电渗注浆加固土遗址片状剥离试验研究(Ⅲ)：回压试验与加固机制

doi:10.3724/1000-6915.jrme.2025.0047

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摘要片状剥离注浆体回压是电渗注浆法加固土遗址片状剥离的重要环节。研究通过预设2种不同回压方式的片状剥离加固现场试验，得到不同回压方式下注浆体的法向压缩量、注浆回压体的加固效果表征指标、回压功与能效比的变化规律，运用微结构分析以及主成分分析法从定性和定量两方面联合揭示了电渗注浆法加固片状剥离的加固机制。研究结果表明：不同回压方式下注浆体的法向压缩量、注浆回压体的加固效果表征指标、回压功随回压级别的增大而非线性增加，能效比随回压级别的增大而非线性衰减，其中以恒力回压25 kPa的表现综合最佳；SH固化提升颗粒黏结性，回压减小颗粒间隙，二者协同强化土颗粒界面连接性与结构密实性，显著提升了片状剥离加固效果。

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	崔凯1
	2
	李淑桓1
	2
	许鹏飞1
	2
	韦鑫1
	2
	文祥宇1
	2
	裴强强3

关键词 ：土力学, 片状剥离, 电渗注浆, 回压, 主成分分析, 加固机制

Abstract：Performing back compression on the scaling-off-stabilized grout body is a crucial aspect of reinforcing earthen sites affected by scaling through electro-osmotic grouting methods. This study involved on-site experiments to assess scaling-off reinforcement by implementing two distinct back compression modes. It evaluated the normal compression of the grouted body under varying back compression conditions, identified characterization indicators for the reinforcement effect of the back-compression-stabilized grout body, and analyzed the relationship between the work done by back compression and the energy efficiency ratio. Microstructural analysis and principal component analysis were employed to elucidate the reinforcement mechanism of the electro-osmotic grouting method from both qualitative and quantitative perspectives. The research findings indicate that the normal compression of the grouted body under different back compression modes, the characterization indicators of the reinforcement effect of the back-compression-stabilized grout body, and the work done by back compression all increase non-linearly with the rise in back-compression levels. Conversely, the energy efficiency ratio declines non-linearly as back-compression levels increase. Notably, the performance of back compression at a constant force of 25 kPa is found to be optimal in a comprehensive assessment. The synergistic effect of SH solution solidification and back compression enhances the interfacial connections between soil particles, establishes a stable combination with effective force chain transmission, and significantly improves resistance to scaling-off reinforcement.

Key words： soil mechanics scaling off electroosmotic grouting back compression principal component analysis reinforcement mechanism

引用本文:

崔凯1，2，李淑桓1，2，许鹏飞1，2，韦鑫1，2，文祥宇1，2，裴强强3. 电渗注浆加固土遗址片状剥离试验研究(Ⅲ)：回压试验与加固机制[J]. 岩石力学与工程学报, 2025, 44(10): 2793-2803.
CUI Kai1, 2, LI Shuhuan1, 2, XU Pengfei1, 2, WEI Xin1, 2, WEN Xiangyu1, 2, PEI Qiangqiang3. Electro-osmosis grouting reinforcement of scaling off earthen sites(III): Back compression experiment and reinforcement mechanism. , 2025, 44(10): 2793-2803.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0047 或 https://rockmech.whrsm.ac.cn/CN/Y2025/V44/I10/2793

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