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| ==Residual and continuous-phase shows== | | ==Residual and continuous-phase shows== |
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| + | [[file:predicting-reservoir-system-quality-and-performance_fig9-43.png|thumb|{{figure number|1}}See text for explanation.]] |
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| During reservoir water drainage, hydrocarbons enter a trap. The trap starts at 0% hydrocarbon saturation (S<sub>o</sub>), or 100% S<sub>w</sub>, and ends up with a higher S<sub>o</sub>. Water refills the reservoir as hydrocarbons exit a trap (fill-up). During fill-up some hydrocarbons are permanently left behind as a residual accumulation. There is no relative permeability to hydrocarbons in rocks containing residual hydrocarbons. At a point during fill-up, hydrocarbons no longer drain because they are no longer connected in a column but are isolated in pores. A DST of a zone with residual hydrocarbons produces no oil or gas, and an RFT would not show a hydrocarbon gradient. | | During reservoir water drainage, hydrocarbons enter a trap. The trap starts at 0% hydrocarbon saturation (S<sub>o</sub>), or 100% S<sub>w</sub>, and ends up with a higher S<sub>o</sub>. Water refills the reservoir as hydrocarbons exit a trap (fill-up). During fill-up some hydrocarbons are permanently left behind as a residual accumulation. There is no relative permeability to hydrocarbons in rocks containing residual hydrocarbons. At a point during fill-up, hydrocarbons no longer drain because they are no longer connected in a column but are isolated in pores. A DST of a zone with residual hydrocarbons produces no oil or gas, and an RFT would not show a hydrocarbon gradient. |
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− | The figure below shows drainage and fill-up relative permeability curves for an oil reservoir. In this example, the reservoir ends up with approximately 60% S<sub>w</sub>, or 40% residual hydrocarbon saturation.
| + | [[:file:predicting-reservoir-system-quality-and-performance_fig9-43.png|Figure 1]] shows drainage and fill-up relative permeability curves for an oil reservoir. In this example, the reservoir ends up with approximately 60% S<sub>w</sub>, or 40% residual hydrocarbon saturation. |
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− | [[file:predicting-reservoir-system-quality-and-performance_fig9-43.png|thumb|{{figure number|9-43}}See text for explanation.]]
| + | ===Trap with transition zone=== |
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− | ===Trap with transition zone===
| + | [[file:predicting-reservoir-system-quality-and-performance_fig9-44.png|thumb|left|{{figure number|2}}See text for explanation.]] |
− | The figure below is a schematic cross section of a [[stratigraphic trap]] with transition, reservoir, and waste zones and their corresponding show characteristics.
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− | [[file:predicting-reservoir-system-quality-and-performance_fig9-44.png|thumb|{{figure number|9-44}}See text for explanation.]] | + | [[:file:predicting-reservoir-system-quality-and-performance_fig9-44.png|Figure 2]] is a schematic cross section of a [[stratigraphic trap]] with transition, reservoir, and waste zones and their corresponding show characteristics. |
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| ===Trap with residual hydrocarbon zone=== | | ===Trap with residual hydrocarbon zone=== |
− | The figure below is a schematic cross section of a stratigraphic trap with residual hydrocarbon saturation, reservoir, and waste zones and their corresponding show characteristics.
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− | [[file:predicting-reservoir-system-quality-and-performance_fig9-45.png|thumb|{{figure number|9-45}}See text for explanation.]] | + | [[file:predicting-reservoir-system-quality-and-performance_fig9-45.png|thumb|{{figure number|3}}See text for explanation.]] |
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| + | [[:ile:predicting-reservoir-system-quality-and-performance_fig9-45.png|Figure 3]] is a schematic cross section of a stratigraphic trap with residual hydrocarbon saturation, reservoir, and waste zones and their corresponding show characteristics. |
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| ==See also== | | ==See also== |