Summary
It is well known that absolute permeability changes occur in coalbed methane
(CBM) reservoirs during primary depletion or enhanced recovery/CO2
sequestration operations. Sorption-induced strain in CBM reservoirs, also known
as matrix shrinkage or swelling, may dominate permeability changes at low
pressures, as is the case for CBM wells undergoing primary depletion in the
Fruitland coal fairway of the San Juan basin.
Several analytical models have been developed to predict changes in coal
permeability as a function of stress and sorption. Most models, however,
utilize an empirical method for estimating sorption-induced strain. Recently, a
theoretical model for sorption-induced strain was developed and applied to
single-component adsorption/strain experimental data. The new model was
developed from basic thermodynamic principles and is more predictive than the
empirically based approaches. In this paper, the theoretical model is expanded
to incorporate multicomponent adsorption models that are more rigorous, and
sometimes more accurate, than the commonly applied extended Langmuir (EL)
equation. This improves predictions of multicomponent gas sorption-induced
strain, as demonstrated by comparison to experimental data. The new
sorption-induced strain model is then used to calculate the sorption-strain
component of the popular Palmer and Mansoori (P&M) equation, which, in
turn, can be used to model permeability changes during both primary (single- or
multicomponent gas) and enhanced recovery operations. Finally, the coupled
sorption-strain/permeability model, incorporated into an analytical simulator,
is used to predict and match permeability growth in a producing CBM well in the
Fruitland coal fairway, which has a binary (CH4 + CO2)
sorbed/produced gas composition.
Matches to field-derived permeability growth using the new model are
accurate but nonunique because of the lack of available data, particularly rock
mechanical properties. Given the availability of rock mechanics and adsorption
isotherm data, the rigorous thermodynamic basis of the new model should allow
for more accurate predictions of coalbed permeability changes, but further
testing is required.
© 2009. Society of Petroleum Engineers
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History
- Original manuscript received:
3 July 2008
- Meeting paper published:
21 September 2008
- Manuscript approved:
15 May 2009
- Published online:
26 October 2009
- Version of record:
12 March 2010
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