| Authors |
M. Winkler, R. Abernethy, M. Nicolo, H. Huang, A. Wang, S. Zhang, A. Simone,
C. Clark, S Crouch, H. De Groot, R. El Mahdy, M. Smith, S. Malik, S. Bourne, R.
Pierpont, V. Hugonet, Shell
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| Source |
SPE International Conference on CO2 Capture, Storage, and Utilization,
10-12 November 2010,
New Orleans, Louisiana, USA
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| Preview |
Abstract
The Athabasca Oil Sands Project Joint Venture (AOSP JV) owners – Shell
Canada Energy (Shell), Chevron Canada Limited (Chevron) and Marathon Oil Sands
L.P. (Marathon) – are advancing front-end development plans of a fully
integrated carbon capture, pipeline and storage project in Alberta called the
Quest CCS Project. A Final Investment Decision for Quest is scheduled for 2012.
Quest is designed as a fully integrated CCS project in the oil sands sector
involving CO2 capture at the Scotford upgrader near Fort Saskatchewan, pipeline
transportation northeast from Scotford and CO2 storage in a deep saline
formation zone, the Basal Cambrian Sand. Over the expected lifetime of 25
years, the project will capture and store up to 1.1 Mt of CO2 per year from the
steam methane reformer units at the existing Scotford upgrader and at the
upgrader’s expansion currently under construction
Conventional volumetric methods for the pore space assessment of CO2 storage,
such as the guidance provided by the 2008 Carbon Sequestration ATLAS of the
United States and Canada, are good tools in estimating the pore space
available, while also considering empirical DOE ranges for storage efficiency,
such as area and vertical sweep efficiency, gravity contact efficiency and
microscopic displacement efficiency. Such assessment would suggest a CO2
storage capacity of the Basal Cambrian Sand at Quest of approximately 7 Mt per
township (6 miles x 6 miles). However, such an estimate is of a static nature,
not taking into account dynamic system constraints such as required injection
rates, bottom-hole pressure constraints and associated well count and well
spacing, including pressure interference and regional pore pressure
increase.
Dynamic reservoir simulation has been performed, for a variety of subsurface
realizations, covering the full range of current subsurface uncertainties, with
the aim to optimize the development while also estimating the required pore
space for CO2 storage. Following the concept of linking the required pore space
to pore pressure increase, rather than CO2 plume extension, resulted in a
significant reduction of pore space utilization in the Basal Cambrian Sand from
the initial 7 Mt per township to only 0.67 Mt per township and will have a
potential impact on additional CCS developments in the region.
Introduction
On the 31st March 2009 Shell Canada Energy, on behalf of the Athabasca Oil
Sands Project (AOSP JV) submitted a Full Project Proposal (FPP) to the Alberta
Department of Energy (ADOE) to develop the Quest CCS Project. The submission
was prepared within a CCS framework set out by the ADOE. The basis of the Quest
Project is to capture and compress 1.1 Mtpa of CO2 from the Shell Scotford
bitumen upgraders and transport it via a new pipeline and wells to an
underground storage complex located approximately 70 km from Scotford (Figure
1). The preferred geological formation for storage is the Basal Cambrian Sands
(BCS) highly saline aquifer which, at 2 km depth in this area, is the deepest
sedimentary formation in the Western Canadian Sedimentary Basin (WCSB).
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