生物质气化

  • 网络biomass gasification
生物质气化生物质气化
  1. 生物质气化对减少CO2排放的作用

    The effect of biomass gasification on reducing CO _ 2 emission

  2. 清洁发展机制(CDM)对促进生物质气化发电技术的作用分析

    CDM promoting influence analysis of biomass gasification power generation project

  3. 生物质气化气要实现高氢浓度的转化,需要通过水煤气变换反应将CO转化为H2。

    High concentration hydrogen of the producer gas could be realized through water-gas shift reaction .

  4. 在流化床生物质气化炉内,用空气进行气化生物质(花生壳)的试验研究,分析的参数是ER(0.20.45),气化床的温度(750850℃)。

    Biomass ( peanut shell ) gasification with air in pilot fluidized bed gasifier is studied .

  5. 该两种菌经颗粒活性炭固定,可高效去除生物质气化发电厂洗焦废水中的COD和有毒化合物,达到了较好的去除效果。

    The process is capable to remove COD and some toxic compounds from the gasification wastewater efficiency .

  6. 中型生物质气化发电CDM项目案例分析

    CDM case study on middle-size biomass gasification power generation

  7. 并利用ASPEN流程模拟软件对生物质气化的情况进行了数值模拟。

    The numerical simulation of biomass gasification process was carried out though ASPEN process simulation software . 2 .

  8. 该燃烧器适用于多种生物质气化燃气,试验表明燃烧器在稳定工作条件下燃烧效率为98%,烟气CO含量小于1×10-6,各项性能指标达到燃气燃烧器的基本要求。

    The burner performances meet the standard of gas burner : its burning efficiency is 98 % and CO in smoke is less than 1 × 10 ~ ( - 6 ) .

  9. FGAS系列生物质气化系统工艺及其技术经济评价

    Technique and its technical economy assessment of gasification system of FGAS series biomass

  10. 双循环流化床生物质气化技术可实现生物质热电可燃气多联产、CO2的近零排放以及较高的碳转化率,实现生物质的高效、清洁利用。

    Double fluidized bed gasification technology can achieve heat , electricity , gas multiple co-generation , Near-Zero Emission of CO2 and high carbon conversion , and also can realize clean , highly effective use of biomass energy .

  11. 以甘蓝为原料在盘管流通式反应器中在550℃,25MPa超临界水条件下进行了生物质气化试验以考察H2O2浓度的影响。

    The gasification of cabbage in supercritical water at 550 ℃ and 25 MPa in a tubular flow reactor was examined .

  12. 在高温低硫的生物质气化气中,钛促进的钴钼耐硫催化剂具有较高的变换活性,CO转化率达到80%以上,合成气H2/CO比在1-8范围内可调;

    TiO2 modified Co-Mo based catalyst had high reaction activity , and CO conversion was above 80 % ; A broad range of the H2 / CO ratio ( 1-8 ) could be adjusted by flowing part of the syngas into the Co-Mo catalyst bed .

  13. 利用aspenplus软件建立串行流化床模型,对生物质气化制氢过程进行了模拟,研究了气化过程中温度以及催化剂与生物质配比等因素对制氢的影响。

    Biomass catalytic gasification is also studied . Aspen Plus software is used to establish the model of interconnected fluidized beds and simulate the process of biomass gasification , the effects of gasification temperature and ratio of catalyst to biomass are discussed .

  14. 利用I-7000系列模块和组态软件,开发了用于生物质气化技术研究实验平台的计算机自动测控系统。

    Using I-7000 series modules and configuration software , a computer auto measure and control system used for the biomass gasification technology experiment platform is established .

  15. 论文进行了生物质气化发电焦油废水的厌氧毒性测定,并应用小试规模的上流式污泥床&过滤器(UpflowBlanketFilter,UBF)复合式厌氧反应器对其进行了厌氧可处理性研究。

    In the research reported in this paper , anaerobic toxicity assay ( ATA ) of tar-containing wastewater from gasification of biomass was conducted I and the availability of its anaerobic treatment was studied in a lab-scale upflow blanket filter ( UBF ) .

  16. 本文采用两步共沉淀法制备了高稳NiO-MgO重整催化剂,以鼓泡流化床为重整反应器,对生物质气化粗燃气NiO-MgO催化重整制取合成气性能进行了研究。

    The synthesis gas production via reforming of biomass raw fuel gas was investigated over NiO-MgO catalyst in a fluidized-bed reactor The NiO-MgO catalyst was prepared by the method of two Steps co-precipitation .

  17. 本文介绍了国内外高温燃料电池(MCFC、SOFC)的研究和主要特点,总结了国内外生物质气化燃料电池一体化发电的研究进展,分析了我国开展该项研究的可行性和应用前景。

    Research status of high temperature fuel cells ( MCFC and SOFC ) are introduced and the study on integrated biomass gasification and power generation system are reviewed . The feasibility and prospect of the technology are analyzed based on the situation of China .

  18. 处理生物质气化发电焦油废水的上流式污泥床过滤器(UBF)内厌氧污泥在环境温度(16~36℃)条件下完成驯化并实现颗粒化,其间焦油废水的COD比例是主要影响因素。

    Acclimation and granulation of anaerobic sludge was achieved in the UBF reactor treating tar containing wastewater from gasification of biomass for power production at ambient temperature ( 16 ~ 36 ℃), the COD proportion of tar containing wastewater in the influent was the main effect factors in the process .

  19. 生物质气化集中供气系统工程优化设计

    Optimization Design of Biomass Gasification System Project for Central Gas Supply

  20. 加压流化床中影响生物质气化气组成因素的研究

    Study on the Sawdust Air Gasification in a Pressurized Fluidized Bed

  21. 生物质气化技术及开发应用研究进展

    Progress of research on technique of biomass gasification and its application

  22. 生物质气化高温燃料电池一体化发电技术研究

    Status of integrated biomass gasification and fuel cell power generation system

  23. 混凝法处理生物质气化洗涤废水研究

    Coagulation Treatment of Gas - Washed Wastewater from Biomass Gas fier

  24. 小型生物质气化发电系统的设计与测试

    Design and test on a small-scale biomass gasification for power system

  25. 基于模糊神经网络的生物质气化炉的智能控制

    The Intelligent Control of Biomass Gasifier Based on Fuzzy Neural Network

  26. 生物质气化过程中焦油的去除方法综述

    A Review of Measures for Tar Elimination in Biomass Gasification Processes

  27. 生物质气化洗焦废水的预处理和微生物降解

    An Experimental Study on Pretreatment and Biodegradation of Biomass Gasification Wastewater

  28. 热管式生物质气化炉反应过程的理论分析

    Estimation on reaction process of the heat pipe biomass gasification furnace

  29. 基于支持向量机的生物质气化过程建模及优化研究

    The Modeling and Optimization of Biomass Gasification Process Based on SVM

  30. 焦油的存在影响整个生物质气化过程。

    The existence of tar effected the whole biomass gasification process .