SYNERGETIC USE OF LIGNITE FLY ASH AND METALLURGICAL CONVERTER SLAG IN GEOPOLYMER CONCRETE

IF 1.3 Q3 Earth and Planetary Sciences Mining Science Pub Date : 2014-08-27 DOI:10.5277/MS142104

G. Mucsi, Á. Rácz, Z. Molnár, R. Szabó, Imre Gombkoto, Á. Debreczeni

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引用次数: 7

Abstract

The application and utilization of the industrial wastes and by-products in the construction industry is a key issue from an environmental and economic point of view. The increased use of lignite has substantially increased the available quantities of lignite fired power plant fly ash, which can be main- ly classified as class C fly ash. The utilization of such raw material however has some difficulties. In the present paper lignite fired power station fly ash and metallurgical converter slag were used for the pro- duction of geopolymer concrete. The fly ash was used as a geopolymer based binder material, and a con- verter slag as aggregate, thus created a geopolymer concrete which contains mainly industrial wastes. As preliminary test experimental series were carried out using andesite as aggregate. The optimal aggre- gate/binder ratio was determined. The effect of the amount of alkaline activator solution in the binder, the aggregate type on the geopolymer concretes' compressive strength and density was investigated. Fur- thermore, the physical properties - freeze-thaw resistance and particle size distribution - of the applied aggregates were measured as well. As a result of the experiments it was found that physical properties of the andesite and converter slag aggregate was close. Therefore andesite can be replaced by converter slag in the concrete mixture. Additionally, geopolymer concrete with nearly 20 MPa compressive strength was produced from class C fly ash and converter slag.

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褐煤粉煤灰与冶金转炉炉渣在地聚合物混凝土中的协同应用

从环境和经济的角度来看，工业废物和副产品在建筑业中的应用和利用是一个关键问题。随着褐煤使用量的增加，褐煤电厂粉煤灰的可用量大大增加，主要可归为C类粉煤灰。然而，这种原料的利用存在一些困难。以褐煤电厂粉煤灰和冶金转炉炉渣为原料生产地聚合物混凝土。粉煤灰作为地聚合物基粘结剂，转炉炉渣作为骨料，制成了以工业废弃物为主的地聚合物混凝土。作为初步试验，以安山岩为集料进行了一系列试验。确定了最佳的集料/粘结剂比。研究了粘结剂中碱性活化剂溶液的掺量、骨料类型对地聚合物混凝土抗压强度和密度的影响。此外，还测量了所施骨料的物理性能——抗冻融性能和粒径分布。试验结果表明，安山岩与转炉矿渣骨料的物性相近。因此，安山岩可以用转炉渣代替混凝土混合料中的安山岩。以C级粉煤灰和转炉炉渣为原料，制备了抗压强度接近20 MPa的地聚合物混凝土。

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来源期刊

Mining Science MINING & MINERAL PROCESSING-

CiteScore

2.40

自引率

0.00%

发文量

审稿时长

24 weeks

期刊介绍： Mining Scince. Scientific Papers of the Department Geoengineering, Mining and Geology of the Wroclaw University of Technology. The journal publishes original papers on mining and geology, geo-engineering and the related issues. The journal is devoted to the following topics: fundamental research in mining, underground and open-cast mining technologies, blasting technology, design and construction of mines, geomechanics and geotechnical engineering, mine ventilation, fluid mechanics and its application in mining, mining machinery and condition monitoring, mineral processing, environmental protection and waste utilization. The journal also accepts papers concerns geoengineering which is a sciences covering mining construction, geotechnical engineering, GIS, and earth sciences.