A machine learning-driven stochastic simulation of underground sulfide distribution with multiple constraints

A machine learning-driven stochastic simulation of underground sulfide distribution with multiple constraints

The increase of sulfide (S ) during the water flooding process has been regarded as an essential and potential risk for oilfield development and safety. Kriging and stochastic simulations are common methods for assessing the element distribution. However, these traditional simulation methods are not...

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Bibliographic Details
Published in:Open Geosciences Vol. 13; no. 1; pp. 807 - 819
Main Authors: Ji, Qiuyan, Han, Feilong, Qian, Wei, Guo, Qing, Wan, Shulin
Format: Journal Article
Language:English
Published: Warsaw De Gruyter 23-07-2021
De Gruyter Poland
Subjects:
chemical estimation
Flooding
machine learning
multiple constraints
Oil and gas fields
Simulation
stochastic simulation
sulfide
Sulfides
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Summary:The increase of sulfide (S ) during the water flooding process has been regarded as an essential and potential risk for oilfield development and safety. Kriging and stochastic simulations are common methods for assessing the element distribution. However, these traditional simulation methods are not able to predict the continuous changes of underground S distribution in the time domain by limited known information directly. This study is a kind of attempt to combine stochastic simulation and the modified probabilistic neural network (modified PNN) for simulating short-term changes of S concentration. The proposed modified PNN constructs the connection between multiple indirect datasets and S concentration at sampling points. These connections, which are treated as indirect data in the stochastic simulation processes, is able to provide extra supports for changing the probability density function (PDF) and enhancing the stability of the simulation. In addition, the simulation process can be controlled by multiple constraints due to which the simulating target has been changed into the increment distribution of S . The actual data test provides S distributions in an oil field with good continuity and accuracy, which demonstrate the outstanding capability of this novel method.
ISSN:2391-5447
2391-5447
DOI:10.1515/geo-2020-0274