Solar thermal treatment of non-metallic minerals: The potential application of the SOLPART technology

SOLARPACES 2018: International Conference on Concentrating Solar Power and Chemical Energy Systems Pub Date : 2019-07-26 DOI:10.1063/1.5117682

J. Baeyens, Huili Zhang, Weibin Kong, P. Dumont, G. Flamant

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引用次数: 9

Abstract

The solar horizontal bubbling fluidized bed concept developed within the SOLPART research project can be used as a solar receiver-reactor. This application offers a considerable industrial potential, as illustrated in the paper further to different experiments and industrial contacts. The most demanding application is the calcination of limestone, either as pure calcite, or as 85% mix in cement raw meal. The decomposition temperature exceeds 850 °C (nearly the application limits of refractory steel alloys). Other calcinations (e.g. dolomite, gypsum, phosphate rock, meta-kaolin, clays, etc.) are less demanding since occurring at a lower calcination temperature and with an endothermic reaction heat that is significantly lower than the reaction heat of CaCO3, which is therefore considered as a relevant test case.The solar horizontal bubbling fluidized bed concept developed within the SOLPART research project can be used as a solar receiver-reactor. This application offers a considerable industrial potential, as illustrated in the paper further to different experiments and industrial contacts. The most demanding application is the calcination of limestone, either as pure calcite, or as 85% mix in cement raw meal. The decomposition temperature exceeds 850 °C (nearly the application limits of refractory steel alloys). Other calcinations (e.g. dolomite, gypsum, phosphate rock, meta-kaolin, clays, etc.) are less demanding since occurring at a lower calcination temperature and with an endothermic reaction heat that is significantly lower than the reaction heat of CaCO3, which is therefore considered as a relevant test case.

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非金属矿物的太阳能热处理:SOLPART技术的潜在应用

SOLPART研究项目中开发的太阳能水平鼓泡流化床概念可以用作太阳能接收器-反应器。这一应用提供了相当大的工业潜力，如论文进一步说明了不同的实验和工业接触。最苛刻的应用是石灰石的煅烧，要么作为纯方解石，要么作为85%的水泥生料混合。分解温度超过850℃(接近耐火钢合金的应用极限)。其他煅烧(如白云石、石膏、磷灰岩、偏高岭土、粘土等)要求较低，因为煅烧温度较低，吸热反应热明显低于碳酸钙的反应热，因此被认为是相关的测试案例。SOLPART研究项目中开发的太阳能水平鼓泡流化床概念可以用作太阳能接收器-反应器。这一应用提供了相当大的工业潜力，如论文进一步说明了不同的实验和工业接触。最苛刻的应用是石灰石的煅烧，要么作为纯方解石，要么作为85%的水泥生料混合。分解温度超过850℃(接近耐火钢合金的应用极限)。其他煅烧(如白云石、石膏、磷灰岩、偏高岭土、粘土等)要求较低，因为煅烧温度较低，吸热反应热明显低于碳酸钙的反应热，因此被认为是相关的测试案例。

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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SOLARPACES 2018: International Conference on Concentrating Solar Power and Chemical Energy Systems

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