The stability of bio-oil is very important for its applications.
稳定性对生物油的应用十分重要。
The yield of bio-oil is determined by materials and reaction conditions.
实验的原料和反应条件决定了液化产物的收率。
Understanding bio-oil composition can provide important information for bio-oil upgrading.
了解生物油的组成可以提供生物油提质的重要信息。
The bio-oil yield from cellulose is the highest of the three fractions, but it is lest stable.
纤维素生物油产量在峰值上最高,但纤维素生物油热稳定性差,高温时挥发分的二次分解最明显;
The technology to converse solid biomass energy into bio-oil by thermochemical is the important way.
热化学高效转化利用技术是生物质能源开发利用的最主要途径。
A fluidized bed reactor biomass fast pyrolysis system for producing bio-oil was developed independently.
大规模生物质快速热解制取生物油将成为解决液体燃料短缺的一个重要途径。
The heat breaks the biomass down into a charcoal-like solid and the bio-oil, giving off some gas in the process.
这种情况下,加热会把生物原料变成木炭似的固体物质和生物原油,同时释放某些气体。
Now reduce the cost and enhance the yeild of bio-oil by improve the pyrolysis set are our effort direction.
改进热裂解装置来降低生产生物油的成本,提高产油率是现阶段努力的方向。
The chemicals determined from the bio-oil are valuable indicating a wide range of application of the bio-oil.
对液化油成分的分析,表明了它具有广阔的应用前景。
Through upgrading, bio-oil by biomass fast pyrolysis is promising technology for diesel or gasoline substitute.
生物质快速热解制取的生物原油,经过精制提质,具有柴油或汽油的特点,可用于车用燃料。
It is shown that the pyrolysis temperature has a great effect on the yield and the compositions of the bio-oil.
结果表明,裂解温度对热解油产率及其族馏分构成的影响很大。
The bonding strength of adhesive was mainly related to the contents of phenolic substances in pyrolysis bio-oil.
胶粘剂的胶接强度主要与热解生物油中酚类物质含量有关。
Fast pyrolysis of biomass for bio-oil is a kind of new technology of energy conversion which attracts growing research rapidly.
生物质的快速热解是一种新型生物能源转化技术。
Using Chinese fir sawdust as raw material, the experiments of biomass vacuum pyrolysis for production of bio-oil were carried out.
以杉木屑为原料,进行了真空热解制备生物油的实验研究。
Deconstruction at higher temperatures (300 to 600 degrees C) produces a biocrude, or bio-oil, that can be refined into gasoline or diesel.
温度再高一些的工艺(300~600摄氏度)得到的则是生物原油(biocrude或bio-oil),可进一步提炼成汽油或柴油。
The effect of operation parameters on pyrolysis behavior of biomass, especially on the composition of bio-oil and gas, was investigated.
考察了运行参数对热解产物分布的影响,重点研究了各个参数对热解气体和生物油组分的影响规律。
Microalgae biomass, as a renewable energy through liquefaction, can be turned into bio-oil, reducing consumption and reliance on fossil fuels.
微藻生物质做为一种可再生能源通过液化可以转化为生物油,减少人类对化石能源的消耗与依赖。
Some overseas research results of bio-oil upgrading were introduced, and the prospect of biomass pyrolysis for producing liquid fuel was discussed.
本文最后介绍了国内外所进行的生物油的改性研究,讨论了生物质热裂解制取生物油技术的应用前景。
This paper mainly introduced the research and progress of the technology about heating through heat-carrier during the process of producing bio-oil.
本文简要介绍了生物燃油生产过程中热载体加热技术的研究及进展。
This paper concludes detailed the current status of biomass pyrolysis for liquid product in china and overseas, especially about analysis of bio-oil composition.
本文详细归纳了国外及我国生物质热裂解制取生物油技术的研究现状,并且对国内外关于生物油组成成分的研究现状进行了系统地总结。
The effects of different additives on the yields of gas, solid and liquid were studied and the composition of organic components in bio-oil was analyzed by GC-MS.
考察了不同添加剂对气、固、液产率的影响,并用GC - MS法分析了生物油中有机成分。
The results show that the main effect on the oil production rate is the pyrolytic temperature. But gas flow rate and bed depth can also affect the rate of bio-oil.
结果表明热解温度是生物质产油率的主要影响因素,流化气流速和床层高度对产油率也有一定的影响。
The component's distribution of bio-oil, which was produced from Fraximus mandshurica by flash pyrolysis in a fluidized bed reactor, was determined by GC-MS analysis.
结合色质联机技术分析了由流化床热裂解水曲柳获得的生物油主要组分的分布。
It's the key technology during the process of producing bio-oil to heat through heat-carrier, whether it's advanced or not is connected directly with the cost of bio-oil.
热载体加热是生物燃油生产过程中的关键环节,热载体技术先进与否直接关系到生物燃油的生产成本。
The technology of biomass pyrolysis can convert low-quality biomass into bio-oil that has the character of high-quality, high energy density, cleanness and zero carbon dioxide emission.
大力开发生物质的热裂解制油技术,可将低品位的生物质能转化成高品质的、高能量密度,清洁、无污染而且二氧化碳排放为零的生物油液体燃料。
In this paper, some typical reactor designs, process engineering, operation conditions, catalyst, reaction mechanism, and thermal analysis of catalytic steam reforming of bio-oil are presented.
本文介绍了生物油水蒸气催化重整反应机理与热力学分析,介绍了催化重整制氢过程催化剂、制氢工艺条件、代表性的反应器及工艺流程。
The gaseous product was mainly consisted of CO, CO2, H2 and CH4. The concentration of CO, H2 and CH4 in gas increased with temperature. The bio-oil contained organic acid, phenol and saccharide.
结果表明,气体产物中主要以CO、CO2、H2和CH4为主,CO、H2和CH4的浓度随着温度升高而上升,生物油主要含有有机酸类、苯酚类和糖类等化合物。
The gaseous product was mainly consisted of CO, CO2, H2 and CH4. The concentration of CO, H2 and CH4 in gas increased with temperature. The bio-oil contained organic acid, phenol and saccharide.
结果表明,气体产物中主要以CO、CO2、H2和CH4为主,CO、H2和CH4的浓度随着温度升高而上升,生物油主要含有有机酸类、苯酚类和糖类等化合物。
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