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- {{merge|Seal capacity}} | chapter = Evaluating top and fault seal2 KB (325 words) - 20:57, 31 March 2022
- #REDIRECT [[Seal and hydrocarbon yield estimates]]50 bytes (6 words) - 20:18, 19 December 2014
- #REDIRECT [[Seal capacity: pitfalls and limitations of estimation]]67 bytes (8 words) - 21:45, 21 May 2014
- #REDIRECT [[Seal capacity variation with depth and hydrocarbon phase]]70 bytes (9 words) - 15:15, 21 July 2014
- | chapter = Evaluating top and fault seal ...ain seals. In practice, however, hydrocarbons continue to flow through the seal until there is no longer a continuous hydrocarbon filament. Although the pr5 KB (693 words) - 14:23, 1 April 2022
- ...utting a reservoir sequence, it is desirable to predict the likely [[Fault seal behavior|sealing behavior]] of each part of the fault system. ...erveld, R. C. M. W. Franssen, G. M. Ingram, and P. D. Richard, 1996, Fault seal processes, in Norwegian Petroleum Society, eds., Hydrocarbon seals-importan8 KB (1,307 words) - 16:05, 14 December 2016
- #REDIRECT [[Fault seal quantitative prediction: shale smear factor, shale gouge ratio, and smear g110 bytes (15 words) - 21:32, 29 September 2014
Page text matches
- | chapter = Evaluating top and fault seal In practice, the [[Top seal displacement pressure|displacement pressure]] (P<sub>d</sub>) is estimated2 KB (258 words) - 18:41, 31 March 2022
- | chapter = Evaluating top and fault seal ...seal]] or [[Cross-leaking faults|cross-leak]] and [[Dip-sealing faults|dip-seal]] or [[Dip-leaking faults|dip-leak]].3 KB (405 words) - 18:19, 29 March 2022
- | chapter = Evaluating top and fault seal ...y hole]] and has less-than-sufficient [[strain]] to [[fracture]] the top [[seal]].3 KB (430 words) - 19:46, 30 March 2022
- | chapter = Evaluating top and fault seal ...field in the Gulf Coast and demonstrates the application of routine fault seal analysis.5 KB (769 words) - 18:12, 29 March 2022
- | chapter = Evaluating top and fault seal ...re and composition of fault zones and the many factors that could affect a seal, it has been surprising to find such a simple relationship, basin after bas4 KB (509 words) - 16:52, 29 March 2022
- ==Significance of r<sub>bt</sub> for seal capacity== ...he same facies as the Midale vuggy beds, analyzed here as a possible updip seal. This study shows the updip change in pore throat sizes could account for 25 KB (723 words) - 17:02, 12 April 2022
- | chapter = Evaluating top and fault seal ...npublished abstract.</ref> Measured displacement pressures predict the top seal is capable of trapping 29–34 m (94–110 ft) of hydrocarbon. The actual c4 KB (587 words) - 13:36, 1 April 2022
- | chapter = Evaluating top and fault seal The most important mechanical property for evaluating seal integrity is [[ductility]]. Ductile rocks make good top seals; [[Brittlenes4 KB (510 words) - 15:22, 30 March 2022
- | chapter = Evaluating top and fault seal ...sk:_expected_value_and_chance_of_success#Probability_of_geological_success|seal risk]].<ref name=ch10r30>Fertl, W. H., and W. G. Leach, 1988, Economics of4 KB (605 words) - 20:30, 30 March 2022
- | chapter = Evaluating top and fault seal ...ccess#Probability_of_geological_success|Risking percent fill]] using fault seal analysis helps avoid needless wells.4 KB (515 words) - 21:31, 29 March 2022
- | chapter = Evaluating top and fault seal * [[Fault seal behavior]]2 KB (248 words) - 17:04, 28 March 2022
- Micropermeable leakage is caused by a variety of seal failure mechanisms, as discussed in the following sections. ...t for a geologically significant amount of time if the permeability of the seal to petroleum is low enough. These seals most likely occur in young basins w5 KB (742 words) - 17:11, 1 February 2022
- ...to [[fracture]] the rock. The result is natural hydraulic fracturing: the seal becomes hydrofractured and the petroleum leaks. Unlike other [[Fractured membrane seal leakage|fractured seals]], hydrofractures remain open only as long as [http5 KB (679 words) - 17:11, 1 February 2022
- | chapter = Evaluating top and fault seal ...not always static. Both hydrodynamic flow and pressure transients change [[seal capacity]].4 KB (477 words) - 14:34, 1 April 2022
- A seal can be either a pressure seal, a capillary seal, or both. They are defined as follows: ...umn]]. Water can move through an interconnected pore system in a capillary seal.5 KB (763 words) - 17:58, 17 February 2022
- ...ly or vertically, with pore throat sizes smaller than the carrier bed. The seal pore throat breakthrough pressure or the distance to the spill point of the1 KB (206 words) - 17:37, 27 January 2015
- | chapter = Evaluating top and fault seal ...kerlec, G., M., 1990, SEALS: A short course for risking top seal and fault seal: Franklin, Pennsylvania, SEALS International, 600 p.</ref> Koch et al., 1995 KB (757 words) - 15:43, 30 March 2022
- | chapter = Evaluating top and fault seal The [[Seal ductility|ductility of a top seal]] can be estimated (1) by using laboratory data and log-derived density val7 KB (1,000 words) - 15:22, 30 March 2022
- | chapter = Evaluating top and fault seal * [[Fault seal and migration pathways]]2 KB (316 words) - 18:20, 29 March 2022
- | chapter = Evaluating top and fault seal Different pressures across a fault imply cross seal. In [[:file:evaluating-top-and-fault-seal_fig10-8.png|Figure 3]], wells 1 a3 KB (399 words) - 21:31, 24 March 2022