Optimization of a Biomass Torrefaction Plant With Near Zero Emissions

ASME 2019 13th International Conference on Energy Sustainability Pub Date : 2019-12-03 DOI:10.1115/es2019-3963

M. Hasan, Y. Haseli

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Abstract

Recent studies have shown that the emissions from conventional torrefaction processes is the second largest contributor to the supply chain. This article presents a torrefaction unit that operates based on oxy-combustion concept, whereby preventing carbon dioxide and nitrogen oxides emissions. The oxygen required in the process is supplied from an Air Separation Unit (ASU) and the working fluid of the new system is carbon dioxide. The process model is implemented in Engineering Equation Solver (EES) and simulation is conducted using the design data of a conventional plant which torrefies wood at 553 K for 17.5 minutes. The overall efficiency of the plant which accounts for both thermal and electrical energy requirement of the process is found to be 88%. The total energy consumption of the system exhibits a minimum at an optimum torrefaction temperature. With willow as the feedstock, the optimum temperature is determined to be 536 K at a residence time of 20 minutes, at which the total equivalent thermal energy required is 2 MJ/kg dry biomass and the energy yield is as high as 91%. The results show that the optimum torrefaction temperature is feedstock dependent and it is lower for a longer residence time.

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近零排放生物质焙烧装置的优化设计

最近的研究表明，传统焙烧过程的排放是供应链的第二大贡献者。本文介绍了一种基于氧燃烧概念的焙烧装置，从而防止二氧化碳和氮氧化物的排放。该工艺所需的氧气由空气分离装置(ASU)提供，新系统的工作流体是二氧化碳。该过程模型在工程方程求解器(EES)中实现，并使用传统工厂的设计数据进行仿真，该工厂在553 K下烘烤木材17.5分钟。该装置的整体效率，即该过程的热能和电能需求，被发现为88%。在最佳干燥温度下，系统的总能耗最小。以柳条为原料，确定最佳温度为536 K，停留时间为20分钟，此时所需的总等效热能为2 MJ/kg干生物质，产能率高达91%。结果表明，最佳焙烧温度与原料有关，停留时间越长，温度越低。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ASME 2019 13th International Conference on Energy Sustainability

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