Direct Gas Thickener

Enhanced Oil Recovery Processes - New Technologies Pub Date : 2019-09-20 DOI:10.5772/intechopen.88083

N. Hinai, M. Myers, C. Wood, A. Saeedi

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引用次数: 2

Abstract

Direct gas thickening technique has been developed to control the gas mobility in the miscible gas injection process for enhanced oil recovery. This technique involves increasing the viscosity of the injected gas by adding chemicals that exhibit good solubility in common gasses, such as CO 2 or hydrocarbon (HC) solvents. This chapter presents a review of the latest attempts to thicken CO 2 and/or hydrocarbon gases using various chemical additives, which can be broadly categorised into polymeric, conventional oligomers, and small-molecule self-interacting compounds. In an ideal situation, chemical compounds must be soluble in the dense CO 2 or hydrocarbon solvents and insoluble in both crude oil and brine at reservoir conditions. However, it has been recognised that the use of additives with extraordinary molecular weights for the above purpose would be quite challenging since most of the supercritical fluids are very stable with reduced properties as solvents due to the very low dielectric constant, lack of dipole momentum, and low density. Therefore, one way to attain adequate solubility is to elevate the system pressure and temperature because such conditions give rise to the intermolecular forces between segments or introduce functional groups that undergo self-interacting or intermolecular interactions in the oligomer molecular chains to form a viscosity-enhancing supramolecular network structure in the solution. According to this review, some of the polymers tested to date, such as polydimethylsiloxane, polyfluoroacrylate styrene, and poly(1,1-dihydroperfluorooctyl acrylate), may induce a significant increase of the solvent viscosity at high concentrations. However, the cost and environmental constraints of these materials have made the field application of these thickeners unfeasible. Until now, thickeners composed of small molecules have shown little success to thicken CO 2 , because CO 2 is a weak solvent due to its ionic and polar characteristics. However, these thickeners have resulted in promising outcomes when used in light

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直接气体增稠器

为了控制混相注气过程中气体的流动性，提高采收率，开发了直接气体增稠技术。该技术通过添加在普通气体(如二氧化碳或碳氢化合物溶剂)中具有良好溶解度的化学物质来增加注入气体的粘度。本章介绍了使用各种化学添加剂增稠二氧化碳和/或碳氢化合物气体的最新尝试，这些添加剂大致可分为聚合物，传统低聚物和小分子自相互作用化合物。在理想情况下，化合物必须可溶于致密的二氧化碳或碳氢化合物溶剂，而不溶于油藏条件下的原油和盐水。然而，人们已经认识到，为上述目的使用具有特殊分子量的添加剂将是相当具有挑战性的，因为大多数超临界流体非常稳定，由于介电常数非常低，缺乏偶极动量和低密度，用作溶剂的性能降低。因此，获得足够溶解度的一种方法是提高系统压力和温度，因为这样的条件会引起片段之间的分子间作用力，或者在低聚分子链中引入官能团，这些官能团会进行自相互作用或分子间相互作用，从而在溶液中形成增强粘度的超分子网络结构。根据这篇综述，迄今为止测试的一些聚合物，如聚二甲基硅氧烷、聚氟丙烯酸酯苯乙烯和聚(1,1-二氢全氟辛基丙烯酸酯)，在高浓度下可能会导致溶剂粘度的显著增加。然而，这些材料的成本和环境限制使得这些增稠剂的现场应用不可行。到目前为止，由小分子组成的增稠剂对二氧化碳的增稠作用几乎没有成功，因为二氧化碳是一种弱溶剂，由于它的离子和极性特性。然而，这些增稠剂在光下使用时产生了有希望的结果

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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Enhanced Oil Recovery Processes - New Technologies

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