Optimizing Metal-Removal Processes for Produced Water With Electrocoagulation

Oil and gas facilities Pub Date : 2015-04-01 DOI:10.2118/173899-PA

Nasim Esmaeilirad, C. Terry, H. Kennedy, Gen Li, K. Carlson

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引用次数: 7

Abstract

gas basin. For example, recycled produced water is less than 10% of the total water used to drill and fracture in the Barnett, Fayetteville, and Haynesville shale plays. However, the fraction of water recycled is significantly higher in the Marcellus play—greater than 90% of the total water used (Mantell 2011). Although treatment methods have been developed to recycle produced water for subsequent fracturing operations, widespread adoption of these methods is often limited by costs. Important treatment aspects for fracturing-water reuse include particle removal, reduction of scale-forming metals, and disinfection. Removal of total dissolved solids (TDS) is expensive and therefore avoided, if possible. Fracturing fluids have been developed that are compatible with high TDS concentrations, but the other objectives (solids reduction, scale control, and bactericide) almost always need to be satisfied. The focus of this study was to examine the metal-removal processes associated with reducing scaling potential by use of laboratory-scale data and chemical-equilibrium modeling, with the goal of optimizing chemical use and minimizing cost.

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电絮凝法优化采出水除金属工艺

天然气盆地。例如，在Barnett、Fayetteville和Haynesville页岩区，回收采出水不到钻井和压裂总用水量的10%。然而，在马塞勒斯地区，循环水的比例明显更高——超过总用水量的90% (Mantell 2011)。尽管已经开发出了回收采出水用于后续压裂作业的处理方法，但这些方法的广泛采用往往受到成本的限制。压裂水回用的重要处理方面包括颗粒去除、减少结垢金属和消毒。去除总溶解固体(TDS)是昂贵的，因此，如果可能的话，尽量避免。目前已经开发出了与高TDS浓度相容的压裂液，但几乎总是需要满足其他目标(固相降低、结垢控制和杀菌剂)。本研究的重点是通过使用实验室规模的数据和化学平衡模型，研究与降低结垢潜力相关的金属去除过程，目标是优化化学品使用和最小化成本。

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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Oil and gas facilities

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