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Results
The resource triangle, Figure 1, describes the distribution of original gas in place (OGIP) in a typical basin.[1] At the top of the triangle are the high permeability reservoirs. These reservoirs are small, and, once discovered, as much as 80 to 90% of the OGIP can be produced using conventional drilling and completion methods. As we go deeper into the resource triangle, the permeability decreases, but the size of the resource increases. Higher gas prices and better technology are required to produce significant volumes of gas from these tight gas reservoirs. The recovery efficiency is computed by dividing the cumulative gas produced by the OGIP volume.
Canada government, complex reservoir, equation, flow in porous media, Fluid Dynamics, fracture, fracture closure, ga reservoir, graph, hydraulic fracture, hyperbolic equation, knowledge management, layered reservoir, OGIP, permeability ga reservoir, permeability reservoir, production control, production monitoring, recovery efficiency, reserves estimation, reservoir, Reservoir Surveillance, table 1, tight gas, triangle, Upstream Oil & Gas
Oilfield Places:
- North America > Canada > British Columbia > Western Canada Sedimentary Basin > Alberta Basin > Deep Basin (0.99)
- North America > Canada > Alberta > Western Canada Sedimentary Basin > Alberta Basin > Deep Basin (0.99)
SPE Disciplines:
- Reservoir Description and Dynamics > Unconventional and Complex Reservoirs > Tight gas (1.00)
- Reservoir Description and Dynamics > Reservoir Fluid Dynamics > Flow in porous media (1.00)
- Reservoir Description and Dynamics > Reserves Evaluation (1.00)
- Production and Well Operations > Well & Reservoir Surveillance and Monitoring (1.00)
Technology:
- Information Technology > Knowledge Management (0.41)
- Information Technology > Communications > Collaboration (0.41)