Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic
When significant pore pressure changes occur because of production from a hydrocarbon reservoir the rocks both inside and outside of the reservoir deform. This deformation results in traveltime changes between reflection events on timelapse seismic data, because the distance between reflection event...
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Heriot-Watt University
2009
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| Online Access: | http://hdl.handle.net/10399/2320 |
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ftheriotwattuniv:oai:www.ros.hw.ac.uk:10399/2320 2023-05-15T17:47:09+02:00 Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic Hodgson, Neil 2009-11 application/pdf http://hdl.handle.net/10399/2320 en eng Heriot-Watt University Petroleum Engineering http://hdl.handle.net/10399/2320 All items in ROS are protected by the Creative Commons copyright license (http://creativecommons.org/licenses/by-nc-nd/2.5/scotland/), with some rights reserved. CC-BY-NC-ND Thesis 2009 ftheriotwattuniv 2021-06-18T06:05:12Z When significant pore pressure changes occur because of production from a hydrocarbon reservoir the rocks both inside and outside of the reservoir deform. This deformation results in traveltime changes between reflection events on timelapse seismic data, because the distance between reflection events is altered and the seismic velocity changes with the strain. These traveltime differences are referred to as time-lapse time shifts. In this thesis, time-lapse time shifts observed in the overburden are used as an input to a linear inversion for reservoir pressure. Measurements from the overburden are used because, in general, time shift estimates are more stable, the strain deformations can be considered linear, and fluid effects are negligible, compared to the reservoirlevel signal. A critical examination of methods currently available to measure time-lapse time shifts is offered. It is found that available methods are most accurate when the time shifts are slowly varying with pressure and changes in the seismic reflectivity are negligible. While both of these conditions are generally met in the overburden they are rarely met at reservoir level. Next, a geomechanical model that linearly relates the overburden time-lapse time shifts to reservoir pressure is considered. This model takes a semi-analytical approach by numerical integration of a nucleus of strain in a homogeneous poroelastic halfspace. Although this model has the potentially limiting assumption of a homogenous medium, it allows for reservoirs of arbitrary geometries, and, in contrast to the complex numerical approaches, it is simple to parameterise and compututationally efficient. This model is used to create a linear inversion scheme which is first tested on synthetic data output from complex finite-element model. Despite the simplifications of the i inversion operator the pressure change is recovered to within ±10% normalised error of the true pressure distribution. Next, the inversion scheme is applied to two real data cases in different geological settings. First to a sector of the Valhall Field, a compacting chalk reservoir in the Norwegian Sea, and then the Genesis Field, a stacked turbidite in the Gulf of Mexico. In both cases the results give good qualitative matches to existing reservoir simulator estimates of compaction or pressure depletion. It is possible that updating of the simulation model may be assisted by these results. Further avenues of investigation are proposed to test the robustness of the simplified geomechanical approach in the presence of more complex geomechanical features such as faults and strong material contrasts. Thesis Norwegian Sea Heriot-Watt University, Edinburgh: ROS - The Research Output Service Norwegian Sea Valhall ENVELOPE(14.217,14.217,68.229,68.229) |
| institution |
Open Polar |
| collection |
Heriot-Watt University, Edinburgh: ROS - The Research Output Service |
| op_collection_id |
ftheriotwattuniv |
| language |
English |
| description |
When significant pore pressure changes occur because of production from a hydrocarbon reservoir the rocks both inside and outside of the reservoir deform. This deformation results in traveltime changes between reflection events on timelapse seismic data, because the distance between reflection events is altered and the seismic velocity changes with the strain. These traveltime differences are referred to as time-lapse time shifts. In this thesis, time-lapse time shifts observed in the overburden are used as an input to a linear inversion for reservoir pressure. Measurements from the overburden are used because, in general, time shift estimates are more stable, the strain deformations can be considered linear, and fluid effects are negligible, compared to the reservoirlevel signal. A critical examination of methods currently available to measure time-lapse time shifts is offered. It is found that available methods are most accurate when the time shifts are slowly varying with pressure and changes in the seismic reflectivity are negligible. While both of these conditions are generally met in the overburden they are rarely met at reservoir level. Next, a geomechanical model that linearly relates the overburden time-lapse time shifts to reservoir pressure is considered. This model takes a semi-analytical approach by numerical integration of a nucleus of strain in a homogeneous poroelastic halfspace. Although this model has the potentially limiting assumption of a homogenous medium, it allows for reservoirs of arbitrary geometries, and, in contrast to the complex numerical approaches, it is simple to parameterise and compututationally efficient. This model is used to create a linear inversion scheme which is first tested on synthetic data output from complex finite-element model. Despite the simplifications of the i inversion operator the pressure change is recovered to within ±10% normalised error of the true pressure distribution. Next, the inversion scheme is applied to two real data cases in different geological settings. First to a sector of the Valhall Field, a compacting chalk reservoir in the Norwegian Sea, and then the Genesis Field, a stacked turbidite in the Gulf of Mexico. In both cases the results give good qualitative matches to existing reservoir simulator estimates of compaction or pressure depletion. It is possible that updating of the simulation model may be assisted by these results. Further avenues of investigation are proposed to test the robustness of the simplified geomechanical approach in the presence of more complex geomechanical features such as faults and strong material contrasts. |
| format |
Thesis |
| author |
Hodgson, Neil |
| spellingShingle |
Hodgson, Neil Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic |
| author_facet |
Hodgson, Neil |
| author_sort |
Hodgson, Neil |
| title |
Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic |
| title_short |
Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic |
| title_full |
Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic |
| title_fullStr |
Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic |
| title_full_unstemmed |
Inversion for reservoir pressure change using overburden strain measurements determined from 4D seismic |
| title_sort |
inversion for reservoir pressure change using overburden strain measurements determined from 4d seismic |
| publisher |
Heriot-Watt University |
| publishDate |
2009 |
| url |
http://hdl.handle.net/10399/2320 |
| long_lat |
ENVELOPE(14.217,14.217,68.229,68.229) |
| geographic |
Norwegian Sea Valhall |
| geographic_facet |
Norwegian Sea Valhall |
| genre |
Norwegian Sea |
| genre_facet |
Norwegian Sea |
| op_relation |
http://hdl.handle.net/10399/2320 |
| op_rights |
All items in ROS are protected by the Creative Commons copyright license (http://creativecommons.org/licenses/by-nc-nd/2.5/scotland/), with some rights reserved. |
| op_rightsnorm |
CC-BY-NC-ND |
| _version_ |
1766151490031845376 |