Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments

Includes bibliographical references. 2020 Fall. The Wisting Field is located at the Barents Sea, Norway. It is a shallow reservoir encountered at 71.9 bar and 17.8°C. The bubble point pressure is 68.6 bar at reservoir temperature, resulting in an undersaturated oil reservoir. The risk of gas hydrate...

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Main Author: Levy Sgroi Geranutti, Bianca
Other Authors: Zerpa, Luis E., Prasad, Manika, Koh, Carolyn A. (Carolyn Ann), Miskimins, Jennifer L., Sonnenberg, Stephen A.
Format: Text
Language:English
Published: Colorado School of Mines. Arthur Lakes Library 2021
Subjects:
gas hydrate
permeability
waterflooding
multiphysics
coreflooding
undersaturated
Barents Sea
Norway
Online Access:https://hdl.handle.net/11124/176290
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record_format openpolar
spelling ftmountainschol:oai:mountainscholar.org:11124/176290 2023-05-15T15:39:13+02:00 Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments Levy Sgroi Geranutti, Bianca Zerpa, Luis E. Prasad, Manika Koh, Carolyn A. (Carolyn Ann) Miskimins, Jennifer L. Sonnenberg, Stephen A. 2021-04-19T10:54:37Z born digital masters theses application/pdf https://hdl.handle.net/11124/176290 English eng eng Colorado School of Mines. Arthur Lakes Library 2020 - Mines Theses & Dissertations LevySgroiGeranutti_mines_0052N_12050.pdf T 9022 https://hdl.handle.net/11124/176290 Copyright of the original work is retained by the author. Embargo Expires: 04/17/2022 gas hydrate permeability waterflooding multiphysics coreflooding undersaturated Text 2021 ftmountainschol 2022-03-07T20:40:27Z Includes bibliographical references. 2020 Fall. The Wisting Field is located at the Barents Sea, Norway. It is a shallow reservoir encountered at 71.9 bar and 17.8°C. The bubble point pressure is 68.6 bar at reservoir temperature, resulting in an undersaturated oil reservoir. The risk of gas hydrates formation is an important strategic knowledge since waterflooding with cold seawater (2 - 5°C) is being considered for the development of the field. The main concern regarding the formation of gas hydrates is that it can negatively affect the waterflooding process by reducing the intrinsic permeability of the reservoir rock. For this reason, the objective of this work was to assess the possibility of gas hydrate formation during the injection of cold water by performing coreflooding experiments and numerical simulations. Three different coreflood experiments were designed to determine hydrate formation conditions during cold water injection. The first setup used a 1.5 inches diameter and 2 inches in length core to assess static gas hydrate conditions with formation water and seawater. The detection of hydrates was performed with ultrasonic measurements. The second experiment was a coreflood that used a core sample of 3 inches in diameter and 10 inches in length instrumented with geophysical sensors to detect fluid phase transitions to a solid phase. The last setup was a coreflood with a 1.5 inches in diameter and 12 inches in length core sample. The experimental procedure consisted of detecting gas hydrate formation by an increase in the differential pressure measured across the core with high accuracy. Numerical simulations of the coreflooding experiments allowed to scale up the laboratory experimental observations to a field-scale waterflooding process. The model captured the permeability reduction as a function of hydrate saturation and was used to predict the performance of a waterflooding process in a five-spot vertical-well pattern. The simulations were performed using the STARS reservoir simulator from Computer Modelling Group (CMG) The results of this research showed that gas hydrates can form from dissolved gas inside porous media and are a risk during the waterflooding process. Fluid flow had a significant impact on triggering the hydrate formation reaction. The static coreflood test required a subcooling of 3°C larger than the coreflood experiments with fluid flow for gas hydrate formation. Results also showed that gas hydrates reduced the permeability of the reservoir. Text Barents Sea Mountain Scholar (Digital Collections of Colorado and Wyoming) Barents Sea Norway
institution Open Polar
collection Mountain Scholar (Digital Collections of Colorado and Wyoming)
op_collection_id ftmountainschol
language English
topic gas hydrate
permeability
waterflooding
multiphysics
coreflooding
undersaturated
spellingShingle gas hydrate
permeability
waterflooding
multiphysics
coreflooding
undersaturated
Levy Sgroi Geranutti, Bianca
Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
topic_facet gas hydrate
permeability
waterflooding
multiphysics
coreflooding
undersaturated
description Includes bibliographical references. 2020 Fall. The Wisting Field is located at the Barents Sea, Norway. It is a shallow reservoir encountered at 71.9 bar and 17.8°C. The bubble point pressure is 68.6 bar at reservoir temperature, resulting in an undersaturated oil reservoir. The risk of gas hydrates formation is an important strategic knowledge since waterflooding with cold seawater (2 - 5°C) is being considered for the development of the field. The main concern regarding the formation of gas hydrates is that it can negatively affect the waterflooding process by reducing the intrinsic permeability of the reservoir rock. For this reason, the objective of this work was to assess the possibility of gas hydrate formation during the injection of cold water by performing coreflooding experiments and numerical simulations. Three different coreflood experiments were designed to determine hydrate formation conditions during cold water injection. The first setup used a 1.5 inches diameter and 2 inches in length core to assess static gas hydrate conditions with formation water and seawater. The detection of hydrates was performed with ultrasonic measurements. The second experiment was a coreflood that used a core sample of 3 inches in diameter and 10 inches in length instrumented with geophysical sensors to detect fluid phase transitions to a solid phase. The last setup was a coreflood with a 1.5 inches in diameter and 12 inches in length core sample. The experimental procedure consisted of detecting gas hydrate formation by an increase in the differential pressure measured across the core with high accuracy. Numerical simulations of the coreflooding experiments allowed to scale up the laboratory experimental observations to a field-scale waterflooding process. The model captured the permeability reduction as a function of hydrate saturation and was used to predict the performance of a waterflooding process in a five-spot vertical-well pattern. The simulations were performed using the STARS reservoir simulator from Computer Modelling Group (CMG) The results of this research showed that gas hydrates can form from dissolved gas inside porous media and are a risk during the waterflooding process. Fluid flow had a significant impact on triggering the hydrate formation reaction. The static coreflood test required a subcooling of 3°C larger than the coreflood experiments with fluid flow for gas hydrate formation. Results also showed that gas hydrates reduced the permeability of the reservoir.
author2 Zerpa, Luis E.
Prasad, Manika
Koh, Carolyn A. (Carolyn Ann)
Miskimins, Jennifer L.
Sonnenberg, Stephen A.
format Text
author Levy Sgroi Geranutti, Bianca
author_facet Levy Sgroi Geranutti, Bianca
author_sort Levy Sgroi Geranutti, Bianca
title Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
title_short Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
title_full Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
title_fullStr Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
title_full_unstemmed Investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
title_sort investigation of gas hydrate formation during sea water injection based on undersaturated oil core flooding experiments
publisher Colorado School of Mines. Arthur Lakes Library
publishDate 2021
url https://hdl.handle.net/11124/176290
geographic Barents Sea
Norway
geographic_facet Barents Sea
Norway
genre Barents Sea
genre_facet Barents Sea
op_relation 2020 - Mines Theses & Dissertations
LevySgroiGeranutti_mines_0052N_12050.pdf
T 9022
https://hdl.handle.net/11124/176290
op_rights Copyright of the original work is retained by the author.
Embargo Expires: 04/17/2022
_version_ 1766370692299751424

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