聚对苯二甲酸乙二醇酯废料与生物质燃料颗粒的特性及燃烧动力学

IF 3.1 Q2 ENVIRONMENTAL SCIENCES
K. Manatura, U. Samaksaman
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引用次数: 4

摘要

背景和目标:对各种原料燃料颗粒的需求为非木质生物质颗粒生产带来了机遇和挑战。塑料回收和木材锯切的废物具有很高的能源潜力,适合作为固体燃料进行造粒。方法:利用聚对苯二甲酸乙二醇酯废料和生物质(Tectona grandis Linn.f)的混合物,以聚对苯二甲酸乙二酯与生物质的比例为9:1,制备燃料颗粒的特性和燃烧动力学。研究内容包括物理化学性质及其官能团分析、重金属浓度和离子浸出性测试以及灰分分析。在这种情况下,在氧气气氛中,在50-800°C的温度范围内,以不同的加热速率进行热重分析。工作结束时,通过三次比较评估讨论了动力学研究以及燃料芯块用于能源利用的可行性。研究结果:以这个比例(9:1)进行造粒具有PET/生物质颗粒的耐用性、均匀的尺寸、易于处理、储存和运输,与木质颗粒一样常见。一些技术挑战,如低水分含量和高挥发性物质含量取决于原料。主要特征是来自两种组成材料的特征的结合。微丸的官能团由对苯二甲酸酯和木质纤维素组成。在球团中加入少量生物质可以改善其热分解行为。聚对苯二甲酸乙二醇酯/生物质颗粒的性能表明,其适合于具有等于19.20MJ/kg的高热值的燃烧。由于原材料的清洁度,重金属和离子污染物低于标准的最高限值。然而,泥土材料和烧碱洗涤剂的轻微影响导致了残留物化学物质的改变。与最初的聚对苯二甲酸乙二醇酯废物相比,该颗粒具有更低的点火、脱挥发分和燃尽温度;同样,峰值温度和燃尽温度转移到较低的区域。使用Kissinger Akahira Sunose、Ozawa Flynn Wall和Starink模型获得的活化能值相似,在142–146 kJ/mol范围内。结论:这些发现可能为聚对苯二甲酸乙二醇酯/生物质混合燃料颗粒的设计和运行提供重要信息,以帮助设计和运行与传统固体燃料的共燃系统。燃料芯块的这种修改表明了在大规模熔炉应用中运行的可能性,并且可以通过现代生物能源转换过程进一步升级为其他燃料生产。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Characteristics and combustion kinetics of fuel pellets composed of waste of polyethylene terephthalate and biomass
BACKGROUND AND OBJECTIVES: The needs of fuel pellets from varied feed stocks have opened up opportunities and challenges for pellets production from non-woody biomass. Wastes of plastic recycling and wood sawing contained a high potential for energy source and suited for pelletizing as a solid fuel. METHODS: The characteristics and combustion kinetics of fuel pellets made using a mixture of waste of polyethylene terephthalate and biomass (Tectona grandis Linn.f) with a polyethylene terephthalate to biomass ratio of 9:1. The investigation covered physico-chemical properties and their functional group analysis, heavy metal concentration and ionic leachability testing, and ash analysis. In this context, thermogravimetric analysis was used in an atmosphere of oxygen gas, over a temperature range of 50-800 °C and at different heating rates. The work ends with discussion of the kinetics study via three comparative evaluations and the feasibility of fuel pellets for energy utilization. FINDINGS: Pelletizing with this ratio (9:1) was present the durability of PET/biomass pellets, a uniform dimension, ease handling, storage, and transportation common as woody pellets. Some technical challenges such as low moisture content and high volatile matter content were feedstock dependent. The major characteristics were a combination of those from both the constituent materials. Functional groups of the pellets were contributed by terephthalate and lignocellulose. The addition of a small amount of biomass in pellets could improve their thermal decomposition behavior. The properties of the polyethylene terephthalate/biomass pellets indicated that were fit for combustion with a high heating value equal to 19.20 MJ/kg. Heavy metals and ionic contaminants were below the maximum limits of the standards because of the cleanliness of the raw materials. However, the minor effects of earth materials and a caustic soda detergent were resulted in the alteration of residue chemicals. The pellets had lower ignition, devolatilization, and burnout temperatures than the original polyethylene terephthalate waste; likewise, the peak and burnout temperatures shifted to a lower zone. The activation energy values obtained using the Kissinger-Akahira-Sunose, Ozawa-Flynn-Wall, and Starink models were similar and in the range 142–146 kJ/mol. CONCLUSION: These findings may provide crucial information on fuel pellets from blended polyethylene terephthalate/biomass to assist the design and operation of a co-combustion system with traditional solid fuels. Such modifications of fuel pellets suggest the possibility of operating in large-scale furnace applications and can further be upgraded to other fuels production via modern bioenergy conversion processes.
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来源期刊
CiteScore
7.90
自引率
2.90%
发文量
11
审稿时长
8 weeks
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