共查询到19条相似文献,搜索用时 93 毫秒
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微藻具有固定CO2和净化有机废水的能力,在环保、食品饲(饵)料、医药和生物能源开发等领域备受关注,但规模化培养及其产业化仍是研究的难点,亟待解决。就常用于大规模培养微藻的光生物反应器的特点和结构进行了综述。其中,封闭式微藻光生物反应器能够较好地调控藻种的培养条件、不易遭受污染,藻种的纯度容易控制,但培养规模小,生产成本较高;而开放式微藻光生物反应器无法精确控制藻种生长环境,但生产规模大、产量高、生产成本低,因此应用广泛。最佳的方法是综合两者优点,即首先利用封闭式微藻光生物反应器进行中试放大,大量繁殖藻种,然后投入开放式微藻光生物反应器内进行大规模商业生产,此方法有望成为微藻光生物反应器的发展方向,以期为微藻大规模培养提供参考借鉴。 相似文献
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产生物柴油微藻培养研究进展 总被引:14,自引:2,他引:14
石油的大量使用会导致能源枯竭和温室气体(CO2)排放的增加。为了实现经济和环境的和谐发展,必须使用可再生能源代替石油。可再生能源使用后不会造成温室气体排放的增加。生物柴油是一种理想的可再生能源, 能满足以上要求,所以近年来得到迅速发展。微藻是一种主要利用太阳能固定 CO2,生成制备生物柴油所需油脂的藻类。因此以微藻油脂为原料转化成的生物柴油是石油理想的替代品。简要介绍了产油微藻的种类和微藻油脂的合成,较详细地阐述了微藻自养培养、异养培养、生物反应器、工程微藻的最新研究进展,并初步展望了微藻产油研究的未来发展方向。 相似文献
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分析了微藻培养系统内光传递过程的数学模型和光分布影响因素,重点综述了光暗循环对微藻生长影响的实验研究和CFD技术应用研究进展,展望了微藻培养系统内光现象的发展方向,以期为规模化、高效微藻培养光生物反应器的设计、优化和放大提供参考。 相似文献
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引言
众所周知,资源、能源和环境是当前人类社会发展必须面临和解决的三大难题.传统化石能源的过量使用导致了石油资源短缺、全球气候变暖和环境污染.目前,各国政府和企业开始大力开发可再生能源,其中生物能源被认为是最具潜力的可再生能源之一.微藻能源集生物能源、生物固碳及N/P废水处理等多种功能于一体,具有独特的优势,已经成为国内外研究与开发的热点①.能源微藻的低成本规模化培养是实现微藻能源产业化的关键,也是当前限制微藻能源产业化的瓶颈. 相似文献
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微藻养殖中的新型光生物反应器系统 总被引:3,自引:0,他引:3
目前世界上微藻的大规模养殖仍普遍采用开放池式生产系统,该系统具有许多不足之处;开发高效、易于控制的新型生产系统是今后开展的趋势。本文对一些新型光生物反应器系统如优化的浅水道工生产系统、密闭管道式、发酵罐式光生物反应器、高密度藻类光生物反应器以及其它类型的光生物反应器进行了较为详细的介绍。 相似文献
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微藻生物柴油的现状与进展 总被引:5,自引:2,他引:5
微藻生物柴油能够解决目前使用植物原料发展生物柴油面临的耕地不足、气候变化对产量影响大和引起农作物价格上涨等突出问题。通过转基因技术培育“工程微藻”,繁衍能力高,生长周期短,比陆生植物产油高出几十倍,并且能用海水作为其天然培养基进行工业化生产。介绍了微藻生物柴油的优势,高脂质微藻选育,以及工程微藻研究与下游生产工艺的研究现状和进展。 相似文献
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微藻细胞富含油脂、淀粉及其他高值代谢物,可用于食品、饲料、化学品和能源的生产。但在规模化培养中,微藻的高生长速率和高产物含量难以兼得,制约了其商业化应用。通过微藻的两阶段培养技术可以将生长和产物积累的时期分离,从而同时获得较高的微藻生物量和产物含量。该技术具有产品得率高、节能减排、适用范围广的优点,是推进微藻商业化的关键之一。本综述总结了现有微藻两阶段培养技术的优势和产品类型,解析了目前微藻两阶段培养技术的限制因素及发展前景,并提出微藻两阶段培养中存在阶段转换时间尚不明确、中间采收步骤成本高这两个限制该技术应用的关键瓶颈,从而为未来微藻两阶段培养技术规模化生产方案的科学决策与实施提供参考。 相似文献
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微藻生物柴油研发态势分析 总被引:3,自引:0,他引:3
微藻是光合效率最高的原始植物之一,与农作物相比,单位面积的产率可高出数十倍。微藻生物柴油技术首先包括微藻的筛选和培育,获得性状优良的高含油量藻种,然后在光生物反应器中吸收阳光、CO2等,生成微藻生物质,最后经过采收、加工,转化为微藻生物柴油。完整的微藻生物柴油成套技术链涵盖多个技术环节,是一个复杂的系统工程,包括微藻生物工程技术、微藻高效规模化养殖技术,以及微藻生物质采收、加工与转化技术等。其中,降低生产成本是当前微藻生物柴油研究面临的主要挑战,各国的研究机构为此开展了多方面的研究。 相似文献
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污水资源化、二氧化碳减排及微藻生物柴油是当前能源与环境领域的前沿课题。以下围绕污水及烟道气资源化培养产油微藻的培养体系,就藻种、营养条件、培养方式、培养环境及微藻生物反应器等影响产油微藻培养的因素研究进展进行了综述。在综述的基础上提出:由于微藻具有特殊营养方式,通过藻种筛选、微藻营养条件和培养环境的优化以及高效光生物反应器和生产工艺等的创新,可利用污水进行产油微藻生产,以获得生物柴油等高附加值产品,实现微藻生物能源、污水资源化处理和CO2减排三者高度耦合的产油微藻生产体系,从而减少微藻培养费用及污水处理费用,因此,该体系具有重要的环境、社会、经济价值和商业化应用前景。 相似文献
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Tylor J. Johnson Sarmila Katuwal Gary A. Anderson Liping Gu Ruanbao Zhou William R. Gibbons 《Biotechnology progress》2018,34(4):811-827
The current burden on fossil‐derived chemicals and fuels combined with the rapidly increasing global population has led to a crucial need to develop renewable and sustainable sources of chemicals and biofuels. Photoautotrophic microorganisms, including cyanobacteria and microalgae, have garnered a great deal of attention for their capability to produce these chemicals from carbon dioxide, mineralized water, and solar energy. While there have been substantial amounts of research directed at scaling‐up production from these microorganisms, several factors have proven difficult to overcome, including high costs associated with cultivation, photobioreactor construction, and artificial lighting. Decreasing these costs will substantially increase the economic feasibility of these production processes. Thus, the purpose of this review is to describe various photobioreactor designs, and then provide an overview on lighting systems, mixing, gas transfer, and the hydrodynamics of bubbles. These factors must be considered when the goal of a production process is economic feasibility. Targets for improving microalgae and cyanobacteria cultivation media, including water reduction strategies will also be described. As fossil fuel reserves continue to be depleted and the world population continues to increase, it is imperative that renewable chemical and biofuel production processes be developed toward becoming economically feasible. Thus, it is essential that future research is directed toward improving these processes. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:811–827, 2018 相似文献
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微藻废水生物处理技术研究进展 总被引:1,自引:0,他引:1
微藻因生长速率快、细胞脂质含量高及具有生物隔离二氧化碳能力,已作为新一代生物质能源受到广泛关注.然而,投入大量淡水资源并需在生长期间持续提供营养物质已成为规模化培育微藻的主要障碍.将微藻培育系统与废水处理相结合是经济可行的污水资源化方案.基于微藻生长期间对氮磷等营养物质的利用机制,本文综述了微藻在各类废水生物处理过程中的应用情况,着重分析了其对废水中有机与无机化合物、重金属以及病原体的去除或抑制能力.同时,考察了废水初始营养物浓度、光照、温度、pH与盐度以及气体交换量等环境因素对微藻生长代谢的影响.此外,结合微藻规模化应用所面临的问题,对微藻废水处理技术的应用前景及发展方向进行了展望,旨在为水生态系统的建设与管理提供参考. 相似文献
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Ouassim Zeriouh José Vicente Reinoso-Moreno Lorenzo López-Rosales María del Carmen Cerón-García Asterio Sánchez-Mirón Francisco García-Camacho 《Critical reviews in biotechnology》2017,37(8):1006-1023
The economic and/or energetic feasibility of processes based on using microalgae biomass requires an efficient cultivation system. In photobioreactors (PBRs), the adhesion of microalgae to the transparent PBR surfaces leads to biofouling and reduces the solar radiation penetrating the PBR. Light reduction within the PBR decreases biomass productivity and, therefore, the photosynthetic efficiency of the cultivation system. Additionally, PBR biofouling leads to a series of further undesirable events including changes in cell pigmentation, culture degradation, and contamination by invasive microorganisms; all of which can result in the cultivation process having to be stopped. Designing PBR surfaces with proper materials, functional groups or surface coatings, to prevent microalgal adhesion is essential for solving the biofouling problem. Such a significant advance in microalgal biotechnology would enable extended operational periods at high productivity and reduce maintenance costs. In this paper, we review the few systematic studies performed so far and applied the existing thermodynamic and colloidal theories for microbial biofouling formation in order to understand microalgal adhesion on PBR surfaces and the microalgae–microalgae cell interactions. Their relationship to the physicochemical properties of the solid PBR surface, the microalgae cell surfaces, and the ionic strength of the culture medium is discussed. The suitability and the applicability of such theories are reviewed. To this end, an example of biofouling formation on a commercial glass surface is presented for the marine microalgae Nannochloropsis gaditana. It highlights the adhesion dynamics and the inaccuracies of the process and the need for further refinement of previous theories so as to apply them to flowing systems, such as is the case for PBRs used to culture microalgae. 相似文献
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Application of a growth-promoting bacteria for stable mass culture of three marine microalgae 总被引:2,自引:0,他引:2
The practical mass culture of marine microalgae, facesoccasionally unexpected problems or collapse. The effect of amarine bacterium, Flavobacterium sp., which was found topromote growth of a marine diatom Chaetoceros gracilisin the axenic culture condition, was examined on the masscultures of three marine microalgae.Three marine microalgae (C. gracilis, Isochrysisgalbana, and Pavlova lutheri) were mass cultured in 3 lflatbottom flasks (2.5 l capacity of culture medium), in anindoor culture room at a commercial pearl oyster hatchery. Themicroalgal cells and the bacterium were inoculated at the sametime, in the culture media. The specific growth rate andmaximal cell density were determined in treated cultures (withadded bacterial strain) and in controls (without addedbacterial strain). The specific growth rate of C.gracilis in treated cultures was significantly higher thanthat of control cultures, and the stationary growth phase inthe treated cultures lasted longer till the end of the cultureperiod. However, the bacterium had no apparent effect on theexponential growth phase of two phytoflagellates, I.galbana and P. lutheri, but kept longer the high celldensity in the stationary growth phases. The added bacterialstrain (Flavobacterium sp.) was the dominant species(more than 45%) among the bacterial flora during the cultureperiod. 相似文献