Publications
Direct Subsurface Measurements through Precise Micro Drilling
Su, Jiann-Cherng S.; Bettin, Giorgia B.; Buerger, Stephen B.; Rittikaidachar, Michal; Hobart, Clinton G.; Slightam, Jonathon S.; McBrayer, Kepra M.; Gonzalez, Levi M.; Pope, Joseph S.; Foris, Adam J.; Bruss, Kathryn B.; Kim, Raymond K.; Mazumdar, Anirban
Wellbore integrity is a significant problem in the U.S. and worldwide, which has serious adverse environmental and energy security consequences. Wells are constructed with a cement barrier designed to last about 50 years. Indirect measurements and models are commonly used to identify wellbore damage and leakage, often producing subjective and even erroneous results. The research presented herein focuses on new technologies to improve monitoring and detection of wellbore failures (leaks) by developing a multi-step machine learning approach to localize two types of thermal defects within a wellbore model, a prototype mechatronic system for automatically drilling small diameter holes of arbitrary depth to monitor the integrity of oil and gas wells in situ, and benchtop testing and analyses to support the development of an autonomous real-time diagnostic tool to enable sensor emplacement for monitoring wellbore integrity. Each technology was supported by experimental results. This research has provided tools to aid in the detection of wellbore leaks and significantly enhanced our understanding of the interaction between small-hole drilling and wellbore materials.