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浙江大学学报(工学版)
Journal of ZheJiang University (Engineering Science)  2026, Vol. 60 Issue (7): 1577-1585    DOI: 10.3785/j.issn.1008-973X.2026.07.019
    
Reconstruction of root system based on foundation beam approach
Yongqi MIAO1,2(),Xingyu ZHANG1,2,*(),Lu YANG3,Shitang KE1,2
1. Department of Civil and Airport Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China
2. Key Laboratory of Dynamic Multi-hazard Protection in Civil Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China
3. Kunming Planning and Design Research Institute Co., Ltd, Kunming 650051, China
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Abstract  

Aiming at complexity of the root architecture, low efficiency of typical numerical simulation method and difficulty of modelling large deformation, a root system reconstruction method was proposed on basis of Winkler foundation beam theory. The individual roots were simplified into horizontal or vertical cylindrical elements while preserving key root distribution characteristics. Two types of complex root system models were built: a narrow-deep model A and a wide-shallow model B, together with their simplified versions Am and Bm. The bending moment-rotation curves and the failure mechanisms before and after root system reconstruction under centrifugal conditions were compared. The initial stage of moment-rotation curves showed high consistency between original and reconstructed models. Model B and Bm exhibited similar responses under large displacement, whereas the tap root in Model Am was broken due to stress concentration, leading to 65% moment reduction. Windward lateral roots were pulled out of the soil, consistent with the field observations. The simplified model accurately reproduces the overturning resistance and effectively captures the failure mechanisms dominated by taproot fracture, providing theoretical basis for physical and numerical modelling of complex root systems.

Key wordsroot system reconstruction      hypergravity      beam on Winkler foundation approach      failure mechanism      moment-rotation curve     
Received: 18 April 2025      Published: 23 May 2026
CLC:  TU 375.4  
Fund:  江苏省自然科学基金资助项目(BK20230895);国家自然科学基金资助项目(52408541, 52321165649);中央高校基本科研业务费专项资金资助项目(NS2025021).
Corresponding Authors: Xingyu ZHANG     E-mail: miaoyongqi@nuaa.edu.cn;x.y.zhang@nuaa.edu.cn
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Yongqi MIAO
Xingyu ZHANG
Lu YANG
Shitang KE
Cite this article:

Yongqi MIAO,Xingyu ZHANG,Lu YANG,Shitang KE. Reconstruction of root system based on foundation beam approach. Journal of ZheJiang University (Engineering Science), 2026, 60(7): 1577-1585.

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https://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2026.07.019     OR     https://www.zjujournals.com/eng/Y2026/V60/I7/1577


基于地基梁法的植被根系重构方法

针对植被根系结构复杂、传统数值分析方法效率低且难以模拟大位移变形的问题,提出基于Winkler地基梁法的根系重构方法,将单根简化为水平或竖直圆柱体,保留关键根系分布特征. 构建窄而深(模型A)和宽而浅(模型B)2种根系的复杂模型及其简化模型(Am、Bm),对比分析超重力条件下根系重构前后的弯矩-转角曲线和破坏机理. 研究发现,初始阶段重构前后模型的弯矩-转角曲线高度吻合;在大位移阶段,模型B和Bm的响应较为相似,而模型Am主根因应力集中断裂,弯矩骤降65%;2种模型横向根拔出现象均与现场试验一致. 简化模型能准确再现根系的抗倾覆性能,可以有效捕捉由主根断裂等机制主导的破坏模式,为复杂根系物理模拟与数值建模提供理论基础.


关键词: 根系重构,  超重力,  Winkler地基梁法,  破坏机理,  弯矩-转角曲线 
Fig.1 Schematic diagram of root system (Black is marked as root of destruction in experiment)
物理量相似系数物理量相似系数
长度1/N应力1
体积1/N31/N2
密度1位移1/N
加速度N弯矩1/N3
刚度1转角1
Tab.1 Scale law
Fig.2 Schematic diagram of simplification of taproot
Fig.3 Schematic diagram of simplification of lateral roots
Fig.4 Schematic diagram of simplification of third order roots
Fig.5 Number of (a)(c) lateral roots and (b)(d) vertical roots in different regions of models A、B、Am and Bm (plan view)
Fig.6 Accumulated root volume for models A、Am、B and Bm
Fig.7 Mechanical properties of ABS material
Fig.8 Particle size distribution curve of test soil
Fig.9 Peak friction angle of test soil
Fig.10 Schematic diagram of centrifuge test setup
Fig.11 Moment-rotation curves for models A、Am、B and Bm
Fig.12 Schematic diagram of modelling of tap root overturning
Fig.13 Moment-rotation curves of taproot and single pile simulations
Fig.14 Coupling constraint of root system based on Winkler foundation beam method
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