Simulation of Process Structure and Operating Parameters on the Efficiency of the Chemical Looping Combustion Combined with Humid Air Turbine Cycle Using Statistical Experimental Design

AlKhawarizmi Engineering Journal Pub Date : 2021-08-31 DOI:10.4186/ej.2021.25.8.21

Watchara Uraisakul, B. Chalermsinsuwan, P. Piumsomboon

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Abstract

This study’s objective is to investigate the process structure and operating variables that affect the efficiency of the CLC combined with humid air turbine (HAT) unit to produce electricity. The investigation was carried out by using the Aspen Plus program with Peng-Robinson-Boston-Mathias (PR-BM) thermodynamics properties. In this study, the process structure and operating parameters were investigated. The process structure was related to process configuration, which reflected the number of compressor stages. The operating parameters were pressure, airflow rate, and compression methods. The four investigated responses consist of LHV efficiency, power production from the air reactor, work of air compressors, and air compressor discharge temperature. The 3k factorial experimental design was employed. After that, the result was analyzed by the analysis of variance (ANOVA). The result showed that the highest LHV efficiency was at 55.87 % when seven stages of compressors were used and the operating condition was at 15 atm of pressure in the air reactor, air compression using method 3, and 61,000 kmol/hr of airflow rate. The pressure and the method of compression highly affected LHV efficiency, as shown by their p-values. The pressure had the highest effect on LHV efficiency. The high pressure provided high power production. Method 3 provided the highest discharged temperature from the air compressor, which was the reason for the high power production in the air reactor. The compression ratio of the last compressor would be 65% of the pressure in the air reactor. Moreover, the efficiency could be improved to 57.67% by increasing the loading of Ni on the oxygen carrier from 25% to 40%. The benefit of the paper will be preliminary data for operation and investment decisions on a CLC power production because this result has not yet been demonstrated.

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用统计实验设计模拟化学循环燃烧与湿空气涡轮循环效率的过程结构和运行参数

本研究的目的是研究影响CLC与湿空气涡轮(HAT)机组发电效率的过程结构和操作变量。采用具有Peng-Robinson-Boston-Mathias (PR-BM)热力学性质的Aspen Plus程序进行研究。研究了该工艺的工艺结构和操作参数。工艺结构与工艺配置有关，反映了压缩机级数。操作参数为压力、气流速率和压缩方式。研究的四个响应包括LHV效率、空气反应器发电量、空压机工作和空压机排气温度。采用3k因子试验设计。之后，对结果进行方差分析(ANOVA)。结果表明:采用7级压气机，在空气反应器内压力为15 atm、空气压缩方式为3、风量为61,000 kmol/hr的工况下，LHV效率最高，为55.87%。压力和压缩方式对LHV效率的影响很大，由它们的p值可以看出。压力对LHV效率的影响最大。高压提供了高功率生产。方法3提供了空气压缩机的最高排气温度，这是空气反应器产生高功率的原因。最后一台压缩机的压缩比为空气反应器压力的65%。将载氧体上Ni的负载由25%提高到40%，效率可提高到57.67%。由于这一结果尚未得到证实，因此本文将为CLC电力生产的运营和投资决策提供初步数据。

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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来源期刊

AlKhawarizmi Engineering Journal

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审稿时长

20 weeks