岩土力学 ›› 2026, Vol. 47 ›› Issue (1): 171-182.doi: 10.16285/j.rsm.2025.0126CSTR: 32223.14.j.rsm.2025.0126

• 基础理论与实验研究 • 上一篇    下一篇

高温条件下膨润土缓冲层材料导热性能的热老化时间效应

曾召田1,林铭宇1,孙德安2,邵捷昇1, 2,曹珊珊1,赵长友1,靳琳1   

  1. 1.桂林理工大学 广西岩土力学与工程重点实验室,广西 桂林 541004;2.上海大学 土木工程系,上海 200444
  • 收稿日期:2025-02-07 接受日期:2025-05-28 出版日期:2026-01-11 发布日期:2026-01-08
  • 通讯作者: 孙德安,男,1962年生,博士,教授,博士生导师,主要从事非饱和土与特殊土力学的研究和教学工作。E-mail: sundean@shu.edu.cn
  • 作者简介:曾召田,男,1981年,博士,教授,博士生导师,主要从事环境岩土工程及非饱和土力学研究工作。E-mail: zengzhaotian@glut.edu.cn
  • 基金资助:
    国家自然科学基金(No.42167020);广西自然科学基金(No.2023GXNSFAA026187);广西研究生教育创新计划项目(No.YCSW2024360)

Temporal influence of thermal ageing on thermal conductivity of bentonite buffer layer materials under high temperature conditions

ZENG Zhao-tian1, LIN Ming-yu1, SUN De-an2, SHAO Jie-sheng1, 2, CAO Shan-shan1, ZHAO Chang-you1, JIN Lin1   

  1. 1. Guangxi Key Laboratory of Geomechanics and Geotechnical Engineering, Guilin University of Technology, Guilin, Guangxi 541004, China; 2. Department of Civil Engineering, Shanghai University, Shanghai 200444, China
  • Received:2025-02-07 Accepted:2025-05-28 Online:2026-01-11 Published:2026-01-08
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (42167020), Guangxi Natural Science Foundation Program (2023GXNSFAA026187) and the Innovation Project of Guangxi Graduate Education (YCSW2024360)

PDF (Chinese)

23

摘要: 为探究高温条件下膨润土缓冲层材料导热性能的热老化时间效应,在100 ℃和200 ℃条件下分别对MX80膨润土粉末进行了0、15、30、60、90、120 d的热老化预处理,利用热探针法测定了预处理后膨润土压实试样的导热性能,并分析其热老化时效性;采用粒度分析、X射线衍射和热重分析等微观试验,揭示出高温条件下MX80膨润土试样导热性能热老化时间效应的产生机制。试验结果表明:(1)高温(100、200 ℃)热老化预处理后膨润土试样的导热系数λ 均随着热老化时间 t 的递增而降低,呈现出明显的热老化时间效应:0~15 d急剧降低,30 d后趋于稳定;相较于100 ℃,200 ℃条件下膨润土试样的热老化时间效应更显著。(2)高温(100、200 ℃)作用均会引起膨润土试样中各形态水逐渐脱附,结合水膜变薄,固体土颗粒粒径减小;此外,在200 ℃条件下,试样中的部分蒙脱石矿物转变为钠云母;上述微观特征演化呈现出与试样导热系数λ 一致的热老化时效性。(3)膨润土材料导热性能热老化时间效应产生的本质原因在于:100 ℃条件下,随着热老化时间 t 的递增,温度作用导致膨润土中各形态水逐渐脱附,结合水膜变薄,颗粒粒径减小,固相体积减少,气相体积增加,但矿物成分未发生变化;而200 ℃条件下,随着热老化时间 t 的递增,上述温度作用进一步加剧,且高温引起了部分蒙脱石矿物转变为导热系数较低的钠云母。

关键词: 膨润土缓冲层, 导热性能, 热老化时效性, 高温条件, 微观机制

Abstract: To investigate the temporal influence of thermal ageing on the thermal conductivity of bentonite buffer material under high temperature conditions, MX80 bentonite powder was pretreated at 100 ℃ and 200 ℃ for durations of 0, 15, 30, 60, 90, 120 days. The thermal conductivity of the compacted bentonite samples after pretreatment was measured using the thermal probe method, and the temporal influence was analyzed. The microscopic mechanism underlying the temporal influence on thermal conductivity λ of bentonite samples was revealed through particle size analysis, X-ray diffraction and thermogravimetric analysis tests. The experimental results indicate that: 1) After high-temperature aging (100 ℃ and 200 ℃), the thermal conductivity λ of bentonite samples decreased significantly with increasing thermal aging time t, demonstrating a significant temporal effect. A sharp decline was observed from 0 to 15 days, followed by stabilization after 30 days. The effect was more pronounced at 200 ℃ compared to 100 ℃. 2) High temperatures (100 °C and 200°C) result in the gradual desorption of various forms of water, thinning of the bound water film, and a reduction in the particle size of bentonite samples. Additionally, at 200°C, some montmorillonite minerals in the samples transform into sodium mica. These microstructural evolutions are consistent with the temporal influence observed in the thermal conductivity λ of the samples. 3)The fundamental reason for the temporal influence of thermal aging on the thermal conductivity of bentonite materials is as follows: At 100 °C, as thermal aging time t increases, the temperature effects lead to the gradual desorption of various forms of water, thinning of the bound water film, reduction in particle size, decrease in solid volume, and increase in gas volume, while the mineral composition remains unchanged. At 200 °C, as the thermal aging time t increases, the aforementioned temperature become more pronounced, and the high temperature causes some montmorillonite minerals to transform into sodium mica, which exhibits a lower thermal conductivity λ.

Key words: bentonite buffer layer, thermal conductivity, time-effectiveness of thermal aging, high temperature conditions, micro-mechanism

中图分类号: TU 411
[1] 贺文昊, 田威, 云伟, 李璐, 赵航宇, 弋郭洋. 响应面法优化靶向激活微生物固化黄土试验研究[J]. 岩土力学, 2026, 47(2): 659-673.
[2] 祁凯, 万志辉, 戴国亮, 胡涛, 周峰, 张鹏, . 基于不同注浆材料固化钙质砂的力学性能试验及微观机制研究[J]. 岩土力学, 2025, 46(6): 1825-1838.
[3] 唐先习, 张徐军, 李昊杰, . 钢渣-煤矸石地聚合物固化黄土的力学特性评价与固化原理分析[J]. 岩土力学, 2025, 46(4): 1205-1214.
[4] 薛钦培, 陈宏信, 冯世进, 刘晓轩, 谢伟, . 干湿循环作用下地聚物隔离墙材料渗透特性演化及微观机制研究[J]. 岩土力学, 2025, 46(3): 811-820.
[5] 吕志涛, 朱小宝, 罗嗣成, 夏才初, 曾祥太, . 砂岩多周期累积冻融变形特性及其微观机制试验研究[J]. 岩土力学, 2025, 46(2): 389-401.
[6] 黎宇, 胡明鉴, 郑思维, 王志兵, . 电石渣-矿渣固化膨胀土强度及微观机制研究[J]. 岩土力学, 2024, 45(S1): 461-470.
[7] 姜启武, 黄明, 崔明娟, 靳贵晓, 彭仪欣, . 酶诱导碳酸钙沉淀技术加固TBM壁后吹填豆砾石最优配比试验及机制研究[J]. 岩土力学, 2024, 45(7): 2037-2049.
[8] 慕焕东, 何也, 白逸松, 邓亚虹, 郑龙浩, . 靖边Q3砂质黄土湿陷特征及其微观机制研究[J]. 岩土力学, 2024, 45(10): 3024-3036.
[9] 龙开荃, 方祥位, 申春妮, 张熙晨, 王明明, . 复合型早强土壤固化剂固化淤泥强度特性研究[J]. 岩土力学, 2023, 44(S1): 309-318.
[10] 曾召田, 张瀚彬, 邵捷昇, 车东泽, 吕海波, 梁珍, . MX-80膨润土高温老化时间效应的细微观分析[J]. 岩土力学, 2023, 44(S1): 145-153.
[11] 曾召田, 崔哲旗, 孙德安, 姚志, 潘斌, . 南宁膨胀土持水性能的温度效应及微观机制[J]. 岩土力学, 2023, 44(8): 2177-2185.
[12] 张凌凯, 崔子晏, . 干湿−冻融循环条件下膨胀土的压缩及渗透特性变化规律[J]. 岩土力学, 2023, 44(3): 728-740.
[13] 刘宽, 叶万军, 高海军, 董琪, . 酸碱污染黄土抗剪强度演化规律及微观机制[J]. 岩土力学, 2022, 43(S1): 1-12.
[14] 张志韬, 陈生水, 吉恩跃, 傅中志, . 聚丙烯纤维加筋砾质黏土的拉伸断裂特性研究[J]. 岩土力学, 2021, 42(10): 2713-2721.
[15] 王东星, 陈政光, . 氯氧镁水泥固化淤泥力学特性及微观机制[J]. 岩土力学, 2021, 42(1): 77-85.
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