减少流动回路中天然气水合物和沥青质的形成、生长和沉积的表面处理策略

M. Pickarts, J. Delgado-Linares, E. Brown, V. Veedu, C. Koh
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引用次数: 1

摘要

包括天然气水合物、蜡和沥青在内的许多固体都有可能在天然气和油田的生产线上形成。这造成了一个非常不理想的情况,因为上述物种的积累会导致流动保障问题,特别是在沉积等长期过程中。由于越来越多的材料沉积在管道表面,停产或积极的缓解措施变得不可避免。后一种生产问题会增加安全风险和运营支出。因此,具有成本效益的被动沉积减缓技术,如管道涂层或表面处理,尤其具有吸引力。在不影响生产的情况下同时解决多个管道流动保证问题的能力将是该领域的一个巨大进步。这项研究是一项长期持续努力的一部分,旨在评估全憎表面处理在工业相关系统中防止固体沉积的性能和应用。特别是,这项具体工作集中在全流动条件下处理的有效性和稳健性。所使用的设备包括两个流动回路:用于天然气水合物和表面处理耐久性研究的实验室规模高压流动回路,以及用于原油和沥青质实验的实验室规模常压回路。高压流环试验中的薄膜生长证实了先前在摇摆细胞中观察到的延迟天然气水合物成核的报告。在没有记忆效应的帮助下,处理过的油为主的实验从未经历过水合物的形成,在水合物稳定区(在过冷/流体测试条件下)花费了一周以上的时间。随后利用记忆效应进行的测试显示,与不锈钢表面相比,经过表面处理的水合物形成速率降低了。该测试是在流动回路中进行的一系列大规模试验的一部分,该试验持续了大约一年。在此期间,对流动条件下的表面处理耐久性进行了评估。即使在经历了约4000小时的工作时间和2个全压力循环后,也没有检测到分层或损坏的证据。最后,作为之前工作的一部分,在台式流动环中进行了腐蚀表面沥青质沉积实验。经过处理的实验表明,总油(原油的所有馏分)和沉积的沥青质馏分都减少了一个数量级。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Surface Treatment Strategies for Mitigating Gas Hydrate & Asphaltene Formation, Growth, and Deposition in Flowloops
Numerous solids including gas hydrates, waxes, and asphaltenes have the potential to form in the production lines of gas and oil fields. This creates a highly non-ideal scenario as the accumulation of said species leads to flow assurance issues, especially with long-term processes like deposition. Since an ever-increasing amount of material is deposited in place at the pipe surface, production stoppage or active mitigation efforts become inevitable. The latter production issues result in increased safety risks and operational expenditures. Therefore, a cost-effective, passive deposition mitigation technology, such as a pipeline coating or surface treatment is especially appealing. The ability to address multiple pipeline flow assurance issues simultaneously without actively disrupting production would represent a dramatic step forward in this area. This study is part of a long-term ongoing effort that evaluates the performance and application of an omniphobic surface treatment for solids deposition prevention in industrially relevant systems. In particular, this specific work concentrates on the efficacy and robustness of the treatment under fully flowing conditions. The apparatuses utilized for this include two flowloops: a lab-scale, high-pressure flowloop for gas hydrate and surface treatment durability studies, and a bench-scale, atmospheric pressure loop for crude oil and asphaltene experiments. Film growth in high-pressure flowloop tests corroborated previous reports of delayed gas hydrate nucleation observed in rocking cells. Without the aid of the memory effect, treated oil-dominated experiments never experienced hydrate formation, spending upwards of a week in the hydrate stability zone (at the subcooled/fluid test conditions). Subsequent tests which utilized the memory effect then revealed that the hydrate formation rate reduced in the presence of the surface treatment compared to a bare stainless-steel surface. This testing was part of a larger set of trials conducted in the flowloop, which lasted about one year. The surface treatment durability under flowing conditions was evaluated during this time. Even after experiencing ∼4000 operating hours and 2 full pressure cycles, no evidence of delamination or damage was detected. Finally, as part of an extension to previous work, corroded surface asphaltene deposition experiments were performed in a bench-top flowloop. Treated experiments displayed an order of magnitude reduction in both total oil (all fractions of crude oil) and asphaltene fraction deposited.
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