岩土力学 ›› 2024, Vol. 45 ›› Issue (2): 364-374.doi: 10.16285/j.rsm.2023.0268

• 基础理论与实验研究 • 上一篇    下一篇

盾构淤泥质废弃黏土氧化镁固化-碳化试验及碳化机制研究

闵凡路1, 2, 3,申政1,李彦澄1,袁大军2,陈健3,李凯1   

  1. 1. 河海大学 土木与交通学院,江苏 南京 210098;2. 北京交通大学 土木建筑工程学院,北京 100091; 3. 中铁十四局集团有限公司,山东 济南 250014
  • 收稿日期:2023-03-04 接受日期:2023-07-08 出版日期:2024-02-11 发布日期:2024-02-06
  • 作者简介:闵凡路,男,1985年生,博士,教授,主要从事盾构隧道及环境岩土方面的研究与教学工作。minfanlu@126.com
  • 基金资助:
    国家自然科学基金(No. 52078189,No. 52378394);中央高校基本科研业务费专项资金(No. B230201037)

Solidification and carbonization experimental study on magnesium oxide in shield waste soil and its carbonization mechanism

MIN Fan-lu1, 2, 3, SHEN Zheng1, LI Yan-cheng1, YUAN Da-jun2, CHEN Jian3, LI Kai1   

  1. 1. College of Civil and Transportation Engineering, Hohai University, Nanjing, Jiangsu 210098, China; 2. School of Civil and Architectural Engineering, Beijing Jiaotong University, Beijing 100091, China; 3. China Railway 14th Bureau Group Co., Ltd., Jinan, Shandong 250014, China
  • Received:2023-03-04 Accepted:2023-07-08 Online:2024-02-11 Published:2024-02-06
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (52078189, 52378394) and the Fundamental Research Funds for the Central Universities of China (B230201037).

PDF (Chinese)

233

摘要: 盾构隧道施工产生的废弃土面临堆放、运输及处理等难题,将原材料丰富、生产耗能少、环境友好的MgO用于废弃土固化处理是一个值得探索的方法。通过改变MgO掺量am、养护龄期T、碳化时间H研究MgO固化-碳化淤泥质废弃黏土界限含水率w、无侧限抗压强度qu、弹性模量E50,结合微观形貌及矿物成分变化规律探讨其固化-碳化机制。结果表明:MgO固化-碳化具有明显的加固土体效果,加固效果随am、T呈先上升后趋于稳定的趋势,随H呈先上升后下降的趋势;不同am、T下,碳化4 h会使土体塑性指数IP降低57%以上,土体可塑性显著下降;不同am和T的固化-碳化土qu均在H为4 h时取得峰值,最高可达1.4 MPa,比碳化前强度提升了220%~350%;固化-碳化反应对土体的E50提升受am影响较大,当am超过9%时,碳化4 h试样的E50增幅在500%左右;MgO固化-碳化过程中水化产物、碳化产物不断生成和发育,形成网状、花朵聚集状的形貌,填充土颗粒间的孔隙,增强了土颗粒间的胶结作用,土体结构更为密实。该研究为长三角地区土压盾构产生的淤泥质废弃黏土的固化-碳化处理与再利用提供了思路。

关键词: 废弃土处理, 活性氧化镁, 加速碳化, 微观形貌, 矿物成分, 碳化机制

Abstract: The waste soil generated during shield tunnel construction poses a challenge in terms of stacking, transportation, and treatment. One promising approach is the use of magnesium oxide (MgO) for the solidification treatment of waste soil, as it is abundant in raw materials, has low production energy consumption, and is eco-friendly. The limit moisture content w, unconfined compressive strength qu and modulus of elasticity E50 of MgO solidified and carbonized mucky waste soil were studied by changing the MgO content am, curing age T, and carbonization time H. The solidification and carbonization mechanism of MgO-treated mucky waste soil was discussed in combination with the microstructure and the change rule of mineral composition. The results demonstrate that MgO solidification and carbonization have a significant reinforcing effect on the soil. The reinforcement effect initially increases and then stabilizes with increasing am and T, while it shows an initial increase followed by a decrease with H. Carbonization for 4 hours reduces the soil plasticity index (IP) by more than 57% under different am and T conditions, leading to a significant reduction in soil plasticity. The qu of solidified and carbonized soils reaches a peak value at H of 4 hours, with values up to 1.4 MPa, which is 220%–350% higher than the strength before carbonization. The effect of solidification and carbonization reaction on the increase in E50 of the soil mass is greatly influenced by am. When am exceeds 9%, the E50 increase of the sample carbonized for 4 hours exceeds 500%. During the process of MgO solidification and carbonization, hydration products and carbonization products are continuously generated and developed. They form a network and flower-like microstructure, filling the pores between soil particles, enhancing cementation between soil particles, and densifying the soil structure. The research provides insights into the efficient and eco-friendly treatment and reuse of mucky waste soil produced by earth pressure shield in the Yangtze River Delta.

Key words: waste soil treatment, active magnesium oxide, accelerated carbonization, microstructure, mineral composition, carbonation mechanism

中图分类号: TU 452
[1] 宋宇, 丁松, 陈凯斌, 江嘉辉, 杨承琨, 陈玉洁, 张建伟, 郑俊杰, . 碳化作用下活性氧化镁固化锌污染土的溶出特性研究[J]. 岩土力学, 2025, 46(S1): 92-105.
[2] 孙银磊, 李志妃, 陈妍歌, 杜清如, 田珂萌, 陈俊磊, 张先伟, . 矿物成分对红土土-水特性的影响[J]. 岩土力学, 2025, 46(10): 3117-3131.
[3] 田威, 王肖辉, 云伟, 程续. 基于不同后处理方法的砂型3D打印类岩石试样力学性能研究[J]. 岩土力学, 2023, 44(5): 1330-1340.
[4] 段玲玲, 邓华锋, 齐豫, 李冠野, 彭萌. 水-岩作用下单裂隙灰岩渗流特性演化规律研究[J]. 岩土力学, 2020, 41(11): 3671-3679.
[5] 黄涛, 方祥位, 张伟, 申春妮, 雷宇龙, . 活性氧化镁−微生物固化黄土试验研究[J]. 岩土力学, 2020, 41(10): 3300-3306.
[6] 徐云山, 孙德安, 曾召田, 吕海波, . 膨润土热传导性能的温度效应[J]. 岩土力学, 2020, 41(1): 39-45.
[7] 赵波, 张广清, 唐梅荣, 庄建满, 林灿坤, . 长期注水对致密砂岩油藏岩石力学 性质影响机制研究[J]. 岩土力学, 2019, 40(9): 3344-3350.
[8] 张 帆,胡 维,郭翰群,胡大伟,盛 谦,邵建富,. 热处理后花岗岩纳米压痕试验研究[J]. , 2018, 39(S1): 235-243.
[9] 邓华锋,王晨玺杰,李建林,张吟钗,王 伟,张恒宾. 加载速率对砂岩抗拉强度的影响机制[J]. , 2018, 39(S1): 79-88.
[10] 刘松玉,曹菁菁,蔡光华, . 活性氧化镁碳化固化粉质黏土微观机制[J]. , 2018, 39(5): 1543-1552.
[11] 苏承东,韦四江,秦本东,杨玉顺,. 高温对细砂岩力学性质影响机制的试验研究[J]. , 2017, 38(3): 623-630.
[12] 李 毅, . 岩石裂隙的非饱和渗透特性及其演化规律研究[J]. , 2016, 37(8): 2254-2262.
[13] 于博伟,杜延军,刘辰阳,薄煜琳. 活性MgO碱性激发粒化高炉矿渣固化黏土的抗硫酸盐侵蚀试验研究[J]. , 2015, 36(S2): 64-72.
[14] 谈云志,喻 波,刘 云,左清军,胡莫珍,郑 爱. 重塑石灰土的强度恢复方法与机制初探[J]. , 2015, 36(3): 633-639.
[15] 伍 艳 ,任海平 ,王玮屏 ,兰 雁 ,沈细中 , . 总氮对土物理力学性能影响的试验研究[J]. , 2014, 35(8): 2278-2285.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
版权所有 © 《岩土力学》编辑部
地址:湖北武汉武昌小洪山中国科学院武汉岩土力学研究所(430071) 邮编:200042 电话:027-87198484 E-mail: ytlx@whrsm.ac.cn
本系统由北京玛格泰克科技发展有限公司设计开发