Transient-Free Filtration of Incompressible Fluid and Gas in an Uniform Porous Medium 363
XXI. Unidemensional Filtration of Incompressible Liquid and Gas in a Nonuniform Reservoirs Under Darcy’s Law 395
XXII. Flat Transient-Free Filtration Flows 409
XXIII. Non-Stationary Flow of an Elastic Fluid in an Elastic Reservoir 427
XXIV. Non-Stationary Flow of Gas in a Porous Medium 469
XXV. Filtration of Non-Newtonian Liquid 489
XXVI. Liquid and Gas Flow in Fractured and Fractured-Porous Media 513
Appendix A 537
Subject Index 565