Gas Hydrate Production Testing – Knowledge Gained

T. Collett
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引用次数: 19

Abstract

Since their initial discovery in the 1960’s, gas hydrates have been considered to be an important potential source of unconventional natural gas. Significant progress has been made relative to our understanding of the geologic and engineering controls on the ultimate energy potential of gas hydrate; however, more work is required to realize the promise of gas hydrates as a future energy source. Gas hydrates have been encountered, recovered or inferred to exist in numerous sedimentary basins in Arctic permafrost settings, regions of alpine permafrost, marine sediments of outer continental margins and in deep lakes. Despite the great abundance of potential gas hydrate resources in the world, a large portion of these resources reside in clay-rich sediments and fracture dominated reservoir systems, and are not generally considered producible with existing technology, but may have future potential with the emergence of new technologies. For a large portion of the world, gas hydrate in sand reservoirs have become a viable production target and the focus of the first production testing efforts. Production tests in Arctic Canada (Mackenzie Delta) and Alaska have shown that gas can be produced from highly-concentrated gas hydrate accumulations in coarse-grained (i.e., sand rich) reservoir systems with conventional production technologies. Production can be achieved through the depressurization method and by more complex methods such as molecular substitution (e.g., CO2-CH4 exchange). In 2013, the gas hydrate production test was conducted in a marine setting in the offshore of Japan. An additional test was conducted in Japan in 2017 to further evaluate alternative well completion technologies. Also in 2018, China initiated a 60-day gas hydrate production test in the Shenhu region of the South China Sea. This report reviews the results of gas hydrate engineering and production testing studies associated with the Mallik, Mount Elbert, and Iġnik Sikumi projects in northern Canada and Alaska. The results of the marine gas hydrate producing testing efforts in the Nankai Trough (Japan) and in the South China Sea (China) are also summarized.
天然气水合物生产测试-获得的知识
自20世纪60年代首次被发现以来,天然气水合物一直被认为是非常规天然气的重要潜在来源。对天然气水合物终极能量潜力的地质和工程控制的认识取得了重大进展;然而,要实现天然气水合物作为未来能源的前景,还需要做更多的工作。在北极永久冻土层、高山永久冻土层、外大陆边缘的海洋沉积物和深湖的许多沉积盆地中都发现、发现或推断存在天然气水合物。尽管世界上潜在的天然气水合物资源非常丰富,但这些资源中的很大一部分位于富含粘土的沉积物和以裂缝为主的储层系统中,一般认为现有技术无法生产,但随着新技术的出现,它们可能具有未来的潜力。对于世界上很大一部分地区来说,砂岩储层中的天然气水合物已经成为一个可行的生产目标,也是首次生产测试的重点。在加拿大北极地区(Mackenzie Delta)和阿拉斯加进行的生产测试表明,采用常规生产技术,可以从粗粒(即富砂)储层系统中高浓度的天然气水合物聚集中生产天然气。生产可以通过减压方法和更复杂的方法,如分子取代(例如,CO2-CH4交换)来实现。2013年,在日本近海的一个海洋环境中进行了天然气水合物生产测试。2017年在日本进行了另一项测试,以进一步评估替代完井技术。同样在2018年,中国在南海神狐地区启动了为期60天的天然气水合物生产试验。本报告回顾了与加拿大北部和阿拉斯加的Mallik、Mount Elbert和Iġnik Sikumi项目相关的天然气水合物工程和生产测试研究结果。总结了日本南开海槽和中国南海的海相天然气水合物生产试验成果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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