{"title":"Integrated Uncertainty Study for Resources Evaluation Under Operational Constraints","authors":"T. Chugunova, M. Trani, N. Shchukina","doi":"10.4043/29502-MS","DOIUrl":null,"url":null,"abstract":"\n Total E&P has developed for its fields an integrated workflow to assess the 2G&R uncertainties which provides a Resource evaluation distribution through the integrated Geoscience platform. If the uncertainty study also considers the operational limitations by integrating them in the modeling process, the reliability of the outputs is clearly improved. The objective of this study was to provide an evaluation of In-Place and Resource on a deep-offshore discovery located in the Gulf of Mexico while assessing not only the multiple Geoscience uncertainties but also capturing the operational constraints identified for this future development.\n The discovery, located under a salt canopy with a thickness up to 18’000 feet, had limitation from seismic imaging for the field interpretation. The well penetrations proved that the reservoir was highly compartmentalized and most of the faults were not seen on seismic. On top of this lateral disconnection, for each of the compartments the fluid contact depends on the structural horizons which are, on their turn, uncertain. The bulk of the information comes from few appraisal wells. Last but not least, the completions of the future development wells should integrate the drilling and well architecture limitations.\n All these uncertainties and constraints were managed in an integrated workflow using a Monte-Carlo Nested Multi-Realization approach. First, the structural uncertainties impact the grid which is distorted for every realization. Second, the filling of the grid with facies and petrophysical properties is done considering global and local geostatistical uncertainties. The contacts distributions are defined for almost hundred compartments. For some of them, the contacts are defined as a function of a crest, for others – a function of a spill while both (crest and spill depths) vary with the structure from one realization to another. The dynamic uncertainties on the permeability multipliers and on the relative permeability curves are considered as well. The risk of having more active faults than seen on seismic is mitigated by randomly sealing additional faults. The modeling chain also takes into account the completion limitations on future development wells. The completion tally design (minimum distance between screens and total distance of the completion intervals) are tailored to every realization in an automatic manner.\n The novelty of this work is that the different sources of uncertainties and the operational constraints are not modeled in separated workflows (e.g.: geophysics + geology + dynamic + completion design) but included in a single automatic process while parametrizing their complex dependencies. Thus, the eventual interactions and non-linear effects of a combination of all parameters can be anticipated, therefore providing a more accurate evaluation for decision making and development options.","PeriodicalId":10948,"journal":{"name":"Day 2 Tue, May 07, 2019","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2019-04-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Day 2 Tue, May 07, 2019","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.4043/29502-MS","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Total E&P has developed for its fields an integrated workflow to assess the 2G&R uncertainties which provides a Resource evaluation distribution through the integrated Geoscience platform. If the uncertainty study also considers the operational limitations by integrating them in the modeling process, the reliability of the outputs is clearly improved. The objective of this study was to provide an evaluation of In-Place and Resource on a deep-offshore discovery located in the Gulf of Mexico while assessing not only the multiple Geoscience uncertainties but also capturing the operational constraints identified for this future development.
The discovery, located under a salt canopy with a thickness up to 18’000 feet, had limitation from seismic imaging for the field interpretation. The well penetrations proved that the reservoir was highly compartmentalized and most of the faults were not seen on seismic. On top of this lateral disconnection, for each of the compartments the fluid contact depends on the structural horizons which are, on their turn, uncertain. The bulk of the information comes from few appraisal wells. Last but not least, the completions of the future development wells should integrate the drilling and well architecture limitations.
All these uncertainties and constraints were managed in an integrated workflow using a Monte-Carlo Nested Multi-Realization approach. First, the structural uncertainties impact the grid which is distorted for every realization. Second, the filling of the grid with facies and petrophysical properties is done considering global and local geostatistical uncertainties. The contacts distributions are defined for almost hundred compartments. For some of them, the contacts are defined as a function of a crest, for others – a function of a spill while both (crest and spill depths) vary with the structure from one realization to another. The dynamic uncertainties on the permeability multipliers and on the relative permeability curves are considered as well. The risk of having more active faults than seen on seismic is mitigated by randomly sealing additional faults. The modeling chain also takes into account the completion limitations on future development wells. The completion tally design (minimum distance between screens and total distance of the completion intervals) are tailored to every realization in an automatic manner.
The novelty of this work is that the different sources of uncertainties and the operational constraints are not modeled in separated workflows (e.g.: geophysics + geology + dynamic + completion design) but included in a single automatic process while parametrizing their complex dependencies. Thus, the eventual interactions and non-linear effects of a combination of all parameters can be anticipated, therefore providing a more accurate evaluation for decision making and development options.
总勘探开发的领域集成的工作流来评估2 g r的不确定性提供了资源评价分布通过综合地球科学平台。如果不确定性研究在建模过程中也考虑到操作限制,则输出的可靠性明显提高。本研究的目的是对墨西哥湾深海发现的就地和资源进行评估,同时不仅评估多种地球科学不确定性,而且还捕获了为未来开发确定的操作限制。该发现位于厚度达1.8万英尺的盐层下,地震成像对现场解释有限制。井侵证明储层分区化程度高,大部分断层在地震上未被发现。在这种横向分离的顶部,对于每个隔室,流体接触取决于构造层位,而构造层位又是不确定的。大部分信息来自少数几口评价井。最后但并非最不重要的是,未来开发井的完井应结合钻井和井结构的限制。利用蒙特卡罗嵌套多实现方法,将所有这些不确定性和约束管理在一个集成工作流中。首先,结构的不确定性会影响网格,网格在每一次实现中都是扭曲的。其次,考虑到全球和局部地统计的不确定性,对网格进行相和岩石物理性质的填充。触点分布被定义为近100个隔室。对于其中的一些,接触被定义为波峰的函数,而对于另一些,则是泄漏的函数,而两者(波峰和泄漏深度)都随着结构的不同而变化。同时考虑了渗透率乘数和相对渗透率曲线的动态不确定性。通过随机封闭额外的断层,可以减少比地震中看到的更活跃断层的风险。建模链还考虑了未来开发井的完井限制。完井计数设计(筛管之间的最小距离和完井间隔的总距离)以自动方式为每个实现量身定制。这项工作的新颖之处在于,不同的不确定性来源和操作约束没有在单独的工作流程中建模(例如:地球物理+地质+动态+完井设计),而是包含在一个自动化过程中,同时参数化它们复杂的依赖关系。因此,可以预测所有参数组合的最终相互作用和非线性影响,从而为决策和发展备选办法提供更准确的评价。