Waltham, Massachusetts ; ; Oxford, [England] : , : Gulf Professional Publishing, , 2015

©2015

0-12-802643-X

0-12-802505-0

1 online resource (289 p.)

622.3381

Drilling muds

Drilling muds - Additives

Drilling muds - Environmental aspects

Oil field chemicals

Inglese

Description based upon print version of record.

Includes bibliographical references at the end of each chapters and index.

Front Cover; Water-Based Chemicals and Technology for Drilling, Completion, and Workover Fluids; Copyright; Contents; Preface; How To Use This Book; Acknowledgments; Chapter I: General Aspects; 1. History; 2. Fields of Application for Water-Based Compositions; References; Chapter II: Drilling Fluids; 1. Classification of Muds; 2. Types of Water-based Drilling Fluids; 2.1. Freshwater Types; 2.2. Seawater Types; 2.3. Saturated Salt Water Types; 2.4. Calcium-Treated Types; 2.5. Potassium-Treated Types; 2.6. Low-solids Types; 2.7. Emulsified Types; 2.8. Inhibitive Types

2.8.1. Environmental Aspects2.9. Foamed Types; 2.10. Volcanic Ash Containing Types; 3. Special Additives for Drilling Fluids; 3.1. Rheology Control; 3.1.1. Compositions with Improved Thermal Stability; 3.1.2. Carboxymethyl Cellulose; 3.1.3. Quaternary Nitrogen Containing Amphoteric Water-Soluble Polymers; 3.1.4. Silicone Resins; 3.1.5. Friction Reducers; 3.1.6. Deflocculants; 3.1.7. Ferrous Sulfate; 3.1.8. Biopolymers; 3.1.9. Biodegradable Thinners; 3.1.10. High-Temperature Formulation; 3.1.11. Low-Temperature Formulation; 3.2. Fluid Loss

Control; 3.2.1. Membrane Formation; 3.2.2. Polydrill

3.2.3. Polymer of Monoallylamine3.2.4. Combination of Nonionic and Ionic Monomers; 3.2.5. Synthetic Polymeric Fibers; 3.2.6. Carboxymethylated Raw Cotton Linters; 3.2.7. Poly-anionic Cellulose; 3.2.8. Sulfonate; 3.2.9. Carboxymethyl Cellulose; 3.2.10. Hydroxyethyl Cellulose; 3.2.11. Starch; 3.2.12. Crosslinked Starch; 3.2.13. Pregelatinized Starch; 3.2.14. Gellan; 3.2.15. Humic Acid Derivates; 3.2.16. Sodium Metasilicate; 3.2.17. Active Filter Cake; 3.2.18. Acid Combination; 3.2.19. Latex; 3.2.20. Carbon Black; 3.2.21. Testing of Fluid Loss Additives; 3.3. Emulsifiers

3.3.1. Oleophilic Ethers3.3.2. AMPS Terpolymer; 3.4. Gas Hydrate Control; 3.5. Lubricants; 3.5.1. Basic Studies; 3.5.2. Biodegradable Olefin Isomers; 3.5.3. Fatty Acid Esters; 3.5.4. Silicate-Based Compositions; 3.5.5. Sulfonated Asphalt; 3.5.6. Graphite; 3.5.7. Paraffins; 3.5.8. Partial Glycerides; 3.5.9. Aminoethanols; 3.5.10. Polymeric Alcohols; 3.5.11. Fatty Acid Polyamine Salts; 3.5.12. Powder-form Lubricants; 3.5.13. Multiphase Lubricant Concentrates; 3.5.14. Filming Amines; 3.6. Density Control; 3.6.1. Ionic Liquids; 3.7. Shale Stabilization; 3.7.1. Shale-Erosion Behavior

3.7.2. Alkyl Ethoxylates3.7.3. Poly(acrylamide)s; 3.7.4. Quaternized Amine Derivatives; 3.7.5. Polymeric Nonionic Amines; 3.7.6. Poly(propyleneimine) Dendrimers; 3.7.7. Copolymer of Styrene and Maleic Anhydride ; 3.7.8. Anions with High Hydrodynamic Radius; 3.8. Corrosion Inhibitors; 3.8.1. Amido Amine Salts; 3.8.2. Boron Compounds; 3.8.3. Phenolic Corrosion Inhibitors; 3.9. Anti-accretion Additives; 4. Special Issues of Water-based Drilling Fluids; 4.1. Formation Damage; 4.2. Uintaite for Borehole Stabilization; 4.3. Clay Swelling Inhibitors; 4.4. Removing Solids

4.5. Removing Water-based Drilling Fluids from the Surfaces in a Wellbore

Oil and gas engineers today use three main factors in deciding drilling fluids: cost, performance, and environmental impact, making water-based products a much more attractive option. Water-Based Chemicals and Technology for Drilling, Completion, and Workover Fluids effectively delivers all the background and infrastructure needed for an oil and gas engineer to utilize more water-based products that benefit the whole spectrum of the well's life cycle. Helping to mitigate critical well issues such as formation damage, fluid loss control, and borehole repair, more operators demand to know the f