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DRILLING ENGINEERING. CHAPTER # 8. Directional Drilling and Deviation Control. Definition. Directional Drilling: The process of directing the wellbore along some trajectory to a predetermined target. Deviation Control:
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DRILLING ENGINEERING CHAPTER # 8 Directional Drilling and Deviation Control
Definition Directional Drilling: The process of directing the wellbore along some trajectory to a predetermined target. Deviation Control: The process of keeping the wellbore contained within some prescribed limits, relative to inclination angle, horizontal excursion from the vertical or both. X-Y Plane • X – Plane = direction plane • Y – Plane = inclination plane
Angles • X-Y = Plane X – angle = direction angle • Y-Z = Plane Y – angle = inclination angle Purpose of Directional Drilling • Res. Under lake (economics, environmental reasons) • Offshore drilling. • Res. beneath population centers. • Res. beneath natural obstruction (mountains) Or severe topographical features. • Sidetracking out of an existing wellbore to bypass an obstruction (fish) or explore additional producing horizons in adjacent sectors. • Relief well to plug a blow out.
Inclination and direction planes as a wellbore proceeds in the depth plane.
Typical offshore development platform with directional wells
Developing a field under a city using directionally drilled wells
Drilling of directional wells where the reservoir is beneath a major surface obstruction
Using an old well to explore for new oil by sidetracking out of the casing and drilling occasionally
7.1 Planning The Directional Well Trajectory Trajectory Well path that will intersect given target. • First design propose the various types of paths that can be drilled economically. • Second includes effects of geology on the bottomhole assemblies (BHA) and other factors that could influence the final wellbore trajectory.
Types of Trajectories • Build and hold trajectory penetrates target at max. build-up angle. • Build-hole and drop (s-shape) penetrate angle vertically • Build-hold drop and/or hold (modified s-shape) penetrates target at angle less than max. inclination angle in the hold section. • Continuous build trajectory inclination angle is increasing. q1 < q3 < q2 < q4
X3 = horizontal departure • g1= radius of curvature • D3 = TVD true vertical depth • D1 = kick off point TVD • q = rate of inclination angle build up
7.2 Build and Hold Trajectory • Circumference = 2pr • S=rq • q in radians max. inclination angle • 1 radian = 180 o/p = 57.29578 o • 1o = p/180 radians • q = degrees per unit length = q/L = inclination angle build up rate • q = 1o/100ft r = S /q • r = radius of curvature
S = g q (8.1)
(8.2) • q = W - T • To find angle T look at triangle OBA (8.3a) (8.3b) To find angle W consider triangle OBC (8.4)
CO = g1 (8.5) • q = W - T
(8.6) Length of the arc section DC (buildup section) (8.7)
Length of CB (Trajectory Path) Straight at constant inclination angle can be determined from BCO Total measured depth DM for TVD of D3 is (8.8)
Horizontal departure at end of build up (8.9) True Vertical depth at end of build up section (8.12)
Measure depth and Horizontal departure before reaching maximum angle along any part of build up. Consider intermediate inclination angle XN=Horizontal Departure at C DN=Vertical depth Consider DOC (8.10) (8.11)
(8.13) New measured depth for any part of the build up New measured depth at TVD of (D*< D3)(D2<D*< D3) (8.16) Horizontal Departure X* (X2<X*< X3) (8.18)
For r1 < X3 (8.20)
Three-dimensional view of a wellbore showing components that comprise the X, Y and Z parts of the trajectory
7.3 Directional Drilling Tools • Stabilizing Tools • The Stiff Hook-Up • The Pendulum Hook-Up • Angle Building Hook-Ups • The Lock-in Hook-Ups • Angle Losing Hook-Ups
Other Application of Stabilizing Tools • Key seat Guide • Avoidance of Pressure Differential Sticking • Whip stock • Knuckle Joint
