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Line 36: − + − {| class = "wikitable"+ − |-+ − ! Step+ − ! Action − |- − | 1 − | Convert pressure scale (Y-axis) to hydrocarbon column length ( ''h'' ), where h = P<sub>c</sub> × conversion factor (if conversion is unknown, use 0.7 for oil and 0.4 for gas). − |- − | 2 − | Using the same scales, plot the curve next to a [[Cross section#Structural cross section|structure section]] showing the trap. Place the base of the curve at the free water level (see Figure 9-23). − |- − | 3 − | Estimate S<sub>w</sub> for any point in the reservoir by reading the S<sub>w</sub> that corresponds to the depth. − |} Line 71:
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Pc curves and saturation profiles (view source)
Revision as of 16:53, 4 April 2022
, 16:53, 4 April 2022added Category:Treatise Handbook 3 using HotCat
| part = Predicting the occurrence of oil and gas traps
| part = Predicting the occurrence of oil and gas traps
| chapter = Predicting reservoir system quality and performance
| chapter = Predicting reservoir system quality and performance
| frompg = 9-1
| frompg = 9-34
| topg = 9-156
| topg = 9-35
| author = Dan J. Hartmann, Edward A. Beaumont
| author = Dan J. Hartmann, Edward A. Beaumont
| link = http://archives.datapages.com/data/specpubs/beaumont/ch09/ch09.htm
| link = http://archives.datapages.com/data/specpubs/beaumont/ch09/ch09.htm
[[file:predicting-reservoir-system-quality-and-performance_fig9-22.png|300px|thumb|{{figure number|1}}Example reservoir cross section.]]
[[file:predicting-reservoir-system-quality-and-performance_fig9-22.png|300px|thumb|{{figure number|1}}Example reservoir cross section.]]
Water in the pore throats of rocks with macroporosity offers little capillary resistance to migrating hydrocarbons compared with the pore throats of rocks with microporosity. As a result, oil and gas migrate through a rock with macroporosity with minimal buoyancy pressure, i.e., hydrocarbon column. Macropore reservoirs have little or no saturation transition zone.
Water in the pore throats of rocks with macroporosity offers little capillary resistance to migrating hydrocarbons compared with the pore throats of rocks with microporosity. As a result, oil and gas migrate through a rock with macroporosity with minimal buoyancy pressure, i.e., [[hydrocarbon column]]. Macropore reservoirs have little or no saturation transition zone.
In rocks with microporosity, capillary forces hold water tightly to rock surfaces, decreasing the effective size of the already small pore throats. Therefore, a greater buoyancy pressure is required for oil or gas to migrate. Micropore reservoirs have longer saturation transition zones than macro- or mesoporous reservoirs; immobile water saturation is lower in macroporous rocks.
In rocks with microporosity, capillary forces hold water tightly to rock surfaces, decreasing the effective size of the already small pore throats. Therefore, a greater buoyancy pressure is required for oil or gas to migrate. Micropore reservoirs have longer saturation transition zones than macroporous or [[Wikipedia:Mesoporous material|mesoporous]] reservoirs; immobile water saturation is lower in macroporous rocks.
In the example reservoir [[cross section]] in [[:file:predicting-reservoir-system-quality-and-performance_fig9-22.png|Figure 1]], the rock in container 1 is mesoporous; the rock in container 2 is macroporous. Container 1 has a longer transition zone than container 2 because of this. Both containers have the same buoyancy pressure and free water level because the two containers are in pressure communication.
In the example reservoir [[cross section]] in [[:file:predicting-reservoir-system-quality-and-performance_fig9-22.png|Figure 1]], the rock in container 1 is mesoporous; the rock in container 2 is macroporous. Container 1 has a longer transition zone than container 2 because of this. Both containers have the same buoyancy pressure and free water level because the two containers are in pressure communication.
[[file:predicting-reservoir-system-quality-and-performance_fig9-23.png|300px|thumb|{{figure number|2}}Hypothetical examples of P<sub>c</sub> curves for rocks with varying pore throat size sorting.]]
[[file:predicting-reservoir-system-quality-and-performance_fig9-23.png|300px|thumb|{{figure number|2}}Hypothetical examples of P<sub>c</sub> curves for rocks with varying pore throat size sorting.]]
The graph in [[:file:predicting-reservoir-system-quality-and-performance_fig9-23.png|Figure 2]] shows hypothetical examples of P<sub>c</sub> curves for rocks with varying pore throat size sorting. The r<sub>35</sub> value is the same for each sample; therefore, all three curves pass through the same point. The curves labeled A illustrate different pore throat size sorting. If the pore throats of the sample have a narrow range of sizes (i.e., are well sorted), the P<sub>c</sub> curve will be flat as the pressure in the mercury reaches the entry pressure for those pore throats. If the range of pore throat sizes is wide, the curve will steepen.
The graph in [[:file:predicting-reservoir-system-quality-and-performance_fig9-23.png|Figure 2]] shows hypothetical examples of P<sub>c</sub> curves for rocks with varying pore throat size sorting. The [[Characterizing_rock_quality#What_is_r35.3F|r<sub>35</sub>]] value is the same for each sample; therefore, all three curves pass through the same point. The curves labeled A illustrate different pore throat size sorting. If the pore throats of the sample have a narrow range of sizes (i.e., are well sorted), the P<sub>c</sub> curve will be flat as the pressure in the mercury reaches the entry pressure for those pore throats. If the range of pore throat sizes is wide, the curve will steepen.
==Making s<sub>w</sub> profiles from p<sub>c</sub> curves==
==Making s<sub>w</sub> profiles from p<sub>c</sub> curves==
If a P<sub>c</sub> curve is available, then a profile of S<sub>w</sub> can be approximated using information from the curve. To make an S<sub>w</sub> profile of a reservoir using a P<sub>c</sub> curve, use the table below.
If a P<sub>c</sub> curve is available, then a profile of S<sub>w</sub> can be approximated using information from the curve. To make an S<sub>w</sub> profile of a reservoir using a P<sub>c</sub> curve, use the table below.
# Convert pressure scale (Y-axis) to hydrocarbon column length ( ''h'' ), where h = P<sub>c</sub> × conversion factor (if conversion is unknown, use 0.7 for oil and 0.4 for gas).
# Using the same scales, plot the curve next to a [[Cross section#Structural cross section|structure section]] showing the trap. Place the base of the curve at the free water level (see Figure 9-23).
# Estimate S<sub>w</sub> for any point in the reservoir by reading the S<sub>w</sub> that corresponds to the depth.
==See also==
==See also==
[[Category:Predicting the occurrence of oil and gas traps]]
[[Category:Predicting the occurrence of oil and gas traps]]
[[Category:Predicting reservoir system quality and performance]]
[[Category:Predicting reservoir system quality and performance]]
[[Category:Treatise Handbook 3]]