Autocatalytic set of chemical reactions of circulating fluidized bed boiler

2012 International Conference on System Engineering and Technology (ICSET) Pub Date : 2012-10-25 DOI:10.1109/ICSENGT.2012.6339282

S. A. Bakar, N. Harish, F. H. Osman, S. Ismail, S. Mokhtar

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引用次数: 5

Abstract

Circulating fluidized bed-boiler (CFB) is considered in some respects to be an improvement over the traditional methods of coal combustion to produce steam for power generation and process or heating purposes. Technical knowledge about the design and operation of circulating fluidized bed-boiler (CFB) is widely available but little has been done in the field of mathematical modeling of combustion in CFBs. Specifically, there is no fundamentally based mathematical model for chemical reactions involved during combustion process in CFBs that has been investigated using graph theory. In this study, several important chemical reactions of combustion process in CFB which considered as significant to the process are identified. Reactant and reactions products are classify as species and the number of species is identified from the reactions. Based on the reactions, the model of chemical reactions during the combustion process for CFB is obtained and represented by G (V, E) where V is a set of nodes which represent species and E is a set of edge which represents catalytic relationship between species. The graph is successfully transformed into its adjacency matrix, A which is non-negative. Analysis of the graph G (V, E) shows that the combustion process of CFB is in accordance to Autocatalytic Set (ACS) theory. The analysis of its adjacency matrix shows that there is a relationship between autocatalytic graph of G (V, E) with Perron-Frobenius theory.

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循环流化床锅炉化学反应自催化装置

循环流化床锅炉(CFB)在某些方面被认为是对传统燃煤方法的改进，以产生用于发电和加工或加热目的的蒸汽。关于循环流化床锅炉(CFB)的设计和运行的技术知识是广泛的，但在循环流化床锅炉燃烧的数学建模方面做得很少。具体来说，对于循环流化床燃烧过程中所涉及的化学反应，目前还没有一个基于图论的基本数学模型。本研究确定了循环流化床燃烧过程中几个重要的化学反应，这些化学反应对循环流化床燃烧过程具有重要意义。反应物和反应产物按种类分类，从反应中确定种类的数目。根据反应得到循环流化床燃烧过程的化学反应模型，用G (V, E)表示，其中V为代表种的节点集，E为代表种间催化关系的边集。图成功地转化为邻接矩阵A，它是非负的。图G (V, E)的分析表明，循环流化床的燃烧过程符合自催化集(ACS)理论。对其邻接矩阵的分析表明，G (V, E)的自催化图与Perron-Frobenius理论有一定的关系。

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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2012 International Conference on System Engineering and Technology (ICSET)

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