Difference between revisions of "Fault seal analysis example: Gulf Coast"

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SGR is calculated over the surface of the entire fault. The following figure is a map of the SGR contoured on the FPP of the fault in Figure 10-26. SGR—and seal potential—vary over the surface of the fault as the throw and stratigraphy change. Areas of high SGR are shown in red and orange. Areas of low SGR are shown in purple and blue.
 
SGR is calculated over the surface of the entire fault. The following figure is a map of the SGR contoured on the FPP of the fault in Figure 10-26. SGR—and seal potential—vary over the surface of the fault as the throw and stratigraphy change. Areas of high SGR are shown in red and orange. Areas of low SGR are shown in purple and blue.
  
[[file:evaluating-top-and-fault-seal_fig10-28.png|thumb|{{figure number|10-28}}See text for explanation.]]
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[[file:evaluating-top-and-fault-seal_fig10-28.jpg|thumb|{{figure number|10-28}}See text for explanation.]]
  
 
The SGR is calculated by “rubber-banding” the stratigraphy in adjacent well logs to fit the stratigraphic cutoffs on the FPR The detailed log stratigraphy is necessary for reliably calculating SGR. The rubber-banding corrects for apparent thicknesses in both the well and fault plane profile.
 
The SGR is calculated by “rubber-banding” the stratigraphy in adjacent well logs to fit the stratigraphic cutoffs on the FPR The detailed log stratigraphy is necessary for reliably calculating SGR. The rubber-banding corrects for apparent thicknesses in both the well and fault plane profile.

Revision as of 16:15, 31 January 2014

Exploring for Oil and Gas Traps
Series Treatise in Petroleum Geology
Part Predicting the occurrence of oil and gas traps
Chapter Evaluating top and fault seal
Author Grant M. Skerlec
Link Web page
Store AAPG Store

Routine fault seal analysis integrates both fault plane profiles and quantitative fault seal analysis. This discussion contains an example from a field in the Gulf Coast and demonstrates the application of routine fault seal analysis.

Procedure

The table below outlines a procedure for analyzing fault seal behavior.

Step Action
1 Construct a fault plane profile (FPP).
2 Determine seal behavior of the fault.
3 Calculate the smear-gouge ratio.
4 Construct a smear-gouge ratio map.
5 Determine the smear-gouge ratio threshold.

Construct an FPP

The following figure is an FPP of a portion of a fault in a Gulf Coast field. It shows the juxtaposition of sands along the fault and the observed distribution of hydrocarbons. Sands are shown in gray (hanging wall) and orange (footwall).

Figure 10-26 See text for explanation.

Determine seal behavior

Examples of cross-leaking and cross-sealing portions of the fault are shown in the following figure, which is a detail of Figure 10-26. Juxtapositions of the 7100/7100 sands and the 7200/7200 sands are cross leaking (left). These sand/sand juxtapositions have common hydrocarbon contacts across the fault. The portion of the fault juxtaposing the 7100/7200 sands, however, is cross sealing (right). Hydrocarbons in the 7200 sand in the hanging wall (Ru) are juxtaposed with water-wet sands of the 7100 sand in the footwall (Rd).

Figure 10-27 See text for explanation.

Calculate SGR and construct SGR map

SGR is calculated over the surface of the entire fault. The following figure is a map of the SGR contoured on the FPP of the fault in Figure 10-26. SGR—and seal potential—vary over the surface of the fault as the throw and stratigraphy change. Areas of high SGR are shown in red and orange. Areas of low SGR are shown in purple and blue.

Figure 10-28 See text for explanation.

The SGR is calculated by “rubber-banding” the stratigraphy in adjacent well logs to fit the stratigraphic cutoffs on the FPR The detailed log stratigraphy is necessary for reliably calculating SGR. The rubber-banding corrects for apparent thicknesses in both the well and fault plane profile.

Example: correlating SGRs, seal behavior

The SGR is calculated for each known sealing and leaking segment of the fault. The SGRs of two cross-leaking and cross-sealing segments of the fault are shown in the following figure (location is on Figure 10-33). SGR values along the cross-leaking sand/sand juxtapositions are high (red). Cross-leakage (right) occurs at both the 7100/7100 and 7200/7200 juxtapositions. Cross-seal (left) occurs where the 7100 sand is juxtaposed with the 7200 sand. This cross-sealing segment is characterized by low SGRs (blue). Cross-leakage occurs where the SGR is high; cross-seal occurs where it is low.

Figure 10-29 See text for explanation.

Calibrating SGR threshold

This same iterative process is used to construct SGR threshold plots and to calibrate the critical SGR necessary for seal and leak. The SGR threshold plot of the Gulf Coast noted earlier in this subsection was constructed from a similar analysis of 160 known sealing and leaking fault segments. The constantly expanding database now includes 246 faults in the Gulf Coast. The result is the ability to risk fault seal behavior with a high degree of confidence. Fewer than 10% of the faults analyzed in the Gulf Coast are exceptions to this pattern.

See also

External links

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Fault seal analysis example: Gulf Coast
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