Effect of Phosphorus and Fluorine on Hydration Process of Tricalcium Silicate and Tricalcium Aluminate

By means of hydration heat, XRD and SEM, effect of phosphorus and fluorine （P205 and F-） in phosphorous slag on hydration process of tricalcium silicate （C3S） and tricalcium aluminate （C3A） was explored. The results indicated that the early hydration exothermic rate of C3S and C3A was obviously lowered by P205 and F- in phosphorous slag, the second peak occurring time of C3A was delayed by 0.9 h, the exothermal output of C3S was reduced by 25.04% and the time of accelerating stage was postponed by 0.86 h. The early hydration degree of C3S and C3A was also decreased. Due to the influence of P205 and F, more pores and thinner crystals can be observed in the microstructure of hardened paste and the chance of cracks was reduced.

新型水泥基材料富镁C_(3)A对氮磷的共去除

将镁掺杂进水泥基材料铝酸三钙(C_(3)A)制得新型富镁铝酸三钙(Mg@C_(3)A)应用于水体氨氮(NH_(4)^(+)-N)和磷(PO_(4)^3(-))的共去除.通过批量实验,考察了Mg@C_(3)A投加量、氮磷浓度、溶液pH值、温度等因素对NH_(4)^(+)-N、PO_(4)^3(-)共去除的影响,并阐述了共去除机制.结果表明:Mg@C_(3)A是由Mg掺杂C_(3)A同构体和表面MgO组成,其中Mg的引入未改变C_(3)A晶体结构和基本形貌.Mg@C_(3)A材料对NH_(4)^(+)和PO_(4)^3(-)具有良好的共去除效果.当Mg@C_(3)A的投加量为3g/L,NH_(4)^(+)和PO_(4)^3(-)的最大去除量分别为38.4,78.9mg/g;温度升高有利于Mg@C_(3)A对NH_(4)^(+)和PO_(4)^3(-)的共去除,而高pH值可促进NH_(4)^(+)的去除.Mg@C_(3)A材料对NH_(4)^(+)的去除主要是OH-的中和作用和鸟粪石的沉淀作用主导,PO_(4)^3(-)主要是与Mg_(2+)或Al^(3+)结合形成鸟粪石或磷酸铝被去除.

水泥基材料铝酸三钙对水体重金属去除机制研究

电镀废水中的Pb(Ⅱ)、Zn(Ⅱ)严重危害人体健康和生态环境,经济有效地处理废水中的Pb(Ⅱ)、Zn(Ⅱ)对保护人体健康和生态环境尤为重要。采用水泥基材料铝酸三钙(C_(3)A)去除Pb(Ⅱ)和Zn(Ⅱ),考察了反应时间、初始质量浓度及溶液pH对去除的影响;且结合反应后固体产物微观表征和宏观溶液组分分析,探讨了Pb(Ⅱ)和Zn(Ⅱ)的去除机制。结果表明:C_(3)A对Pb(Ⅱ)和Zn(Ⅱ)的去除分别符合准二级动力学模型(R^(2)=0.9849)和准一级动力学模型(R^(2)=0.9539),C_(3)A对Pb(Ⅱ)和Zn(Ⅱ)的最大去除量分别为8.44、13.73 mmol·g^(-1);高pH值有利于C_(3)A对金属离子的去除。C_(3)A对Pb(Ⅱ)的去除主要是碱式硝酸铅的沉淀作用和无定形氢氧化铝的絮凝作用主导,Zn(Ⅱ)主要是通过阳离子交换与沉淀作用形成ZnAl-LDH被去除。

140℃高温下SiO_(2)晶态对硅酸三钙水化产物的影响

目前,在G级油井水泥中加入SiO_(2)是降低其水化产物在温度高于110℃下力学性能衰退的主要手段。然而,SiO_(2)晶体形态不同,导致水泥水化产物不同,耐高温性能也不同。为了探究SiO_(2)晶体形态对水泥水化产物的影响,笔者以油井水泥的主要成分硅酸三钙(C_(3)S)为研究对象,采用核磁共振、X射线衍射、热重分析和扫描电镜以及能谱等手段分析了晶体SiO_(2)(石英砂)和非晶体SiO_(2)(微硅)对C_(3)S水化产物的影响。结果表明:SiO_(2)通过填充孔隙以及转化水化产物,能有效防止C_(3)S水化产物在高温下强度衰退,以及孔隙度和渗透率的增加。微硅比石英砂更活跃,能迅速与Ca(OH)_(2)发生火山灰反应生成次生水化硅酸钙。此外,SiO_(2)还能将高钙硅比的水化硅酸钙(针硅钙石(Ca_(2)SiO_(3)(OH)_(2))、羟硅钙石(Ca_(6)Si_(2)O_(7)(OH)_(6))和重硅钙石(Ca_(5)(SiO_(4))_(2)(OH)_(2)))转化为低钙硅比的水化硅酸钙(雪硅钙石(Ca_(5)Si_(6)O_(16)(OH)_(2)·4H_(2)O)、白钙沸石(Ca_(4)Si_(6)O_(15)(OH)_(2)·3H_(2)O)、水硅钙石(CaSi_(2)O_(5)·2H_(2)O)和新硅钙石(Ca_(3)Si_(6)O_(12)(OH)_(6)·5H_(2)O))。