Rockslides can cause severe damage to infrastructure, while flexible barriers offer an effective prevention measure. The protection and control effect of flexible barriers can be estimated from the process of rockslide break-runout-impact on the flexible barrier, which can be simulated using the DEM-FDM coupled method in the finite difference code FLAC3D. However, accurate modeling of this process has been hindered by the inability to adequately describe the mechanical behavior of flexible barriers in FLAC3D. To address this issue, this study presents an equivalent continuum model to describe the mechanical behavior of a flexible barrier under rockslide impact. This equivalent model reduces computational complexity while maintaining accuracy. The proposed theoretical model incorporates tensile and bending components along with yield criteria governing stress state changes. Furthermore, the model was implemented in FLAC3D through secondary development. Three experiments were numerically simulated to verify the effectiveness of the proposed model. Utilizing the proposed flexible barrier model and the DEM-FDM coupled method, the process of rockslide break-runout-impact on flexible barriers was numerically investigated. The proposed method was applied to predict the rockslide break-runout-impact process on a flexible barrier in Sichuan Province, China. The numerical results offer scientific guidance for the selection of appropriate flexible barriers.
AlbabaALambertSKneibF, et al. (2017) DEM modeling of a flexible barrier impacted by a dry granular flow. Rock Mechanics and Rock Engineering50(11): 3029–3048.
2.
AsteriouPTsiambaosG (2018) Effect of impact velocity, block mass and hardness on the coefficients of restitution for rockfall analysis. International Journal of Rock Mechanics and Mining Sciences106: 41–50.
3.
BoulaudRDoutheC (2022) A comparative assessment of ASM4 rockfall barrier modelling. Engineering Structures251: 113512.
4.
CaiMKaiserPKMoriokaH, et al. (2007) FLAC/PFC coupled numerical simulation of AE in large-scale underground excavations. International Journal of Rock Mechanics and Mining Sciences44(4): 550–564.
5.
CastanonJLBlancoFCastro-FD, et al. (2018) Use of explicit FEM models for the structural and parametrical analysis of rockfall protection barriers. Engineering Structures166: 212–226.
6.
ChenHYZhaoCYTomasR, et al. (2023) Retrieving the kinematic process of repeated-mining-induced landslides by fusing SAR/InSAR displacement, logistic model, and probability integral method. Remote Sensing15(12): 3145.
7.
CoulibalyJBChanutMLambertS, et al. (2019) Toward a generic computational approach for flexible rockfall barrier modeling. Rock Mechanics and Rock Engineering52(11): 4475–4496.
8.
CuiSLiangYPeiX, et al. (2023) Structural characteristics of landslide failure boundaries using three-dimensional point clouds: a case study of the Zhaobiyan landslide, China. Bulletin of Engineering Geology and the Environment82(4): 127.
9.
DhakalSBhandaryNPYatabeR, et al. (2011) Experimental, numerical and analytical modelling of a newly developed rockfall protective cable-net structure. Natural Hazards and Earth System Sciences12(12): 3197–3212.
10.
di PriscoCRedaelliIZerbiM (2023) Inclined block impacts on granular strata: coupled DEM-FDM numerical investigation and rheological modelling. Rock Mechanics and Rock Engineering56: 6761–6778.
11.
EscallónJPBoetticherVWendelerC, et al. (2015) Mechanics of chain-link wire nets with loose connections. Engineering Structures101: 68–87.
12.
GentiliniCGovoniLMirandaS, et al. (2012) Three-dimensional numerical modelling of falling rock protection barriers. Computers and Geotechnics44: 58–72.
13.
GottardiGGovoniL (2010) Full-scale modelling of falling rock protection barriers. Rock Mechanics and Rock Engineering43(3): 261–274.
14.
HuXDHuKHTangJB, et al. (2019) Assessment of debris-flow potential dangers in the Jiuzhaigou Valley following the August 8, 2017, Jiuzhaigou earthquake, Western China. Engineering Geology256: 57–66.
15.
KwanJSHSunHWLamC, et al. (2016) Recent advances in landslide risk management measures in Hong Kong. In: 12th International Symposium on Landslides, Napoli, ITALY, 1219–1227.
16.
LeonardiAWittelFKMendozaM, et al. (2016) Particle-Fluid-Structure interaction for debris flow impact on flexible barriers. Computer-Aided Civil and Infrastructure Engineering31(5): 323–333.
17.
LiBGongWTangH, et al. (2021) Probabilistic analysis of a discrete element modelling of the runout behavior of the Jiweishan landslide. International Journal for Numerical and Analytical Methods in Geomechanics45(8): 1120–1138.
18.
LiLJuNShengD (2023) Seismic performance and failure mechanism of interbedded slopes with steep rock layers. Engineering Geology326: 107312.
19.
LingSXSunCWLiXN, et al. (2021) Characterizing the distribution pattern and geologic and geomorphic controls on earthquake-triggered landslide occurrence during the 2017 Ms7.0 Jiuzhaigou earthquake, Sichuan, China. Landslides18(4): 1275–1291.
20.
LiuKLiuH (2022) Simulation of the earthquake-induced soil-rock mixed accumulation body sliding movement using discrete-continuous coupled approach. Natural Hazards114(2): 2087–2108.
21.
MentaniAGovoniLGiacominiA, et al. (2018) An equivalent continuum approach to efficiently model the response of steel wire meshes to rockfall impacts. Rock Mechanics and Rock Engineering51(9): 2825–2838.
22.
NicotFCambouBMG (2001) Design of rockfall restraining nets from a discrete element modelling. Rock Mechanics and Rock Engineering34(2): 99–118.
23.
QiXYuZXZhaoL, et al. (2018) A new numerical modeling approach for flexible rockfall protection barriers based on failure modes. Advanced Steel Construction14(3): 479–495.
24.
SautterKBHofmannHWendelerC, et al. (2021) Advanced modeling and simulation of rockfall attenuator barriers via partitioned DEM-FEM coupling. Frontiers in Built Environment7: 659382.
25.
ScuderiLAOnyangoEANagleMT (2023) A remote sensing and GIS analysis of Rockfall Distributions from the 5 July 2019 Ridgecrest (MW>7.1) and 24 June 2020 Owens Lake (MW>5.8) earthquakes. Remote Sensing15(8): 1962.
26.
ShaoXMaSXuC, et al. (2023) Insight into the characteristics and triggers of loess landslides during the 2013 heavy rainfall event in the tianshui area, China. Remote Sensing15(17): 4304.
27.
ShiCZhaoCFZhangX, et al. (2021) Coupled discrete-continuum approach for railway ballast track and subgrade macro-meso analysis. International Journal of Pavement Engineering22(13): 1744–1759.
28.
TahmasbiSGiacominiAWendelerC, et al. (2019) On the computational efficiency of the hybrid approach in numerical simulation of rockall flexible chain-link mesh. Rock Mechanics and Rock Engineering52(10): 3849–3866.
29.
TangJLLiTBZengP (2024) Rockburst-specific flexible protection net (RFPN) for tunnels: creation, characteristics, and preliminary application. Rock Mechanics and Rock Engineering57(7): 1–19.
30.
TomásRPinheiroMPintoP, et al. (2023) Preliminary analysis of the mechanisms, characteristics, and causes of a recent catastrophic structurally controlled rock planar slide in Esposende (northern Portugal). Landslides20(8): 1657–1665.
31.
VerrucciLForteGDeF, et al. (2023) Instantaneous limit equilibrium back analyses of major rockslides triggered during the 2016-2017 central Italy seismic sequence. Natural Hazard Earth System23(3): 1177–1190.
32.
WangXMXiaoYJShiW, et al. (2022) Forensic analysis and numerical simulation of a catastrophic landslide of dissolved and fractured rock slope subject to underground mining. Landslides19(5): 1045–1067.
33.
XuHGentiliniCYuZ, et al. (2018) An energy allocation based design approach for flexible rockfall protection barriers. Engineering Structures173: 831–852.
34.
YangJJDuanSLiQF, et al. (2019) A review of flexible protection in rockfall protection. Natural Hazards99(1): 71–89.
35.
YangXTongJYuZ, et al. (2024) Deep learning-based automatic rockfall impact force reconstruction for flexible barrier systems in full-scale tests. Automation in Construction165: 105510.
36.
YuZXLiuCGuoLP, et al. (2019) Nonlinear numerical modeling of the wire-ring net for flexible barriers. Shock and Vibration2019: 3040213.
37.
ZhaoYN (2018) Analysis of Deformation and Energy Dissipation Performance of the Passive Flexible Protection Struction. Doctor Degree Dissertation. South Jiaotong University. in Chinese.
38.
ZhaoLHeJWYuZX, et al. (2020) Coupled numerical simulation of a flexible barrier impacted by debris flow with boulders in front. Landslides17(12): 2723–2736.
