An edition of Exercises in Drilling Fluid Engineering
(2013)
Exercises in Drilling Fluid Engineering
by Pål Skalle
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Last edited by Alice Kirk
June 5, 2015 | History
This book presents how to apply fluid mechanics on drilling fluid related challenges and explains the related physics involved and the different engineering approaches. Mud has many functions, the single most important one is to remove the cuttings a) away from under the bit and b) transport them from the bottom to the surface. Viscosity of drilling fluids is not a constant parameter; it varies with shear rate.
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Publish Date
2013
Publisher
Bookboon.com
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Book Details
Table of Contents
Content
1. Fluid Properties
1.1. Filtration control
1.2. Filtration control
1.3. Density control
1.4. Density control
1.5. Rheology control
1.6. Rheology control
1.7. Flocculation
1.8. Mud contamination
1.9. Flocculation
1.10. Fluid additives
1.11. Fluid additives
2. Rheological models
2.1. Bingham/ Power law
2.2. Bingham/Power-law
2.3. Bingham / Power-law. Regression
2.4. Effective viscosity
2.5. All models
2.6. All models. Regression
2.7. All models
3. Drilling fluid dynamics
3.1. Velocity profile. Continuity equation
3.2. Velocity profile. Momentum flux
3.3. Velocity profile
3.4. Pressure loss vs. rheology
3.5. Pressure loss vs. rheology
3.6. Pressure loss. Power-law
3.7. Pressure loss. Turbulent. Energy equation
3.8. Pressure loss vs. flow rate
3.9. Pressure loss. Field data
3.10. Pressure loss. Effect of rotation
3.11. Pressure loss. Bit nozzles. OFU
3.12. Swab pressure. Cling factor
4. Hydraulic program
4.1. Mud pump issues
4.2. Optimal nozzles? Section wise
4.3. Liner selection. Section wise
4.4. Hydraulic program. Section wise
4.5. Optimal parameters for BHHP. OFU. Section wise
4.6. Liner selection. Complete well
4.7. Liner selection. Complete well
5. Well challenges
5.1. Cuttings concentration
5.2. Cuttings concentration
5.3. ECD. Barite
5.4. ECD. Fluid and flow
5.5. Water activity
5.6. Shale stability
5.7. Wellbore problem
6. Supportive Information
6.1. Pump (National 12-P-160) and hydraulic program data
6.2. Pressure loss equations
6.3. Conversion factors and formulas
7. Solutions To Exercises In Drilling Fluid Engineering
8. Fluid Properties – Solutions
8.1. Filtration control
8.2. Filtration control
8.3. Density control
8.4. Density control
8.5. Rheology control
8.6. Rheology control
8.7. Flocculation
8.8. Mud contamination
8.9. Flocculation
8.10. Fluid additives
8.11. Fluid additives
9. Rheological models – Solutions
9.1. Bingham / Power-law
9.2. Bingham / Power-law
9.3. Bingham / Power-law. Regression
9.4. Effective viscosity
9.5. All models
9.6. All models. Regression
9.7. All models
10. Drilling fluid dynamics – Solutions
10.1. Velocity profile. Continuity equation
10.2. Velocity profile. Momentum flux
10.3. Flow profile
10.4. Pressure loss vs. rheology
10.5. Pressure loss vs. Rheology
10.6. Pressure loss. Power law
10.7. Pressure loss. Turbulent flow. Energy equation
10.8. Pressure loss vs. flow rate
10.9. Pressure loss. Field data
10.10. Pressure loss. Effects of rotation
10.11. Pressure loss. Bit nozzle. OFU
10.12. Swab pressure. Cling factor
11. Hydraulic program – Solutions
11.1. Mud pump issues
11.2. Nozzle selection. Section wise
11.3. Liner selection. Section wise
11.4. Hydraulic program. Section wise
11.5. Optimal parameters with BHHP. OFU. Section wise
11.6. Liner selection. Complete well
11.7. Liner selection. Complete well
12. Wellbore challenges – Solutions
12.1. Cuttings concentration
12.2. Cuttings
12.3. ECD. Barite
12.4. ECD. Fluid and flow
12.5. Water activity
12.6. Shale stability
12.7. Wellbore problems
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| June 5, 2015 | Edited by Alice Kirk | Edited without comment. |
| June 5, 2015 | Created by Alice Kirk | Added new book. |