防腐杀菌剂在高压高温生物反应器中的应用

J. Ferrar, Philip Maun, K. Wunch, Joseph D. Moore, Jana Rajan, J. Raymond, E. Solomon, M. Paschoalino
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引用次数: 0

摘要

防腐杀菌剂的设计目的是控制井下环境中的微生物生长和生物酸化。我们报道了在模拟水力压裂页岩储层的高压高温(HPHT)生物反应器中,与三丁基十四烷基氯化磷(TTPC,一种阳离子表面活性杀菌剂)相比,4,4-二甲氧基恶唑烷(DMO,一种防腐杀菌剂)和戊二醛预防生物源性酸变的效果。这些新型生物反应器的设计可以在受控的实验室环境中重现井下环境(温度、压力、地层固体和压裂添加剂),从而能够在现场相关条件下对杀菌剂进行评估。未进行杀菌剂处理或高浓度TTPC(有效成分为50 ppm)处理的生物反应器在关闭后的前两周内迅速变质,并且在向反应器中添加活微生物后,所有生物反应器的H2S均超过了可检测的最大水平(343 ppm)。相反,高负荷的DMO (150 ppm的有效成分)使H2S浓度在6周内保持在最低可检测水平(5 ppm)以下,并在关井15周和两次关井后的微生物再挑战后将H2S浓度保持在10.3 +/- 5.2 ppm。在第二项研究中,低浓度的DMO (50 ppm的活性成分)在三周后通过添加活微生物使H2S浓度保持在最低可检测水平以下,而在五周后第二次添加活微生物时H2S浓度仅高于10 ppm。在同一项研究中(在中等温度下进行),通过添加活微生物,50 ppm(活性成分)的戊二醛处理也在三周后将H2S浓度维持在最低可检测水平以下,四周后H2S浓度为15.0 +/- 9.7 ppm H2S。通过枚举每个反应器中存在的微生物,在每个处理条件下观察到类似的保护时间尺度。DMO和戊二醛在抗菌活性(特别是防止生物源性酸败)方面的差异表明,在测试浓度下,与TTPC等表面活性杀菌剂相比,这种非离子型防腐杀菌剂是控制问题微生物的优越选择。DMO和戊二醛在这一首个模拟储层中提供的有效持续时间表明,从完井到生产的全面保存和预防生物酸变质是可行的。这种全面、长时间的保护尤其适用于长时间关井或已钻但未完井(DUCS),例如在COVID-19大流行期间经历的油井。生物反应器内模拟的环境表明,防腐杀菌剂提供的相容性提供了阳离子表面活性杀菌剂所不能提供的井下保护。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Extended Downhole Protection by Preservative Biocides as Demonstrated in High Pressure, High Temperature Bioreactors
Preservative biocides are designed to control microbial growth and biogenic souring in the downhole environment. We report the prevention of biogenic souring by 4,4-dimethyloxazolidine (DMO, a preservative biocide) and glutaraldehyde as compared to that afforded by tributyl tetradecyl phosphonium chloride (TTPC, a cationic surface-active biocide), in a first-of-its kind suite of High Pressure, High Temperature (HPHT) Bioreactors that simulate hydraulically fractured shale reservoirs. The design of these new bioreactors, which recreate the downhole environment (temperatures, pressures, formation solids, and frac additives) in a controlled laboratory environment, enables the evaluation of biocides under field-relevant conditions. The bioreactors receiving either no biocide treatment or treatment with a high concentration of TTPC (50 ppm active ingredient) rapidly soured within the first two weeks of shut-in, and all surpassed the maximum detectable level of H2S (343 ppm) after the addition of live microbes to the reactors. Conversely, a higher loading of DMO (150 pppm active ingredient) maintained H2S concentrations below the minimum dectable level (5 ppm) for six weeks, and held H2S concentrations to 10.3 +/- 5.2 ppm after fifteen weeks of shut-in and two post shut-in microbial rechallenges. In a second study, a lower concentration of DMO (50 ppm active ingredient) maintained H2S concentrations below the minimum detectable level through the addition of live microbes after three weeks, and H2S concentrations only registered above 10 ppm upon a second addition of live microbes after five weeks. In this same study (which was performed at moderate temperatures), a 50 ppm (active ingredient) treatment of glutaraldehyde also maintained H2S concentrations below the minimum detectable level through the addition of live microbes after three weeks, and H2S concentrations registered 15.0 +/- 9.7 ppm H2S after four weeks. Similar time scales of protection are observed for each treatment condition through the enumeration of microbes present in each reactor. The differentiation in antimicrobial activity (and specifically, prevention of biogenic souring) afforded by DMO and glutaraldehyde suggests that such nonionic, preservative biocides are a superior choice for maintaining control over problematic microorganisms as compared to surface-active biocides like TTPC at the concentrations tested. The significant duration of efficacy provided by DMO and glutaraldehyde in this first-of-its-kind suite of simulated reservoirs demonstrates that comprehensive preservation and prevention of biogenic souring from completion through to production is feasible. Such comprehensive, prolonged protection is especially relevant for extended shut-ins or drilled but uncompleted wells (DUCS) such as those experienced during the COVID-19 pandemic. The environment simulated within the bioreactors demonstrates that the compatibility afforded by a preservative biocide offers downhole protection that cationic, surface-active biocides do not.
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