生物质快速热解制备液体燃料

本文回顾了生物质快速热解液化技术的国内外研究现状,重点叙述了初级生物油的化学组成和燃料性质,指出生物油是一种复杂的含氧有机混合物,具有水分含量高、氧含量高、热值低、酸含量高、安定性差和化石燃油不互溶等独特的性质;针对这些性质,介绍了几种常用的生物油精制提炼方法,包括催化裂解、催化加氢、高温热解气过滤、添加助剂、催化酯化、柴油乳化以及制备富氢合成气与费托合成,并分析了各种精制技术发展的关键问题。     

生物质快速热解制备液体燃料

本文回顾了生物质快速热解液化技术的国内外研究现状,重点叙述了初级生物油的化学组成和燃料性质,指出生物油是一种复杂的含氧有机混合物,具有水分含量高、氧含量高、热值低、酸含量高、安定性差和化石燃油不互溶等独特的性质;针对这些性质,介绍了几种常用的生物油精制提炼方法,包括催化裂解、催化加氢、高温热解气过滤、添加助剂、催化酯化、柴油乳化以及制备富氢合成气与费托合成,并分析了各种精制技术发展的关键问题.     

生物油酸性组分分离精制研究

生物油因水分含量高和呈酸性未能作为高品位能源直接规模化应用。利用分子蒸馏技术将生物油水分与酸性组分作为整体对象进行分离,既得到生物油酸性组分富集馏分,又获得了水分含量低、酸性较弱与热值较高的精制生物油Ⅰ（蒸馏重质馏分）与精制生物油Ⅱ（常温冷凝馏分）。同时,具体考察了精制前后生物油的pH值、热值和水分等参数的变化规律。研究表明,生物油的水分与酸性组分得到有效分离,精制生物油Ⅰ和Ⅱ的低级羧酸含量从原始生物油的18.85%分别降低至0.96%和2.2%     

MCM-41和HZSM-5协同催化对油菜秸秆热解的影响

以油菜秸秆为原料,采用两种方案分层布置催化剂(HZSM-5/MCM-41和MCM-41/HZSM-5),并与MCM-41和HZSM-5单独催化进行对比,从生物油品质和催化剂耐久性两个角度探究协同催化作用机理;对精制生物油有机相进行理化特性分析,采用FT-IR和GC-MS进行成分分析,对催化剂进行耐久性分析。结果表明,与单独催化相比,协同催化所得精制生物油液相产率略有降低,气相产率升高,精制生物油有机相理化特性进一步提高,其中,MCM-41/HZSM-5协同催化所得精制生物油有机相热值较高,为34.31 MJ/kg;精制生物油有机相中含有多种芳香族类物质和少量的羰基类物质,协同催化较单独催化能产生较多的烃类物质及较少的含氧芳香族类物质,其中,MCM-41/HZSM-5协同催化所得精制生物油有机相中烃类物质含量较高,且以单环芳香烃为主;HZSM-5分子筛在300-800℃有两个失重峰,MCM-41分子筛在300-800℃仅有一个失重峰,表明MCM-41催化剂上沉积的焦炭成分单一,较易去除,且协同催化后分子筛表面沉积的焦炭总含量较少。     

精制废木屑热解油/柴油新型混合燃料制备实验研究

为提高废木屑热解油品质,使其能够作为发动机燃料使用,提出了一条新的热解油提质路线。首先将热解原油进行基于组分分离的乙醚萃取和化学催化相结合的精制过程,得到精制热解油;其次,利用超声反应器制备了精制热解油/柴油新型混合燃料,以单位体积柴油所溶解的精制油的体积定为S值,作为判断乳化效果的准则,考察了不同的影响因素对S值的影响。研究结果表明,乳化剂添加量对S值影响较大,在V_{精制生物油}:V_柴油:V_乳化剂=10:30:5条件下,存在最佳的乳化超声操作条件:超声时间、超声电功率、乳化温度分别为20 min、540 W、50℃。制备了不同S值的乳化燃料,通过对燃料物理指标的分析发现,该燃料性质稳定、燃烧性能优良,有望成为柴油的替代产品。     

生物质热化学转化制备生物燃料及化学品

生物质是环境友好的可再生能源。近年来相关研究不断升温,文献报道量激增。本文在现有文献综述及近期报道的基础上,从利用热化学方法由生物质获得燃料油及化学品的角度对各方案进行了归纳、适当补充及简要述评,重点介绍了生物油催化裂解精制、水相重整制备烷烃、超临界水/水热制备化学品3个领域。     

生物质热化学转化制备生物燃料及化学品

生物质是环境友好的可再生能源.近年来相关研究不断升温,文献报道量激增.本文在现有文献综述及近期报道的基础上,从利用热化学方法由生物质获得燃料油及化学品的角度对各方案进行了归纳、适当补充及简要述评,重点介绍了生物油催化裂解精制、水相重整制备烷烃、超临界水/水热制备化学品3个领域.     

生物质热解油品位催化提升的思考和初步进展

生物质热解油是一种由几百种含氧有机物组成的混合物,需经过提质才能直接用作车用燃料.多数研究者以降低生物油的含氧量作为提质的目标,作者提出了一个完全不同的思路,以转化得到的稳定而易燃的含氧有机物为生物油提质的目标.实验表明,催化提质后生物粗油中不稳定的、腐蚀性的组分(如醛、酸、酚类等物质)大为减少,而相对稳定的、腐蚀性较低的组分(如酯、醇、酮类等物质)明显增加.本文小结了作者所在的研究团队在生物质热解油品位提升方面的近期研究进展.     

介孔分子筛反应精馏催化改性生物质裂解油

采用反应精馏的方法,以含锆介孔分子筛(S042-/Zr-MCM-41)为酸性催化剂,对生物质热解油进行了催化改性.通过XRD、N2吸附脱附及FT-IR表征了介孔分子筛的孔结构和表面基团.对生物油改性的较佳反应条件进行了考察,较佳的催化剂用量为生物油质量的4%,生物油、乙醇及过氧化氢水溶液(30%)的质量比为1:0.5:0.4,回流比1:6.在上述条件下,轻油收率21.4%(以生物油计).改性所得两种改性油与原料油相比,含水量由33%分别降至0.5%和5.0%,黏度由18.5 mm2/s分别降至0.46 mm2/s和3.65 mm2/s(30℃),pH值由2.82分别提升至7.06和5.35,热值由14.3 MJ/kg分别提升至21.5 MJ/kg和24.5 MJ/kg.经过GPC、Fr-IR和1H NMR分析,轻油主要成分是原料油中的轻组分所转化的酯类化合物,重油主要是原料油中难挥发的成分.     

生物质热解产物中焦油的催化裂解

对生物质热解产物（粗煤气）中焦油的催化裂解过程进行了实验研究。实验装置主体由一个常压鼓泡床热解反应器和一个固定床催化裂解反应器组合而成,生物质原料为玉米杆屑,催化剂分别选用煅烧石灰石和煅烧白云石,实验结果表明,当催化裂解反应器内温度在800－850℃之间时,两种催化剂对粗煤气中焦油的催化裂解效果均非常明显,焦油裂解率均可达到90％以上,虽然煅烧石灰石的催化活性比煅烧白云石高,其失活速率也相对大一些。     

Catalytic Vapor Cracking for Improvement of Bio-Oil Quality

Bio-oil has attracted considerable interest as a promising renewable energy resource because it can be utilized as a feedstock in integrated bio-refineries for the production of highly valuable chemicals and next-generation hydrocarbon fuels. However, it is necessary to improve the bio-oil quality before it can be fed to bio-refineries. Currently, catalytic vapor cracking seems a more attractive process than catalytic upgrading technologies, such as hydrotreating and esterification, in order to improve the bio-oil quality. This review presents a summary of recent research and the state of art technology for the catalytic vapor cracking of bio-oil, focusing on the catalysts applied, upgrading methods and reaction mechanisms.     

固体酸改质生物油的研究

利用乙酸和乙醇生成乙酸乙酯的酯化反应为模型反应，筛选得到催化活性最好的固体酸催化剂40％SiO2/TiO2SO42－。 在一定的反应条件下，添加固体酸催化剂和溶剂，生物油的品质得到提高，热值提高了50.7％，运动黏度降低到原来的10％，密度降低了22.6％。生物油改质前后的GC MS分析表明，固体酸可以将生物油中含有的有机羧酸转化为酯类，如甲酸酯、乙酸酯等，使生物油中的羧酸组分发生了催化酯化反应，改善了生物油的品质，生物油物理化学性能得到明显的提高。3A分子筛对生物油的脱水作用不显著，对酸性、密度、黏度等方面影响较小。     

HZSM-5上生物质催化裂解的近期研究进展

概述了近期的HZSM-5对生物质和生物油催化裂解的研究进展,重点介绍了催化剂的应用、生物油提质的方法和反应机理.     

Valorisation of bio-oil resulting from fast pyrolysis of wood

Bio-oil resulting from the pyrolysis of lignocellulose is a complex mixture of polar low molecular mass oxygenated compounds of various functionalities and non-polar high molecular mass lignin derivatives. Several approaches to the upgrading of bio-oil are currently in progress. This study investigates the valorisation of crude bio-oil using physical and chemical methods. The effects of methanol addition on some properties of the bio-oil are investigated. Stable bio-oil/diesel oil emulsions are produced by the addition of surfactants with a hydrophilic-lipophilic balance value of 5–6. An alternative approach towards the upgrading of bio-oil is the hydrotreatment of the water-soluble fraction of bio-oil. Two-stage hydroprocessing with noble-metal catalysts Ru/C and Pt/C increases the intrinsic hydrogen content of the water-soluble fraction. The results show that the thermally unstable components including sugars, ketones and aldehydes are readily converted to diols and alcohols at pressures of 5 MPa. These observations can be explained by a set of reaction pathways for the compounds identified.     

Effective hydrodeoxygenation bio-oil via natural zeolite supported transition metal oxide catalyst

Bio-oil from biomass pyrolysis is promising to be used as a sustainable biofuel and high-value-added chemical. However, the presence of high acid, water, and oxygenate causes corrosive properties, low higher heating value (HHV), and instability of the bio-oil component. Therefore, refining the bio-oil is essential to improve its quality. In this study, we introduced natural zeolite (HZ) impregnated with transition metal oxide (TMO) to refine the bio-oil using the hydrodeoxygenation method (HDO) at various catalyst ratios and temperatures. We find that ZnO/HZ 5% wt. shows the best catalytic performance, with the conversion of organic phase reaching ～ 50%. The refined bio-oil from Fe₂O₃, ZnO, and CuO has high-quality physicochemical properties with carbon, oxygen, water level, and HHV values are 37–52%, 40–53%, 8–27%, and 17–21 MJ/kg, respectively. This result represents a high catalytic performance for the hydrodeoxygenation process of bio-oil using natural zeolite-based transition metal oxide for better and low-cost biofuel production.     

生物质热解油气化试验研究

生物质是一种环境友好可再生资源，可以通过多种途径转化为液体燃料。生物质热解液化即是在缺氧状态下对生物质进行快速加热，然后再对热解产物进行快速冷凝，最后获得一种称为生物油的液体燃料的技术。该技术以及生物油的特点主要有：热解液化温度为500℃，远低于生物质热解气化所     

Effect of Acid, Steam Explosion, and Size Reduction Pretreatments on Bio-oil Production from Sweetgum, Switchgrass, and Corn Stover

Bio-oil produced from biomass by fast pyrolysis has the potential to be a valuable substitute for fossil fuels. In a recent work on pinewood, we found that pretreatment alters the structure and chemical composition of biomass, which influence fast pyrolysis. In this study, we evaluated dilute acid, steam explosion, and size reduction pretreatments on sweetgum, switchgrass, and corn stover feedstocks. Bio-oils were produced from untreated and pretreated feedstocks in an auger reactor at 450?°C. The bio-oil??s physical properties of pH, water content, acid value, density, and viscosity were measured. The chemical characteristics of the bio-oils were determined by gas chromatography?Cmass spectrometry. The results showed that bio-oil yield and composition were influenced by the pretreatment method and feedstock type. Bio-oil yields of 52, 33, and 35?wt% were obtained from medium-sized (0.68?C1.532?mm) untreated sweetgum, switchgrass, and corn stover, respectively, which were higher than the yields from other sizes. Bio-oil yields of 56, 46, and 51?wt% were obtained from 1?% H₂SO₄-treated medium-sized sweetgum, switchgrass, and corn stover, respectively, which were higher than the yields from untreated and steam explosion treatments.     

微波条件下固体酸催化剂催化酯化生物油的研究

以乙醇和乙酸的酯化作为反应模型,考察固体酸催化剂阳离子交换树脂、SO₄²-/ZrO₂和分子筛在微波加热条件下的酯化活性。结果表明,三类固体酸催化剂的活性顺序为Amberlite树脂﹥SO₄²-/ZrO₂﹥HZSM-5,催化剂活性与酸度一致;酯化反应中水的含量对催化剂的活性有不同程度的影响,水含量较高时催化剂SO₄²-/ZrO₂酯化活性明显变差,而阳离子交换树脂仍具有较高的酯化活性。采用阳离子交换树脂对生物油进行微波催化酯化提质后,原生物油中含有的大量不同种类的羧酸被有效地转化成各种酯类,酯类化合物由原油中的4种增加到13种。与传统加热条件下生物油催化提质比较,生物油微波提质具有明显优势,提质后生物油组分得到优化。     

Cost-effective routes for catalytic biomass upgrading

Catalytic hydrodeoxygenation (HDO) is a fundamental and promising route for bio-oil upgrading to produce petroleum-like hydrocarbon fuels or chemical building blocks. One of the main challenges of this technology is the demand of high-pressure H₂, which poses high costs and safety concerns. Accordingly, developing cost-effective routes for biomass or bio-oil upgrading without the supply of commercial H₂ is essential to implement the HDO at commercial scale. This article critically reviewed the very recent studies relating to the novel strategies for upgrading the biofeedstocks with ‘green’ H₂ generated from renewable sources. More precisely, catalytic transfer hydrogenation/hydrogenolysis, combined reforming and HDO, combined metal hydrolysis and HDO, water-assisted in-situ HDO and nonthermal plasma technology and self-supported hydrogenolysis are reviewed herein. Current challenges and research trends of each strategy are also proposed aiming to motivate further improvement of these novel routes to become competitive alternatives to conventional HDO technology.