Study on Enhanced Oil Recovery Using Microorganism Generating Foam in Presence of Nanobubbles

Miu Ito, Y. Sugai
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引用次数: 1

Abstract

Both high cost and environmental load of surfactant are issues to be solved in foam EOR. Moreover, it is difficult to control the injection of surfactant and gas so that the foam is generated in only high permeable zones selectively in oil reservoir. The authors have found a foam generating microorganism and hit upon an idea of the microbial foam EOR which makes the microorganism do generating foam in oil reservoir. The mechanism of the microbial foam generation and culture condition suitable for the foam generation were studied in this study. A species of Pseudomonas aeruginosa was used as a foam producer in this study. It was cultured in the medium consisting of glucose and eight kinds of minerals at 30 °C and atmospheric pressure under anaerobic conditions. Because P. aeruginosa generally grows better under aerobic conditions, the microorganism was supplied with oxygen nanobubbles as the oxygen source. The carbon dioxide nanobubbles were also used as a comparison target in this study. The state of foam generation in the culture solution was observed during the cultivation. The surface tension, surfactant concentration, protein concentration, polysaccharides concentration and bacterial population of the culture solution were measured respectively. The foam was started to be generated by the microorganism after 2 days of cultivation and its volume became maximum after 3 days of cultivation. The foam generation was found in the culture solution which contained both oxygen nanobubbles and carbon dioxide nanobubbles whereas little foam was found in non-nanobubbles culture solution. The foam generation found in the culture solution containing carbon dioxide nanobubbles was more than that in the culture solution containing oxygen nanobubbles. Both gas and protein concentration increased along with the formation of the foam whereas surfactant and polysaccharides were not increased, therefore, the foam was assumed to be generated with gas and protein which were generated by P. aeruginosa. It was found that the carbon dioxide nanobubbles were positively charged in the culture medium whereas they were negatively charged in tap water through the measurement of zeta potential of nanobubbles, therefore, the carbon dioxide nanobubbles attracted cations in the culture medium and became positively charged. Positively charged carbon dioxide nanobubbles transported cations to the microbial cells of P. aeruginosa. Among cations in the culture medium, ferrous ions are essential for the protein generation of P. aeruginosa, therefore, the positively charged carbon dioxide nanobubbles attracted ferrous ions and transport them to the microbial cells, resulting the growth and metabolism of P. aeruginosa were activated. Those results suggest that the microbial foam EOR can be materialized by supplying the microorganism with carbon dioxide nanobubbles or ferrous ions.
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纳米气泡存在下微生物生泡沫提高采收率的研究
表面活性剂的高成本和环境负荷是泡沫提高采收率需要解决的问题。此外,表面活性剂和气体的注入难以控制,导致油藏中只有高渗透层才有选择性地产生泡沫。作者发现了一种产泡微生物,并提出了利用微生物在油藏中产泡提高采收率的思路。研究了微生物泡沫产生的机理和适宜泡沫产生的培养条件。本研究以一种铜绿假单胞菌作为泡沫产生菌。在由葡萄糖和8种矿物质组成的培养基中,在30℃常压厌氧条件下进行培养。由于铜绿假单胞菌一般在好氧条件下生长较好,因此采用氧纳米泡作为供氧源。在本研究中,二氧化碳纳米气泡也被用作比较目标。在培养过程中,观察了培养液中泡沫的生成情况。分别测定培养液的表面张力、表面活性剂浓度、蛋白质浓度、多糖浓度和细菌数量。微生物在培养2天后开始产生泡沫,培养3天后体积达到最大值。含氧纳米泡和含二氧化碳纳米泡的培养液均产生泡沫,而无纳米泡的培养液几乎不产生泡沫。在含有二氧化碳纳米气泡的培养液中发现的泡沫生成比在含有氧气纳米气泡的培养液中发现的泡沫生成多。气体和蛋白质的浓度随着泡沫的形成而增加,而表面活性剂和多糖的含量没有增加,因此可以认为泡沫是由铜绿假单胞菌产生的气体和蛋白质产生的。通过对纳米气泡zeta电位的测量发现,二氧化碳纳米气泡在培养基中带正电,而在自来水中带负电,因此二氧化碳纳米气泡吸引了培养基中的阳离子而带正电。带正电的二氧化碳纳米泡将阳离子输送到铜绿假单胞菌的微生物细胞中。在培养基中的阳离子中,亚铁离子是P. aeruginosa生成蛋白质所必需的,因此带正电的二氧化碳纳米泡吸引亚铁离子并将其运输到微生物细胞中,从而激活P. aeruginosa的生长和代谢。这些结果表明,微生物泡沫提高采收率可以通过向微生物提供二氧化碳纳米泡或亚铁离子来实现。
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