CO_(2)矿化养护建筑垃圾再生砖的性能研究

以建筑垃圾为主要原材料制备了建筑垃圾再生砖,研究了CO_(2)矿化养护时间(2、6、12、24 h)和CO_(2)浓度(20%、30%、50%)对建筑垃圾再生砖抗压强度和固碳率的影响。结果表明:随着CO_(2)矿化养护时间的增加,试件的抗压强度和固碳率增大;随着CO_(2)浓度的增加,试件的抗压强度在CO_(2)矿化养护6 h内呈增大趋势,在CO_(2)矿化养护12 h后呈先增大后减小的趋势;试件的固碳率随着CO_(2)浓度的增加而增大;综合考虑成本、抗压强度和固碳率,推荐CO_(2)矿化养护时间为12 h,CO_(2)浓度为20%。

基于SEM和ICT的建筑垃圾再生砖细观破坏机理

以建筑垃圾再生砖为研究对象,进行了单轴压缩试验,拟合了应力-应变曲线,采用扫描电镜(SEM)对再生砖的细观结构进行观测,利用工业CT获得了再生砖压缩破坏过程中的裂纹分布特征,并借助分形理论进行分析裂纹演化特征。研究结果表明:建筑垃圾再生砖具有较大的孔隙率,存在诸多的初始缺陷,裂纹容易最先在这些薄弱环节出现。水泥石将骨料包裹起来形成筋络结构可分割破坏区,延缓裂缝的伸展及汇聚过程,可有效提高再生砖的强度。同时再生砖具显著的不均匀性,在荷载作用下不同断面的分形维数的变化规律有较大的差异,断面上平均强度越高,分形维数的变化越平缓,反之则变化要更剧烈,但整体物理性能与混凝土是相似的。CT和SEM结合可有效地对建筑材料的微观结构和破坏机理进行分析,为进一步揭示再生砖的细观损伤破裂机理奠定基础。

外加剂对建筑垃圾再生砖早强性能的影响

选用两种减水剂和四种早强剂对建筑垃圾再生砖进行改性,研究了其掺量对建筑垃圾再生砖早期抗压强度(8 h)的影响,并对不同龄期的建筑垃圾再生砖进行了XRD表征。实验结果显示:适量减水剂的添加可促进水化反应的进行,并抑制钙矾石晶核的过快生长,当聚羧酸系减水剂掺量为0.3%时,相应再生砖早期抗压强度可达10.45 MPa。早强剂NaCl、Na_2SiO_3?9H_2O和Na_2CO_3可降低水化反应过程中Ca^(2+)的浓度,减缓钙矾石晶核的生长速度,其中NaCl添加量为2%时,再生砖早期抗压强度可增加20%以上。而添加三乙醇胺(TEOA)的早龄期建筑垃圾再生砖中水化硅酸钙的XRD峰强度较低,后期强度则较高,说明水化硅酸钙的形成具有一定迟滞性。

再生砖砌体砖混结构房屋抗震性能试验研究

为了研究再生砖砌体砖混结构房屋的抗震性能,采用Taft地震波对一个用再生砖砌成的四层、1/3缩尺比例的房屋模型进行振动台试验,观察记录了在不同强度和烈度下结构的地震反应和破坏机理,并测得各测点加速度反应的最大值、各楼层相对底层的最大位移和位移时程曲线。试验结果表明,用再生砖砌成的房屋经合理的设计可满足砖混结构"小震不坏,中震可修,大震不倒"的要求,具有良好的抗震性能,并建议在结构承重墙体内设置水平配筋,以减轻墙体的脆性,增加其延性,进而提高该结构的抗震性能。

Controlled low-strength material incorporating recycled fine aggregate from urban red brick based construction waste

Sixteen controlled low-strength material( CLSM)mixtures with various cement-to-sand( C/Sa) ratios and water-to-solid( W/So) ratios were prepared using recycled fine aggregate from urban red brick based construction waste.The fluidity and bleeding of the fresh CLSM mixtures were measured via the modified test methods, and the hardened CLSM mixtures were then molded to evaluate their compressive strength and durability. The results showthat the fluidity of the fresh CLSM mixtures is 105 to 227 mm with the corresponding bleeding rate of 3. 7% to 15. 5%, which increases with the increase in fluidity. After aging for 28 d,the compressive strength of the hardened CLSM mixtures reaches 1. 15 to 13. 96 M Pa, and their strength can be further enhanced with longer curing ages. Additionally, the strength increases with the increase of the C/Sa ratio, and decreases with the increase of the W/So ratio under the same curing age. Based on the obtained compressive strength, a fitting model for accurately predicting the compressive strength of the CLSM mixtures was established, which takes into account the above two independent variables( C/Sa and W/So ratios).M oreover, the durability of the hardened CLSM mixtures is enhanced for samples with higher C/Sa ratios.