A Landslide Susceptibility Evaluation of Highway Disasters Based on the Frequency Ratio Coupling Model

Fan, Huadan; Lu, Yihuan; Hu, Yulong; Fang, Jun; Lv, Chengzhe; Xu, Changqing; Feng, Xinyi; Liu, Yanru

doi:10.3390/su14137740

Cited by 30 publications

(18 citation statements)

References 27 publications

(25 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is this complexity that makes the relationship between the stress and strain of rock one of the most concerned problems in geotechnical engineering [ 15 , 16 , 17 ]. In 1948, Cook [ 18 ] put forward the concept of the whole stress–strain process of rock, and divided the actual typical uniaxial compression test curve of rock into the compaction stage, the elastic stage, the plastic hardening stage, and the strain softening stage, which simulate the whole deformation process and have become powerful tools to study the failure mode and mechanism of rocks [ 19 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

Fracture Closure Empirical Model and Theoretical Damage Model of Rock under Compression

et al. 2023

View full text Add to dashboard Cite

The rock or rock mass in engineering often contains joints, fractures, voids, and other defects, which are the root cause of local or overall failure. In response to most of the current constitutive models that fail to simulate the nonlinear fracture compaction deformation in the whole process of rock failure, especially brittle rocks, a piecewise constitutive model was proposed to represent the global constitutive relation of rocks in this study, which was composed of the fracture compaction empirical model and the damage statistical constitutive model. The fracture empirical compaction model was determined by fitting the expressions of fracture closure curves of various rocks, while the rock damage evolution equation was derived underpinned by the fracture growth. According to the effective stress concept and strain equivalence hypothesis, the rock damage constitutive model was deduced. The model parameters of the fracture compaction empirical model and damage statistical constitutive model were all calculated by the geometrical characteristics of the global axial stress–strain curve to guarantee that the models are continuous and smooth at the curve intersection, which is also simple and ready to program. Finally, the uniaxial compression test data and the triaxial compression test data of different rocks in previous studies were employed to validate the models, and the determination coefficient was used to measure the accuracy. The results showed great consistency between the model curves and test data, especially in the pre-peak stage.

show abstract

Section: Introductionmentioning

confidence: 99%

Fracture Closure Empirical Model and Theoretical Damage Model of Rock under Compression

et al. 2023

View full text Add to dashboard Cite

show abstract

“…As the weak plane in rock mass, the joint is usually the key factor in the stability of instances of rock mass engineering such as slopes, dam foundations and underground chambers [ 1 , 2 , 3 ], thus further affecting human life and property as well as the environment [ 4 , 5 , 6 ]. Research on the deformation and strength characteristics of joints aims to provide a basis for the evaluation and utilization of rock mass stability [ 7 , 8 ].…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on Shear Behavior of Rock Composite Material under Normal Unloading Conditions

et al. 2023

View full text Add to dashboard Cite

As a composite material, the stability of rock mass is usually controlled by a joint. During the process of excavation, the normal stress of the joint decreases continuously, and then the shear strength of the joint decreases, which may eventually lead to the instability and failure of rock mass. Previous studies have mainly focused on the shear behavior of joints under constant normal stress, but have rarely considered the unloading of normal stress. In this paper, a direct shear test of joints with different roughness was carried out, in which the shear stress remained unchanged while the normal stress decreased. The strength characteristics of joints were explored, and the deformation and acoustic emission-counting characteristics of joints were analyzed by digital image correlation (DIC) techniques and acoustic emission (AE). A new method for predicting the instability of joints under normal unloading was proposed based on the evolution law of normal deformation energy (Un), tangential deformation energy (Us) and total deformation energy (U0). The results show the following: (1) The unloading amount of normal stress was enlarged for greater initial normal stress and roughness, while it decreased with an increase in initial shear stress. (2) AE events reached their maximum when the normal stress was equal to the failure normal stress, and the b-value fluctuated more frequently in stable development periods under normal unloading conditions. (3) U0 would change with the loading and unloading of stress, and this may be used to predict the unloading instability of rock mass using the abrupt change of U0.

show abstract

“…As a common construction and reinforcement material, cement mortar material is widely used in rock mass reinforcement, tunnel excavation, highway and bridge construction, and other rock mass engineering due to the excellent performance [ 50 , 51 , 52 ], generating numerous rock–mortar interface structure [ 53 , 54 ], which also bring huge workload and difficulty to the safety management and disaster prevention in the construction and operation of basic transportation facilities [ 55 , 56 , 57 ]. Considering bridge operation as an example, as shown in Figure 2 , rock-socketed piles and bedrock are cemented to provide support for piers and beams on the bridge, while the stability of rock–mortar cementation interface is the basis of safe and stable train operation.…”

Section: Introductionmentioning

confidence: 99%

Apparent Deterioration Law and Shear Failure Mode of Rock–Mortar Interface Based on Topography-Sensing Technology

et al. 2023

View full text Add to dashboard Cite

As an advanced spatial technology, topography-sensing technology is comprehensive, macroscopic, and intuitive. It shows unique advantages for rock structure interpretation and has important guiding significance for the research of the shear performances of rock–mortar interface under cyclic load in rock mass engineering. In this paper, cyclic shearing tests combined with the shear surface topography-sensing technology are employed to investigate the evolution characteristics of the interface morphology and the strength deterioration of the rock–mortar interface. Primarily, mortar and three types of rocks are used to prepare different rock–mortar interfaces, which are then applied to cyclic shear loading under two constant normal stresses. Subsequently, the shear strength degradation and dilatancy characteristics of rock–mortar interfaces with varying shear times are discussed. In addition, on the basis of the non-contact three-dimensional topography-sensing technology, the apparent three-dimensional point–cloud coordinate information of rock–mortar interface before and after each shear loading is obtained, and the apparent three-dimensional topography parameters of rock–mortar interface are calculated, according to which the influences of normal stress and lithology on the topography of interface subjected to cyclic shearing loading are analyzed.

show abstract

A Landslide Susceptibility Evaluation of Highway Disasters Based on the Frequency Ratio Coupling Model

Cited by 30 publications

References 27 publications

Fracture Closure Empirical Model and Theoretical Damage Model of Rock under Compression

Fracture Closure Empirical Model and Theoretical Damage Model of Rock under Compression

Experimental Study on Shear Behavior of Rock Composite Material under Normal Unloading Conditions

Apparent Deterioration Law and Shear Failure Mode of Rock–Mortar Interface Based on Topography-Sensing Technology

Contact Info

Product

Resources

About