首页/文章/ 详情

基于离散元法的粉质粘土单向冻结过程水热耦合模拟

11月前浏览8774

论文题目


 

Hydrological–Thermal Coupling Simulation of Silty Clay during Unidirectional Freezing Based on the Discrete Element Method


Wei Shan 1,2,3,4* , Shiyao Qu 1 and Ying Guo 1,2,3,4

Institute of Cold Regions Science and Engineering, Northeast Forestry University, Harbin 150040, China;ying-guo@nefu.edu.cn (Y.G.);

2 Ministry of Education Observation and Research Station of Permafrost Geo-Environment System in Northeast China (MEORS-PGSNEC), Harbin 150040, China;

3 Collaborative Innovation Centre for Permafrost Environment and Road Construction and Maintenance in Northeast China (CIC-PERCM), Harbin 150040, China;

4 Low-Carbon Road Construction and Maintenance Engineering Technology Research Center in Northeast Permafrost Region of Heilongjiang Province (LCRCMT-HLJ), Harbin 150040, China;

* Correspondence: shanwei456@163.com.



 

研究内容

Abstract: A hydrological–thermal coupling discrete element model depicting the unidirectional freezing process of unsaturated silty clay was developed in order to investigate the migration law of unfrozen water in unsaturated silty clay under unidirectional freezing circumstances. The model uses the contact heat transfer equation to calculate the heat transfer process while taking into account the latent heat of phase transition. To obtain the silty clay’s freezing characteristic curve, the model combines the unfrozen water content curve with the Clausius–Clapeyron equation. The water migration from the unfrozen zone to the frozen zone was calculated using Harlan’s model and the frozen fringe hypothesis. The discrete element application MatDEM 3.0 was used to incorporate the mathematical model for computation, and the output was compared to the result of indoor unidirectional freezing tests. The soil closest to the stable freezing front had the largest water content, according to the findings of numerical modeling and laboratory testing, and unfrozen water in the soil would move from the unfrozen zone to the frozen zone under the action of water potential difference. The results of laboratory tests and numerical simulations can accurately describe the temperature variation and water migration of soil during freezing, demonstrating the accuracy of the established discrete element model and proving the viability of the discrete element method in the

study of frozen soil.

Keywords: discrete element method; hydrological–thermal coupling; numerical analysis; unidirectional freezing

FIGURE 6 Temperature distribution of samples after freezing at different cold end temperatures:(a) the cold end temperature is -5°C; (b) the cold end temperature is -7°C; (c) the cold end temperature is -10°C.

FIGURE 7 Temperature profiles at different heights of the sample during unidirectional freezing.

FIGURE 8 The position of the freezing front varies with time.

FIGURE 9 Distribution of water content along the height of the sample at different cold end temperatures: (a) cold end temperature of -5°C; (b) cold end temperature of -7°C; (c) cold end temperature of -10°C.

了解详情


 
Shan W, Qu S, Guo Y. Hydrological–Thermal Coupling Simulation of Silty Clay during Unidirectional Freezing Based on the Discrete Element Method. Water. 2023; 15(7):1338. https://doi.org/10.3390/w15071338

来源:矩阵离散元MatDEM
ACTSystemUM离散元MathematicaInVEST
著作权归作者所有,欢迎分享,未经许可,不得转载
首次发布时间:2023-12-30
最近编辑:11月前
MatDEM
中国自己的工程数值计算软件
获赞 163粉丝 1212文章 147课程 36
点赞
收藏
未登录
还没有评论
课程
培训
服务
行家
VIP会员 学习 福利任务 兑换礼品
下载APP
联系我们
帮助与反馈