碳转化率

  • 网络efficiency of carbon conversion;carbon conversion
碳转化率碳转化率
  1. 随着压力提高、煤焦的基碳转化率和比气化反应速率均增加;Cf&H2O气化反应级数在0.23~0.33范围内;

    Base carbon conversion and specific gasification rate increase with elevating gasification pressure , the order of Cf-H2O gasification reaction is in the range of 0.23 ~ 0.33 ;

  2. 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 .

  3. 通过对14C样品制作三个步骤的分析,找出了影响14C样品碳转化率的因素;

    Three procedures were given to this technique , and we can find the influential factors to conversion coefficient of radiocarbon .

  4. 在该试验阶段获得的煤气的最高热值为3.84MJ/Nm3,最高碳转化率为73.6%。

    At present stage , the maximum calorific value of product gas was 3.84MJ/Nm3 and the highest coal conversion efficiency was 73.7 % .

  5. 实验结果表明:提高热解温度可以提高产气率、碳转化率和热效率;热解气热值随温度而变化,在973K左右达到最大值;

    The results show that the gas field , carbon conversion rate , and energy transform efficiency improve with increasing pyrolysis temperature with the gas calorific value varying with temperature to a peak at about 973 K.

  6. 试验结果表明,空气部分气化半焦燃烧方案得到的煤气热值较低,为4-5MJ/Nm~3,气化炉床层温度对碳转化率影响较大,随着反应温度升高碳转化率提高。

    The results achieved at long time steady operation status of the facility show that , with air as gasification agent , the system can produce 4-5MJ / Nm3 low heating value gas and the carbon conversion efficiency increases with the bed temperature in the gasifier .

  7. 再循环煤气煤热解半焦燃烧方案产生的是12-14MJ/Nm~3中热值煤气,但气化炉内碳转化率较低。

    The system can produce 12-14MJ / Nm3 middle heating value gas by using high temperature circulation solid as heat carrier and recycle gas or steam as gasification media , but the fuel conversion efficiency is lower in the gasifier and most of fuel energy is converted in the combustor .

  8. 加大反应器的煤处理量会带来碳转化率的降低;

    The carbon conversion is enhanced by decreasing feed rate .

  9. 气化反应速率随着碳转化率的增加而降低。

    And the gasification reaction rate decreases with an increasing of carbon conversion .

  10. 实验结果表明,气化反应温度越高,碳转化率和气化反应速率越高。

    The higher the gasification temperature is , the higher the carbon conversion is .

  11. 活性的表示方法用基碳转化率&时间图或比反应速率表示。

    It is shown that the activity with base carbon conversion ratio and time diagram .

  12. 高碳转化率下热解神府煤焦-CO2高温气化反应性

    Gasification reactivity of rapid and slow pyrolyzed Shenfu chars with CO_2 at high carbon conversions and elevated temperatures

  13. 气化介质预热温度的变化对碳转化率和干煤气产率影响不大。

    The carbon conversion and dry gas yield were almost constant regardless of the preheated air / steam temperature .

  14. 以提高系统效率为目标,对系统压力和气化炉碳转化率这两个重要参数进行了优化。

    Aimed at enhancing the system efficiency , the system pressure and the gasifier carbon conversion ratio were optimized .

  15. 结果表明,系统效率随操作压力和气化炉碳转化率增加而呈上升趋势。

    The results indicate that the system efficiency increases with increasing of the pressure and the gasifier carbon conversion ratio .

  16. 随机孔模型能较好的模拟混合物气化反应速率和碳转化率的关系。

    The random pore model is found to be suitable for simulating the reaction rate of gasification and carbon conversion rate .

  17. 总碳转化率、二甲醚的选择性、甲醇和二甲醚产量几乎不随直径的变化而变化。

    Total carbon conversion , selectivity of DME , and yield of methanol / DME keep almost constant with reactor diameter .

  18. 两种煤焦的最佳气化反应温度为1200℃,碳转化率最高。

    The optimal gasification temperature for two chars was 1200 ℃, in which the carbon conversion were higher than other temperatures .

  19. 实验结果表明,催化剂添加量和气化温度对碳转化率和煤气组成的影响最为显著。

    The results showed that both carbon conversion and gas composition were strongly influenced by the catalyst content and reaction temperature .

  20. 所得到的三种不同煤焦(神木、彬县、西山)在不同温度,不同气化碳转化率下的部分气化,燃烧失重曲线表明:煤种、气化碳转化率对燃烧失重均有影响。

    Weight loss curves have been obtained under different temperature and gasification-combustion ratio with three coals ( Shenmu , Binxian and Xishan ) .

  21. 黑液水煤浆焦的碳转化率为98.37%,比普通水煤浆焦碳转化率(93.60%)高出5.1%,催化气化作用明显。

    The carbon conversion of CBLS char was 98.37 % , which was 5.1 % higher than that of Coal water slurry char .

  22. 用随机孔模型模拟北宿煤反应速率与碳转化率的关系曲线,与未反应芯缩核模型和混合模型模拟结果比较。

    The random pore model , the unreacted shrinking core reaction model and the integrated model were tested by the experimental data respectively .

  23. 水煤比的增大整体提高了样品的碳转化率,但是H2+CO相对含量减少。

    As steam / coal ratio increased , the overall carbon conversion increases , while , relative contents of H2 + CO decreases .

  24. 重点考察了气化温度对煤气成分、煤气热值、碳转化率和煤气产率等气化指标的影响。

    The study focused on the influence of gasfication temperature on gas compos - tions , gas beating value , carbon conversion and gas yield .

  25. 考察了五种烟煤的多喷嘴对置式气化炉性能,碳转化率在98.1%-99.9%之间。

    The OMB gasifier - performance of five bituminous coal are investigated , and the carbon conversion approaches to 98.1 % ~ 99.9 % . 3 .

  26. 固定床气化炉是一种技术成熟、应用最广的高热效率和高碳转化率的反应器。

    Fixed bed gasification is a reactor that has mature technology , high heat efficiency and high carbon conversion . And it is the best widely used .

  27. 煤浆浓度从59wt%增加至62wt%,气化炉出口温度和碳转化率略微降低,氧耗、煤耗降低。

    When the slurry concentration increases from 59wt % to 62wt % , the gasifier temperature and carbon conversion slightly decrease , while the feedstock consumption decreases .

  28. 实验结果表明,工业纯碱作为催化剂添加5%可使碳转化率增加3倍,实现了煤的高效转化;

    With the 5 % loading of sodium carbonate , the carbon conversion increases by 3 times , but the coal price only increases by 1.18 times .

  29. 结果表明,高温有利于生物质气化,促进碳转化率和冷煤气效率的提高。

    The results indicate that high temperature is in favor of gasification . And it is conducive to improving the rate of carbon conversion and cold gas efficiency .

  30. 随着温度的升高,总碳转化率和二甲醚的选择性均略有降低,甲醇产量基本不变,而二甲醚的产量有所减小,静液床层高度和操作床层高度均降低。

    Total carbon conversion , selectivity and yield of DME decrease slightly with increasing temperature . Static bed height and operating bed height drop suddenly as the temperature increases .