The Art of Deploying Data Mining and Machine Learning in Developing and Managing Deepwater Turbidite Gas Assets

Edo Pratama
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Abstract

Many oil and gas operators have challenges in deepwater turbidite gas asset's reservoir management plan (RMP) readiness due to lack of experience and very limited analog field data. The objective of this article is to demonstrate how data analytics workflow, comprising of data mining and machine learning-based global deepwater turbidite gas field benchmarking and lessons learned, to identify field performance and mitigate subsurface challenges in developing and managing deepwater turbidite gas assets. To mine turbidite field data from around the world, a customized R script was constructed using optical character recognition, regular expression (regex), rule-based logic to extract subsurface and surface data attributes from unstructured data sources. All extracted contents were transformed into a properly structured query language (SQL) database relational format for the cleansing process. Having established the turbidite assets repository, exploratory data analysis (EDA) was then employed to discover insight datasets. To analyze the field performance, the number of wells needed to deplete the field was identified using support vector regression, subsequently, K-means clustering was used to classify the reservoirs productivity. The results of field benchmarking analysis from EDA are deployed in a fit-for-purpose dashboard application, which provides an elegant and powerful framework for data management and analytics purposes. The analytic dashboard which was developed to visualize EDA findings will be presented in this article. The productivity of deepwater turbidite gas reservoirs has been classified based on the maximum gas flow rate and estimated ultimate recovery per well. This result help in identifying the high-rate, high-ultimate-recovery (HRHU) reservoirs of a deepwater turbidite gas field. The regex pattern for subsurface challenges specifically as related to reservoir uncertainties and associated risks, including operational challenges in developing and managing deepwater turbidite gas fields were identified through word cloud recognition. Key subsurface challenges were then categorized and statistically ranked, finally, a decomposition tree was used to identify the issues, impacts, and mitigation plan for dealing with identified risks based on best practices from a global project point of view. Deployment of this novel workflow provides insight for better decision-making and can be a prudent complementary tool for de-risking subsurface uncertainties in developing and managing deepwater turbidite gas assets. The findings from this study can be used to develop the framework that captures current best-practices in the formulation and execution of a RMP including monitoring and benchmark of asset performance in deepwater turbidite gas fields.
在开发和管理深水浊积气资产中部署数据挖掘和机器学习的艺术
由于缺乏经验和非常有限的模拟现场数据,许多油气运营商在深水浊积气资产的储层管理计划(RMP)准备方面面临挑战。本文的目的是展示数据分析工作流程(包括数据挖掘和基于机器学习的全球深水浊积气藏基准测试和经验教训)如何识别油田性能,并减轻深水浊积气藏资产开发和管理中的地下挑战。为了挖掘来自世界各地的浊积岩数据,利用光学字符识别、正则表达式(regex)和基于规则的逻辑构建了定制的R脚本,从非结构化数据源中提取地下和地表数据属性。所有提取的内容都被转换为结构合理的查询语言(SQL)数据库关系格式,以用于清理过程。在建立了浊积资产存储库之后,探索性数据分析(EDA)被用来发现洞察数据集。为了分析油田动态,使用支持向量回归识别耗尽油田所需的井数,随后使用K-means聚类对储层产能进行分类。EDA的现场基准分析结果部署在一个适合用途的仪表板应用程序中,该应用程序为数据管理和分析目的提供了一个优雅而强大的框架。本文将介绍用于可视化EDA结果的分析仪表板。深水浊积气藏的产能是根据最大气体流量和单井估计的最终采收率进行分类的。该结果有助于识别深水浊积岩气田的高速率、高最终采收率(HRHU)储层。通过词云识别,确定了地下挑战的正则表达式模式,特别是与储层不确定性和相关风险相关的挑战,包括开发和管理深水浊积气田的操作挑战。然后对主要的地下挑战进行分类和统计排名,最后,根据全球项目的最佳做法,使用分解树来确定问题、影响和缓解计划,以处理已确定的风险。部署这种新颖的工作流程可以为更好的决策提供洞察力,并且可以作为谨慎的补充工具,在开发和管理深水浊积气资产时降低地下不确定性的风险。该研究的结果可用于开发框架,以捕获当前制定和执行RMP的最佳实践,包括深水浊积气田资产性能的监测和基准。
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