Development of High Strength Fly Ash Glass-ceramics by Concrete Sludge Addition

Journal of High Temperature Society Pub Date : 2009-01-21 DOI:10.7791/JHTS.35.45

K. Ikeda, A. Yoshikawa, A. Hiratsuka, R. Tsujino, H. Kinoshita, Ryusuke Kawamura, Y. Nakayama, M. Iguchi

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引用次数: 1

Abstract

A large amount of fly ash is exhausted from the thermal powder plant and it is a poisonous substance including the heavy metals and dioxin. The glass solidification is an effective method as one of the waste solidification technologies. Further, producing new materials by mixing together more than two kinds of raw materials is a more useful method. However, a number of trials are required in this method. We selected glass-ceramics with the crystal structure of an Anorthite (CaO·Al 2 O 3 ・ 2SiO 2 ), fly ash as inorganic wastes and concrete sludge for construction materials. It is necessary to clarify the optimum production method. Batches were prepared by mixing these raw materials with various weight ratios. Glass samples were produced by melting the batches at 1450 ℃ and quenching. They were reheated in the region of 950-1100 ℃ to make into glass-ceramic. The properties of obtained glass-ceramics were examined by XRD analysis, SEM observation, and some material tests for the strength, hardness, toughness, and so on. The XRD analysis and SEM observation showed that the crystallized phase of the produced glass-ceramics were identified as an Anorthite. The material tests showed that the Vickers hardness was very high, while the chemical resistance was relatively low.

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掺加混凝土污泥制备高强度粉煤灰微晶玻璃

热粉厂排放的大量粉煤灰是含重金属和二恶英的有毒物质。玻璃固化是一种有效的废弃物固化技术。此外，通过混合两种以上的原材料来生产新材料是一种更有用的方法。然而，这种方法需要进行大量的试验。我们选择了具有钙长石(CaO·al2o3·2sio2)晶体结构的微晶玻璃，粉煤灰作为无机废物，混凝土污泥作为建筑材料。有必要明确最佳生产方法。将这些原料以不同的重量比混合制备成批。采用1450℃熔融淬火法制备玻璃样品。在950-1100℃范围内再加热制成玻璃陶瓷。通过XRD分析、SEM观察和材料强度、硬度、韧性等测试对所得微晶玻璃的性能进行了表征。XRD分析和SEM观察表明，所制微晶玻璃的结晶相为钙长石。材料试验表明，其维氏硬度很高，耐化学性较低。

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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Journal of High Temperature Society

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