基于电阻率反演的工作流程——从地下不确定性管理到不同复杂性油藏的定量油藏规模剖面更新和井眼布置

Junling Wan, Xiang Wu, B. Chang, Chao Wang, Gong Li, Fei Wang, Y. Shim
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引用次数: 0

摘要

在深度开发阶段,H油田目前的水平充填活动针对的是剩余油潜力高且受构造和岩性控制的复杂油藏。这些构造和岩性油藏具有地层倾角和油水接触(OWC)不确定性、地层非均质性严重、横向物性变化、砂岩连通性差、油柱和互层厚度变化(小于5 m)等特点。为了有效挤压潜在剩余储量,目前的充填范围主要包括:(1)油柱不确定、储层侧向变化的背斜圈闭的有限波峰和(2)靠近储层针尖线的未开发边缘区域。因此,有必要定量更新储层规模的地下剖面,并通过个性化的服务和工作流程来解决上述不确定性,从而实施配井作业。在这些多样化的储层中,由于大尺度地震资料的分辨率和小尺度常规测井资料的调查深度(DOI)有限,井间构造和地层的不确定性很高。基于此,采用高分辨率边界探测服务(HDBDS),该服务可以提供随机电阻率反演,远程识别定量地下特征,DOI高达6 m,分辨率约为1 m。其平衡分辨率和DOI的优势可以精确描述高清晰度井间细节,包括地层叠加配置、储层尖点和动态井间含水率。此外,HDBDS反演可以将三维地震数据与常规测井数据相结合,有效地引导了从地下不确定性管理到定量油藏规模剖面更新和井位的工作流程。基于HDBDS的反演工作流程有效地帮助我们实现了本次充填活动的目标,从而大致揭示了沿水平段的高清晰油藏剖面。最多四个边界和五个层同时绘制,距离钻孔最多3米。在这些特定的环境中,更新的定量特征的高覆盖率和概率导致了比基于常规服务的油藏剖面更新率更高。在主要受构造和岩性控制的复杂发育区,定量反演了储层顶部、横向变化物性和动态倾斜的含水率,确定了有效的1.5 ~ 3 m油柱,低于预测的5 m油柱。在块体边缘控岩性油藏中,清晰地圈定了地层叠加构型、尖点和横向物性变化特征。因此,定量配井作业能够有效地分配连接多个砂岩体的实际光滑轨迹,风险较小,并且最大限度地避免了倾斜的OWC。反演工作流程的定量结果可以进一步优化完井配置、水驱增产效率和井网,通过有效挤压这些复杂结构和岩性油藏中的剩余油,尽可能地推动开发极限。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Resistivity-Inversion-Derived Workflow from the Subsurface Uncertainty Management to the Quantitative Reservoir-Scale Profile Update and Well Placement in Reservoirs with Diverse Complexities
At the in-depth development phase, the current horizontal infill campaign in H oil field targets reservoirs with high remaining oil potential and the diverse complexities subject to both structural and lithological controls. These structural and lithological reservoirs are characterized by the uncertainties of formation dip and oil/water contact (OWC), severe stratigraphic heterogeneity, lateral properties change, poor sandstone connectivity, and thickness variation (less than 5 m) of the oil column and interbeds. To effectively squeeze the potential remaining reserves, the scope of the current infill campaign mainly encompasses: (1) the limited crests of the anticlinal traps with uncertain oil column and lateral changed reservoir, and (2) the unexploited marginal areas close to the reservoir pinchout line. Accordingly, it is necessary to quantitatively update the reservoir-scale subsurface profile and execute well placement operations by addressing the above uncertainties with individualized services and workflow. In these diverse reservoirs, interwell structural and stratigraphic uncertainties are high because resolution of large-scale seismic data and depth-of-investigation (DOI) of small-scale conventional logging data are limited. On these grounds, a high-definition boundary detection service (HDBDS) was employed, which can provide a stochastic resistivity inversion to remotely identify quantitative subsurface features with DOI up to 6 m and resolution of approximately 1 m. Its advantage of balancing resolution and DOI can induce the accurate description of high-definition interwell details, including formation superposition configuration, reservoir pinchout points, and dynamic OWC. Furthermore, HDBDS inversion can combine 3D seismic data and conventional logging data to effectively induce the workflow from subsurface uncertainty management to the quantitative reservoir-scale profile update and well placement. HDBDS inversion-derived workflow effectively contributed to us achieving our objectives of this infill campaign by generally revealing the high-definition reservoir profiles along the horizontal sections. Up to four boundaries and five layers were mapped simultaneously with a maximum of 3 m distance from the borehole. High coverage and probability of the updated quantitative features induced the higher reservoir profile update rate in these specific environments than that based on the conventional services. In the complex developed areas mainly subject to both structural and lithological controls, the reservoir top, lateral changed properties, and dynamic tilted OWC were quantitatively inverted to identify the effective 1.5- to 3-m oil column, lower than prognosed 5-m column. In the lithological-control reservoirs at block margins, formation superposition configuration, pinchout points, and lateral properties changing features were clearly delineated. Accordingly, the quantitative well placement operations were efficiently executed to distribute the actual smooth trajectory connecting multiple sandstone bodies with the less risk, as well as with maximum standoff to the tilted OWC. The quantitative results from the inversion-derived workflow could further optimize the completion configuration, waterflooding stimulation efficiency, and well pattern to push development limits as much as possible by efficiently squeezing the remaining oil in these complex structural and lithological reservoirs.
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