基于3D打印技术的碳酸盐岩储层可持续开发研究

Xu Chen, Zubo Zhang, Jian Gao, Hao Kang
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引用次数: 0

摘要

碳酸盐岩储层储量丰富,在世界范围内已成为未来油气开发的主要目标之一。因此,加快碳酸盐岩储层的研究和开发对提高世界能源供应能力具有重要意义。但长期以来,碳酸盐岩储层评价存在缝洞体描述精度低、流型多样、储层模拟预测困难等问题。与传统制造方法相比,3D打印是一种快速成型的先进制造技术。它具有制造周期短、不受零件复杂性的限制、节省材料和节能等特点,因此在储层岩石分析中具有无可比拟的优势。本文以塔里木盆地英麦里地区碳酸盐岩岩心为研究对象,利用KINGS-600型3D光固化打印机和光敏树脂材料,设计并测试了3种不同材料打印的小岩心的单轴压缩力学性能。之后选择强度最高的UV-9400S白色树脂作为溶洞全直径岩心模型的打印材料。结合对成型样品的CT扫描,测试了3D打印岩心样品对溶洞形态的控制精度,充分证明了3D打印岩心样品可以进行流动实验。最后,文章还分析了3D打印技术存在的不足,指出了3D打印技术在油气开采领域大规模应用的方向。本研究可为3D打印技术在碳酸盐岩储层开发领域的应用提供参考,最终促进油气资源的可持续供应。
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Study on Sustainable Development of Carbonate Reservoir Based on 3D Printing Technology
With its abundant reserves in the world, carbonate reservoir has become one of the main targets for future oil and gas development. Accelerating the research and development of carbonate reservoirs is thus significant to enhance the world’s energy supply capacity. However, there have been some problems in the evaluation of carbonate reservoirs for a long time, such as low description accuracy of fractured-vuggy bodies, diverse flow patterns, and difficult reservoir simulation and prediction. Compared with traditional manufacturing methods, 3D printing is an advanced manufacturing technology of rapid prototyping. It has the characteristics of short manufacturing cycle, not limited by the complexity of parts, material saving and energy saving, and thus has unparalleled advantages in reservoir rock analysis. In this paper, the carbonate core of Yingmaili region in Tarim Basin was taken as the research object, and the uniaxial compression mechanical properties of three small cores printed with different materials were designed and tested by using KINGS-600 3D photocuring printer and photosensitive resin materials. After that, UV-9400S white resin with the highest strength is selected as the printing material of the full diameter core model of the karst cave. Combined with the CT scanning of the formed samples, the control accuracy concerning the cave morphology of the 3D printed samples was tested which adequately proves that flow experiments can be carried out with 3D printed core samples. At last, the article also analyzes the shortcomings of 3D printing technology, and points out the direction for its large-scale application in the field of oil and gas exploitation. This study can especially provide a reference for the application of 3D printing technology in the field of carbonate reservoir development, and ultimately promote the sustainable supply of oil and gas resources.
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来源期刊
Strategic Planning for Energy and the Environment
Strategic Planning for Energy and the Environment Environmental Science-Environmental Science (all)
CiteScore
1.50
自引率
0.00%
发文量
25
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