木质纤维生产燃料乙醇工艺的研究进展

利用丰富而廉价的木质纤维原料代替粮食生产燃料乙醇,对经济和社会的可持续发展有着重要的意义。以木质纤维为原料发酵生产燃料乙醇可分为4种工艺:分步糖水解化发酵法、同步糖化发酵法、同步糖化共发酵法和直接微生物转化法。介绍了以上4种工艺的研究进展,并对今后进一步研究提出了建议。     

Characteristics of Lignin Extracted from Different Lignocellulosic Materials via Organosolv Fractionation

Among biomass-derived compounds, lignin is an underused component with potential for conversion to industrial-needed products in biorefinery. In this study, organosolv fractionation of four lignocellulosic materials including bagasse (BG), pararubber wood sawdust (PS), palm fiber (PF), and cassava fiber (CF) was studied using a ternary solvent mixture comprising methyl isobutyl ketone (MIBK), ethanol, and water in the presence of H₂SO₄ to separate high-purity lignin. The fractionation reaction was performed at 160 °C for 40 min with MIBK/ethanol/water proportion of 0.25/0.42/0.33 and 0.025 M of H₂SO₄, which led to the highest lignin removal efficiency of 88.2, 70.6, 67.3, and 71.7% (w/w) from BG, PS, PF, and CF, respectively. Physicochemical characteristics of the fractionated lignin were determined for Klason lignin and by X-ray fluorescence spectroscopy, organic elemental analysis, ¹H nuclear magnetic resonance spectroscopy, and Fourier transform infrared spectroscopy. The lignin samples were thermally depolymerized in MIBK to determine the content of specific lignin-derived chemicals. The main phenolic derivatives from BG-lignin were 4-ethylphenol and 4-vinylguaiacol, whereas those from PS-lignin were syringaldehyde and cis-isoeugenol. Phenol and bis(2-ethylhexyl) phthalate were mainly produced from depolymerization of PF-lignin while trans-isoeugenol and hexadecanoic acid were the major products from CF-lignin. This work demonstrates the potential of the fractionated lignin for production of valuable chemicals in biorefineries.     

木质纤维素稀酸水解糖液乙醇发酵研究进展

以木质纤维素为原料生产燃料乙醇,首先要对原料进行预处理得到可发酵糖,在稀酸水解木质纤维素得到的糖液中,除含有葡萄糖、木糖等六碳糖和五碳糖外,根据水解温度、酸浓度和时间的不同,还含有不同浓度的发酵抑制剂。因此,在研究木质纤维素稀酸水解糖液的乙醇发酵中,对代谢木糖成乙醇的菌种的研究、对耐/代谢发酵抑制剂微生物的研究、对稀酸水解糖液的脱毒方法的研究以及对稀酸水解糖液不同发酵方式的乙醇发酵研究等非常重要。重点介绍了以上几个方面近几年研究的进展。     

Routes to Potential Bioproducts from Lignocellulosic Biomass Lignin and Hemicelluloses

An essential feature of proposed fermentation-based lignocellulose to biofuel conversion processes will be the co-production of higher value chemicals from lignin and hemicellulose components. Over the years, many routes for chemical conversion of lignin and hemicelluloses have been developed by the pulp and paper industry and we propose that some of these can be applied for bioproducts manufacturing. For lignin products, thermochemical, chemical pulping, and bleaching methods for production of polymeric and monomeric chemicals are reviewed. We conclude that peroxyacid chemistry for phenol and ring-opened products looks most interesting. For hemicellulose products, preextraction of hemicelluloses from woody biomass is important and influences the mixture of solubilized material obtained. Furfural, xylitol, acetic acid, and lactic acid are possible targets for commercialization, and the latter can be further converted to acrylic acid. Pre-extraction of hemicelluloses can be integrated into most biomass-to-biofuel conversion processes.     

C_4 Plants as Biofuel Feedstocks: Optimising Biomass Production and Feedstock Quality from a Lignocellulosic Perspective

The main feedstocks for bioethanol are sugarcane (Saccharum officinarum) and maize (Zea mays),both of which are C4 grasses,highly efficient at converting solar energy into chemical energy,and both are food crops.As the systems for lignocellulosic bioethanol production become more efficient and cost effective,plant biomass from any source may be used as a feedstock for bioethanol production.Thus,a move away from using food plants to make fuel is possible,and sources of biomass such as wood from forestry and ...     

Technical and Economic Modeling for the Production of Torrefied Lignocellulosic Biomass for the U.S. Densified Fuel Industry

During recent years, a renovated interest in the pre-treatment of biomass through torrefaction has led to several proposals on industrial-scale application of the technology. Torrefaction holds promising characteristics for obtaining a high-energy yield biomass for further processing, including densified biofuels such as pellets and briquettes, at low overall costs, low energy input, and high capacity and availability for the near future, having the capability of displacing coal in power facilities. Despite many efforts in developing the technology at an industrial scale, very few manufacturers and companies are offering torrefied machinery and lignocellulosic torrefied biomass. Furthermore, information about the actual profitability of the business, sensitivity, and costs of torrefied biomass are very scarce and are limited to very focused studies in some areas of the production, but not in the overall supply chain, and manufacturing processes. This study aimed to develop and validate a technical and economic model for the production of lignocellulosic torrefied biomass for its utilization in the solid biofuels industry, with a focus on production and delivered costs for U.S. potential manufacturers. This model also includes analysis of important variables affecting production, such as biomass delivered costs, capital expenditure (CAPEX), and technology availability. Results indicate that the production of torrefied lignocellulosic biomass can be profitable for U.S. manufacturers, subject to a high sensitivity on biomass cost, CAPEX, and technology affordability for large-scale production. Other sensitive facts include carbon credits scenarios, which may influence profitability based on analyses of net present value and internal rate of return for the manufacturing facility.     

微生物利用木质纤维素的研究进展

木质纤维素原料是世界上最为丰富的资源之一,可用作微生物发酵生产高附加值生物化学品的原料。与传统用于微生物发酵的可食用生物质原料相比,目前微生物利用木质纤维素还存在以下几个关键问题:开发经济有效的木质纤维素预处理工艺、提高微生物对木质纤维素水解液中第二大单糖木糖的有效利用水平、增强微生物对木质纤维素水解液中混糖的综合利用能力以及提高微生物对木质纤维素水解液中糠醛、乙酸等发酵抑制物的耐受能力。综述了近年来国内外针对这几个关键问题的最新研究成果。为今后微生物大规模利用木质纤维素进行商业生产提出了展望和建议。     

Consolidated Bioprocessing of Lignocellulosic Feedstocks for Ethanol Fuel Production

Ethanol fuel can be produced renewably from numerous plant and waste materials, but harnessing the energy of lignocellulosic feedstocks has been particularly challenging in the development of this alternative fuel as a substitute for petroleum-based fuels. Consolidated bioprocessing has the potential to make the conversion of biomass to fuel an economical process by combining enzyme production, polysaccharide hydrolysis, and sugar fermentation into a single unit operation. This consolidation of steps takes advantage of the synergistic nature of enzyme systems but requires the use of one or a few organisms capable of producing highly efficient cellulolytic enzymes and fermenting most of the resulting sugars to ethanol with minimal byproduct formation while tolerating high levels of ethanol. In this review, conventional ethanol production, consolidated bioprocessing, and simultaneous saccharification and fermentation are described and compared. Several wild-type and genetically engineered microorganisms, including strains of Clostridium thermocellum, Saccharomyces cerevisiae, Klebsiella oxytoca, Escherichia coli, Flammulina velutipes, and Zymomonas mobilis, among others, are highlighted for their potential in consolidated bioprocessing. This review examines the favorable and undesirable qualities of these microorganisms and their enzyme systems, process engineering considerations for particular organisms, characteristics of cellulosomes, enzyme engineering strategies, progress in commercial development, and the impact of these topics on current and future research.     

筛选微生物降解木质纤维素的研究进展

木质纤维素资源是自然界中含量丰富的可再生资源,利用微生物降解木质纤维素是一种重要的策略。在综合国内外对木质纤维素降解微生物的筛选方法和研究策略的基础上,从单一菌株、复合微生物菌系和组学技术三个方面对筛选微生物降解木质纤维素进行了总结和分析,阐述了各个策略的优势特点和应用价值,即单一菌株易于培养但降解能力较低,复合菌系降解能力强但传代稳定性较差,组学技术能够更好的解释微生物降解木质纤维素的机理,为筛选木质纤维素降解微生物提供一定的指导。同时提出使用合成生物学的策略进行相应微生物的筛选,旨在为筛选高效降解木质纤维素的微生物提供一定的参考。     

Thermodynamics of Energy Production from Biomass

With high quality petroleum running out in the next 50 years, the world governments and petrochemical industry alike are looking at biomass as a substitute refinery feedstock for liquid fuels and other bulk chemicals. New large plantations are being established in many countries, mostly in the tropics, but also in China, North America, Northern Europe, and in Russia. These industrial plantations will impact the global carbon, nitrogen, phosphorus, and water cycles in complex ways. The purpose of this paper is to use thermodynamics to quantify a few of the many global problems created by industrial forestry and agriculture. It is assumed that a typical tree biomass-for-energy plantation is combined with an efficient local pelleting facility to produce wood pellets for overseas export. The highest biomass-to-energy conversion efficiency is afforded by an efficient electrical power plant, followed by a combination of the FISCHER-TROPSCH diesel fuel burned in a 35%-efficient car, plus electricity. Wood pellet conversion to ethanol fuel is always the worst option. It is then shown that neither a prolific acacia stand in Indonesia nor an adjacent eucalypt stand is “sustainable.” The acacia stand can be made “sustainable” in a limited sense if the cumulative free energy consumption in wood drying and chipping is cut by a factor of two by increased reliance on sun-drying of raw wood. The average industrial sugarcane-for-ethanol plantation in Brazil could be “sustainable” if the cane ethanol powered a 60%-efficient fuel cell that, we show, does not exist. With some differences (ethanol distillation vs. pellet production), this sugarcane plantation performs very similarly to the acacia plantation, and is unsustainable in conjunction with efficient internal combustion engines.     

根霉菌利用木质纤维素发酵生产有机酸的研究进展*

木质纤维素是世界上储量最丰富、最廉价的可再生生物质资源,利用木质纤维素发酵生产有机酸具有重大的经济效益及社会效益。为发掘影响木质纤维素利用的关键因素,对根霉菌的木糖代谢途径以及利用木质纤维素发酵生产乳酸、富马酸等重要有机酸的生产方式、发酵策略等进行了阐述,指出针对木糖的转化率是制约木质纤维素高效利用的瓶颈。     

基因组改组及其在木质纤维素水解液乙醇发酵菌种选育中的应用展望

能高效代谢木质纤维素水解液中的可发酵糖、同时可耐受/分解发酵抑制剂的菌种, 是利用木质纤维素为原料生产燃料乙醇技术的关键。基因组改组技术是近些年发展起来的一项新型育种技术, 该技术已运用于食品和医药行业菌种的改良。本文综述了基因组改组技术的原理、方法、特点、及其运用, 并对其在木质纤维素水解液乙醇发酵菌种选育方面的应用进行了展望。     

Sustainable Cultivation Concepts for Domestic Energy Production from Biomass

Referee: Dr. J. Grant McLeod, Semiarid Prairie Agricultural Research Centre, Research Branch, Agriculture and Agri-Food Canada, P.O. Box 1030 Swift Current, Saskatchewan S9H 3X2, Canada According to the European Union, biomass will play a major role in the substitution of fossil fuels with renewable resources. Biomass will contribute 83% to the increased use of renewable resources by the year 2010. In contrast to other solar energy sources, plant biomass is always available and can be converted into energy continuously. An important objective in the production of energy crops on arable farm land should be to realize a high net energy yield and fulfill obligations in the field of environmental protection. The “double cropping system” was developed to meet these obligations. Silaging as a conservation method for wet biomass makes this sustainable cultivation system possible. It includes a diverse array of crops and provides the opportunity to integrate rural organic wastes into this energy concept. The model presented, “the energy self supplying farm”, shows that it is possible to meet the energy consumption requirements of a livestock farming operation with energy crop production on 10 to 18% of the arable farm land. According to a new rape energy concept, a land resource requirement of roughly 10% is feasible if biomass residues from rape oil production for liquid fuels are also utilized for energy production. For a farm with livestock, anaerobic digestion technology is an appropriate technique to deliver heat and electricity for the farmstead. Digestion residues, used as fertilizer in energy crop production, results in an almost complete nutrient recycling. Energy output can be increased above the demand of the farm via the biogas reactor, using the total biomass produced with double cropping. Surplus electricity is supplied to the grid at a guaranteed price. Biomass is a domestic energy resource, and farmers have the chance to extend their function from a supplier of raw material to managers of domestic energy resources. Under the currently established framework, monetary return per hectare could be more than double with biomass energy production via biogas. This will allow the agricultural economy to recover and promote a sustainable regional development. In addition to being a convenient method of waste management, sustainable energy crop production can make a significant contribution to environmental protection and the improvement of the social and economic cohesion within a community.     

解脂耶氏酵母基于木质纤维素原料生产化学品研究进展*

解脂耶氏酵母具有遗传背景清晰、分子操作体系较为成熟、抗逆性强、底物谱广、有机酸和蛋白质分泌能力强等优点,在微生物发酵生产化学品领域极具应用潜力。木质纤维素是丰富的可再生生物质资源,以木质纤维素原料替代化石原料生产化学品对于缓解全球能源危机、保障粮食安全等意义重大。解脂耶氏酵母可以天然代谢木质纤维素水解产生的葡萄糖,但对其他水解产物(如木糖)的利用效率极低。综述解脂耶氏酵母利用木质纤维素原料的代谢途径及改造策略,以木质纤维素原料生产化学品为例,重点讨论该过程中的主要瓶颈问题及解决办法,为后续研究提供参考。     

System Development for Linked-Fermentation Production of Solvents from Algal Biomass

Five species of the genus Dunaliella (D. tertiolecta, D. primolecta, D. parva, D. bardawil, and D. salina) were examined for glycerol accumulation, growth rate, cell density, and protein and chlorophyll content. The suitability of each algal species for use as a fermentation substrate was judged according to glycerol accumulation and quantities of neutral solvents produced after sequential bacterial fermentations. When grown in 2 M NaCl, with 24 mM NaHCO₃ or 3% CO₂ at 28°C and with 10,000 to 15,000 lx of incident light on two sides of a glass aquarium, four of the five species tested produced ca. 10 to 20 mg of glycerol per liter of culture. Clostridium pasteurianum was found to convert an algal biomass mixture supplemented with 4% glycerol to ca. 16 g of mixed solvents (n-butanol, 1,3-propanediol, and ethanol) per liter. Acetone was not detected. Additionally, it has been demonstrated that Dunaliella concentrates of up to 300-fold can be directly fermented to an identical pattern of mixed solvents. Overall solvent yields were reduced by >50% when fermentations were performed in the presence of 2% NaCl. These results are discussed in terms of practical application in tropical coastal zones.     

Ethanol and High-Value Terpene Co-Production from Lignocellulosic Biomass of Cymbopogon flexuosus and Cymbopogon martinii

Cymbopogon flexuosus, lemongrass, and C. martinii, palmarosa, are perennial grasses grown to produce essential oils for the fragrance industry. The objectives of this study were (1) to evaluate biomass and oil yields as a function of nitrogen and sulfur fertilization, and (2) to characterize their utility for lignocellulosic ethanol compared to Panicum virgatum (switchgrass). Mean biomass yields were 12.83 Mg lemongrass ha^-1 and 15.11 Mg palmarosa ha^-1 during the second harvest year resulting in theoretical biofuel yields of 2541 and 2569 L ethanol ha^-1 respectively compared to reported 1749–3691 L ethanol ha^-1 for switchgrass. Pretreated lemongrass yielded 198 mL ethanol (g biomass)^-1 and pretreated palmarosa yielded 170 mL ethanol (g biomass)^-1. Additionally, lemongrass yielded 85.7 kg essential oil ha^-1 and palmarosa yielded 67.0 kg ha^-1 with an estimated value of USD $857 and $1005 ha^-1. These data suggest that dual-use crops such as lemongrass and palmarosa may increase the economic viability of lignocellulosic biofuels.     

利用废弃物原料生产燃料乙醇的研究进展

乙醇是一种十分重要的工业用途的化工原料。目前国内外学者纷纷采用不同的方法和手段对乙醇发酵进行研究,目前,利用废弃物为原料生产乙醇是热点。本文阐述了利用各种废弃原料生产乙醇的必要性,并分别论述了利用纤维质废弃物、淀粉质废弃物、糖质废弃物等生产乙醇的研究进展,着重论述了利用纤维质废弃物的生产情况,提出了需进一步研究和解决的问题。     

Validation of PyMBMS as a High-throughput Screen for Lignin Abundance in Lignocellulosic Biomass of Grasses

Pyrolysis molecular-beam mass spectrometry (PyMBMS) was tested as a high-throughput method for relative abundances of guaiacyl and syringyl lignin in lignocellulosic cell-wall materials from stems of a population of maize intermated B73?×?Mo17 (IBM) recombinant inbred lines. Variations of up to twofold across the population in phenylpropanoid abundance were observed. Several histochemical and quantitative biochemical assays were used to validate the mass spectrometric data for lignin, hydroxycinnamic acids, crystalline cellulose, non-cellulosic glucans, and xylans. We demonstrate PyMBMS to be a valid high-throughput screen suitable for analysis of lignin abundance in large populations of bioenergy grasses. Pentose from xylans and hexose from cellulosic and non-cellulosic glucans also varied substantially across the population, but abundances of diagnostic fragments for these monosaccharides were not well correlated with the abundance of cell-wall polysaccharides.     

Fed-batch Cultivation of Mucor indicus in Dilute-acid Lignocellulosic Hydrolyzate for Ethanol Production

Mucor indicus fermented dilute-acid lignocellulosic hydrolyzates to ethanol in fed-batch cultivation with complete hexose utilization and partial uptake of xylose. The fungus was tolerant to the inhibitors present in the hydrolyzates. It grew in media containing furfural (1 g/l), hydroxymethylfurfural (1 g/l), vanillin (1 g/l), or acetic acid (7 g/l), but did not germinate directly in the hydrolyzate. However, with fed-batch methodology, after initial growth of M. indicus in 500 ml enzymatic wheat hydrolyzate, lignocellulosic hydrolyzate was fermented with feeding rates 55 and 100 ml/h. The fungus consumed more than 46% of the initial xylose, while less than half of this xylose was excreted in the form of xylitol. The ethanol yield was 0.43 g/g total consumed sugar, and reached the maximum concentration of 19.6 g ethanol/l at the end of feeding phase. Filamentous growth, which is regarded as the main obstacle to large-scale cultivation of M. indicus, was avoided in the fed-batch experiments.