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- 14:43, 14 January 2014 diff hist -7,410 Reservoir modeling for simulation purposes Initial import
- 14:35, 14 January 2014 diff hist +143 N File:Reservoir-modeling-for-simulation-purposes fig5.png Mapping of reservoir properties per grid block layer to provide input for the reservoir simulation. Category:Reservoir engineering methods current
- 14:35, 14 January 2014 diff hist +118 N File:Reservoir-modeling-for-simulation-purposes fig4.png Correlation of reservoir units and subdivision of reservoir In flow units. Category:Reservoir engineering methods current
- 14:35, 14 January 2014 diff hist +124 N File:Reservoir-modeling-for-simulation-purposes fig3.png Log-facies calibration and determination of facies-related rock characteristics. Category:Reservoir engineering methods current
- 14:35, 14 January 2014 diff hist +120 N File:Reservoir-modeling-for-simulation-purposes fig2.png Analysis of core data for facies identification and rock quality assessment. Category:Reservoir engineering methods current
- 14:35, 14 January 2014 diff hist +92 N File:Reservoir-modeling-for-simulation-purposes fig1.png Classification of reservoir heterogeneity types. Category:Reservoir engineering methods current
- 14:35, 14 January 2014 diff hist +24,481 N Reservoir modeling for simulation purposes Initial import
- 14:35, 14 January 2014 diff hist +224 N File:Forward-modeling-of-seismic-data fig2.png Synthetic seismograms for the model in Figure 1. By synthetic modeling of a migrated section, the expected seismic signatures of reefs containing porosity and tight reefs have been obtained. Category:Geophysical methods current
- 14:35, 14 January 2014 diff hist +180 N File:Forward-modeling-of-seismic-data fig1.png A strike cross section of a carbonate reef play. The reef structure on the left contains porosity, while the reef structure on the right is tight. Category:Geophysical methods current
- 14:35, 14 January 2014 diff hist +10,283 N Forward modeling of seismic data Initial import
- 13:58, 14 January 2014 diff hist +9,293 N Formation evaluation of naturally fractured reservoirs Initial import
- 01:52, 14 January 2014 diff hist +163 N File:Petroleum-reservoir-fluid-properties fig2.png Pressure-temperature phase diagrams of gas cap and oil fluids in a reservoir that is Initially at saturated conditions. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +258 N File:Petroleum-reservoir-fluid-properties fig1.png Pressure-temperature phase diagram. Reservoir classification would be <italic>oil</italic> if reservoir temperature were less than 127 °F and <italic>gas</italic> if reservoir temperature were greater than 127°F. [[Category:Reservoir engineering met... current
- 01:52, 14 January 2014 diff hist +19,762 N Petroleum reservoir fluid properties Initial import
- 01:52, 14 January 2014 diff hist +70 N File:Fundamentals-of-fluid-flow fig7.png Stimulation effect on IPR. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +75 N File:Fundamentals-of-fluid-flow fig6.png Depletion deterioration of IPR. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +56 N File:Fundamentals-of-fluid-flow fig5.png Skin effect. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +88 N File:Fundamentals-of-fluid-flow fig4.png Pressure distribution in a radiai reservoir. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +76 N File:Fundamentals-of-fluid-flow fig3.png Two-phase relative permeability. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +80 N File:Fundamentals-of-fluid-flow fig2.png Plots of multi-rate production data. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +94 N File:Fundamentals-of-fluid-flow fig1.png Pressure conditions in a simple production system. Category:Reservoir engineering methods current
- 01:52, 14 January 2014 diff hist +19,218 N Fluid flow fundamentals Initial import
- 01:52, 14 January 2014 diff hist +723 N File:Fluid-contacts fig5.png Irregular contact caused by semipermeable barriers in a reservoir. (a) Capillary behavior of the reservoir and barriers A, B, and C. (b) Fluid contact elevations result from charging of the reservoir from the left. Each compartment of the reservoir has... current
- 01:52, 14 January 2014 diff hist +788 N File:Fluid-contacts fig4.png Effect of reservoir heterogeneity on fluid contacts. (a) Capillary pressure curves for facies A and B within the reservoir. The dashed line corresponds to the saturation trend of the well In part (b). Sharp changes in saturation correspond to elevation... current
- 01:51, 14 January 2014 diff hist +195 N File:Fluid-contacts fig3.png Example of calculating hydrodynamic fluid contacts from pressure data. Pressure elevations are shown by arrows. Calculated fluid contacts are shown by thin lines. Category:Geological methods current
- 01:51, 14 January 2014 diff hist +432 N File:Fluid-contacts fig2.png Geometries of fluid contacts. (a) Horizontal contacts indicative of hydrostatic conditions in homogeneous reservoir rock. (b) Tilted, flat contacts resulting from hydrodynamic conditions. (c) Contact elevation is constant for each lithology type, but p... current
- 01:51, 14 January 2014 diff hist +635 N File:Fluid-contacts fig1.png Contact definitions and relationship of contacts in a pool (right) to reservoir capillary pressure and fluid production curves (left). The free water surface is the highest elevation with the same oil and water pressure (zero capillary pressure). The o... current
- 01:51, 14 January 2014 diff hist +17,276 N Fluid contacts Initial import
- 01:50, 14 January 2014 diff hist +46 N File:Fishing fig11.png Wireline spear. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +42 N File:Fishing fig10.png Pipe spear. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +40 N File:Fishing fig9.png Overshot. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +45 N File:Fishing fig8.png Washover pipe. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +63 N File:Fishing fig7.png (a) Tapered mill, (b) Flat mill. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +48 N File:Fishing fig6.png Core type basket. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +131 N File:Fishing fig5.png {{copyright|Exploration Logging, 1979}} Poor boy junk basket. Copyright: Exploration Logging, 1979. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +43 N File:Fishing fig4.png Junk basket. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +38 N File:Fishing fig3.png Magnet. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +164 N File:Fishing fig2.png {{copyright|Short, 1981</xref>; courtesy of PennWell Books}} Key seating. Copyright: Short, 1981</xref>; courtesy of PennWell Books. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +132 N File:Fishing fig1.png {{copyright|Exploration Logging, 1979}} Differential sticking. Copyright: Exploration Logging, 1979. Category:Wellsite methods current
- 01:50, 14 January 2014 diff hist +7,079 N Fishing Initial import
- 01:49, 14 January 2014 diff hist +331 N File:Enhanced-oil-recovery fig4.png {{copyright|U.S. Department of Energy, Bartlesville, Oklahoma}} Schematic diagram of <italic>in situ</italic> combustion. The mobility of oil is increased by reduced viscosity caused by heat and solution of combustion gases. Copyright: U.S. Department... current
- 01:49, 14 January 2014 diff hist +285 N File:Enhanced-oil-recovery fig3.png {{copyright|U.S. Department of Energy, Bartlesville, Oklahoma}} Schematic diagram of steam flooding. In this method, heat reduces the viscosity of oil and increases its mobility. Copyright: U.S. Department of Energy, Bartlesville, Oklahoma. [[Categor... current
- 01:49, 14 January 2014 diff hist +297 N File:Enhanced-oil-recovery fig2.png {{copyright|U.S. Department of Energy, Bartlesville, Oklahoma}} Schematic diagram of carbon dioxide flooding. The viscosity of oil is reduced, providing more efficient miscible displacement. Copyright: U.S. Department of Energy, Bartlesville, Oklahoma... current
- 01:49, 14 January 2014 diff hist +221 N File:Enhanced-oil-recovery fig1.png {{copyright|U.S. Department of Energy, Bartlesville, Oklahoma}} Schematic diagram of chemical flooding (alkaline). Copyright: U.S. Department of Energy, Bartlesville, Oklahoma. Category:Reservoir engineering methods current
- 01:49, 14 January 2014 diff hist +12,256 N Enhanced oil recovery Initial import
- 01:48, 14 January 2014 diff hist +15,278 N Electrical methods Initial import
- 01:45, 14 January 2014 diff hist +189 N File:Key-economic-parameters fig3.png Expected value profile plot. Expected value is plotted versus probability of success example for development well and multiwell extension project. Category:Economics and risk asseement
- 01:45, 14 January 2014 diff hist +144 N File:Key-economic-parameters fig2.png Undiscounted and discounted cumulative net cash flow streams for example multiwell extension project. Category:Economics and risk asseement
- 01:45, 14 January 2014 diff hist +162 N File:Key-economic-parameters fig1.png Present value profile and determination of DCFROR for example development well and example multiwell extension project. Category:Economics and risk asseement
- 01:45, 14 January 2014 diff hist +19,223 N Economics: key parameters Initial import