生物制氢最新研究进展与发展趋势

氢能具有清洁、高效、可再生的特点,是一种最具发展潜力的化石燃料替代能源.与传统的热化学和电化学制氢技术相比,生物制氢具有低能耗、少污染等优势.近年来,生物制氢技术在发酵菌株筛选、产氢机制、制氢工艺等方面取得了较大进展.暗发酵和光发酵结合制氢技术是一种新技术,具有较高的氢气产量.以厌氧细菌和光合细菌为发酵菌种,以富含碳水化合物的工农业废弃物为原料,进行暗发酵和光发酵结合制氢,具有广阔发展前途前景.本文综述了国内外生物制氢技术研究进展,展望了未来发展趋势.     

给水生物预处理反应器的细菌种群多样性和群落结构

提取一生产性规模的给水生物预处理反应器中生物膜样品的总DNA,构建细菌16S rDNA克隆文库,并通过16S rDNA序列的系统发育分析,对生物膜中的细菌种群多样性和群落结构进行了研究.实验结果表明,给水生物膜反应器中的细菌种群多样性十分丰富;生物膜中的细菌分别属于10个主要类群,其中α-Proteobacteria是克隆文库中的最大细菌类群,占克隆子总数的32.28%,其次是β-Proteobacteria;与Rhodobacter系统关系密切的细菌是克隆文库中所占比例最大的一个菌属,占克隆子总数的12.6%;反应器中与硝化作用有关的是Nitrosomonas和Nitrospira属的细菌.研究结果表明,给水生物预处理反应器中的细菌群落结构和废水生物处理反应器中的细菌群落结构是有所差异的.图1表1参13     

不同酸碱条件下光合细菌的生长产氢特性

为了解光合细菌的产氢机理,对沼泽红假单胞光合产氢菌CQK-01在光生物平板反应器中进行序批次培养,以470 nm LED灯提供连续光照,葡萄糖为碳源底物,研究不同初始酸碱条件下产氢光合细菌的生长特性、产氢特性以及能量转化效率.结果表明,在弱碱性条件下最适宜产氢光合细菌的生长;在反应液为酸性条件下,光合细菌具有较高的产氢量、产氢速率和能量转化效率,然而产氢纯度随着初始pH值的增大而升高;在温度30℃、光照强度1 000lx、底物浓度75 mmol/L的实验条件下,光合细菌的最佳产氢pH值为7.0,实验中最大累积产氢量为8.0 mmol,最大产氢速率为3.39 mmol g-1(cell dry weight)h-1,产氢纯度高达70%,底物能量转化效率最大为1.98%,光能转化效率最大为7.7%.     

光合细菌光合产氢机理研究进展[综述]

７０年代以来，随着全球性的能源危机和温室效应的加剧，无污染、可再生的氢能的研究开发日受重视．物制氢技术是氢能开发研究的一项重要内容．至今已知的具产氢活性的微生物有“光合细菌”（ｐｈｏｔｏｓｙｎｔｈｅｔｉｃｂａｃｔｅｒｉａ，ＰＳＢ）、藻类（ａｌｇａｅ）和非光合细菌（ｎｏｎｐｈｏｔｏｓｙｎｔｈｅｔｉｃｂａｃｔｅｒｉａ）［１］．由于ＰＳＢ光合产氢的速度要比藻类快，能量利用率比非光合细菌高，且能将产氢与光能利用、有机物的去除有机地耦合在一起，因而得到了众多研究者的关注．本文就ＰＳＢ的产氢的机理及影响产…     

产氢光合细菌的分离鉴定及高产氢菌株的筛选

利用特殊培养基从光照充裕、有机质含量高的污水沟、稻田淤泥中富集培养得到光合细菌优势菌种,采用梯度稀释法,通过双层固体平板进行分离和纯化,得到4株具有产氢性能的光合细菌菌株,按照<伯杰细菌鉴定手册>(第8版)关于光合细菌分类的方法进行生理生化特征鉴定,进行了16S rDNA的基因序列分析,并与NCBI上标准菌株基因序列进行比对,确定CQU-z、GLS-Z、CQK-Z、CJK-C的16S rDNA碱基长度分别为1 368 bp、1 453 bp、1 369 bp、1 432 bp,结果表明,这4株光合细菌菌株分别属于Rhodopseudomonas palustris和R.gelatinosa.同时通过光生物反应器进行产氢性能研究,表明光照条件为590 nm、6 000 lx时,菌种CQK-Z在连续62 h培养中总产氢量最高,为12.04mmol,相应的光化学效率和最大产氢速率分别为33.45%、1.84mmol L-1h-1.     

光合细菌PCR检测技术的建立与应用

针对光合细菌传统的菌种鉴定方法和MPN定量方法存在费时、费力和准确性筹的问题,本研究建立了光合细菌特异PCR鉴定技术和实时荧光PCR定量的检测技术.以微生物肥料产品常用的光合细菌沼泽红假单胞菌和类球红细菌作为研究对象,分别依据16S rDNA序列和gyrB序列设计出具有种水平特异性的引物,优化并确定了PCR反应条件,其灵敏度达到100 pg/μL,对6个光合细菌产品鉴定的符合率为100%,结果表明建立的PCR鉴定技术具有特异性、灵敏性和实用性.再根据16S rDNA的保守序列设计了常用光合细菌通用引物,用其对系列稀释的已知菌含量样品的DNA模板进行荧光定量PCR,制作标准曲线.对10个光合细菌样品进行荧光定量PCR法测定,根据与标准曲线比较得出样品中的光合细菌含量,其结果与MPN法的相关系数为0.98,两者具有良好的相天性,结果表明建立的荧光定量PCR法可用于光合细菌的定量检测,并具有高特异性和快速等优点.     

水源水生物预处理反应器微生物学特征

处理微污染水源水的生物陶粒反应器中，细菌的数量分布具有一定的区域化特征，上层生物陶粒的细菌数量较中、下层生物陶粒的细菌数量分别高１～２个数量级。从生物陶粒反应器中分离出７２株细菌，其中最多的是假单胞菌属，占４４．６％，其次为克雷伯氏菌属细菌，占２ｌ．６％。另外还分离到芽孢杆菌属、不动细菌属、黄单胞菌属和邻单胞菌金的细菌。除芽孢杆菌属外，其它各属细菌生反应器中的分布特征是上层多，下层少。     

厌氧膜生物反应器(AnMBR)膜污染过程及控制方法研究进展

厌氧膜生物反应器(Anaerobic membrane bioreactor,AnMBR)是一种将厌氧生物处理与膜分离技术相结合的新型处理技术,在提升出水水质的同时同步强化生物能回收.因此,AnMBR对于生物质废物处理和缓解能源危机具有重要意义.尽管目前在作用原理、操作优化和污染机制探索方面有了重大进展,但膜污染问题仍然是制约该技术进一步发展和应用的重要原因.本文介绍了厌氧膜生物反应器膜污染形成的基本机理与影响因素,并对膜污染控制技术进行了相关介绍,以期为AnMBR膜污染控制方面提供理论和技术参考.     

CO厌氧发酵制氢过程中的微生物特性及其影响因素

以发酵液中溶解的一氧化碳(CO)为底物,研究高温嗜热菌(Carboxydothermus hydrogenoformans)厌氧发酵制氢的工艺过程.通过C.hydrogenoformans菌的生长规律、絮凝能力和反应特性等实验研究,建立菌株的生长规律模型,得出微生物衰减系数和最大比生长速率.结果表明,C.hydrogenoformans菌产氢率高,絮凝效果好,用于连续CO生物发酵制氢工艺是可行的.对发酵制氢过程的影响因素进行考察,得出最佳食微比及CO对发酵制氢过程的抑制浓度等过程参数,为有效开发CO厌氧生物发酵制氢的工艺路线提供了参考依据.图4表2参17     

无色硫细菌氧化SRB还原硫酸盐产物硫化氢生成单质硫

以人工合成含硫化物废水作为进水 ,采用以陶粒为填料、小试规模的逆流式和顺流式好氧CSB(无色硫细菌 )生物膜反应器 ,在常温 ( 1 7℃～2 2℃ )、HRT为 2 6min、进水pH为 7.0和对反应器中pH不进行控制的条件下 ,研究了利用CSB将水中硫化物转化成单质硫的可行性及条件。实验表明 :为达到硫的最大回收率 ,在硫化物低负荷(NS <6 .1kg/ (m3 ·d) )时建议采用顺流式 ,高负荷 (NS>6 .1kg/ (m3 ·d) )时采用逆流式 ;反应器内的最佳DO值与进水硫化物容积负荷呈线性关系 ,出水pH值和出水pH值的升高值与硫的回收率呈线性关系。此外还研究了反冲洗对生物脱硫效果的影响及尾气中H2 S的生物去除     

The bridge between diversity and adaptivity: Answering McIntosh and Jeffrey

SUMMARY

The emerging concept of industrial ecology (IE) has been applied in practice in few case studies on local/regional industrial recycling networks. Analogously to a natural ecosystem, the aim is to develop material cycles and energy cascades between local cooperative actors. An optimal resource basis of an industrial ecosystem is the sustainable use of local renewable natural resources. In this paper, we consider the region of North Karelia in Finland, with 19 municipalities, and hence somewhat expand the system boundaries of an industrial ecosystem case study. The current situation and two scenarios of municipal heating energy production are presented. The heating system consists of individual, district and electric heating. The heat production and related greenhouse gas emissions are considered. The current fuel use is based on imported oil and regional fuels (peat, wood wastes). Also, shares for co-production of heat and electricity (CHP) are shown. In scenario one, we assume the majority of the fuel basis in oil and absence of CHP. Scenario two illustrates nearly complete dependence on regional wood wastes and firewood with the current share of CHP. The North Karelia region provides the IE theory with a fruitful case study because the supply of waste fuels and local renewables is vast and waste utilisation technologies (CHP, fluidized bed burning) constitute a significant part of energy production. Implications of the applied scenario approach are discussed in the context of regional decision making and, in particular, for its implementation with the concepts of a regional environmental management system (EMS) and a regional industrial ecosystem management system (RIEMS).     

降解氯氰菊酯光合细菌的分离鉴定及降解特性研究

从农药厂污水处理池的活性污泥中分离到一株高效氯氰菊酯农药降解菌,命名为PSB07-13。根据该菌体培养特征、菌落形态特征、活细胞光谱吸收特征、生理生化特性、光合作用内膜系统结构类型,并结合16S rRNA（Genebank Accession NO.EU366142）序列相似性分析,将其鉴定为沼泽红假单胞菌（Rhodopseudomonas palustris）。利用气相色谱对PSB07-13的降解能力进行了测定,结果表明：该菌培养6d后,对50mg·L-1的氯氰菊酯的降解率达到80.94%。降解特性研究结果表明：该菌在含氯氰菊酯培养基中的最适生长温度为30℃、pH为7.0及光照强度为7500lx;该菌不能以氯氰菊酯为唯一碳源和能源生长;该降解菌还能较好地降解甲氰菊酯、联苯菊酯、溴氰菊酯等菊酯类农药。该农药残留降解菌可以用于农药厂有机废水处理及农田农药残留降解,具有一定的应用前景。     

生物产氢技术研究进展

由于矿物资源的日益枯竭 ,寻找清洁的替代能源已成为一项迫切的课题 .氢被普遍认为是一种最有吸引力的替代能源 .这是因为氢是宇宙间最简单同时也是最为丰富的元素 ,它的热值高达 118.4ｋＪ/ｇ ,是甲烷的 2 .3倍 ;氢又是一种十分清洁的能源 ,它燃烧后只生成水 ;氢还能够比较容易地储存在一些特殊的金属间化合物或纳米非金属材料中 ,并能快速释放 ,这样 ,在运输和使用上比较方便 .氢除了作为优异的能源外 ,它还是一种工业上必不可少的原材料[1] .然而 ,氢气在地球表面的浓度小于 1ｍｇ/Ｌ ,仅占地球表面大气的极小部分 .在自然界中大部分的氢…     

Algal biomass valorization for biofuel production and carbon sequestration: a review

The world is experiencing an energy crisis and environmental issues due to the depletion of fossil fuels and the continuous increase in carbon dioxide concentrations. Microalgal biofuels are produced using sunlight, water, and simple salt minerals. Their high growth rate, photosynthesis, and carbon dioxide sequestration capacity make them one of the most important biorefinery platforms. Furthermore, microalgae's ability to alter their metabolism in response to environmental stresses to produce relatively high levels of high-value compounds makes them a promising alternative to fossil fuels. As a result, microalgae can significantly contribute to long-term solutions to critical global issues such as the energy crisis and climate change. The environmental benefits of algal biofuel have been demonstrated by significant reductions in carbon dioxide, nitrogen oxide, and sulfur oxide emissions. Microalgae-derived biomass has the potential to generate a wide range of commercially important high-value compounds, novel materials, and feedstock for a variety of industries, including cosmetics, food, and feed. This review evaluates the potential of using microalgal biomass to produce a variety of bioenergy carriers, including biodiesel from stored lipids, alcohols from reserved carbohydrate fermentation, and hydrogen, syngas, methane, biochar and bio-oils via anaerobic digestion, pyrolysis, and gasification. Furthermore, the potential use of microalgal biomass in carbon sequestration routes as an atmospheric carbon removal approach is being evaluated. The cost of algal biofuel production is primarily determined by culturing (77%), harvesting (12%), and lipid extraction (7.9%). As a result, the choice of microalgal species and cultivation mode (autotrophic, heterotrophic, and mixotrophic) are important factors in controlling biomass and bioenergy production, as well as fuel properties. The simultaneous production of microalgal biomass in agricultural, municipal, or industrial wastewater is a low-cost option that could significantly reduce economic and environmental costs while also providing a valuable remediation service. Microalgae have also been proposed as a viable candidate for carbon dioxide capture from the atmosphere or an industrial point source. Microalgae can sequester 1.3 kg of carbon dioxide to produce 1 kg of biomass. Using potent microalgal strains in efficient design bioreactors for carbon dioxide sequestration is thus a challenge. Microalgae can theoretically use up to 9% of light energy to capture and convert 513 tons of carbon dioxide into 280 tons of dry biomass per hectare per year in open and closed cultures. Using an integrated microalgal bio-refinery to recover high-value-added products could reduce waste and create efficient biomass processing into bioenergy. To design an efficient atmospheric carbon removal system, algal biomass cultivation should be coupled with thermochemical technologies, such as pyrolysis.

     

Quantification of energy related industrial eco-efficiency of China

Improving eco-efficiency is propitious for saving resources and reducing emissions, and has become a popular route to sustainable development. We define two energy-related eco-efficiencies: energy efficiency (ENE) and greenhouse gas (GHG) emission-related eco-efficiency (GEE) using energy consumption and the associated GHG emissions as the environmental impacts. Using statistical data, we analyze China??s energy consumption and GHG emissions by industrial subsystem and sector, and estimate the ENE and GEE values for China in 2007 as 4.871×10⁷ US$/PJ and 4.26×10⁸ US$/TgCO₂eq, respectively. Industry is the primary contributing subsystem of China??s economy, contributing 45.2% to the total economic production, using 79.6% of the energy consumed, and generating 91.4% of the total GHG emissions. We distinguish the individual contributions of the 39 industrial sectors to the national economy, overall energy consumption, and GHG emissions, and estimate their energyrelated eco-efficiencies. The results show that although ferrous metal production contributes only 3.5% to the national industrial economy, it consumes the most industrial energy (20% of total), contributes 16% to the total industrial global warming potential (GWP), and ranks third in GHG emissions. The power and heat sector ranks first in GHG emissions and contributes one-third of the total industrial GWP, although it only consumes about 8% of total industrial energy and, like ferrous metal production, contributes 3.5% to the national economy. The ENE of the ferrous metal and power and heat sectors are only 8 and 2.1×10⁷ US$/PJ, while the GEE for these two sectors are 9 and 4×10⁴ US$/GgCO₂eq, respectively; these are nearly the lowest ENE and GEE values among all 39 industry sectors. Finally, we discuss the possibility of ecoefficiency improvement through a comparison with other countries.     

区域环评中能源及资源合理利用类比分析

在区域开发项目中合理地利用资源是反映区域内经济布局,产业结构及生产工艺先进与清洁的一个方面,其合理性分析是区域环境评价与环境规划中必不可少的一部分。本文列举了天津市近年来完成的有代表性的区域环境规划与环境评价项目中有关内容的类比分析方法。     

城市生活垃圾有机组分厌氧发酵产氢和甲烷

为了提高能源回收效率,采用大米、土豆、生菜、瘦肉、花生油和榕树叶作为实验原料,模拟有机垃圾中普遍存在的淀粉、膳食纤维、蛋白质、脂肪和木质纤维类成分,进行厌氧发酵产氢以及对其剩余物厌氧发酵产甲烷.结果表明.在厌氧发酵产氢阶段,整个过程没有甲烷生成,大米、土豆、生菜、瘦肉、花生油和榕树叶的氢气产率分别为125、103、35、0、5和0 mL g-1(VS),能源回收效率分别为7.9%、6.8%、1.9%、0、0.1%和0.大米、土豆和生菜的氢气浓度分别为34%～59%、41%～56%和37%～70%,整个产氢阶段没有甲烷生成.在厌氧发酵产甲烷阶段,上述原料的甲烷产率分别为232、237、148、278、866和50 mL g-1(VS),生物气中甲烷含量分别为42%～70%、57%～71%、73%～77%、59%～73%、68%～80%和54%～74%.厌氧发酵联产氢气和甲烷整个过程上述原料的能源回收效率分别为56.3%、58.4%、28.8%、39.2%、81.2%和8.8%,总COD去除率分别为72.30%、81.70%、32.63%、47.59%、97.46%和11.29%.图4表5参35     

Sorption-enhanced chemical looping oxidative steam reforming of methanol for on-board hydrogen supply

Hydrogen is an indispensable energy carrier for the sustainable development of human society. Nevertheless, its storage, transportation, and in situ generation still face significant challenges. Methanol can be used as an intermediate carrier for hydrogen supplies, providing hydrogen energy through instant methanol conversion. In this study, a sorption-enhanced, chemical-looping, oxidative steam methanol-reforming (SECL-OSRM) process is proposed using CuO–MgO for the on-board hydrogen supply, which could be a promising method for safe and efficient hydrogen production. Aspen Plus software was used for feasibility verification and parameter optimization of the SECL-OSRM process. The effects of CuO/CH3OH, MgO/CH3OH, and H2O/CH3OH mole ratios and of temperature on H2 production rate, H utilization efficiency, CH3OH conversion, CO concentration, and system heat balance are discussed thoroughly. The results indicate that the system can be operated in auto-thermal conditions with high-purity hydrogen (99.50 vol％) and ultra-low-concentration CO (<50 ppm) generation, which confirms the pos-sibility of integrating low-temperature proton-exchange membrane fuel cells (LT-PEFMCs) with the SECL-OSRM process. The simulation results indicate that the CO can be modulated in a lower concentration by reducing the temperature and by improving the H2O/CH3OH and MgO/CH3OH mole ratios.     

光合细菌PSB07-15对辣椒及土壤中甲氰菊酯残留的生物修复

利用光合细菌菌株PSB07-15对辣椒促生作用及对植株与土壤中甲氰菊酯残留的生物修复进行了研究,为光合细菌生物修复菊酯类农药残留的实际应用提供科学依据。结果表明：菌株PSB07-15菌液用ddH2O稀释100倍液、200倍液浸种处理后能够显著提高辣椒种子发芽率;田间小区试验结果表明,菌株PSB07-15施用1 875、3 750、7 500 mL.hm-2,辣椒鲜质量分别增加15.12%、21.68%、14.79%;菌株PSB07-15能够有效降解辣椒和土壤中甲氰菊酯残留（辣椒中大于47.20%,土壤中大于50.73%）。