Aiming at the problems of high energy consumption,high emission,large impact on the surrounding environ-ment,high maintenance cost in traditional uranium tail slag processing methods,the cementing effect of Bacillus Pasteurii in-duce deposition on calcium carbonate uranium tail slag was studied. Results indicated that,adding Bacillus Pasteurii can effi-ciently cement uranium tail slag. Bacteria liquid uranium cementing effect on coarse tail slag is better than on fine grained ce-ment. The interval between cemented uranium tails slag are filled with CaCO3 ,which forms of different sizes of spherical aggre-gates,belongs to calcite type. The compressive strength on cementing body analysis results show that,as the consolidation time extension,compressive strength of cementing body gradually improves, when biological cementation sand column was com-pressed,it's broken from the both ends of cementing body. Compressive strength of coarse sand was obviously higher than that of the fine sand,and higher the filling,the higher the compressive strength. adding carbon nanotubes can markedly increase the compressive strength of the cement.%传统铀尾矿渣的处理方法存在高能耗、高排放、对周边环境影响大、维护费用高等问题,为此,考察了巴氏芽孢杆菌诱导沉积碳酸钙对铀尾矿渣的胶结效果.结果表明:添加巴氏芽孢杆菌可以有效胶结铀尾矿渣;菌液对粗粒铀尾矿渣的胶结效果好于对细粒的胶结效果;胶结后的铀尾矿渣间隙中填充的CaCO3形成大小不一的球状聚集体,属方解石类型.对胶结体进行抗压强度测定表明:随着胶结时间的延长,胶结体的抗压强度逐渐提高;生物法胶结的砂柱受到压缩时,是从两端起逐步被破坏;粗砂形成的胶结体的抗压强度明显高于细砂,装填高度越高抗压强度越强,碳纳米管的加入可以显著提高胶结体的抗压强度.
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