Field-Scale and Wellbore Modeling of Compaction-Induced Casing Failures

Hilbert, L.B.; Gwinn, R.L.; Moroney, T.A.; Deitrick, G.L.

doi:10.2118/56863-pa

Cited by 17 publications

(2 citation statements)

References 12 publications

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“…By 1985, the number of subsidence-related producer failures approached historic levels (20% per year) 8 , leading to a reevaluation of reliance on primary recovery and of pattern configuration. Others have studied Diatomite reservoir compaction, subsidence-induced well casing failures, and large-impact surface subsidence 8,9,10,11,12,13 . As a result, the first Opal-A waterflood was instituted in the South Belridge Diatomite area in the mid 1980s, primarily for reservoir pressure maintenance to minimize elevated well failure occurrence.…”

Section: Early Well Completion Design and Pattern Configurationsmentioning

confidence: 99%

Innovative Use of Open-Hole Wireline Formation Pressure Testing in Waterflood Optimization of an Ultra-Tight, Light Oil Reservoir, Belridge Field

Zannitto¹,

Rahman²,

Allan³

2011

SPE Western North American Region Meeting

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There are not many oil reservoirs in the world with permeabilities less than 1 md that are under waterflood. Aera Energy's Diatomite reservoir at Belridge field in California is one of the few: a massively thick reservoir, with very low permeability, very high porosity, and high rock compressibility that has been undergoing water injection for pressure maintenance for over 20 years.Optimizing subsurface injection conformance, or injection profile, is the key to operating a successful waterflood in the Diatomite. However, because of wellbore obstructions, the majority of Diatomite injectors are not accessible to conventional radioactive tracer tools for monitoring injection profile. Without a good understanding of vertical profile, it is difficult to balance voidage on a layer by layer basis. Failure to maintain good zonal pressure support can result in poor vertical sweep, as well as reservoir compaction that can lead to irreversible permeability reduction and productivity impairment.Due to reservoir compaction and elevated rate of well failures, sustaining Diatomite production requires continuous drilling of replacement and infill wells at very close well spacing (20-50 ft). Aggressive replacement drilling programs (300 wells per year) have made it possible to run open-hole Wireline Formation Tests (WFT) in sufficient density over time to effectively monitor vertical and areal pressure profiles. As a result, reservoir intervals lacking injection support have been identified for optimization.Between 2003 and 2008, Aera ran over 300 open-hole WFT surveys in the South Grande area at Belridge field, vertically covering the Opal-A and upper Opal-CT reservoirs. Large-scale pressure testing has aided in pressure maintenance operations by improving completion strategy in new injection strings, targeting differentially depleted zones. This has improved overall layer voidage profiles, as evidenced by lower producing GOR and greatly reduced occurrence of producerfailures. WFT surveys continue to serve in a feedback loop to optimize injection target setting, voidage management, and strategy for completing replacement wells. This paper reports on the innovative use of wireline formation testing to optimize water injection pressure maintenance in a major onshore waterflood, with the unique challenge of not being able to monitor injection profile in a majority of wells. The learning may apply to other tight, light oil waterfloods.

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Section: Early Well Completion Design and Pattern Configurationsmentioning

confidence: 99%

Innovative Use of Open-Hole Wireline Formation Pressure Testing in Waterflood Optimization of an Ultra-Tight, Light Oil Reservoir, Belridge Field

Zannitto¹,

Rahman²,

Allan³

2011

SPE Western North American Region Meeting

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“…However, most of this work either assumed constant formation mechanical properties thereby ignoring the heterogeneity of the formation mechanical properties, or the detailed geometry of well completions was not considered. A few authors (Hilbert et al, 1998;Li et al, 2003;Rutqvist and Moridis, 2007) recognized the importance of honoring this complexity at both the field and near-wellbore scales but did not implement models that did so. Among them, numerical evaluation of well integrity in methane hydrate-bearing formation was very rarely published (Freij-Ayoub et al, 2007;Freij-Ayoub, 2009;Salehabadi et al, 2009).…”

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confidence: 99%

Well Integrity Evaluation for Methane Hydrate Production in the Deepwater Nankai Trough

et al. 2014

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Large accumulations of methane hydrates are known to exist in the deepwater Nankai Trough located off the southern coast of Japan. Due to its enormous potential as an energy source, there is growing interest in the production of methane gas from these deposits. An offshore production test was scheduled to test the technological viability to produce the methane hydrate by using a depressurization method. However, methane hydrate production may cause large amounts of compaction and subsidence, which can damage well integrity and cause loss of zonal isolation in the overburden. This condition could provide potential leakage pathways for methane gas to the surface and endanger offshore operations.The paper presents a study in which well integrity was evaluated for a methane hydrate production test well in the Nankai Trough. In this study, a new workflow was proposed and applied to honor both fieldwide formation heterogeneity and near-wellbore geometry. The geomechanics properties were determined through integration of seismic inversion data, log data, and core data from the Nankai Trough. Interface elements were installed between the casing and cement and the cement and formation to evaluate the impact of cement bond quality on the well integrity. The numerical simulation was conducted through coupling of the simulation results produced by a methane hydrate production simulator from a third party with a 3D finite-element (FE) geomechanics simulator.The study predicted the occurrence of 2-cm of subsidence on the seafloor generated by approximately 1.5% of reservoir compaction for a production test of 20 days. Over this period, casing would yield with a plastic strain of about 1%. Most findings indicated a low risk in the loss of zonal isolation which is consistent with the results of the production test conducted in March 2013.This simulation evaluated potential risks related to well integrity, and provided critical information for the preparation and execution of the pioneering offshore methane hydrate production test in the Nankai Trough.

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

Yuan

Calvert²,

Schutjens

et al. 2019

Rock Mech Rock Eng

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Field-Scale and Wellbore Modeling of Compaction-Induced Casing Failures

Cited by 17 publications

References 12 publications

Innovative Use of Open-Hole Wireline Formation Pressure Testing in Waterflood Optimization of an Ultra-Tight, Light Oil Reservoir, Belridge Field

Innovative Use of Open-Hole Wireline Formation Pressure Testing in Waterflood Optimization of an Ultra-Tight, Light Oil Reservoir, Belridge Field

Well Integrity Evaluation for Methane Hydrate Production in the Deepwater Nankai Trough

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

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