Multi-scenario Geomechanical Modeling for Investigating Well Deformation in the Deep Overburden Over a Compacting Reservoir in the North Sea

A multi-scenario geomechanical modeling approach is presented to investigate the potential mechanisms that lead to a series of well-deformation incidents in the deep overburden overlying a depleting and compacting chalk reservoir in the North Sea. Complementary to the commonly pursued approach of bu...

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Bibliographic Details
Published inRock mechanics and rock engineering Vol. 52; no. 12; pp. 5225 - 5244
Main Authors Yuan, R. S., Calvert, M. A., Schutjens, P. M. T. M., Bourgeois, F. G.
Format Journal Article
LanguageEnglish
Published Vienna Springer Vienna 01.12.2019
Springer Nature B.V
Subjects
Carbonates
Chalk
Civil Engineering
Compacting
Compaction
Computer simulation
Data acquisition
Deformation
Deformation mechanisms
Depletion
Earth and Environmental Science
Earth Sciences
Finite element method
Geological faults
Geomechanics
Geophysics/Geodesy
Mapping
Mathematical models
Mechanical properties
Modelling
Original Paper
Overburden
Pipe stringers
Reservoirs
Rock mechanics
Rocks
Shear zone
Slippage
Stratigraphy
Stringers
North Sea
Overburden deformation
Bed-parallel shear
“domino” or “bookshelf” style shear zone
Fault slip
Well deformation and damage
Mechanical stratigraphy
Reservoir compaction and subsidence
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Summary:A multi-scenario geomechanical modeling approach is presented to investigate the potential mechanisms that lead to a series of well-deformation incidents in the deep overburden overlying a depleting and compacting chalk reservoir in the North Sea. Complementary to the commonly pursued approach of building a full-field geomechanical model presented in the companion paper of this special issue (Schutjens et al. in Compaction- and shear-induced well deformation in Tyra: geomechanics for impact on production, accepted by the ARMA 2018 special issue of Rock Mechanics and Rock Engineering, 2018 ), a suite of finite-element-based sector-scale ideal geomechanical models is developed based on data and evidence-driven scenarios that take into considerations fault population and juxtaposition, contrasting mechanical stratigraphy, intra-bedding contact conditions, and lateral persistence of thin stringer beds. The simulation results of extensive runs suggest that most of the geological faults in the overburden mudstones are stable under the pre-production stress state and remain largely inactive in the course of overburden deformation resulting from depletion of the underlying reservoir. Alternatively, the contrasting mechanical stratigraphy of the overburden, consisting of thick compliant mudstones and thin stiff carbonate stringers, facilitates “domino” or “bookshelf” style intra-bedded shear slippage in response to the developing dominant shear zone right above and around the periphery of the active compacting region. This multi-scenario approach provides new and accelerated insights into the diagnosis of compaction-induced well failure in the deep overburden and allows mapping of competing mechanisms potentially responsible for the problem. These new insights help to steer further modeling efforts and guides future data acquisitions.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-019-01863-z