Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer

Sliding zone dynamics in the Qinling-Daba mountain area under different dynamic parameters have not been studied extensively. In this study, we investigated the dynamic behavior of the sliding zones of a high-steep rock landslide in the Qinling-Daba mountain area under the influence of dynamic stres...

Full description

Bibliographic Details
Main Authors: Jingjing Zhou, Fasuo Zhao, Yanbo Zhu, Wenqi Dong, Ziguang He
Format: Article
Language:English
Published: Hindawi Limited 2021-01-01
Series:Shock and Vibration
Online Access:http://dx.doi.org/10.1155/2021/3330127
id doaj-786ba70d3a864f3dbcdc7dd66a5d3743
record_format Article
spelling doaj-786ba70d3a864f3dbcdc7dd66a5d37432021-09-06T00:01:19ZengHindawi LimitedShock and Vibration1875-92032021-01-01202110.1155/2021/3330127Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak InterlayerJingjing Zhou0Fasuo Zhao1Yanbo Zhu2Wenqi Dong3Ziguang He4College of Geological Engineering and GeomaticsCollege of Geological Engineering and GeomaticsCollege of Geological Engineering and GeomaticsCollege of Geological Engineering and GeomaticsHuanghuai UniversitySliding zone dynamics in the Qinling-Daba mountain area under different dynamic parameters have not been studied extensively. In this study, we investigated the dynamic behavior of the sliding zones of a high-steep rock landslide in the Qinling-Daba mountain area under the influence of dynamic stress amplitude and frequency and proposed an empirical model of the dynamic constitutive relationship. The dynamic behavior was studied based on a cyclic triaxial test system. The results indicated that an increase in the dynamic stress amplitude decreased the dynamic elastic modulus linearly, increased the damping ratio, and increased the axial strain exponentially. Among these properties, the elastic strain was found to be more sensitive to the increase in the dynamic stress amplitude than the plastic strain. As the loading frequency increased, the dynamic elastic modulus increased, whereas the damping ratio decreased. Furthermore, the proposed empirical model of the dynamic constitutive relationship between the vibration number and loading frequency based on the dynamic elastic modulus could satisfactorily describe the dynamic stress-strain relationships of the samples from test stability and failure zones. These findings are expected to make a significant contribution toward further revealing the sliding mechanism of such landslides.http://dx.doi.org/10.1155/2021/3330127
collection DOAJ
language English
format Article
sources DOAJ
author Jingjing Zhou
Fasuo Zhao
Yanbo Zhu
Wenqi Dong
Ziguang He
spellingShingle Jingjing Zhou
Fasuo Zhao
Yanbo Zhu
Wenqi Dong
Ziguang He
Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer
Shock and Vibration
author_facet Jingjing Zhou
Fasuo Zhao
Yanbo Zhu
Wenqi Dong
Ziguang He
author_sort Jingjing Zhou
title Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer
title_short Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer
title_full Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer
title_fullStr Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer
title_full_unstemmed Dynamic Behavior and Constitutive Relationship of Mudstone Slip Zone of Landslide with Weak Interlayer
title_sort dynamic behavior and constitutive relationship of mudstone slip zone of landslide with weak interlayer
publisher Hindawi Limited
series Shock and Vibration
issn 1875-9203
publishDate 2021-01-01
description Sliding zone dynamics in the Qinling-Daba mountain area under different dynamic parameters have not been studied extensively. In this study, we investigated the dynamic behavior of the sliding zones of a high-steep rock landslide in the Qinling-Daba mountain area under the influence of dynamic stress amplitude and frequency and proposed an empirical model of the dynamic constitutive relationship. The dynamic behavior was studied based on a cyclic triaxial test system. The results indicated that an increase in the dynamic stress amplitude decreased the dynamic elastic modulus linearly, increased the damping ratio, and increased the axial strain exponentially. Among these properties, the elastic strain was found to be more sensitive to the increase in the dynamic stress amplitude than the plastic strain. As the loading frequency increased, the dynamic elastic modulus increased, whereas the damping ratio decreased. Furthermore, the proposed empirical model of the dynamic constitutive relationship between the vibration number and loading frequency based on the dynamic elastic modulus could satisfactorily describe the dynamic stress-strain relationships of the samples from test stability and failure zones. These findings are expected to make a significant contribution toward further revealing the sliding mechanism of such landslides.
url http://dx.doi.org/10.1155/2021/3330127
work_keys_str_mv AT jingjingzhou dynamicbehaviorandconstitutiverelationshipofmudstoneslipzoneoflandslidewithweakinterlayer
AT fasuozhao dynamicbehaviorandconstitutiverelationshipofmudstoneslipzoneoflandslidewithweakinterlayer
AT yanbozhu dynamicbehaviorandconstitutiverelationshipofmudstoneslipzoneoflandslidewithweakinterlayer
AT wenqidong dynamicbehaviorandconstitutiverelationshipofmudstoneslipzoneoflandslidewithweakinterlayer
AT ziguanghe dynamicbehaviorandconstitutiverelationshipofmudstoneslipzoneoflandslidewithweakinterlayer
_version_ 1717780180622114816