为此,开展了利用生物制氢废液筛选高效产絮菌的研究。
Screening high-efficiency flocculant-producing bacteria by the effluent of bio-hydrogen production reactors was investigated.
乙醇型发酵是有机废水发酵法生物制氢的最佳产氢发酵类型。
Ethanol type fermentation was proved to be optimum for bio-hydrogen production by organic wastewater fermentation.
目前生产氢气的方法主要有化学制氢法和生物制氢法两大类。
Up to now, there are two main Hydrogen production methods-chemical and biological methods.
目前生物制氢技术中存在产氢效率低、氢气百分含量低等问题。
Currently, some problems exist in the biological hydrogen production, such as low efficiency of hydrogen-producing, low percentages of hydrogen.
结果表明:乙醇型发酵是目前最好的产氢类型,生物制氢技术具有良好的发展前景。
The result shows: it is the best producing hydrogen type at present that the ethanol type ferments, it has good development prospects that the microorganism make hydrogen technology.
介绍了目前制氢的主要方法,光合微生物制氢被认为是最具潜力的氢能生产技术之一。
The main methods for hydrogen production currently are introduced. And production mechanism by photosynthetic microbe was described.
对生物制氢反应器乙醇型发酵和丁酸型发酵的产氢能力及其生态学特性进行了对比分析。
Hydrogen production capacity and ecological characteristics of ethanol-type and butyrate-type fermentation were investigated in continuous-flow reactor.
厌氧发酵生物制氢技术可利用有机废水及固体废弃物等进行氢气生产,制氢过程清洁、节能。
The study of the biohydrogen anaerobic fermentation technology, mainly focuses on the details of hydrogen production bacteria screening and the hydrogen production process optimization.
中国在世界上首次完成生物制氢中试研究,利用细菌从污水中分解收集氢气具备了工业化的条件。
China for the first time in the world succeeded in using bacteria to trial produce hydrogen gas from sewage rich in sugar or plant fibers, and acquired conditions for industrial production.
从生物制氢反应器中富集、分离培养发酵产氢细菌并发挥其最大产氢能力,可以提高高浓度有机废水制氢系统的产氢性能。
The use of the effluent from biohydrogen production reactor for producing microbial flocculants can decrease the production cost and realize the entirely clean production.
本文综述了目前国内外生物制氢技术各个方面的研究进展和成果,并详细描述了光合产氢细菌及发酵产氢细菌等主要产氢生物的产氢机制。
The paper reviewed the current research progress and the main achievements of biohydrogen production technology research both at home and abroad, and described the hydrogen production mechanisms o…
生物质制氢是农业废弃物资源化利用的一项很有发展前途的技术。
Hydrogen production by biomass gasification is a promising technology, which belongs to the comprehensive utilization of agricultural wastes.
集中讨论了生物质超临界水汽化制氢中催化剂的应用,及各类催化剂的比较。
This paper focus on the application of catalysts to hydrogen from gasification of biomass in supercritical water, and comparison among different types of catalysts.
微生物厌氧发酵制氢与餐厨垃圾生物利用相结合具有很好的开发和利用潜力。
The integration of hydrogen production by anaerobic fermentation and bio-processing of food waste has a great development and utilizing prospect.
生物质气化制氢是一项富有前景的制氢技术,已引起了世界各国的普遍关注。
The prospective future of rich hydrogen gas from biomass gasification makes it a common concern of researchers all around the world.
生物质制氢清洁、节能,值得推广。
Producing hydrogen from biomass, which is clean and energy-saving, is worth to be popularized.
本文介绍了两种最有前途的制氢方法:利用太阳能光解水制氢和生物法制氢,总结了其制氢的原理和特点,并对未来的研究趋势做了展望。
Two methods were introduced in this paper: hydrogen production by solar energy and biology. The principle, the trait and the investigation tendency of hydrogen preparation were given.
分析了串行流化床生物质气化制氢的反应机理,并研究了催化剂作用下的气化过程。
The principle of hydrogen production from biomass gasification in interconnected fluidized beds is analyzed;
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。
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。
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.
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