利用细菌分离和筛选生物表面活性剂生产烃类:提高采收率的应用

O. Sylvester, M. Onyekonwu, G. Okpokwasili
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引用次数: 1

摘要

三次采油技术包括混相驱、化学、热和微生物注入,以提高采收率。为了提高采收率,已经进行了几项使用表面活性剂和聚合物注入的研究。但本研究的重点是利用细菌分离和表征碳氢化合物,用于生物表面活性剂和生物聚合物的生产。微生物提高采收率的概念包括注入营养物来激活储层中的原生微生物,或者在现场应用过程中注入外部烃降解微生物和营养物,以确保微生物产生所需的代谢物。这些微生物能够产生气体来增加储层压力和置换不流动的油,能够产生生物表面活性剂来降低界面张力,能够产生生物聚合物来控制流动性,能够产生注入性剖面和粘度改性,能够产生溶剂、酸和生物质。在本研究中,土壤样本取自尼日利亚河流州Ogoniland的Gio, Tai地方政府区域的碳氢化合物污染场地。样品被转移到一个聚乙烯袋中,放在冰袋中,并立即运送到实验室进行理化和微生物分析,如乳化指数,溶血活性和油扩散技术。对37株分离菌进行了生物表面活性剂生产试验,筛选出3株分离菌具有较强的生物表面活性剂降解能力。选取芽孢杆菌(Bacillus sp)、假单胞菌(Pseudomonas sp)和肠杆菌(Enterobacter sp)进行生化鉴定,并对其进行温度、pH、营养源、盐度和接种浓度等条件的研究,以确定其最佳储层性能条件。结果表明,3种微生物的最佳参数范围为pH 7 ~ 8、温度25 ~ 35℃、盐度0.5% ~ 5%,随着接种量的增加,乳化指数越大,芽孢杆菌的最佳氮源为蛋白胨,假单胞菌和肠杆菌的最佳碳源为葡萄糖和甘油。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Isolation and Screening of Hydrocarbon Utilizing Bacteria for Biosurfactant Production: Application for Enhanced Oil Recovery
Tertiary oil recovery techniques comprise miscible flooding, chemical, thermal and microbial injection into oil reservoirs to enhanced recovery. Several studies have been performed on the use of surfactants and polymers injection for enhanced oil recovery. But this study is focused on isolation and characterization of hydrocarbon utilizing bacteria for biosurfactants and biopolymers production. The concept of microbial enhanced oil recovery consists the injection of nutrients to activate indigenous microbes in the reservoir or injection of external hydrocarbon degrading microbes plus nutrients during field applications to ensure the organisms produce the required metabolites. These microbes have the ability to produce gases to increase reservoir pressure and displacement of immobile oil, bio-surfactants to reduce interfacial tension, biopolymer for mobility control, Injectivity profile and viscosity modification, solvent, acid and biomass. In this study, soil samples were obtained from hydrocarbon-contaminated site in Gio, Tai Local Government Area, in Ogoniland, Rivers State, Nigeria. The samples were transferred into a polythene bag, placed in an ice pack, and transported immediately to the laboratory for physicochemical and microbiological analyses such as emulsification index, haemolytic activity and oil spreading technique. 37 isolates were tested for biosurfactant production and 3 of the isolates were selected for biosurfactant production with strong ability to degrade hydrocarbon. The selected microbes (Bacillus sp, Pseudomonas sp and Enterobacter sp) were identified by biochemical characterization and subjected to ranges of temperature, pH, nutrient sources, salinity, and inoculum concentration to determine their optimum reservoir performance conditions. The result shows the optimum parameter ranges for the three microbes: pH 7-8, temperature within 25 – 35°C, salinity within 0.5% - 5%, the result shows that as the inoculum size increases, the more the emulsification index, the best nitrogen source is peptone and the best carbon source for bacillus sp is glucose and glycerol for Pseudomonas sp and Enterobacter sp.
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