Modeling Early-Time Gas Migration Through Cement Slurries (includes associated papers 36370 and 36766 and 37387 and 37684)

Michael Prohaska; Rudolf Fruhwirth; Michael J. Economides

doi:10.2118/27878-PA

Modeling Early-Time Gas Migration Through Cement Slurries (includes associated papers 36370 and 36766 and 37387 and 37684)

Michael Prohaska, Rudolf Fruhwirth, Michael J. Economides

Chair of Geoenergy Production Engineering (550)

Institute for Water Resources Management Hydrogeology and Geophysics

Research output: Contribution to journal › Article › Research › peer-review

7 Citations (Scopus)

Abstract

This work identifies a mechanism that could be responsible for substantial gas invasion into a cemented column after placement. A model is developed to predict the risk for gas invasion and to aid in the design of a cement job suggesting a "tail" and a delayed "lead" slurry. The model provides the absolute theoretical migration height when cement properties and formation parameters are known. The work accounts for the calculation of the hydrostatic pressure drop, for the estimation of the inflow rates resulting from shrinkage and filtration, and for the description of the bubble-rise process. A sensitivity study on important design and well parameters is included.

Original language	English
Pages (from-to)	178-185
Number of pages	8
Journal	SPE Drilling & Completion
Volume	10.1995
Issue number	03
DOIs	https://doi.org/10.2118/27878-PA
Publication status	Published - 1995

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10.2118/27878-PA

Cite this

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AB - This work identifies a mechanism that could be responsible for substantial gas invasion into a cemented column after placement. A model is developed to predict the risk for gas invasion and to aid in the design of a cement job suggesting a "tail" and a delayed "lead" slurry. The model provides the absolute theoretical migration height when cement properties and formation parameters are known. The work accounts for the calculation of the hydrostatic pressure drop, for the estimation of the inflow rates resulting from shrinkage and filtration, and for the description of the bubble-rise process. A sensitivity study on important design and well parameters is included.

U2 - 10.2118/27878-PA

DO - 10.2118/27878-PA

M3 - Article

SN - 1064-6671

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