Numerical Estimation of Heat Recovery within a Distributed Incinerator Using Water and Hydrocarbons as Working Fluids

International Journal of Mechanical Engineering and Applications Pub Date : 2019-04-03 DOI:10.11648/J.IJMEA.20190701.12

H. Yamashiro, T. Yara, Kenji Fukutomi

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Abstract

The potential of a cogeneration system combined with a small combustion furnace was investigated in this study. The heat transfer between the exhaust gas and working fluid flowing in a spiral tube heat exchanger was estimated numerically and the amount of vapor generated was predicted. The combustion chamber had a 0.49 m3 inside volume with a chimney height of 2.5 m and an inner diameter of 0.28 m. A uniform gas side temperature condition that was referenced from the results of a preliminary experiment and a computational fluid dynamics simulation were adopted to simplify calculations and clarify the effects of working fluids. The amounts of heat recovery when utilizing water and other types of working fluids (Pentane, Butane) were compared. The most effective tube length considering pressure drop and phase change was also predicted. Isentropic theoretical thermal efficiency and T-s diagrams are analyzed to evaluate the vapor-power conversion rate using waste heat. As a result, a potential the heat recovery rate of approximately 100 kW at a 150 kg/h mass flow rate is expected.

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以水和碳氢化合物为工质的分布式焚烧炉内热回收的数值估计

本研究探讨了小型燃烧炉结合热电联产系统的潜力。对螺旋管换热器中废气与工质之间的换热进行了数值估计，并对蒸汽的产生量进行了预测。燃烧室内容积为0.49 m3，烟囱高2.5 m，内径0.28 m。为了简化计算，明确工质的影响，采用了初步实验结果和计算流体力学模拟相结合的均匀气侧温度条件。比较了利用水和其他类型的工质(戊烷、丁烷)时的热回收率。同时预测了考虑压降和相变的最有效管长。分析了等熵理论热效率和T-s图，以评估利用余热的蒸汽功率转化率。因此，预计在150kg /h的质量流量下，潜在的热回收率约为100kw。

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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International Journal of Mechanical Engineering and Applications

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