Impact of an indigenous microbial enhanced oil recovery field trial on microbial community structure in a high pour-point oil reservoir

Based on preliminary investigation of microbial populations in a high pour-point oil reservoir, an indigenous microbial enhanced oil recovery (MEOR) field trial was carried out. The purpose of the study is to reveal the impact of the indigenous MEOR process on microbial community structure in the oil reservoir using 16Sr DNA clone library technique. The detailed monitoring results showed significant response of microbial communities during the field trial and large discrepancies of stimulated microorganisms in the laboratory and in the natural oil reservoir. More specifically, after nutrients injection, the original dominant populations of Petrobacter and Alishewanella in the production wells almost disappeared. The expected desirable population of Pseudomonas aeruginosa, determined by enrichment experiments in laboratory, was stimulated successfully in two wells of the five monitored wells. Unexpectedly, another potential population of Pseudomonas pseudoalcaligenes which were not detected in the enrichment culture in laboratory was stimulated in the other three monitored production wells. In this study, monitoring of microbial community displayed a comprehensive alteration of microbial populations during the field trial to remedy the deficiency of culture-dependent monitoring methods. The results would help to develop and apply more MEOR processes.     

Monitoring exogenous and indigenous bacteria by PCR-DGGE technology during the process of microbial enhanced oil recovery

A field experiment was performed to monitor changes in exogenous bacteria and to investigate the diversity of indigenous bacteria during a field trial of microbial enhanced oil recovery (MEOR). Two wells (26-195 and 27-221) were injected with three exogenous strains and then closed to allow for microbial growth and metabolism. After a waiting period, the pumps were restarted and the samples were collected. The bacterial populations of these samples were analyzed by denaturing gradient gel electrophoresis (DGGE) with PCR-amplified 16S rRNA fragments. DGGE profiles indicated that the exogenous strains were retrieved in the production water samples and indigenous strains could also be detected. After the pumps were restarted, average oil yield increased to 1.58 and 4.52 tons per day in wells 26-195 and 27-221, respectively, compared with almost no oil output before the injection of exogenous bacteria. Exogenous bacteria and indigenous bacteria contributed together to the increased oil output. Sequence analysis of the DGGE bands revealed that Proteobacteria were a major component of the predominant bacteria in both wells. Changes in the bacteria population in the reservoirs during MEOR process were monitored by molecular analysis of the 16S rRNA gene sequence. DGGE analysis was a successful approach to investigate the changes in microorganisms used for enhancing oil recovery. The feasibility of MEOR technology in the petroleum industry was also demonstrated.     

油藏微生物群落研究的方法学

油藏微生物群落的解析和认知是开发和应用微生物采油技术的基础。利用各种提高油藏微生物可培养性的方法和非培养技术解析不同油藏微生物的群落结构、功能和多样性,对定向调控油藏微生物群落、开发和应用有效微生物驱油技术具有重要的指导意义。通过调查新近发展的提高微生物可培养性的方法和措施以及不依赖于培养的分子微生物生态学技术,总结了油藏微生物群落研究方法学的最新进展。提高微生物可培养性的方法和措施主要通过模拟微生物的生存环境,减少富营养的毒害作用、添加信号分子维持微生物细胞间的作用和提供新型电子供体和受体等手段采用稀释法、高通量培养法等方法得以实现;不依赖于培养的分子微生物生态学技术主要包括荧光原位杂交、末端限制性片断长度多态性分析、变性梯度凝胶电泳和构建克隆文库等技术。这些方法学的进展为更有效的获得各种油藏微生物资源、调控油藏微生物群落以提高石油采收率提供理论指导。     

长庆油田延9低渗透油藏微生物群落研究

目的:研究长庆油田延9低渗透油藏微生物群落,为实施微生物提高原油采收率提供指导和依据。方法:长庆油田延9油藏三口不同油井(柳28-46、柳28-47和柳27-45)的油水样品建立16S rDNA克隆文库进行研究。结果:构建了柳28-46、柳28-47和柳27-45油井样品的微生物基因克隆文库,其分类操作单元(OUT)数分别为21、20和20个;序列分析比对表明,3口井的共同的优势微生物菌群为铜绿假单胞菌(Pseudomonas aeruginos),分别占各文库的32.8%、32%和42.9%,它是最常见最主要的采油功能菌之一。此外硫酸盐还原菌(SRB)和铁细菌也处于优势地位,它们是原油开采中的有害菌。结论:延9低渗透油藏微生物群落和其潜在功能的分析为开展微生物提高石油采收率应用提供了良好的基础资料。     

大庆油田微生物采油现场试验进展

本文介绍近十几年以来大庆油田利用具有产气、降解原油、产生物表面活性剂及堵调性能的菌剂,通过地下发酵,开展微生物采油现场试验取得的进展.分析了该项技术适用的油藏条件和应用特点.截止到2012年底,应用微生物采油技术增产原油达12×104 t.其中微生物单井吞吐518口,累计增油6.3×104t,实施微生物驱和调驱项目10项(45个井组),累计增油5.7×104 t,为大庆油田稳产发挥了重要作用.     

Characterization of microbial diversity and community in water flooding oil reservoirs in China

The diversity and distribution of bacterial and archaeal communities in four different water flooding oil reservoirs with different geological properties were investigated using 16S rDNA clone library construction method. Canonical correspondence analysis was used to analyze microbial community clustering and the correlation with environmental factors. The results indicated that the diversity and abundance in the bacterial communities were significantly higher than the archaeal communities, while both of them had high similarity within the communities respectively. Phylogenetic analysis showed that of compositions of bacterial communities were distinctly different both at phylum and genus level. Proteobacteria dominated in each bacterial community, ranging from 61.35 to 75.83?%, in which α-proteobacteria and γ-proteobacteria were the main groups. In comparison to bacterial communities, the compositions of archaeal communities were similar at phylum level, while varied at genus level, and the dominant population was Methanomicrobia, ranging from 65.91 to 92.74?% in the single oil reservoir. The factor that most significantly influenced the microbial communities in these reservoirs was found to be temperature. Other environmental factors also influenced the microbial communities but not significantly. It is therefore assumed that microbial communities are formed by an accumulated effect of several factors. These results are essential for understanding ecological environment of the water flooding oil reservoirs and providing scientific guidance to the performance of MEOR technology.     

采油微生物在微驱过程中的生长、运移及分布规律

[目的]深入了解现场微生物驱油机理、效果评价标准及影响因素.[方法]结合现场微生物驱油过程产出液的跟踪监测及室内物模实验对微生物在地层中的生长繁殖、运移及分布规律进行研究.[结果]结果表明,通过从水井注入的外源微生物在油藏中能够有效生长繁殖,而且注入的营养液也能够激活内源微生物,但由于地层渗透率及营养液浓度的影响,产出液菌浓要比注入菌浓低1-2个数量级;葡萄糖的快速降解以及地层对微生物的过滤及吸附作用使大量的微生物停留在近井地带,仅有部分微生物能够从生产井采出,而且其运移速度要比营养液慢.[结论]地层渗透率和产出液中营养物浓度是影响微生物数量及分布的两个关键因素,现场微生物驱油产出液中的菌浓一般很难达到106个/mL以上,该研究结果对微生物驱油技术的发展和应用具有重要意义.     

Microbial processes in the Athabasca Oil Sands and their potential applications in microbial enhanced oil recovery

The Athabasca Oil Sands are located within the Western Canadian Sedimentary Basin, which covers over 140,200 km² of land in Alberta, Canada. The oil sands provide a unique environment for bacteria as a result of the stressors of low water availability and high hydrocarbon concentrations. Understanding the mechanisms bacteria use to tolerate these stresses may aid in our understanding of how hydrocarbon degradation has occurred over geological time, and how these processes and related tolerance mechanisms may be used in biotechnology applications such as microbial enhanced oil recovery (MEOR). The majority of research has focused on microbiology processes in oil reservoirs and oilfields; as such there is a paucity of information specific to oil sands. By studying microbial processes in oil sands there is the potential to use microbes in MEOR applications. This article reviews the microbiology of the Athabasca Oil Sands and the mechanisms bacteria use to tolerate low water and high hydrocarbon availability in oil reservoirs and oilfields, and potential applications in MEOR.     

微生物采油技术用于聚驱后油藏的研究进展

聚合物驱后仍会有大量的剩余油残留在低渗透层中,而且油层中滞留的聚合物还会给后续的驱油带来负面影响。有很多证据表明,在聚驱油藏中、聚驱油田产出液中、油田土壤中,存在能降解常用驱油聚合物,并以之为唯一营养源的细菌。这样人们就可以利用微生物的降解作用除去油藏中残留聚合物,再结合常规微生物采油技术进一步提高聚驱后油藏的采收率。目前已经进行的室内、现场实验取得了一定成效,但有明显局限性。不过通过进一步的理论研究,大部分问题会得到解决,所以该技术的发展前景仍然广大。     

油藏微生物的代谢特征与提高原油采收率技术

油藏是一个高温、高压、少氧、寡营养和封闭的极端环境,油田经过多年注水开发后,在油藏内部形成了相对稳定的微生物群落体系,这些微生物以石油烃分解为起始,形成了一个复杂的食物链,对油藏碳、硫和金属离子的元素地球化学循环起着非常重要的作用。微生物提高原油采收率技术(MEOR)是利用微生物及其代谢产物与油藏和原油发生作用来提高原油采收率的一种新技术,具有成本低、适应性强和环境友好等特点,因此有望成为未来化学驱后油藏和高含水油藏进一步提高采收率的重要手段。对油藏内源微生物及其介导的生化反应,微生物采油原理、发展历程和现场试验进行综述,并提出了未来的发展方向。     

内源微生物驱油及其对油藏微生物活动的影响

【目的】新疆油田六中区为典型水驱普通稠油油藏，水驱效果较差，油藏具有丰富的内源微生物，本研究通过分析内源微生物驱油对油藏微生物活动的影响，确定内源微生物驱油技术在该类油藏的应用潜力。【方法】采用高通量测序及分析化学技术，系统研究实施内源微生物驱油技术后油藏细菌群落结构组成、细菌总数和功能菌群的浓度以及采出液的流体性质，总结内源微生物驱油对油藏微生物活动的影响。【结果】现场试验注入激活剂和空气后，内源微生物被显著激活，细菌群落结构发生明显变化，细菌总数及功能菌群浓度普遍提高了2–3个数量级；各种内源微生物代谢活动显著增强，与地层流体相互作用后，原油明显被乳化，最终石油采收率提高5.2%。【结论】对于内源微生物较为丰富的水驱普通稠油油藏，内源微生物驱油技术对油藏微生物活动的影响显著，具有显著的技术优势和较大的应用潜力，微生物群落结构、功能菌群浓度及其相关代谢产物可以作为评价内源微生物驱油现场激活效果的重要指标，为其他内源微生物驱油现场试验提供技术参考。     

模拟油藏条件下内源微生物群落空间分布规律

【背景】油藏内源微生物群落是开展内源微生物驱油技术的物质基础,由于油藏多孔介质取样技术难度大、成本高,实施内源微生物驱油后从注入端到产出端多孔介质中的内源微生物空间分布规律尚不明确。【目的】通过室内长岩心连续驱替实验模拟油藏内源微生物驱油过程,分析实施后不同空间位点油砂上吸附的内源微生物群落结构,揭示从注入端到产出端内源微生物群落的空间分布规律。【方法】借助高通量测序技术及荧光定量PCR技术解析不同空间位点油砂原位微生物群落信息。【结果】注入端到产出端不同空间位点生态环境的差异及菌属间的相互作用造成油藏内源微生物群落空间分布差异,存在明显的好氧、厌氧空间演替变化规律。岩心前端主要存在一些好氧类的产生物表面活性剂类微生物如假单胞菌属,岩心中部主要存在兼性和厌氧类的微生物如地芽孢杆菌、厌氧杆菌属,岩心末端主要分布严格厌氧类细菌和产甲烷古菌,厌氧类微生物代谢产生的H2、CO2和乙酸分子可以为产甲烷古菌提供代谢底物。【结论】通过室内物模油砂研究,首次明确了内源微生物群落在多孔介质中从注入端到产出端的空间分布规律,证实油藏内源微生物的好氧、厌氧空间接替分布规律,深化了对油藏内源微生物的认识。     

Microbially enhanced oil recovery from carbonate reservoirs

About half of the world's oil production is from carbonate formations. However, most of the research in microbially enhanced oil recovery (MEOR), a potentially important tertiary recovery technology, has focused on sandstone reservoirs because, in general, they are geologically simpler than carbonate reservoirs and easier to model in the laboratory. Carbonate formations have a wide range of pore geometries and distributions, resulting in complex flow dynamics. The low matrix permeabilities and the dual porosity characteristics of most carbonate formations, coupled with the chemistry of carbonates, have slowed implementation of enhanced oil recovery methods. A review of the data on carbonate reservoirs in Dwight's Energydata TOTL System indicated that 40% of the oil‐producing carbonate reservoirs surveyed in the United States have environmental, geological, and petrophysical conditions that would make them candidates for MEOR. A review of a number of MEOR field trials showed that rates of oil production could be increased by as much as 200%. Microbial activity in these trials was probably due to that of indigenous populations rather than the microorganisms injected for the trials. Detrimental effects such as loss of injectivity and increased souring were not reported. Based on analysis of the geology and petrophysical characteristics of carbonates, two common mechanisms of MEOR, microbial acid production and microbial gas production, are especially suited for application in carbonate reservoirs.     

胜利油田单12高温油藏非培养和富集培养样品的细菌组成特性

[目的]通过比较分析油藏样品的微生物群落结构特点,认识油藏微生物的生态功能.[方法]利用3种油藏微生物研究中常用的富集培养方法,对胜利油田单12区块S12-4油井产出水样品进行了选择性富集培养,运用构建16S rRNA基因文库的方法分析了富集样品和非培养样品的细菌多样性.[结果]通过16S rRNA基因序列比对发现,非培养样品、异养菌富集样品、烃降解菌富集样品和硫酸盐还原菌富集样品中的优势菌分别为Pseudomonas属,Thermotoga属,Thermaerobacter属和Thermotoga属的成员.多样性分析结果表明,非培养样品的微生物多样性最丰富,同时非培养样品和富集样品的微生物群落结构存在很大的差异,富集样品中的微生物包括优势菌在油藏原位环境中含量很低.[结论]细菌组成差异的比较结果,对油藏微生物的生态功能研究和微生物驱油潜力评估具有重要意义.     

超低渗油藏微生物吞吐技术的矿场试验

【目的】通过对渭北低渗油藏内源微生物的研究,考察分离纯化的内源解烃菌产生表面活性剂和降解原油的能力、岩心驱替增油效率,同时验证其在超低渗油田单井吞吐矿场实验的应用效果,探讨微生物采油技术在超低渗油田提高采收率的工艺和可行性。【方法】采集超低渗油藏的油水样,应用油平板进行产表面活性剂解烃菌的分离,通过生理生化特性和16S r RNA基因序列分析对菌株进行种属鉴定,评价其油藏环境适应性,利用内源-外源功能微生物复配体系进行原油降解,在填砂管和岩心物模上进行驱油实验,将优化好的微生物复配体系应用于现场实施单井吞吐工艺的实验。【结果】从渭北某区块超低渗油藏的原油样品中分离得到一株铜绿假单胞菌(Pseudomonas aeruginosa),命名为WB-001。该菌株可使发酵液的表面张力降至29.04 m N/m,使渭北原油蜡质含量降至8.48%。填砂管实验表明WB-001与外源枯草芽胞杆菌OPUS-HOB-001(Bacillus subtilis)复配后,驱油效率较单纯水驱提高了9.72%;岩心驱替实验较水驱提高12.54%。微生物单井吞吐措施后,平均日产油由措施前的0.42 t增加到0.89 t,累计增油44.47 t;原油降粘率为11.70%,降凝率为9.41%,采出水表面张力降低幅度为18.93%。【结论】通过详细的室内评估和成功的矿场实验,证明微生物采油技术在超低渗油藏有一定的应用可行性,并为后续规模化应用提供了理论基础和物质基础,为超低渗油田的高效精细开发探索一条新的途径。     

Expanding the microbial monitoring toolkit: Evaluation of traditional and molecular monitoring methods

Evaluation of microbial populations in oilfield systems is critical to understand the risk of microbiologically influenced corrosion, reservoir and surface souring (hydrogen sulfide production), and biofouling. Although traditional culture based methods have dominated oilfield microbial monitoring for years, use of molecular tools is becoming more common for both field and laboratory evaluations. The implementation of these additional tools is in response to some of the disadvantages of culture-based methods such as long incubation times and underestimation of actual microbial populations. The current work provides a direct comparison of culture-based methods (serial dilution for sulfate reducing, acid producing, and general heterotrophic bacteria) with molecular methods including adenosine triphosphate (ATP) and adenosine monophosphate (AMP) quantification and quantitative polymerase chain reaction (qPCR). The results demonstrate that these technologies provide nearly identical results in untreated samples with known culturable organisms, but show some differences when used in the context of a planktonic kill study. The pros and cons of each technology were addressed with respect to their use in field monitoring, laboratory monitoring, and microbial kill studies. The authors found that none of the technologies described in this work provide an all-inclusive answer, but together they provide significant insight into the microbial population in an oilfield system. In short, the authors demonstrate that it is advantageous for oilfield stakeholders to expand their microbial monitoring toolkit with these new technologies to ensure sustainable, cost-effective operation.     

厌氧产表面活性剂微生物提高原油采收率的研究进展

微生物强化采油(microbial enhanced oil recovery,MEOR)是近年来在国内外发展迅速的一项提高原油采收率技术。微生物在油藏中高效生产表面活性剂等驱油物质是微生物采油技术成功实施的关键之一。然而,油藏的缺/厌氧环境严重影响好氧表面活性剂产生菌在油藏原位的生存与代谢活性;油藏注空气会增加开采成本,且注入空气的作用时效和范围难以确定。因此,开发厌氧产表面活性剂菌种资源并强化其驱油效率对于提高原油采收率具有重要意义。本文综述了国内外近年来利用厌氧产表面活性剂微生物提高原油采收率的研究进展,简述了微生物厌氧产表面活性剂的相关驱油机理、菌种资源开发现状以及油藏原位驱油应用进展,并对当前的研究提出了一些思考。     

大港孔店油田水驱油藏微生物群落的分子分析

通过多聚酶链式反应温度梯度凝胶电泳（PCRTGGE）和构建16S rRNA基因克隆文库两种方法对比研究了大港油田孔二北断块注水井和采油井的微生物群落结构。16S rDNA V3区PCR扩增产物的TGGE图谱分析表明,这两个油井的微生物群落结构差异很大。注水井样品的TGGE图谱中有6条主要条带,而采油井样品中只有一个条带占绝对优势。同时,建立了两个样品的16S rRNA基因克隆文库,从中分别挑选了108和50个克隆进行限制性酶切片段长度多样性分析（ARDRA）。注水井样品有33个操作分类单元（OUT）,其中6个OUT是优势类型;而采油井样品只有8个OUT,有1个OUT在文库中占绝对优势。克隆文库和TGGE的研究结果一致,均表明注水井样品的微生物多样性比采油井丰富很多。每个OUT的代表克隆序列分析结果表明,注水井样品中的细菌主要属于α、β、γ变形菌纲和放线菌纲,尤其是红细菌亚纲（47%）。采油井样品的细菌主要属于α、β、γ变形菌纲,尤其是假单胞菌属（62%）。油藏微生物多样性的分子分析可为开展微生物采油技术研究奠定基础。     

Systematic Modeling Approach to Selective Plugging Using In Situ Bacterial Biopolymer Production and Its Potential for Microbial-enhanced Oil Recovery

This study presents a systematic modeling approach for examining the efficiency of the MEOR process based on in situ selective plugging by bacterial biopolymer production and optimization of the nutrient injection strategy to yield the maximum oil recovery. This study focuses on modeling in situ selective plugging by the bacterial biopolymer dextran that is generated by Leuconostoc mesenteroides. Bacterial growth and dextran generation were described by a stoichiometric equation and kinetic reactions using batch model simulation. Based on the parameters for permeability reduction obtained from the sandpack model, the MEOR process was implemented in a pilot-scale system that included a highly permeable thief zone in a low-permeability reservoir. The base MEOR design yielded a 61.5% improvement of the recovery factor compared to that obtained with waterflooding. The parametric simulations revealed that the recovery efficiency was influenced by the amount of dextran, as well as the distribution of dextran, and thus, the injection strategy is critical for controlling the dextran distribution. By incorporating the results from the sensitivity analysis and optimization to determine the optimal design parameters, a 36.7% improvement of the oil recovery was achieved with the optimized MEOR process in comparison with the base case.     

Effects of oil reservoir conditions on the production of water‐insoluble Levan by Bacillus licheniformis

Bacillus licheniformis produced a water‐insoluble levan which has potential application as a selective plugging agent in microbial enhanced oil recovery (MEOR). The microorganism grew on sucrose, glucose, and fructose but produced levan only on sucrose. Plugging may thus be selectively controlled in the reservoir by substrate manipulation. B. licheniformis and a crude preparation of its extracellular enzymes were evaluated for their ability to produce levan under reservoir conditions. Oil reservoirs which have a temperature of less than 55°C, a pH between 6 and 9, a pressure less than 500 atm, and a salt concentration of 4% or less are potentially suitable. Examples of such reservoir conditions are found in Lloydminster on the Alberta‐Saskatchewan border, one of the largest Canadian oil reserves.