CO2 Injection for Enhanced Gas Recovery and Geological Storage of CO2 in the Long Coulee Glauconite F Pool, Alberta

Abstract: Impure CO2 containing less than 2% H2S has been injected since 2002 into the depleted Long Coulee Glauconite F gas Pool in southeastern Alberta. Breakthrough was observed within one to three years in producing wells, leading to their abandonment. Simulation studies reported in this paper indicate that additional gas was recovered as a result of CO2 injection. An interesting observation at the breakthrough wells was that the CO2 broke through ahead of the H2S. The partitioning of the H2S and CO2 as they flow th… Show more

“…Physical dispersion at smaller length scales is also important because, as discussed below, the description of transport at the core scale can play an important role in the prediction of mixing at the field scale, particularly for carbonate formations. These challenges to describing the mixing of CO 2 and natural gas have limited EGR projects to only a few field trials (Pooladi-Darvish et al, 2008;Vandeweijer et al, 2011). The only current field-scale EGR project is the Rotliegend K12-B gas reservoir, located offshore of the Netherlands, which started in 2004 after 17 years of conventional gas production (Vandeweijer et al, 2011).…”

“…The EGR process began by injecting produced CO 2 into the formation of this depleted gas reservoir, improving the gas recovery along with CO 2 sequestration. A Canadian depleted gas reservoir was also used for an EGR/CO 2 sequestration trial in 2002 but the operation was terminated after three years due to the early CO 2 breakthrough into the producing wells (Pooladi-Darvish et al, 2008). Both of these two EGR field trials were implemented in sandstone formations, and carbonate reservoirs have not yet been considered for any EGR projects, largely due to their inherent heterogeneity and fluid flow and transport complexity.…”

Enhanced gas recovery with CO2 sequestration: The effect of medium heterogeneity on the dispersion of supercritical CO2–CH4

“…Physical dispersion at smaller length scales is also important because, as discussed below, the description of transport at the core scale can play an important role in the prediction of mixing at the field scale, particularly for carbonate formations. These challenges to describing the mixing of CO 2 and natural gas have limited EGR projects to only a few field trials (Pooladi-Darvish et al, 2008;Vandeweijer et al, 2011). The only current field-scale EGR project is the Rotliegend K12-B gas reservoir, located offshore of the Netherlands, which started in 2004 after 17 years of conventional gas production (Vandeweijer et al, 2011).…”

“…The EGR process began by injecting produced CO 2 into the formation of this depleted gas reservoir, improving the gas recovery along with CO 2 sequestration. A Canadian depleted gas reservoir was also used for an EGR/CO 2 sequestration trial in 2002 but the operation was terminated after three years due to the early CO 2 breakthrough into the producing wells (Pooladi-Darvish et al, 2008). Both of these two EGR field trials were implemented in sandstone formations, and carbonate reservoirs have not yet been considered for any EGR projects, largely due to their inherent heterogeneity and fluid flow and transport complexity.…”

Enhanced gas recovery with CO2 sequestration: The effect of medium heterogeneity on the dispersion of supercritical CO2–CH4

“…In these cases, sites must meet an additional set of criteria very specific to the respective process of enhanced oil or gas recovery. use of cO 2 in enhanced gas recovery has not been practised to date, and it is questionable because gas reservoirs have a high recovery factor (greater than 80 %) and because, at the low reservoir pressures attained at this stage of production, cO 2 will expand quickly in the reservoir and will be produced together with the remaining gas (e.g., Pooladi-Darvish et al, 2008), hence necessitating additional separating facilities and recirculating the produced cO 2 . Thus, cO 2 will most likely be stored in gas reservoirs after abandonment (depletion).…”

Screening and selection criteria, and characterisation techniques for the geological sequestration of carbon dioxide (CO2)

“…Since 2004 a total of 90 kT of CO 2 has been injected . A Canadian depleted gas reservoir was also used for an EGR/CO 2 sequestration trial in 2002; however, the operation was terminated after 3 years due to early CO 2 breakthrough at the natural gas production wells . Nevertheless, the outlook for EGR remains generally positive: a recent review of active CO 2 storage sites including the K12‐B EGR operation, established that they do not have a negative impact on the environment and considerations regarding such operations are now extending to include site closure at the end of the injection period .…”

Quantitative dependence of CH₄‐CO₂ dispersion on immobile water fraction