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Drive-Around Surveys for Detection and Quantification of Methane Leaks Estimating Emission Rates from Drive-Around Surveys
  • +5
  • Jeffrey Nivitanont,
  • Kristen Pozsonyi,
  • Tim Vaughn,
  • Arthur Barbaro,
  • Santos sr.,
  • Stuart Riddick,
  • Shane Murphy,
  • Daniel Zimmerle
Jeffrey Nivitanont
Department of Atmospheric Science, University of Wyoming

Corresponding Author:[email protected]

Author Profile
Kristen Pozsonyi
Department of Atmospheric Science, University of Wyoming
Tim Vaughn
Energy Institute, Colorado State University
Arthur Barbaro
Santos sr.
Energy Institute, Colorado State University
Stuart Riddick
Energy Institute, Colorado State University
Shane Murphy
Department of Atmospheric Science, University of Wyoming
Daniel Zimmerle
Energy Institute, Colorado State University

Abstract

Current MMRV solutions have the potential to quickly survey entire oilfields or detect methane leaks down to the component level, but also carry high price tags or, indirectly, high implementation costs. The Stanford/EDF Mobile Monitoring Challenge (MMC) conducted in 2018 was the first study to systematically evaluate methane mitigation technologies for incorporation into LDAR programs at the operator level. Three vehicle-based solutions tested in the MMC utilized a fence-line screening pattern that encompassed a production site and equipment, which we refer to as a “drive-around survey,” and showed promising results of greater than or equal to 88% true positive source identification rates for controlled releases in the 0-26 kg CH4/hr range.
In this work, we evaluate a similar on-site drive-around survey as an alternative methane leak detection method under the EPA’s recent update to the Standards of Performance for New, Reconstructed, and Modified Sources and Emissions: Oil and Natural Gas Sector (NSPS). We find that a simple methane enhancement threshold binary classification system performs well with true positive rates > 0.8, though the precision of this classifier is inversely related to the magnitude of the emission rates for each class. We also describe a heuristic approach to estimating dispersion without source distance information. Incorporating this information into a linear model of emission rates regressed on survey data, we improve the model fit to R^2 > 0.9.
13 Dec 2023Submitted to ESS Open Archive
27 Dec 2023Published in ESS Open Archive