Two-Stage Combustion of PVC-Containing Wastes with HCI Recovery: An Experimental Assessment

Energy Sources Pub Date : 2005-06-01 DOI:10.1080/00908310490449388

L. Saeed, A. Tohka, R. Zevenhoven, M. Haapala

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引用次数: 4

Abstract

In this article, the design of a test facility for a two-stage combustion process is presented, and an assessment of waste PVC (polyvinyl chlorine) processing is reported. The test facility contained two fluidized bed reactors. The first reactor was a bubbling fluidized bed (BFB) that was operated in the temperature range 200–400°C and the second reactor was a circulating fluidized bed combustor (CFBC) that operated at 700–900°C. The process idea was based on the fact that PVC can be decomposed into recoverable HCl and low-chlorine or chlorine-free residue by heating to a temperature of around 300–350°C. The design of the test facility was based on a kinetic decomposition calculation for PVC, design procedures found in the literature, and on the theoretic analysis results from using a process simulation software (PROSIM). Details for all important parts of the process are discussed. Results from pyrolysis/de-hydrochlorination of the PVC and char combustion tests using a waste PVC sewage pipe are presented. It shows that PVC (chlorine content > 50%wt) can be converted into HCl and a char (chlorine content 2.6%wt) plus small amounts of by-products.

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含聚氯乙烯废弃物的两段燃烧与HCI回收:实验评估

本文介绍了两段燃烧试验装置的设计，并对废旧聚氯乙烯(聚氯乙烯)处理进行了评价。试验设施包括两个流化床反应器。第一个反应器为鼓泡流化床(BFB)，运行温度范围为200-400℃，第二个反应器为循环流化床燃烧室(CFBC)，运行温度范围为700-900℃。该工艺理念是基于这样一个事实，即PVC可以通过加热到300-350°C左右的温度分解成可回收的HCl和低氯或无氯残留物。试验装置的设计基于PVC的动力学分解计算、文献中的设计程序以及过程仿真软件(PROSIM)的理论分析结果。讨论了该过程中所有重要部分的细节。本文介绍了聚氯乙烯的热解/脱氯化氢和废聚氯乙烯污水管道炭燃烧试验的结果。结果表明，PVC(含氯量> 50%wt)可转化为HCl和焦炭(含氯量2.6%wt)以及少量副产物。

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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Energy Sources

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