Discovery and intensity characterization of TDP and PRP based on temperature evolution history during the pyrolysis for large biomass particle

IF 6.4 3区 环境科学与生态学 Q2 ENERGY & FUELS
Rui Chen , Jun Cai , Xinli Li , Xiaobin Qi
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Abstract

The pyrolysis behaviors and temperature evolution history of lignocellulosic biomass (Beech, BH) were characterized using a novel pyrolysis model—C-DAEM. The simulation results were validated through corresponding experimental data. Based on the simulation results, two distinct peaks were observed in the temperature difference between the surface and center (TDSC) curve, namely the thermal disturbance peak (TDP) and the pyrolysis reaction peak (PRP). The presence of TDP and PRP was confirmed by examining the heat flux ratio between the pyrolysis rate and the temperature rise rate. Moreover, the results indicated that three factors, namely heating temperature, particle size, and pyrolysis rate, influenced the relative intensity between TDP and PRP. By changing the values of each impact factor, conditions where TDP owns the same height with PRP were obtained under different working conditions. These findings have led to the development of a dimensionless number, naming the pyrolysis-heating surface-center number (PHSC number). This number could provide a comprehensive indication of the collective impact of the aforementioned factors when TDP and PRP exhibit equal peak heights.

Abstract Image

根据大型生物质颗粒热解过程中的温度演变历史,发现 TDP 和 PRP 并确定其强度特征
利用新型热解模型--C-DAEM,对木质纤维素生物质(山毛榉,BH)的热解行为和温度演变历史进行了表征。模拟结果通过相应的实验数据进行了验证。根据模拟结果,在表面与中心温差(TDSC)曲线上观察到两个明显的峰值,即热扰动峰(TDP)和热解反应峰(PRP)。通过研究热解速率与温升速率之间的热通量比,证实了 TDP 和 PRP 的存在。此外,研究结果表明,加热温度、粒度和热解速率这三个因素影响了 TDP 和 PRP 的相对强度。通过改变各影响因素的值,可在不同的工作条件下获得 TDP 与 PRP 高度相同的条件。根据这些发现,我们提出了一个无量纲数值,命名为热解-加热表面-中心数值(PHSC 数值)。当 TDP 和 PRP 显示出相同的峰高时,该数值可全面反映上述因素的综合影响。
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来源期刊
Carbon Resources Conversion
Carbon Resources Conversion Materials Science-Materials Science (miscellaneous)
CiteScore
9.90
自引率
11.70%
发文量
36
审稿时长
10 weeks
期刊介绍: Carbon Resources Conversion (CRC) publishes fundamental studies and industrial developments regarding relevant technologies aiming for the clean, efficient, value-added, and low-carbon utilization of carbon-containing resources as fuel for energy and as feedstock for materials or chemicals from, for example, fossil fuels, biomass, syngas, CO2, hydrocarbons, and organic wastes via physical, thermal, chemical, biological, and other technical methods. CRC also publishes scientific and engineering studies on resource characterization and pretreatment, carbon material innovation and production, clean technologies related to carbon resource conversion and utilization, and various process-supporting technologies, including on-line or off-line measurement and monitoring, modeling, simulations focused on safe and efficient process operation and control, and process and equipment optimization.
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