Chin W.C. Formation Testing: Supercharge, Pressure Testing, and Contamination Models

Scrivener Publishing / Wiley, 2019. — 399 p. — (Advances in Petroleum Engineering Series). — ISBN: 978-1-119-28377-5.This volume, possibly the third and final of three in the "Formation Testing" series, summarizes new and important methods and approaches for wireline and LWD/MWD formation tester pressure transient interpretation. Two prior monographs, Formation Testing: Pressure Transient and Contamination Analysis (2014) and Formation Testing: Low Mobility Pressure Transient Analysis (2015), had developed essential models and algorithms for exact forward analysis; rapid, real-time, inverse mobility and pore pressure prediction methods in low mobility environments with non-negligible flow line volume effects; steady-state and transient forward and inverse techniques; miscible, multiphase flow contamination modeling for sample quality control; fast “phase-delay” methods for realtime prediction in tight zone applications, and other useful mathematical methods.
In the 1990s through 2000s, the author co-developed Halliburton’s commercially successful GeoTap real-time LWD/MWD (Logging-While-Drilling / Measurement-While-Drilling) method for formation testing, and also a parallel method used by China Oilfield Services, which enabled the use of data taken at early times, in low mobility and large flow line volume environments, to support the important estimation of mobility, compressibility and pore pressure, which are necessary for flow economics and fluid contact boundaries analyses (this work was later extended through two Department of Energy Small Business Innovation Research awards).
While extremely significant, the effect of high pressures in the borehole could not be fully accounted for – the formation tester measures a combination of reservoir and mud pressure and cannot ascertain how much is attributed to unimportant borehole effects. The usual approach is "simply wait" until the effects dissipate, which may require hours – which imply high drilling and logging costs, plus increased risks in safety and tool loss. The author has now modeled this "supercharge" effect and developed a powerful mathematical algorithm that fully accounts to mud iterations. In short, accurate predictions for mobility, compressibility and pore pressure can now be undertaken immediately after an interval is drilled without waiting.
This groundbreaking new work is a must-have for any petroleum, reservoir, or mud engineer working in the industry, solving day-to-day problems that he or she encounters in the field.