OptiDrill. Real-time drilling intelligence service

OptiDrill Real-time drilling intelligence service

OptiDrill Real-time drilling intelligence service Manage downhole conditions and HA dynamics with the OptiDrill* real-time drilling intelligence service. Integrated downhole and surface data provide actionable information on a rigsite display to mitigate risk and increase efficiency. These data are simultaneously interpreted by remote experts, who collaborate with the drilling team to improve performance. Applications mitigation Drilling performance improvement Wellbore quality enhancement enefits Reduce HA failures Identify and mitigate poor hole cleaning and sticking pipe tendencies Improve by maximizing drilling efficiency Extend bit runs by preserving cutting structures Manage borehole tortuosity to aid casing running Optimize HA design and bit selection Evaluate drilling technology performance Validate and calibrate drilling models Features sub with 19 drilling mechanics and dynamics sensors Real-time drilling answers, including downhole detection of whirl, bit bounce, and stick/slip motions and severity estimation of weight on reamer continuous calculation of borehole friction factors estimation of wellbore curvature from bending moment plugged-nozzle and drillstring washout quick event detection Rigsite dashboard with integrated data display While-drilling monitoring, analysis, and recommendations from remote experts Continuous recording of low- and high-frequency data for postrun analysis

I I Quantify risk and manage downhole conditions The OptiDrill service helps you mitigate risk and improve drilling performance through early detection of limiters and drilling hazards. Real-time motion detection and weight-on-reamer information allow the rigsite team to proactively manage parameters. The OptiDrill service provides the driller with immediate guidance on how to mitigate severe downhole dynamics. Early intervention typically lessens the severity of an event, protecting the HA and extending the length of the bit run. Mitigating shock and vibration to maximize drilling efficiency The OptiDrill service detects whirl, bit bounce, and stick/slip motions and their severity. In the example below, a large-hole HA is crossing a formation boundary and experiencing severe backward whirl. This motion is detected downhole by the OptiDrill service s sub and displayed in real time with a recommended mitigation on the rigsite display. MOTION A HA STALL STICK SLIP VIRATION AMPLITUDE (3 min) ENDING (3 min) 1 1, ft.lbf G N D N E C D ackward Whirl Advice: Stop and restart with lower surface RPM WEIGHT TRANSFER (1, lbf) 1 2 TORQUE TRANSFER (1, ft.lbf) 6 12 /MWin (lbm/gal) MWTI 9.5 1 1.5 KEY TIME-ASED TRENDS (6 min) 1.5 IT HOLE TVD 4,549.7 ft. 4,549.7 ft. 4,354.67 ft. MOTION ENDING (3 min) 1 HA STALL 1, ft.lbf STICK SLIP VIRATION AMPLITUDE (3 min) G N E AXIAL D N LATERAL LATERAL T O R S AXIAL I O N A L E (lbm/gal) DMSE (psi) 1 1, T O R S I O N A L 167 ft/h 1.36 lbm/gal RPM DIFF PRESSURE 3: 3:15 3:3 3:45 Sensor MD (ft) Incl (deg) Azim (deg) TVD (ft) X,153.16 27.91 281.71 X,9.72 X,277.91 28.95 284.67 X,119.42 119 c/min 1,98 psi PRESSURE FLOW 2,481 psi 1,268 gal/min X,43.45 3.9 287.62 X,228.67 A Animation of downhole motions requiring immediate attention to preserve the life of the HA D Quantification of weight and torque transfer to enable early identification of abnormal downhole conditions C Progression of vibration type and amplitude to help modify drilling parameters and minimize energy lost to vibrations Guidance to aid mitigation E Calculation of equivalent circulation density () and downhole mechanical specific energy (DMSE) to understand hole cleaning and drilling efficiency trends

Managing drilling parameters to extend the life of the reamer In reaming-while-drilling applications, the OptiDrill service continuously estimates weight on reamer by combining downhole measurements from below the reamer with surface measurements. In the example below, the HA is passing through formations with significant strength contrasts. The driller is using the estimated weight on reamer and a visualization of the reamer location to proactively manage surface weight to keep the weight on reamer within an acceptable range. X,81 Gamma Ray Weight On Reamer X,86 A X,88 22:45 X,9 22:5 X,92 X,91 RTSTAT 22:55 389 ON OTTOM IT HOLE TVD X,38.98 ft X,38.98 ft X,586.42 ft X,96 X,98 X, X,81 X,86 X,88 23: 23:5 Gamma Ray 22:45 Weight On Reamer GTF -3 3 TF 168-6 6 X,2 ft/h X,9 X,92 2 X,91 X,96 X,98 X, gapi 2 23:1 22:5 22:55 1, lb 2 23: 23:5-9 -12-15 18 15 12 9 X,2 2 2 23:1 2 MD Incl Azim TVD R TR DLS (ft) (deg) (deg) (ft) (deg/1ft) MWD X,527.99 34.68 299.1 X,18.19 -.11.26.18 MWD X,655.55 34.67 298.56 X,273.1 -.1 -.36.2 MWD X,782.69 35.44 296.12 X,377.18.61-1.92 1.26 MWD X,97.44 35.22 295.9 X,478.96 -.18 -.82.51 MWD X,992.46 35.29 295.15 RSS X,3.52 35.65 298.15 AXIAL VI LOW Weight 1, 14 lbf LATERAL VI LOW it Weight 1, 3 lbf TORSION VI LOW Weight on Reamer 1, 11 lbf RPM 11.1 lbm/ gal 111 ft/h 82 c/min A Visualization of the location of the reamer in the formation to help determine cause of change in weight on reamer Estimation of weight on reamer to increase the life of the reamer through proactive management of surface weight on bit and rpm

Wellbore Quality Drilling Performance Improvement Mitigation Depth, m Scale HA and Caliper EcoScope* Caliper orehole Image EcoScope Density Image orehole Curvature PowerDrive Orbit* Inclination ending Curvature Pressure Pressures Equivalent Mud Weight Drilling Mechanics and Forces Weight Torque and Rotational Speed ending Moment Drilling Efficiency Mechanical Specific Energy rms Axial it-ounce Drilling Dynamics, Amplitudes, and Motions rms Lateral Whirl Type Whirl rms Torsional Stick/Slip orehole Friction Factor Quick Event Detection Algorithms orehole Friction Factor Quick Event Detection X,925 X,95 X,975 X, Absent 1.846 2.41 2.236 2.431 2.626 g/cm3 84 degree 88 Receive while-drilling support from interpretation experts Tool ending Curvature 6 º/3 m Wellbore ending Curvature 6 º/3 m Flow Rate 1, galus/min Standpipe Pressure psi 4, Differential Pressure psi 4, Equivalent Static Density Max. Static Density Min. Static Density Mud Weight In m/h 2 WO lbf 2, Avg WO lbf 2, Max. WO lbf 2, Torque ft.lbf 25, Avg Torque ft.lbf 1, Max. Torque ft.lbf 1, rpm c/min 2 Dynamic ending Avg ending Moment ft.lbf 25, Max. ending Moment ft.lbf 25, Delta Mechanical Specific Energy Mechanical Specific Energy 6,, psi Mechanical Specific Energy 6,, psi Low High Low High Low High Normal Drilling Forward Whirl ackward Whirl Chaotic Whirl Normal Drilling High 7 7 7 3 1 3 Low High 7 Low High 7 Rotating Friction Factor.5 Slack-Off Friction Factor.5 Pickup Friction Factor.5 Plugged- Nozzle Quick Event Detection 1 Drillstring Washout Quick Event Detection Probability 1 Data from the OptiDrill service is transmitted to surface for use by the rigsite team and for interpretation by remote experts. The experts collaborate with the drilling team to reduce risk, improve drilling performance, and manage borehole quality. Wellbore quality monitoring To aid casing running, the service detects microdogleg and spiraling using bending moment data. Real-time wellbore quality data logs enable evaluation of the stability of the borehole over time. Drilling performance improvement In addition to the rigsite visualization of drilling efficiency information and immediate guidance for mitigating HA dynamics, remote interpretations are shared with the rigsite team to help identify optimal surface parameters. mitigation Automated quick event detection algorithms monitor for indications of plugged bit nozzles and drillstring washout. Using surface and downhole measurements, the OptiDrill service continuously calculates torque and drag to provide borehole friction factors for early identification of sticking pipe tendencies.

Improve future performance with postrun insight The OptiDrill service records low- and high-frequency data, which are available for postrun analysis to evaluate drilling system performance. This information provides valuable input for the planning of future wells. Key applications of this recordedmode information include validating and calibrating drilling models increasing knowledge of formation drillability optimizing HA design and bit selection evaluating the performance of drilling technology. ending moment, up down ending moment, left right Forward whirl Time, min Chaotic whirl 1 2 3 A HA with a reamer entered forward whirl motions and then chaotic whirl motions, which were detected and mitigated in real time. Postrun analysis revealed that the whirling motions occurred when the reamer entered an unstable formation. This information will be used while drilling future wells planned in this formation. 25 2 rpm rpm Rotational speed, rpm 15 1 5 18:26 18:27 18:28 18:29 18:3 18:31 18:32 18:33 18:34 18:35 18:36 Time A postrun visualization of surface and downhole rpm was used to evaluate the effectiveness of a surface control system to minimize stick/slip. The chart was created using high-resolution (5-Hz) data recorded by the OptiDrill service.

Specifications Mechanical OptiDrill 675 OptiDrill 9 Nominal OD, in [cm] 6.89 [17.5] 9.18 [23.31] Nominal ID, in [cm] 4.8 [12.19] 5.74 [14.57] Max. OD (wearband), in [cm] 7.78 [19.76] 1.4 [26.41] Length, ft [m] 9.84 [2.99] 11.54 [3.51] Weight in air, lbm [kg] 93 [41] 2,151 [976] Top thread connection 5½ FH box 75/8 H9 box ottom thread connection NC5 (41/2 IF) box 75/8 Reg box Connection makeup torque, ft.lbf [N.m] 24, [32,539] 65, [88,128] Connection yield torque, ft.lbf [N.m] 44, [59,655] 114, [154,563] Mechanical Operations Max. temperature, degf [degc] 32 [15] 32 [15] Max. shock (cycles), g n 25 25 Operating flow range, galus/min to 8 to 1,6 Max. operating pressure, psi [MPa] 3, [26] 3, [26] Max. differential pressure, psi [MPa] 5, [34] 5, [34] Pressure drop coefficient (C) 142, 1,42, Max. dogleg severity, /1 ft Rotating 8 6 Sliding 16 12 Max. overpull (tension), lbf 55, 93, Max. weight on bit, lbf 12,,/L 2 55,,/L 2 Max. operating torque, ft.lbf [N.m] 24, [32,539] 65, [88,128] Mud properties Max. lost circulation material No limit No limit Max. sand content, % 1 1 Pressure drop, psi = [(mud weight, lbm/galus) (flow, galus/min)2] /C. L = the distance (ft) from the bottom of the stabilizer blades immediately above the OptiDrill service sub to the top of the stabilizer blades immediately below the OptiDrill service sub. Data Acquisition and Processing Sample rate Digital signal processor Processing time Real-time telemetry 19 channels at 1, Hz 18 Mflops 2-s Fully compatible with Orion II* data compression platform and the IntelliServ Network memory Low frequency 2 M (25 h at.5 Hz [configurable]) High frequency 1,5 M (14 h at 5 Hz [fixed]) Power supply Low-power tool bus (LT) and battery (75 h) Power-saving mode Trip-in time attery-saver time

Specifications OptiDrill 675 Service Measurement Sensor Real-Time Range Weight on bit Strain gauge ±75, lbf [±333,616 N] Torque Strain gauge ±24, ft.lbf [32,54 N.m] ending moment Strain gauge 61, ft.lbf [82,75 N.m] Range ±93, lbf [±413,684 N] ±3, ft.lbf [4,675 N.m] 76, ft.lbf [13,42 N.m] Real-Time Resolution 3 lbf [1,334 N] 1 ft.lbf [135 N.m] 12 ft.lbf [163 N.m] Resolution 5 lbf [222 N] 7 ft.lbf [9 N.m] 5 ft.lbf [7 N.m] Accuracy ±3, lbf [±13,344 N] ±1, ft.lbf [±1,355 N.m] ±3, ft.lbf [±4,67 N.m] Real-Time Processing 1-s moving 1-s moving 1-s moving Processing andwidth Accelerometer Axial (x) to 31.75 g n to 31.75 g n.125 g n.7 g n ±.25-g n rms 3-s rms 3-s rms.2 to 15 Hz Lateral (y and z) to 63.5 g n to 63.5 g n.25 g n.7 g n ±.25-g n rms 3-s rms 3-s rms.2 to 15 Hz Rotational speed Magnetometer 5 to 5 to 1 rpm <1 rpm ±5 rpm 3-s moving 2-s 4 Hz and gyroscope 1, rpm 1, rpm Annular and internal pressure Strain gauge 3, psi 3, psi 1 psi <1 psi ±3 psi 1-s avg 2-s 2 Hz Annular and internal temperature PT1 5 to 24 degc 2 Hz 2 Hz 2 Hz 5 to 24 degc 1 degc.4 degc ±1 degc 1-s avg 2-s 1 Hz Continuous inclination Accelerometer to 18 to 18.1.1 ±.4 3-s avg 3-s 1 Hz Weight on bit, torque, and bending moment are compensated downhole for temperature, differential pressure, and hydrostatic pressure. OptiDrill 9 Service Measurement Sensor Real-Time Range Weight on bit Strain gauge ±125, lbf [±556,27 N] Torque Strain gauge ±81, ft.lbf [19,821 N.m] ending moment Strain gauge 132, ft.lbf [178,968 N.m] Range ±156, lbf [±693,922 N] ±11, ft.lbf [136,938 N.m] 165, ft.lbf [223,71 N.m] Real-Time Resolution 5 lbf [2,224 N] 32 ft.lbf [434 N.m] 26 ft.lbf [353 N.m] Resolution 8 lbf [355 N] 17 ft.lbf [23 N.m] 11 ft.lbf [15 N.m] Accuracy ±4, lbf [±17,792 N] ±2, ft.lbf [±2,712 N.m] ±6, ft.lbf [±8,135 N.m] Real-Time Processing 1-s moving 1-s moving 1-s moving Processing andwidth Accelerometer Axial (x) to 31.75 g n to 31.75 g n.125 g n.7 g n ±.25-g n rms 3-s rms 3-s rms.2 to 15 Hz Lateral (y and z) to 63.5 g n to 63.5 g n.25 g n.7 g n ±.25-g n rms 3-s rms 3-s rms.2 to 15 Hz Rotational speed Magnetometer 5 to 5 to 1 rpm <1 rpm ±5 rpm 3-s moving 2-s 4 Hz and gyroscope 1, rpm 1, rpm Annular and internal pressure Strain gauge 3, psi 3, psi 1 psi <1 psi ±3 psi 1-s avg 2-s 2 Hz Annular and internal temperature PT1 5 to 24 degc 2 Hz 2 Hz 2 Hz 5 to 24 degc 1 degc.4 degc ±1 degc 1-s avg 2-s 1 Hz Continuous inclination Accelerometer to 18 to 18.1.1 ±.4 3-s avg 3-s 1 Hz Weight on bit, torque, and bending moment are compensated downhole for temperature, differential pressure, and hydrostatic pressure.

Find out more about the OptiDrill service at slb.com/optidrill Animation Watch an animation that shows how the OptiDrill service provides actionable information to mitigate drilling risk and increase efficiency. Case Study Total eliminates a planned bit run with OptiDrill service in a 17½-in section in the North Sea. Tech Report OptiDrill service improves HA reliability to help an operator drill to section TD in one run in deepwater Gulf of Mexico. slb.com/optidrill *Mark of Schlumberger Other company, product, and service names are the properties of their respective owners. Japan Oil, Gas and Metals National Corporation (JOGMEC), formerly Japan National Oil Corporation (JNOC), and Schlumberger collaborated on a research project to develop LWD technology that reduces the need for traditional chemical sources. Designed around the pulsed neutron generator (PNG), EcoScope service uses technology that resulted from this collaboration. The PNG and the comprehensive suite of measurements in a single collar are key components of the EcoScope service that deliver game-changing LWD technology. Copyright 215 Schlumberger. All rights reserved. 14-DR-183