Multiscale effects caused by the fracturing and fragmentation of rock blocks during rock mass movement: implications for rock avalanche propagation

Lin, Qiwen; Wang, Yufeng; Xie, Yuanfu; Cheng, Qiangong; Deng, Kaifeng

doi:10.5194/nhess-22-639-2022

Cited by 12 publications

(6 citation statements)

References 103 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Two sites (Nax, Fläsch 1) have higher b values compared to the range (0.63-1.29) obtained by Lanfranconi et al (2020), who also found a different trend in the lithology dependence. The value of the parameter b depends mainly on the geology of the cliff, and fragmentation is often caused by fracturing along pre-existing weak joint planes (e.g., Lin et al, 2022). Additionally, the fall height of the blocks plays a role (De Blasio and Crosta, 2015;Ruiz Carulla et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

Estimating Rockfall and Block Volume Scenarios Based on a Straightforward Rockfall Frequency Model

Moos¹,

Bontognali²,

Dorren³

et al. 2022

SSRN Journal

View full text Add to dashboard Cite

Section: Discussionmentioning

confidence: 99%

Estimating Rockfall and Block Volume Scenarios Based on a Straightforward Rockfall Frequency Model

Moos¹,

Bontognali²,

Dorren³

et al. 2022

SSRN Journal

View full text Add to dashboard Cite

“…In the past two decades, many scholars have conducted in-depth research on this technique and developed corresponding programs to reproduce the rock structural surface, such as the Fracman program, Blocks program, and Geofrac program [24]. These programs are generally based on the Monte Carlo method to generate rock mass fracture networks, and the basic process of Monte Carlo random simulation technology can be summarized as (1) conducting on-site joint geological surveys to obtain basic geological parameters of rock fracture samples, such as fracture density, attitude, spacing, and aperture ratio; (2) performing statistically analyses on the geological parameters of the fracture samples and fitting corresponding probability density and distribution functions; and (3) using the Monte Carlo method to generate random fracture networks that statistically match the actual distribution of the rock mass fractures based on specific distributions of random numbers. The implementation process of random fracture network simulation is shown in Figure 1.…”

Section: Characterization Of Random Fracture Network In Broken Rock M...mentioning

confidence: 99%

“…Within various geological regions, the rock masses manifest diverse quantities and types of structural surfaces. For broken rock masses that are characterized by a high-dispersion structure due to extensive jointing, fissuring, and faulting, the discontinuity and anisotropy of the structure become more pronounced [1,2]. In engineering practices involving broken rock masses, such as tunnels at near-fault regions and side slopes in highly weathered rock formations, the randomness of discontinuities, the variability in rock mass parameters, and the uncertainty associated with surrounding rock loads pose potential risks to the safety of the construction projects [3,4].…”

Section: Introductionmentioning

confidence: 99%

Determining Digital Representation and Representative Elementary Volume Size of Broken Rock Mass Using the Discrete Fracture Network–Discrete Element Method Coupling Technique

Huang,

Li,

Jin

et al. 2024

Applied Sciences

View full text Add to dashboard Cite

Obtaining the digital characterization and representative elementary volume (REV) of broken rock masses is an important foundation for simulating their mechanical properties and behavior. In this study, utilizing the broken surrounding rock of the main powerhouse at the Liyang pumped storage power station as an engineering background, a three-dimensional fracture network generation program is first developed based on the theories of discrete fracture network (DFN) and discrete element method (DEM). The program is then integrated with a distinct element modelling platform to generate equivalent rock mass models for broken rock masses based on the DFN–DEM coupling technique. Numerical compression tests are conducted on cylindrical rock specimens produced using the proposed modelling approach, aiming to determining the REV size of the target rock masses at the Liyang power station. A comparative validation is also performed to examine the REV result obtained from the proposed approach, which adopted a REV measuring scale index (RMSI) to determine the REV size. Results indicate that the organic integration of DFN simulation techniques and DEM platforms can effectively construct numerical models for actual broken rock masses, with structural surface distributions statistically similar to the real ones. The results also show that the REV size of the investigated rock masses determined by the cylindrical rock models is 5 m × 10 m, which aligns with the size determined by the cubic rock models, as the target cubes show the same height as the cylindrical specimens. This study provides a model and parameter basis for the numerical calculation of the mechanical behavior of broken rock mass.

show abstract

“…As soon as the Champati slide impacts the horizontal plane, it behaves as if it was a fragmented rock particles. With this behaviour, one may even think if some kind of force, akin to the dispersive pressure in rock fragmentation(Davies and McSaveney, 2009;Dufresne et al, 2016;Lin et al, 2022), is involved that ultimately…”

mentioning

confidence: 99%

“…For this reasons, Champatis are said to exhibit the hyperspreading during their motion, deformation and deposition. Such spreading may be useful to model and describe the super-spreading of the fragmented clasts in the natural rock-avalanches in the distal run-out fan(Davies and McSaveney, 2009;Dufresne et al, 2016;Lin et al, 2022). Once the bucket is lifted, the Champatis in the outer part of the moving/deforming heap roll and spin…”

mentioning

confidence: 99%

The Champati Slide

Pudasaini,

Dangol,

Tiwari

et al. 2024

Preprint

View full text Add to dashboard Cite

Here, we report some novel findings of chute experiments with native Nepalese granular seeds, called Champatis, and when mixed with other food grain of a fundamentally different physical properties, Silam. The epitomic supergrain Champati exhibits complex frictional, spin and rolling motion. We hypothesize that the Champati slide results in an essentially unique dynamical spreading, separation from other grains, mobility, run-out and deposition morphology. Particularly, the surface anatomy of Champati acted vitally in characterizing these aspects. We reveal spectacular dynamical flow obstacle interaction and depositional behaviour of Champati and the mixture slide. Champati slide manifests hyper-spreading in the run-out. Soon after the mass hits the ground, the behaviour is unprecedented and unpredictable, mainly around the frontal periphery. The very special properties of Champatis control the frontal spreading, rapid grain marching and the zigzag sporadic Champati motion. Particle rolling, spinning, exceptionally lower frictional energy dissipation and grain collision played the major role resulting in an unexpectedly longer travel time and distance, explaining the astonishing hypermobility of Champati grains. The obstacle substantially changes the flow dynamics as the Champati has the higher object mobilization capacity. Due to the unique property of the supergrain, the eye-catching, amazingly strong separation of Champati from Silam evolves swiftly right after the flow inception, and the process intensifies quickly. The separation length characterizes the complex interfacial momentum exchange between the phases in the mixture. The separation length between the frontal Champatis and Silam grains increases exceptionally as it does between the main body and the exclusively Silam-covered tremendously long tail of the flow in the inclined portion of the channel. These results may be useful in better understanding the phase separation, super-wide-spreading and hypermobility of some geological flows, including fragmented rock avalanches, probably helping resolve some relevant standing challenges.

show abstract

Multiscale effects caused by the fracturing and fragmentation of rock blocks during rock mass movement: implications for rock avalanche propagation

Cited by 12 publications

References 103 publications

Estimating Rockfall and Block Volume Scenarios Based on a Straightforward Rockfall Frequency Model

Estimating Rockfall and Block Volume Scenarios Based on a Straightforward Rockfall Frequency Model

Determining Digital Representation and Representative Elementary Volume Size of Broken Rock Mass Using the Discrete Fracture Network–Discrete Element Method Coupling Technique

The Champati Slide

Contact Info

Product

Resources

About