SPE Reservoir Evaluation & Engineering
Volume 15,
Number 4,
December 2012,
pp. 662-675
Summary
Steam-assisted gravity drainage (SAGD) is the primary in-situ recovery
method for bitumen from the large Athabasca deposit in Alberta, Canada. SAGD
field operations encounter a significant decrease in production performance
when low-permeability shale barriers are present in the formation. These layers
can reduce SAGD performance and impede the growth of the steam chamber. They
also significantly limit the percentage of the deposit from which bitumen can
be economically recovered with SAGD. The concept of drilling vertical slimholes
to create flow paths through barriers was conceived and investigated at Alberta
Innovates?Technology Futures (AITF), formerly the Alberta Research Council. The
use of slimholes has the potential to significantly increase the amount of
recoverable bitumen (reserves) and the rate at which it is produced during
SAGD. For shallow reservoirs, the slimholes could be drilled from the surface
at a relatively low cost. It is believed that the process can be economically
viable after its technical operation has been optimized with improvements in
drilling technology, slimhole size and spacing, and enhanced usage of the
slimholes in the development of steam chambers above the shale layers.
Alternatively, the slimholes could be drilled from the horizontal wellbores (to
avoid surface disturbance) as either horizontal slimholes from the producer or
as horizontal/vertical slimhole combinations from the injector. The 2D and 3D
field-scale numerical simulations were performed by use of reservoir properties
and operating conditions based on published information for the MacKay River
SAGD operation in the Athabasca deposit. The reservoir depth was 135 m, the
initial pressure 500 kPaa, the initial temperature 7.5°C, and the initial oil
saturation (SO ) 0.8. The simulations explored the effect of
vertical slimholes, which were laterally offset 7 m from the horizontal
well-pair in reservoirs with and without shale layers or shale lenses. The
effects on SAGD performance that were investigated were slimhole cross section
(25 cm x 25 cm or 50 cm x 50 cm), the distance between slimholes (12 or 24 m)
in the direction parallel to the well pair, the permeability of the reservoir
and the vertical slimholes, and horizontal slimholes from the injector or
producer. The slimhole cross section represents the disturbed area adjacent to
the drilled slimhole and the drilled hole itself and is therefore relatively
large. The slimholes were represented as high-permeability vertical channels by
use of refined grids. For a reservoir with a continuous shale layer, SAGD
performance was improved by vertical slimholes because of the recovery of
previously inaccessible oil from above the shale layer, where a secondary steam
chamber was formed.
© 2012. Society of Petroleum Engineers
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History
- Original manuscript received:
14 October 2011
- Meeting paper published:
15 November 2011
- Revised manuscript received:
10 September 2012
- Manuscript approved:
17 September 2012
- Published online:
29 November 2012
- Version of record:
27 December 2012
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