A model for calculating the formation resistivity factor in low and middle porosity sandstone formations considering the effect of pore geometry

TitleA model for calculating the formation resistivity factor in low and middle porosity sandstone formations considering the effect of pore geometry
Publication TypeJournal Article
Year of Publication2017
AuthorsHaliburton), WLi (, Zou, C, Wang, H, Peng, C
JournalJournal of Petroleum Science and Engineering
Volume152
Pagination193 - 203
Date PublishedJan-04-2017
ISSN09204105
KeywordsFormation resistivity factor, Low and middle porosity sandstone, Pore geometry, Thin section, Tortuosity, Water saturation
Abstract

Pore geometry is one of the main factors that may lead Archie's equation inaccurate in low and middle porosity sandstone formations. In order to build a robust relationship between the formation resistivity factor and the porosity for the low and middle porosity sandstone formations, we presented a pore-throat model (PT model) that considered the effect of pore geometry. The PT model is an effective medium model that treats the pore space as a series of a spherical pore and two throats. The spherical pore can be described by the pore radius, and the throat can be described by the ratio of the pore radius over the throat radius (the pore-throat radius ratio) and the tortuosity. We collected seventy-two core plugs from the typical low and middle porosity sandstone formation in the Ordos Basin in China, having porosity ranging from about 3–20%. Forty-seven of the samples with low clay content were chosen for laboratory resistivity measurements to validate the PT model. The core experiments and the application to the well logging interpretation indicated that the PT model provides a more convincing formation resistivity factor, while the formation resistivity factor calculated using Archie's equation is larger than that measured in the lab, especially when the porosity is relatively low. The tortuosity used in the PT model was calculated by a theoretical method and verified by a thin section analysis method. The PT model enhances the understanding of the effects of the pore geometry on the relationship of the formation resistivity factor and the porosity.

URLhttp://linkinghub.elsevier.com/retrieve/pii/S0920410517303637
DOI10.1016/j.petrol.2017.03.006
Short TitleJournal of Petroleum Science and Engineering