10,335
edits
Changes
Jump to navigation
Jump to search
Line 16:
Line 16: − +
Fracture threshold in the real world (view source)
Revision as of 14:49, 10 February 2014
, 14:49, 10 February 2014no edit summary
We don't really know how high the pore pressure must be to induce fracturing. In field examples, failure seems to occur below the fracture pressure.<ref name=ch10r70>Skerlec, G., M., 1982, Risking top seals in the Central Graben: Exxon Production Research Company internal report.</ref><ref name=ch10r71>Skerlec, G., M., 1990, SEALS: A short course for risking top seal and fault seal: Franklin, Pennsylvania, SEALS International, 600 p.</ref><ref name=ch10r21>Dutta, N., C., 1987, Fluid flow in low [[permeability]] porous media, in Doligez, B., ed., [[Migration]] of Hydrocarbons in Sedimentary Basins: Paris, Editions Technip, p. 567–596.</ref><ref name=ch10r49>Lerche, I., 1990, Basin Analysis I: San Diego, Academic Press, 562 p.</ref><ref name=ch10r84>Ungerer, P., Burrus, J., Doligez, B., Chenet, P., Y., Bessis, F., 1990, [http://archives.datapages.com/data/bulletns/1990-91/data/pg/0074/0003/0000/0309.htm Basin evaluation by integrated two-dimensional modeling of heat transfer, fluid flow, hydrocarbon generation, and migration]: AAPG Bulletin, vol. 74, no. 3, p. 309–335.</ref> Risk increases as overpressure increases relative to P<sub>f</sub>, but failure may occur below the theoretical fracture pressure. Other factors, not yet understood, control the point at which failure occurs.
We don't really know how high the pore pressure must be to induce fracturing. In field examples, failure seems to occur below the fracture pressure.<ref name=ch10r70>Skerlec, G., M., 1982, Risking top seals in the Central Graben: Exxon Production Research Company internal report.</ref><ref name=ch10r71>Skerlec, G., M., 1990, SEALS: A short course for risking top seal and fault seal: Franklin, Pennsylvania, SEALS International, 600 p.</ref><ref name=ch10r21>Dutta, N., C., 1987, Fluid flow in low [[permeability]] porous media, in Doligez, B., ed., [[Migration]] of Hydrocarbons in Sedimentary Basins: Paris, Editions Technip, p. 567–596.</ref><ref name=ch10r49>Lerche, I., 1990, Basin Analysis I: San Diego, Academic Press, 562 p.</ref><ref name=ch10r84>Ungerer, P., Burrus, J., Doligez, B., Chenet, P., Y., Bessis, F., 1990, [http://archives.datapages.com/data/bulletns/1990-91/data/pg/0074/0003/0000/0309.htm Basin evaluation by integrated two-dimensional modeling of heat transfer, fluid flow, hydrocarbon generation, and migration]: AAPG Bulletin, vol. 74, no. 3, p. 309–335.</ref> Risk increases as overpressure increases relative to P<sub>f</sub>, but failure may occur below the theoretical fracture pressure. Other factors, not yet understood, control the point at which failure occurs.
Theoretically, fracturing occurs when the pore pressure reaches P<sub>f</sub>. However, P<sub>f</sub> increases as pore pressure increases. Although the theory generally is described in terms of the pore pressure needed to overcome the horizontal stress keeping the fractures closed, in practice the pore pressure must approach the lithostatic pressure for brittle failure to occur.<ref name=ch10r52>Lorenz, J., C., Teufel, L., W., Warpinski, N., R., 1991, Regional fractures: a mechanism for the formation of regional fractures at depth in flat-lying reservoirs: AAPG Bulletin, vol. 75, no. 11, p. 1714–1737.</ref>
Theoretically, fracturing occurs when the pore pressure reaches P<sub>f</sub>. However, P<sub>f</sub> increases as pore pressure increases. Although the theory generally is described in terms of the pore pressure needed to overcome the horizontal stress keeping the fractures closed, in practice the pore pressure must approach the lithostatic pressure for brittle failure to occur.<ref name=ch10r52>Lorenz, J., C., Teufel, L., W., Warpinski, N., R., 1991, [http://archives.datapages.com/data/bulletns/1990-91/data/pg/0075/0011/0000/1714.htm Regional fractures: a mechanism for the formation of regional fractures at depth in flat-lying reservoirs]: AAPG Bulletin, vol. 75, no. 11, p. 1714–1737.</ref>
[[:file:evaluating-top-and-fault-seal_fig10-42.png|figure 1]] charts P<sub>f</sub> vs. pore pressure for a range of overburden stress gradients (0.5–1.0). The pore pressure equals or exceeds P<sub>f</sub> only when the pore pressure is equal to or greater than the lithostatic stress. Fracture occurs when P<sub>f</sub> equals the pore pressure.
[[:file:evaluating-top-and-fault-seal_fig10-42.png|figure 1]] charts P<sub>f</sub> vs. pore pressure for a range of overburden stress gradients (0.5–1.0). The pore pressure equals or exceeds P<sub>f</sub> only when the pore pressure is equal to or greater than the lithostatic stress. Fracture occurs when P<sub>f</sub> equals the pore pressure.