热溶煤的燃烧特性

Combustion characteristics of thermal dissolution coal

  • 摘要: 低阶煤的高值化利用对拓宽能源途径,提高能源效率和解决环境问题具有重要意义.以N-甲基吡咯烷酮为有机溶剂,对4种低阶煤进行热萃取,获得低灰分、高挥发分的热溶煤产物.通过热重分析研究了热溶煤的燃烧特性,并利用拉曼光谱分析,对比了原煤与热溶煤碳结构的变化规律.结果表明:与原煤相比,热溶煤的灰分含量明显降低,挥发分含量增高,固定碳含量减少,热值增大.其中KL、GD和ZS 3种热溶煤的H/C原子比大于原煤,XB的热溶煤小于原煤.KL、GD和ZS 3种热溶煤的峰强度(ID/IG)和峰面积(AD/AG)的比值大于相应的原煤,其有序化程度减小,结构缺陷增多,相应的其热溶煤的燃烧反应性增大.而XB热溶煤的ID/IGAD/AG的值小于相应的原煤,有序化程度增大,燃烧反应性降低.

     

    Abstract: Coal is one of the most important energy sources in our society. However, there have been increasing environment concerns regarding coal utilization. The high-value application of low-rank coal has an important significance for broadening the energy pathways, improving energy efficiency, and solving environmental problems. In this study, thermal dissolution coals (TDCs), which have low ash and high volatility, were extracted from four types of low-rank coal by N-2-methyl-2-pyrrolidinone (NMP). The combustion characteristics of TDCs were investigated by thermogravimetric analysis, and the structure variation law of raw coals and TDCs were compared using Raman spectra. The results show that the ash content and fixed carbon of TDCs significantly decrease, whereas the volatile content and high heating valve increase. The H/C atomic ratios of KL, GD, and ZS TDCs are higher than those of raw coals, whereas XB has a lower H/C atomic ratio than that of raw coal. The ratio of peak intensity (ID/IG) and peak area (AD/AG) values of KL, GD, and ZS TDCs are greater than those of raw coals, indicating that as the ordering degrees of these TDCs decrease, the structure deficiencies and combustion reactivity increase. In contrast, XB coal showed opposite results.

     

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