带压环境下泥浆-泡沫组合改良级配不良砂剪切特性研究

盾构穿越富水砂性地层时易出现排渣不畅或喷涌等风险,仅采用泡沫改良往往无法有效改善级配不良渣土的流动性与抗渗性,归因于泡沫易消散和流失,故须引入膨润土泥浆进行组合改良。正确认识土舱压力环境泥浆-泡沫组合改良级配不良砂土的剪切大变形行为有助于优化满足盾构安全掘进的渣土组合改良方案。因此,开展了泥浆-泡沫组合改良级配不良砂土的加压十字板剪切试验,研究结果表明:在土舱压力环境下,组合改良砂土的初始孔隙比和饱和度随泥浆注入比(bentonite injection ratio,简称BIR)增加而增大,有效应力降低,进而导致峰值强度和残余强度降低;然而剪切强度的剪切率相关性和有效内摩擦角对BIR的敏感性较弱;BIR增加还使大变形后改良砂土的屈服应力有所降低。此外,对比常压下流动性相似的3类不同改良砂土带压剪切大变形行为,表明带压环境下提高BIR或泡沫注入比(foam injection ratio,简称FIR)均可提高孔隙比且减小有效应力,但相较于纯泡沫改良砂土,组合改良砂土具有更低的有效应力和剪切强度。该类级配不良砂土的合适组合改良参数为FIR=20%、BIR=10%~15%。最后,细观成像结果揭示了膨润土对改良砂土剪切强度的双重削弱作用:(1)吸附砂土颗粒表面,降低颗粒间摩擦力;(2)延缓泡沫衰变,使得小粒径气泡较均匀分布于孔隙中,进而有效削弱土骨架强度。

钱江隧道盾构废弃泥浆的混凝分离

为了实现钱江隧道盾构废弃泥浆的无害化处理,对盾构废弃的砂土泥浆和粘土泥浆分别进行混凝分离的实验条件研究,结果表明:对于砂土泥浆,密度为1.20 g/cm3有利于实现高效的泥水分离;PAM作为絮凝剂的分离效果最好;混凝分离的最优化分离条件为:投药量为150 mg/L,pH为8左右,水力条件为以300 r/min搅拌1 min,再以80 r/min搅拌20 min。对于粘土泥浆,密度为1.10 g/cm3有利于实现高效的泥水分离;PAM作为絮凝剂的分离效果最好;混凝分离的最优化分离条件为:投药量为150 mg/L,pH为6左右,水力条件为以300 r/min搅拌1 min,再以80 r/min搅拌20 min。该实验为废弃泥浆的进一步处理奠定了基础。

Preparation of Rapid Hardening Mortars Using Ultrafine Portland Cement

During the hydration process, the Ultra-fine Cements present specific physical and chemical characteristics; they are, very short setting time and high heat release. For special applications, such as rapid hardening and early high strength mortars or concretes, these characteristics can be considered advantageous. Some commercial products used for concrete reinforcement and repairs are the Rapid Hardening Mortars, these mortars must develop a time of setting up to 3 h and an initial compressive strength of about 3.5 MPa once the hardening of the paste is reached. The objective of the present research work is to use Ultra-fine Cement for the preparation of a series of different Rapid Hardening Mortars （with different percentages of Ultra-fine Cement）, these mortars required the addition of a polycarboxylate-base specification F Superplasticizer. It was observed that the optimum water/cement （W/C） ratio for the hydration of the Ultra-fine Cements is W/C = 0.385. The Ultra-fine Cements were obtained by the High Energy Ball-milling technique at laboratory scale, 90% of the Particle Size Distribution is below 11 μm and the Blaine Specific Surface Area is over 9000 cm^2/g.