三元复合胶凝体系中硅灰和粉煤灰反应程度的确定<sup>*</sup>

doi:10.11901/1005.3093.2013.480

材料研究学报

2014, Vol. 28

Issue (3): 197-203 DOI: 10.11901/1005.3093.2013.480

本期目录 | 过刊浏览

三元复合胶凝体系中硅灰和粉煤灰反应程度的确定^*

姚武(

),吴梦雪,魏永起

同济大学先进土木工程材料教育部重点实验室上海 201804

Determination of Reaction Degree of Silica Fume and Fly Ash in a Cement - silica fume - fly ash Ternary Cementitious System

Wu YAO(

),Mengxue WU,Yongqi WEI

Key Laboratory of Advanced Civil Engineering Materials(Tongji University), Ministry of Education, Shanghai 201804

引用本文:

姚武,吴梦雪,魏永起. 三元复合胶凝体系中硅灰和粉煤灰反应程度的确定^*[J]. 材料研究学报, 2014, 28(3): 197-203.
Wu YAO, Mengxue WU, Yongqi WEI. Determination of Reaction Degree of Silica Fume and Fly Ash in a Cement - silica fume - fly ash Ternary Cementitious System[J]. Chinese Journal of Materials Research, 2014, 28(3): 197-203.

全文: PDF(722 KB) HTML

摘要:

采用选择性溶解法和非蒸发水量法定量研究了不同龄期、不同掺量水泥-硅灰-粉煤灰三元复合胶凝体系中矿物掺合料的反应进程。用同细度同掺量的惰性石英粉替代粉煤灰以消除粉煤灰的稀释效应和异核成核效应, 得到三元复合胶凝体系中硅灰的反应程度; 根据三元复合胶凝体系中矿物掺合料的整体反应程度, 计算了粉煤灰的反应程度。结果表明, 硅灰的火山灰反应在复合胶凝体系水化1 d时就已经开始, 并呈现早期快而后期慢的特点; 而粉煤灰的火山灰效应, 在7 d以后才开始并加快。在三元复合胶凝体系中, 硅灰和粉煤灰的反应程度均随着粉煤灰掺量的提高而降低。

关键词 ：材料科学基础学科, 三元复合胶凝体系, 粉煤灰, 硅灰, 反应程度, 选择性溶解

Abstract：

The reaction processes of mineral admixtures in a cement-silica fume-fly ash ternary cementitious system aged for different time were quantitatively studied by means of selective dissolution and non-evaporative water content methods. To determine separately the degree of pozzolanic reaction for silica fume in the ternary system, fly ash was replaced by the inert quartz powder with the same fineness and same dosage in order to eliminate the dilution effect and heterogeneous nucleation effect. Then the reaction degree of fly ash can be calculated from the total reaction degree of all the admixtures in the system. The test results demonstrated that only 1 d after the beginning of the hydration, the pozzolanic reaction for silica fume already started, and the reaction exhibited a fast rate in the early stage but a slow one in the later stage. However, the same reaction with a rapidly increasing rate for fly ash just began only 7 d after the beginning of the hydration. In the ternary cementitious system, the hydration degrees for both silica fume and fly ash were reduced with the increasing fly ash content.

Key words： foundational discipline in materials science ternary cementitious system fly ash silica fume reaction degree selective dissolution

收稿日期: 2013-07-10

基金资助:* 国家重点基础研究计划2009CB62305 和上海市国际科技合作项目12230708700 资助。

作者简介:

本文联系人: 姚武, 教授

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表1 试验原材料的化学组成

图1 水泥、粉煤灰、硅灰和石英粉的粒度分布

表2 试样的编号及配合比

表3 EDTA-AS与SD-PA选择性溶解测试结果的对比

表4 原材料的选择性溶解不溶物含量

表5 不同龄期试样的非蒸发水量

图2 试样C、C-4FA及C-4Q中水泥水化程度

表6 三元复合胶凝体系中硅灰和粉煤灰的水化程度

图3 不同水化龄期时硅灰的反应程度

图4 不同水化龄期时粉煤灰的反应程度

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