碱性和无碱液体速凝剂促凝早强作用机理对比研究

硅酸盐通报 ›› 2022, Vol. 41 ›› Issue (12): 4172-4179.

所属专题：水泥混凝土

碱性和无碱液体速凝剂促凝早强作用机理对比研究

苏美娟, 王子明, 赵攀, 刘晓

北京工业大学材料与制造学部,北京 100124

收稿日期:2022-07-10 修订日期:2022-08-30 出版日期:2022-12-15 发布日期:2023-01-11
通信作者: 王子明,博士,教授。E-mail:wangziming@bjut.edu.cn
作者简介:苏美娟(1997—),女,硕士研究生。主要从事水泥速凝剂的研究。E-mail:18706759068@163.com

Comparative Study on Mechanism of Quick Setting and Hardening Accelerating Effects of Alkaline and Alkali-Free Liquid Accelerators

SU Meijuan, WANG Ziming, ZHAO Pan, LIU Xiao

Faculty of Materials and Manufacturing, Beijing University of Technology, Beijing 100124, China

Received:2022-07-10 Revised:2022-08-30 Online:2022-12-15 Published:2023-01-11

摘要/Abstract

摘要： 碱性和无碱速凝剂掺入水泥后的水化机理不同,导致应用性能存在明显差异。本文通过测试凝结时间和砂浆抗压强度等宏观性能对比了两种速凝剂的应用性能,并通过水化放热分析、XRD定量分析、热重分析和SEM微观形貌观察等微观方法综合分析了两者的早期水化历程。结果表明:碱性速凝剂加入水泥后,[Al(OH)₄]^-加快了水泥中石膏的消耗速度,水化初期生成大量钙矾石(AFt),促进了硅酸三钙(C₃S)矿物的水化,缩短了水泥浆体的凝结时间并提高了砂浆的早期抗压强度,但石膏的加速消耗也使得单硫型水化硫铝酸钙(AFm)和水化铝酸钙(C-A-H)等水化产物提前生成,影响了水泥基材料的后期抗压强度发展;无碱速凝剂加入水泥后,[Al(OH)₄]^-和SO^2-₄在液相中生成了大量AFt,促进了铝酸三钙(C₃A)和C₃S矿物的水化,影响了氢氧化钙(CH)的结晶析出。值得注意的是,SO^2-₄不仅促进了C₃A生成AFt的过程,也延缓了水泥中石膏的消耗及AFm和C-A-H等产物的生成,因此无碱速凝剂的加入除了明显提高早期抗压强度外,后期28 d抗压强度也不受影响。

关键词: 速凝剂, 速凝机理, 早期抗压强度, 钙矾石, 石膏, 水化热

Abstract: Due to the different hydration mechanism ofcement mixed with alkaline and alkali-free accelerators, there are obvious differences in application performance. In this paper, the application performance and early hydration process of two accelerators were comprehensively analyzed through the test of macroscopic properties such as setting time and compressive strength of mortar, and the microscopic methods such as hydration heat analysis, XRD quantitative analysis, thermogravimetric analysis and scanning electron microscope observation. The results show that the [Al(OH)₄]^- accelerates the consumption rate of gypsum in cement and a large amount of ettringite (AFt) are generated in the initial hydration stage after the alkaline accolerator is added to the cement. At the same time, the alkaline accolerator also promotes the hydration of C₃S minerals, shortens the setting time of cement paste and improves the early compressive strength of mortar. However, the accelerated consumption of gypsum also makes the hydration products such as monosulfur-type hydrated calcium sulfoaluminate (AFm) and hydrated calcium aluminate (C-A-H) form in advance, which negatively affects the long-term compressive strength development of cement-based materials. While the alkali-free accelerator is added to the cement, the [Al(OH)₄]^- and SO^2-₄ form a large amount of AFt in the liquid phase, which promotes the hydration of C₃A and C₃S minerals, and affects the crystallization and precipitation of Ca(OH)₂(CH). It is worth noting that SO^2-₄ from the alkali-free accolerator not only promotes the process of C₃A to generate AFt, but also delays the consumption of gypsum in cement and the formation of hydration products such as AFm and C-A-H. Therefore, the 28 d compressive strength is not negatively affected in addition to the obvious improvement of the early compressive strength.

Key words: accelerator, quick setting mechanism, early compressive strength, ettringite, gypsum, hydration heat

中图分类号:

TU528.53

苏美娟, 王子明, 赵攀, 刘晓. 碱性和无碱液体速凝剂促凝早强作用机理对比研究[J]. 硅酸盐通报, 2022, 41(12): 4172-4179.

SU Meijuan, WANG Ziming, ZHAO Pan, LIU Xiao. Comparative Study on Mechanism of Quick Setting and Hardening Accelerating Effects of Alkaline and Alkali-Free Liquid Accelerators[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2022, 41(12): 4172-4179.

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碱性和无碱液体速凝剂促凝早强作用机理对比研究

Comparative Study on Mechanism of Quick Setting and Hardening Accelerating Effects of Alkaline and Alkali-Free Liquid Accelerators

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