3 Borehole Image Analysis and Intro To Geosteering
3 Borehole Image Analysis and Intro To Geosteering
3 Borehole Image Analysis and Intro To Geosteering
Course Synopsis
Upon the completion of this course, the participants will be able to plan, supervise and check validity
of borehole image acquisition with LWD and Wireline instruments. They will be able to perform
fundamentals of the wellbore image processing and interpretation and visualize results. The
participants will be able to function as a structural geology member2 of Geosteering team and be able to
operate Schlumberger Techlog, advising drillers and other specialists on the well trajectory for optimal
reservoir penetration. Special attention is dedicated to the operations' efficiency and capability to
automate and document the image analysis process.
The course presumes basic practical knowledge of Schlumberger Techlog and Petrel software.
During practical exercises, participants will be required to perform an end-to-end image processing and
structural interpretation over PETRONODE sample/training dataset composed of basic electric logs and
wellbore electric image. Client-provided datasets may be also considered for the course if available
(prior confirmation is required).
DAY 1
Introductions & Safety
Wellbore images as part of integrated formation evaluation
Wireline dipmeters and imagers: electric/galvanic, electric/induction, ultrasonic
LWD imagers: density, electric/galvanic, electric/induction, GR
Advantages and disadvantages of various tools and techniques
Techlog refresher: loading and accessing data
Q&A.
DAY 2
Image quality control: gains/saturation, resolution, tool artifacts
Using Techlog histograms for image quality control and image equalization
Image quality control: directional sensors
Using Techlog cross-plots for image quality control
Image quality control: calipers
Using Techlog log plots (layouts) for image quality control
Tool speed corrections
1 For practical exercises, Client should provide students' workstations installed with either educational or commercial
license Schlumberger Techlog (versions 2010 or higher). As minimum, WBI and Python modules are required.
2 This course is not intended to and does not qualify as a Driller Well Control Course or Directional Engineer Collision
Prevention Course.
DAY 3
Drilling artifacts: threads, keysitting, breakouts, tensile fractures
Advanced image processing: flattening and gap removal
Advantages and dangers of advanced image processing
Introduction to dip geometry
True dip and azimuth vs apparent dip and azimuth
Dip presentations: sinusoids and tadpoles
Dip statistics: Rose Diagrams, Stereonet Plots, Cumulative Dip Plots
Automated dip picking: MSD algorithm.
Manual feature picking in Techlog
Basic Geomechanics answers from wellbore images
Q&A.
DAY 4
Feature classification and interpretation
Bedding
Cross-bedding
Erosional surfaces and discontinuities
Fractures, fissures and cleats
Faults and displacement
Non-plane features (concretia, fossils etc)
Conductive minerals on electric images (halo effect)
Finalizing and presenting your Structural Interpretation
Q&A.
DAY 5
Setting up Geosteering project3
Geosteering roles. Your role as structural geologist in Geosteering project
Well collisions, stuck pipe and well control (brief review)
Specific techniques: bent assemblies, adjustable stand-off tools, rotary steerable tools
Advantages and limitations of drilling techniques
Specific LWD tools for Geosteering: sensor position and other considerations
Pilot hole information handling
Planning the lateral and landing a well into the target formation
Dealing with imperfect landings
Formation following
Dealing with uncertainty
Dealing with unexpected geological events (eg unexpected faults)
Dealing with formation exits
Q&A.
3 At Client request, Geosteering chapters may be substituted with 1D Mechanical Earth Model.