Bio Enhanced Energy Recovery Technology for Clean and Efficient Energy Production

Langbauer Clemens, H. Herbert, Mukhamedzianova Albina
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引用次数: 2

Abstract

The demand for environmentally friendly and efficient oil and gas production, especially in unconventional reservoirs, is continuously increasing. Conventional hydraulic fracturing jobs use numerous different harmful (U.S. Environmental Protection Agency, 2016) chemicals to stabilize the fracturing fluid and to maintain its proppant caring capacity. The Bio-Enhanced Energy Recovery (BEER®) fracturing technology is a new technology for clean and efficient energy recovery in tight oil and shale gas reservoirs using biological substances, without the use of environmentally harmful chemicals. This paper shows the potential of the BEER® technology in a tight gas sandstone reservoir with the help of the 3D simulator GOHFER® and laboratory tests. The technology itself consists of two essential parts. On the one hand, a biological hydraulic fracturing fluid to create the fracture and to carry the proppants is just a mixture of a few harmless components. On the other hand, special proppants, based on silicon dioxide, are applied to keep the fracture open. Experiments and lab tests have shown the high potential of the fluid. Fluid rheology, caring capacity, breaking behavior and other relevant properties are examined. The investigations of the proppants result in a very high compressive strength, narrow size range, perfect sphericity at a much lower price, compared to the common commercially available products. Based on those results by the usage of the simulator GOHFER®, the fracturing job efficiency of the BEER® technology is comparable to the performance of the standard fracturing technology. Reservoir properties, the treatment job design, the 3D fracture geometry and post-treatment production enhancement are investigated. A sensitivity analysis of gross fracture length, propped cut-off fracture length, and fracture conductivity confirms the significant potential of this technology. The results presented here indicate that the proposed technology is indeed suitable for performing environmentally friendly and clean hydraulic fracturing jobs, resulting in higher production rates at much lower costs than the conventional technology.
清洁和高效能源生产的生物增强能源回收技术
对环保和高效油气生产的需求正在不断增加,尤其是在非常规油藏中。传统的水力压裂作业使用了许多不同的有害化学物质(美国环境保护署,2016年)来稳定压裂液并保持支撑剂的承载能力。Bio-Enhanced Energy Recovery (BEER®)压裂技术是一项利用生物物质在致密油和页岩气储层中清洁高效地回收能源的新技术,不使用对环境有害的化学物质。本文借助GOHFER®3D模拟器和实验室测试,展示了BEER®技术在致密砂岩气藏中的潜力。这项技术本身由两个基本部分组成。一方面,用于制造裂缝和携带支撑剂的生物水力压裂液只是几种无害成分的混合物。另一方面,基于二氧化硅的特殊支撑剂被应用于保持裂缝打开。实验和实验室测试表明,这种液体具有很高的潜力。考察了流体流变学、承载能力、断裂行为和其他相关性质。研究结果表明,与市面上常见的支撑剂相比,该支撑剂具有非常高的抗压强度、较小的尺寸范围、完美的球形度和更低的价格。基于模拟GOHFER®的结果,BEER®技术的压裂作业效率与标准压裂技术的性能相当。研究了储层性质、处理作业设计、三维裂缝几何形状和处理后的增产效果。对总裂缝长度、支撑截止裂缝长度和裂缝导流能力的敏感性分析证实了该技术的巨大潜力。研究结果表明,该技术确实适用于环境友好、清洁的水力压裂作业,与传统技术相比,能够以更低的成本实现更高的产量。
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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