干湿循环作用对水泥基复合充填材料的影响

Effects of dry-wet circulation on cement-based composite filling materials

  • 摘要: 为探究干湿循环对水泥基复合充填材料长期稳定性的影响,以水灰比4∶1水泥基复合材料为研究对象,借助ETM力学试验系统、X射线衍射及扫描电镜扫描装置,对不同干湿循环次数下“饱水”状态和“失水”状态的试件进行单轴抗压强度试验,并通过物相分析及微观结构探讨干湿循环对其影响机理。结果表明,随着干湿循环次数的增加,“饱水”状态下失水率逐渐增大,含水率和容重呈下降趋势,峰值强度先增加后减小,增幅最高达9%;“失水”状态下失水率、含水率和容重均变化不大,峰值强度较初始状态有所降低,最高达13.5%;两种状态弹性模量和残余强度都呈下降趋势。通过机理分析发现,“干”过程中碳化反应是材料强度降低的主要原因,而“湿”过程中吸水将部分碳酸钙等物质转化为具有承载能力的钙矾石(AFT)和碳硫硅钙石(TSA)是材料强度恢复的主要原因,但恢复能力有限,长期的干湿循环会对水泥基复合充填材料稳定性产生不利影响。

     

    Abstract: In recent years, cement-based composite materials have been widely used in mine filling, which can well solve the hidden danger of goaf collapse. However, when the water table and surrounding rock moisture content change, the filling materials will be in the process of dry and wet alternation, which will affect the long-term stability of the filling materials and goaf. In order to explore the influence of dry and wet cycles on the long-term stability of cement-based composite filling materials, taking water-cement ratio 4∶1 cement-based composites as the research object and using ETM mechanical test system, X-ray diffraction (XRD) and scanning electron microscopy (SEM) device, uniaxial compressive strength tests were carried out in the state of "water saturation" and "water loss" under different dry-wet circulation. The influence mechanism of dry-wet circulation was discussed by phase analysis and microstructure. The results show that as the number of dry-wet circulation increases, the loss rate increases gradually while the water content and bulk density decrease, the peak intensity first increases and then decreases, and the increase is as high as 9% under the saturated state. The water loss rate, water content and bulk density do not change much under the condition of "water loss", while the peak strength decreases from the initial state to up to 13.5%. The elastic modulus and residual strength of the two states show a downward trend. Through mechanism analysis, it is found that carbonation reaction is the main reason for material strength reduction in the "dry" process, while the CaCO3 and other materials are converted into ettringite (AFT) and thaumasite (TSA) with some bearing capacity during the absorbing water process in "wet" process, which is the main reason for the strength recovery of materials. However, the recovery ability is limited, and the long-term dry-wet circulation will adversely affect the stability of cement-based composite filling material.

     

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