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.     

Application of microbial enhanced oil recovery technique to a Turkish heavy oil

Summary Microbial enhance oil recovery utilizes microorganisms and their metabolic products to improve the recovery of crude oil from reservoir rocks. In this study an anaerobic bacterium, Clostridium acetobutylicum was injected into a one-dimensional model reservoir containing a Turkish heavy oil (Raman oil) at 38° C. This injection was followed by water flooding after a suitable shut-in period. Comparison of oil recovery results of pure water flooding runs with experiments in which bacterial concentration and shut-in periods were varied indicated increases in oil recovery of about 12% of the original oil in place. This increase was attributed to changes in the viscosity and pH of the crude oil.Offprint requests to: T. Mehmetoglu     

微生物提高原油采出率的室内研究

微生物采油技术是一种提高原油采出率的卓有成效的方法。本文通过在实验室条件下模拟江苏油田韦4区块的储层情况,进行岩芯的驱替实验,对微生物采油技术在韦4区块的运用作了一些研究和评价,并得出应用结论,为该技术在现场的实验奠定了理论基础。     

Hemicellulose sugar recovery from steam-exploded wheat straw for microbial oil production

There are currently few successful examples of using straw hemicellulose as a carbon source in the fermentation industry. In this paper, hemicellulose hydrolysates were recovered from steam-exploded wheat straw (SEWS) and used to produce microbial oil. The effects of the steam explosion treatment conditions, the elution temperature and the ratio of elution water to SEWS on sugar recovery were examined. A broth with 3.8 g l^?1 of reducing sugar and 22.3 g l^?1 of total soluble sugars was obtained with a 10-fold excess (w/w) of water at 40 °C to wash the SEWS treated under steam explosion conditions at 200 °C for 5 min. This broth was used to produce microbial oil by the oleaginous fungus Microsphaeropsis sp., which was able to secrete xylanase to degrade oligosaccharides from straw hemicellulose and accumulate microbial oil. Under optimized conditions, the oil concentration was 2.6 g l^?1. The yield of oil from sugar consumed was 0.14 g g^?1. The microbial oil produced by this research could be used as feedstock for biodiesel production because the microbial oil was primarily composed of neutral lipids. This research establishes a novel protocol for microbial oil production from straw hemicellulose.     

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.     

Microbially enhanced oil recovery from miniature model columns through stimulation of indigenous microflora with nitrate

Sandpack columns filled with heavy oil and water, with or without a nitrate-reducing inoculum, were used to determine if nitrate injections could lead to enhanced oil recovery. Production of oil and water into vials filled with helium or argon was monitored during repeated anaerobic incubations at 30 °C. Regardless of the presence of inoculum, columns containing nitrate consistently produced more oil than those without nitrate during incubations. Microbial reduction of nitrate to nitrogen with production of carbon dioxide might contribute to the establishment of gas drive. The presence of nitrate could also lead to increased production of biomass and/or biosurfactants, reducing oil-water interfacial tension. Counter-diffusion of nitrogen and carbon dioxide dissolved in column liquids and of helium or argon present in the vial gas phase likely contributed to the establishment of gas drive in all columns. Heptane was present in consistently lower concentrations in columns with nitrate than in those without nitrate at the end of incubations, suggesting that it was an important source of carbon and energy for microbial growth. Azoarcus spp. dominated the consortium when the inoculum was grown with heptane as the sole source of carbon and energy, indicating that this bacterium might contribute to the observed oil production.     

Comparison of mono-rhamnolipids and di-rhamnolipids on microbial enhanced oil recovery (MEOR) applications

Rhamnolipids (RMLs) have more effectiveness for specific uses according to their homologue proportions. Thus, the novelty of this work was to compare mono-RMLs and di-RMLs physicochemical properties on microbial enhanced oil recovery (MEOR) applications. For this, RML produced by three strains of Pseudomonas aeruginosa containing different homologues proportion were used: a mainly mono-RMLs producer (mono-RMLs); a mainly di-RMLs producer (di-RMLs), and the other one that produces relatively balanced amounts of mono-RML and di-RML homologues (mono/di-RML). For mono-RML, the most abundant molecules were Rha-C₁₀C₁₀ (m/z 503.3), for di-RML were RhaRha-C₁₀C₁₀ (m/z 649.4) and for Mono/di-RML were Rha-C₁₀C₁₀ (m/z 503.3) and RhaRha-C₁₀C₁₀ (m/z 649.4). All RMLs types presented robustness under high temperature and variation of salinity and pH, and high ability for oil displacement, foam stability, wettability reversal and were classified as safe for environment according to the European Union Directive No. 67/548/EEC. For all these properties, it was observed a highlight for mono-RML. Mono-RML presented the lowest surface tension (26.40 mN/m), interfacial tension (1.14 mN/m), and critical micellar concentration (CMC 27.04 mg/L), the highest emulsification index (EI₂₄ 100%) and the best wettability reversal (100% with 25 ppm). In addition, mono-RML showed the best acute toxicity value (454 mg/L), making its application potential even more attractive. Based on the results, it was concluded that all RMLs homologues studied have potential for MEOR applications. However, results showed that mono-RML stood out and have the best mechanism of oil incorporation in micelles due their most effective surface-active physicochemical features.     

Exopolysaccharide production by a genetically engineered Enterobacter cloacae strain for microbial enhanced oil recovery

Microbial enhanced oil recovery (MEOR) is a petroleum biotechnology for manipulating function and/or structure of microbial environments existing in oil reservoirs for prolonged exploitation of the largest source of energy. In this study, an Enterobacter cloacae which is capable of producing water-insoluble biopolymers at 37 °C and a thermophilic Geobacillus strain were used to construct an engineered strain for exopolysaccharide production at higher temperature. The resultant transformants, GW3-3.0, could produce exopolysaccharide up to 8.83 g l⁻¹ in molasses medium at 54 °C. This elevated temperature was within the same temperature range as that for many oil reservoirs. The transformants had stable genetic phenotype which was genetically fingerprinted by RAPD analysis. Core flooding experiments were carried out to ensure effective controlled profile for the simulation of oil recovery. The results have demonstrated that this approach has a promising application potential in MEOR.     

生物表面活性剂在提高原油采收率方面的应用

生物表面活性剂和一般的化学表面活性剂一样,都拥有亲水和疏水基因,是微生物生长在水不溶的有机物中并以营养物而产生的代谢产物。在油田应用中,生物表面活性剂的作用是微生物提高采收率的重要机理之一,具有水溶性好、反应产物均一、安全无毒、驱油效果好等特点。本文从产生生物表面活性剂的菌种及生物表面活性剂的类型、生物表面活性剂的特性、实验研究、矿场实验及展望等五个方面综述了生物表面活性剂在提高原油采收率方面的应     

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.     

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.     

Microbial selective plugging and enhanced oil recovery

Summary The ability of indigenous populations of microorganisms in Berea sandstone to improve the volumetric sweep efficiency and increase oil recovery by in situ growth and metabolism following the injection of nutrients was studied. Cores of differing permeabilities connected in parallel without crossflow and slabs of sandstone with differing permeabilities in capillary contact to allow crossflow were used. The addition of a sucrosenitrate mineral salts medium stimulated the growth and metabolism of microorganisms in the sandstone systems. This resulted in a preferential decrease in permeability in the core or slab with the higher initial permeability, diverted flow into the lower-permeability core or slab and improved the volumetric sweep efficiency. Injectivity into the slab with the lower initial permeability in the crossflow system increased during subsequent nutrient injections. Thus, microbial selective plugging does occur in laboratory systems that have the complex flow patterns observed in petroleum reservoirs without losing the ability to inject fluids into the formation. In situ microbial growth and metabolism increased oil recovery 10 to 38% of the original oil in place. Biogenic gas production accompanied oil production, and much of the gas was entrained within the produced oil suggesting that gas production was an important factor leading to increased oil recovery. Quantitation of the amount of phospholipid in the core confirmed that microbial growth preferentially occurred throughout the core with the higher initial permeability. These data showed that in situ microbial growth in the high-permeability regions improved not only the volumetric sweep efficiency but also the microscopic oil displacement efficiency.     

Cyclic lipopeptide signature as fingerprinting for the screening of halotolerant Bacillus strains towards microbial enhanced oil recovery

Applied Microbiology and Biotechnology - Cyclic lipopeptides (CLPs) are non-ribosomal biosurfactants produced by Bacillus species that exhibit outstanding interfacial activity. The synthesis of...     

用假单胞菌进行三次采油的研究

人大庆油田油层水中分离得到1株假单胞菌P－21,对其发酵液进行研究。室内实验证明,8％的P－21发酵液与原油混合,在45℃的条件下作用24h,对原油的降粘率达到57.8％,防蜡率达到80％。而10％的P－21发酵液可能使人工岩芯中的原油采收率提高11.2%,同时使注入压力下降38.4%。因此,P－21在微生物提高原油采收率中有很大的应用潜力。     

Effect of a genetically modified Pseudomonas aureofaciens on indigenous microbial populations of wheat

Abstract An isolate of Pseudomonas aureofaciens from the phylloplane of sugar beet which was chromosomally modified for monitors purposes by the insertion of two gene cassettes (km^r- xyl E and lac ZY) was introduced to the phytosphere of spring wheat in a number of experiments and the resulting microbial perturbations quantified. Such studies involving innocuous bacterial isolates can serve as a guide in the assessment of risk associated with the release of functionally modified microorganisms. Introductions of P. aureofaciens on seeds caused large microbial perturbations (up to 2 log units) at the seedling stage on seeds and roots. As the inoculated plants matured (tillering, flowering and ripening), perturbations of total microbial populations were found to be non-significant. Microbial perturbation on maturing wheat roots as a result of seed inoculations with P. aureofaciens could only be detected using more sensitive monitoring procedures describing the Pseudomonas community in terms of colony appearance rate on a selective Pseudomonas medium. Spray applications of the marked P. aureofaciens isolate onto the leaf surface of wheat caused no significant perturbations of the indigenous microbial present on the phylloplane.