Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation

Sand production encountered in the 2013 offshore field gas production tests at the Nankai Trough, Japan, could be attributed to well failure during reservoir compaction. In this study, well integrity under various reservoir compaction patterns for the Nankai Trough case is examined using a well-form...

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Main Authors: Sasaki, Tsubasa, Shao, Benshun, Elshafie, Mohammed, Papadopoulou, Marilena, Yamamoto, Koji, Soga, Kenichi
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2021
Subjects:
Civil Engineering
Engineering
Methane hydrate
Soil
Cement
Well integrity
Reservoir compaction
Resources Engineering and Extractive Metallurgy
Interdisciplinary Engineering
Geological & Geomatics Engineering
Online Access:https://escholarship.org/uc/item/66k4z9wd
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spelling ftcdlib:oai:escholarship.org:ark:/13030/qt66k4z9wd 2024-02-04T10:02:04+01:00 Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation Sasaki, Tsubasa Shao, Benshun Elshafie, Mohammed Papadopoulou, Marilena Yamamoto, Koji Soga, Kenichi 2021-01-01 application/pdf https://escholarship.org/uc/item/66k4z9wd unknown eScholarship, University of California qt66k4z9wd https://escholarship.org/uc/item/66k4z9wd public Civil Engineering Engineering Methane hydrate Soil Cement Well integrity Reservoir compaction Resources Engineering and Extractive Metallurgy Interdisciplinary Engineering Geological & Geomatics Engineering article 2021 ftcdlib 2024-01-08T19:06:10Z Sand production encountered in the 2013 offshore field gas production tests at the Nankai Trough, Japan, could be attributed to well failure during reservoir compaction. In this study, well integrity under various reservoir compaction patterns for the Nankai Trough case is examined using a well-formation finite element model. The modelling details include the inclusion of a cement sheath as well as the modelling of construction processes (such as cement shrinkage). Well elongation in the overburden layer becomes significant when the reservoir subsidence is localized near the wellbore under large depressurization. Results show that the maximum plastic deviatoric strain level in the cement could reach 0.7% when the maximum reservoir subsidence reaches 0.85 m and cement shrinkage is limited. When cement shrinkage rises to 0.75%, the maximum plastic deviatoric strain increases to 2.4% as the cement accumulates additional plastic strain during shrinkage due to its deformation being constrained by the casing. In order to prevent the cement from failure, it might be effective to hold the pressure drawdown at a low level (e.g., several MPa) until the hydrate dissociation front advances to a certain radius from the well (e.g., a couple of tens of metres). Article in Journal/Newspaper Methane hydrate University of California: eScholarship
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language unknown
topic Civil Engineering
Engineering
Methane hydrate
Soil
Cement
Well integrity
Reservoir compaction
Resources Engineering and Extractive Metallurgy
Interdisciplinary Engineering
Geological & Geomatics Engineering
spellingShingle Civil Engineering
Engineering
Methane hydrate
Soil
Cement
Well integrity
Reservoir compaction
Resources Engineering and Extractive Metallurgy
Interdisciplinary Engineering
Geological & Geomatics Engineering
Sasaki, Tsubasa
Shao, Benshun
Elshafie, Mohammed
Papadopoulou, Marilena
Yamamoto, Koji
Soga, Kenichi
Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
topic_facet Civil Engineering
Engineering
Methane hydrate
Soil
Cement
Well integrity
Reservoir compaction
Resources Engineering and Extractive Metallurgy
Interdisciplinary Engineering
Geological & Geomatics Engineering
description Sand production encountered in the 2013 offshore field gas production tests at the Nankai Trough, Japan, could be attributed to well failure during reservoir compaction. In this study, well integrity under various reservoir compaction patterns for the Nankai Trough case is examined using a well-formation finite element model. The modelling details include the inclusion of a cement sheath as well as the modelling of construction processes (such as cement shrinkage). Well elongation in the overburden layer becomes significant when the reservoir subsidence is localized near the wellbore under large depressurization. Results show that the maximum plastic deviatoric strain level in the cement could reach 0.7% when the maximum reservoir subsidence reaches 0.85 m and cement shrinkage is limited. When cement shrinkage rises to 0.75%, the maximum plastic deviatoric strain increases to 2.4% as the cement accumulates additional plastic strain during shrinkage due to its deformation being constrained by the casing. In order to prevent the cement from failure, it might be effective to hold the pressure drawdown at a low level (e.g., several MPa) until the hydrate dissociation front advances to a certain radius from the well (e.g., a couple of tens of metres).
format Article in Journal/Newspaper
author Sasaki, Tsubasa
Shao, Benshun
Elshafie, Mohammed
Papadopoulou, Marilena
Yamamoto, Koji
Soga, Kenichi
author_facet Sasaki, Tsubasa
Shao, Benshun
Elshafie, Mohammed
Papadopoulou, Marilena
Yamamoto, Koji
Soga, Kenichi
author_sort Sasaki, Tsubasa
title Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
title_short Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
title_full Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
title_fullStr Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
title_full_unstemmed Simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
title_sort simulation of axial tensile well deformation during reservoir compaction in offshore unconsolidated methane hydrate-bearing formation
publisher eScholarship, University of California
publishDate 2021
url https://escholarship.org/uc/item/66k4z9wd
genre Methane hydrate
genre_facet Methane hydrate
op_relation qt66k4z9wd
https://escholarship.org/uc/item/66k4z9wd
op_rights public
_version_ 1789968412451012608

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