| Qingdao Institute of marine geology, China Geological Survey | Host |
| Citation: |
PENG Song, LI Shanshan, LI Ming, TAN Shun, ZHU Jinqi. APPLICATION OF FLOW UNITS TO COMPLICATED RESERVOIR OF A FAN DELTA DEPOSITIONAL SYSTEM IN WUSHI A OILFIELD[J]. Marine Geology Frontiers, 2019, 35(4): 10-17. doi: 10.16028/j.1009-2722.2019.04002
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APPLICATION OF FLOW UNITS TO COMPLICATED RESERVOIR OF A FAN DELTA DEPOSITIONAL SYSTEM IN WUSHI A OILFIELD
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Abstract
The WS-A Oil Field is a newly discovered one in the western basin of the South China Sea, which is mainly accumulated in a near-provenance fan deltaic depositional system. The productivity and pressure testing data of the evaluation well demonstrates that the reservoir of the field is complex in flowing characteristics, and the production capacity is poorly related with the reservoir physical property from logging interpretation, and thus the conventional method is not able to accurately characterize the flowing characteristics of the reservoir. Therefore, the concept of flow unit is introduced in this article. Since such a case is relatively scarce in offshore oil fields, we have to classify the flow units upon the basis of both the micro and macro characteristics of pore throat structure. Sorting of the sediments, electrical properties and porosity parameters are selected from among the others as the criteria for flow unit classification and production capacity evaluation. Evaluation results are well correlated with the measured data, suggesting that this method can accurately and effectively evaluate the complex reservoir as such and guide the oilfield development at present and in the future.
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Keywords:
- fan delta /
- complicated reservoir /
- micro pore throat structure /
- flow units
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References
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PENG Song, LI Shanshan, LI Ming, TAN Shun, ZHU Jinqi. APPLICATION OF FLOW UNITS TO COMPLICATED RESERVOIR OF A FAN DELTA DEPOSITIONAL SYSTEM IN WUSHI A OILFIELD[J]. Marine Geology Frontiers, 2019, 35(4): 10-17. doi: 10.16028/j.1009-2722.2019.04002
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Figure 1.
Tectonic location of WS A Oilfield
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Figure 2.
Relationship between pressure liquidity
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Figure 3.
Relationship between testing permeability and logging porosity
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Figure 4.
Microscopic characteristics of the reservoir
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Figure 5.
Relationship between pressure liquidity and logging porosity (classification)
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Figure 6.
Relationship between core permeability and core porosity (classification)
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Figure 7.
Relationship between pressure liquidity and logging resistivity
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Figure 8.
Relationship between specific productivity index and logging resistivity
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Figure 9.
Characteristics of intergranular clay minerals
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Figure 10.
Characteristics of different flow unit
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Figure 11.
Relationship between flow unit permeability and productivity
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Figure 12.
Typical well flow unit classification