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1.
The seismic stability of reinforced earth has been investigated in this paper using pseudo-static method of analysis considering horizontal and vertical seismic acceleration with non-linear failure surface. The sliding wedge is divided into a number of horizontal slices to determine the strength and length of the geo-synthetic reinforcement for seismic internal stability of battered face rigid retaining wall supporting c-Φ backfill. Results are presented in graphical form representing the required length of geo-sythetic reinforcement under seismic condition to maintain the internal stability of reinforced soil. The influences of horizontal and vertical seismic acceleration, soil friction angle, cohesion, adhesion and wall inclination angle on the required length of the geo-sythetic reinforcement have been studied. From the present study it is seen that the required length of geo-synthetic reinforcement increases due to increase in the value of seismic accelerations. 相似文献
2.
Deepankar Choudhury Kanakapura. S. Subba Rao 《Geotechnical and Geological Engineering》2004,22(1):59-72
Uplift capacity of horizontal strip anchors in soil embedded under an inclined ground surface has been obtained under seismic
conditions. Limit equilibrium approach with logspiral failure surface together with pseudo-static seismic forces has been
adopted. The results have been presented in the form of seismic uplift capacity factors as functions of ground inclination,
embedment ratio, angle of internal friction of the soil and seismic acceleration coefficients. The uplift capacity factors
have been worked out separately for cohesion, surcharge and density components. Effect of the vertical seismic acceleration
coefficient has been found to always reduce the uplift capacity whereas the effect of horizontal seismic acceleration coefficient
has been found to reduce the uplift capacity in most of the cases. The obtained results of seismic uplift capacity factors
are found to be the minimum when compared with the results available in literature on the basis of planar failure surface.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
3.
4.
This paper extends a previously developed three-part wedge method for the seismic stability analysis of the landfill with a triangular berm using pseudo-static method, and moreover, the translation failure condition of the landfill along under bottom of the berm is only presented. In the seismic impact zone, it is necessary to consider the impact of the seismic force on the stability of the landfill. Generally, apart from the horizontal seismic force, the landfill is also subjected to both upward and downward vertical seismic forces. The downward vertical seismic force has a positive impact on the seismic stability of the landfill, while the upward vertical seismic force is just opposite. Therefore, simply ignoring vertical seismic force, the seismic stability of the landfill will be overestimated or underestimated in the seismic condition. Besides, the seismic yield coefficient is calculated by assuming FSV = 2FS and the ratio of vertical seismic coefficient to horizontal seismic coefficient is equal to 2/3. 相似文献
5.
This paper presents a method to evaluate reliability for internal stability of reinforced soil structures using reliability
based design optimization. Using limit equilibrium method and assuming the failure surface to be logarithmic spiral, analysis
is conducted to maintain internal stability against both tensile and pullout failure of the reinforcements. Properties of
backfill soil and strength of the geosynthetic reinforcement are considered as random variables. For the seismic conditions,
reliability indices of all the geosynthetic layers in relation to tension and pullout failure modes are determined for different
magnitudes of seismic accelerations both in the horizontal and vertical directions, surcharge load and design strength of
the reinforcement. The efforts have been made to obtain the number of layers, pullout length and total length of the reinforcement
at each level for the desired target reliability index values against tension and pullout modes of failure. The influence
of horizontal and vertical earthquake acceleration, surcharge load, design strength of the reinforcement, coefficient of variation
of soil friction angle and design strength of the reinforcement on number of layers, pullout length and total length of the
reinforcement needed for the stability at each level is discussed. 相似文献
6.
Sunil M. Rangari Deepankar Choudhury D. M. Dewaikar 《Geotechnical and Geological Engineering》2013,31(2):569-580
In this paper, the limit equilibrium method is used to compute seismic passive earth pressure coefficients and the vertical uplift capacity of horizontal strip anchors in presence of both horizontal and vertical pseudo-static earthquake forces. By considering a simple planar failure surface, distribution of soil reaction is obtained through the use of Kötter’s equation. Presence of pseudo-static seismic forces induces a considerable reduction in the seismic passive earth pressure coefficients. The reduction in seismic passive earth pressure coefficients increases with increase in magnitude of the earthquake accelerations in both horizontal and vertical directions and with increase in wall friction angle. The vertical uplift capacity of horizontal strip anchor is obtained for various values of soil friction angle, embedment ratio and seismic acceleration coefficients in both horizontal and vertical directions by using rigorous computational optimization. Proper justification for selected value of wall friction angle is established. Results are presented in the form of non-dimensional breakout factor for anchor. A significant reduction in breakout factor is observed in presence of both the seismic acceleration coefficients whereas breakout factor increases with increase in soil friction angle and embedment ratio even under the seismic condition. Angles of failure planes keep changing with change in seismic acceleration coefficients and failure zone shifts towards the critical direction of seismic acceleration coefficients. Present results are compared and found in good agreement with some specific available results in literature. 相似文献
7.
Seismic Passive Earth Thrust on Retaining Walls with Cohesive Backfills Using Pseudo-Dynamic Approach 总被引:2,自引:1,他引:1
A. H. Shafiee A. Eskandarinejad M. Jahanandish 《Geotechnical and Geological Engineering》2010,28(4):525-531
In this paper, the pseudo-dynamic approach is used to estimate seismic passive earth thrust on retaining walls with cohesive-frictional
backfills. The time-dependent pseudo-dynamic approach considers the influence of dynamic parameters such as the velocity of
primary and shear waves, the period of lateral shaking, and the phase and amplitude variations of horizontal and vertical
earthquake accelerations with depth. The failure plane behind the wall is assumed to be planar. The analysis is based on the
equilibrium of forces which act within the failure wedge. The obtained results show that the backfill cohesion increases both
the seismic passive earth thrust and the failure plane inclination angle with the horizontal plane. It is also observed that
both horizontal and vertical seismic accelerations have decreasing effect on seismic passive earth thrust as well as failure
plane inclination angle. The results of present pseudo-dynamic analysis propose a lower solution for seismic passive earth
thrust compared to earlier pseudo-static solution available in the literature. 相似文献
8.
The paper pertains to the pseudo-static seismic stability analysis of reinforced soil structures. Using limit equilibrium
method and assuming the failure surface to be logarithmic spiral, analysis has been conducted to maintain internal stability
against both tensile and pullout failure of the reinforcements. The external stability of the reinforced earth wall is also
assessed in terms of its sliding, overturning, eccentricity and bearing modes of failure. The influence of the intensity of
the surcharge load placed on the backfill is also considered in the analysis. The obtained results are validated by comparing
the same with those reported in literature. Studies have also been made regarding the influence of backfill soil friction
angle, horizontal and vertical seismic accelerations, surcharge load, the tensile strength of reinforcement, pullout length
of the reinforcement and number of reinforcement layers on the seismic stability against various failure modes as mentioned
earlier. 相似文献
9.
简述了某软土基坑复合土钉支护结构失稳过程,分析失稳原因,介绍工程治理措施.文中还对软土基坑与残积土基坑破坏机理进行探讨,提出了软土基坑按地层可分为双层软土基坑、三层软土基坑.三层软土基坑比双层软土基坑采用复合土钉支护结构能较优控制变形和提高稳定性.可供工程技术人员参考. 相似文献
10.
Probabilistic Horizontal Stress Ratios in Rock 总被引:1,自引:0,他引:1
Prior to excavation, any point in a rock mass is subjected to stress, which has to be considered in the overall stress distribution after the excavation work is completed. Over the past three decades, empirical, analytical, and field studies have shown that the ratio of average horizontal stress to vertical stress plays a dominant role in engineering structure design. Notationally, this ratio is referred to as the coefficient of lateral stress K, which is a dimensionless positive quantity. The intent of this paper was to bring out the intrinsic characteristic of K with the use of probabilistic and statistical techniques, which have not been considered extensively in any previous context. 相似文献
11.
Ground movement analysis of soil nailing construction by three-dimensional (3-D) finite element modeling (FEM) 总被引:10,自引:0,他引:10
In recent years, soil nailing has been widely used to stabilize excavated steep slopes. Its design is often controlled by the allowable deformation level especially when buildings and/or other underground facilities exit near the excavation. In this paper a three-dimensional (3-D) finite element model (FEM) has been developed for the deformation analysis of nailed soil structures. In this model, the soil nonlinearity, the soil–nail interaction and the staged construction are all considered. Parametric studies are carried out to investigate some influence factors on the deformation behavior. An engineering case is also analyzed and the predicted soil movements at various stages of excavation are compared with field measurements. Good agreement between the prediction and the measurements proves the reliability of the model. 相似文献
12.
River bank erosion control by soil nailing 总被引:2,自引:0,他引:2
A study has been done for analysing soil nailed cuts with circular type wedge failure by friction circle method. Various parameters
such as nail length, nail diameter, nail inclination, wall inclination and angle of internal friction of soil have been considered
to determine the factor of safety of nailed open cuts. The study shows that for cohesionless soil nailed cut, factor of safety
increase with increase of parameters like angle of internal friction of soil, length of nail (L) versus height of cut (H) ratio, cohesion of soil and nail inclination (upto 15°) with horizontal. The study revealed that nails grouted with cement
perform better than driven nails. A case study further confirms the analytical findings.
Received 7 October 相似文献
13.
旋转位移假设下,将挡土墙和填土看成一个系统,建立挡土墙在地震作用下的旋转破坏模式,应用极限分析上限法推导了系统外力功率和耗散功率,得到了水平屈服加速度系数的理论计算公式,并采用MATLAB语言进行数值求解,获得了破裂角和水平屈服加速度系数的数值解。计算公式考虑了填土与墙体接触面上的黏聚力、墙和填土的摩擦角、竖向地震加速度系数、填土黏聚力、填土内摩擦角等对水平屈服加速度系数的影响。研究结果表明:填土与墙体接触面上的黏聚力、墙和填土的摩擦角和竖向地震作用对水平屈服加速度系数的影响显著,在实际工程设计中需合理取值以达到安全经济的目的。 相似文献
14.
Seismic active earth pressure on walls with bilinear backface using pseudo-dynamic approach 总被引:2,自引:0,他引:2
This paper presents a study on the seismic active earth pressure behind a rigid cantilever retaining wall with bilinear backface using pseudo-dynamic approach. The wall has sudden change in inclination along its depth and a planar failure surface has been considered behind the retaining wall. The effects of a wide range of parameters like soil friction angle, wall inclination, wall friction angle, amplification of vibration, variation of shear modulus, and horizontal and vertical seismic accelerations on the active earth pressure have been explored in the present study. Unlike the Mononobe-Okabe method, which incorporates pseudo-static analysis, the present analysis predicts a nonlinear variation of active earth pressure along the wall. The results have been compared with the existing values in the literature. 相似文献
15.
By using pseudo-dynamic approach, a method has been proposed in this paper to compute the seismic passive earth pressure behind
a rigid cantilever retaining wall with bilinear backface. The wall has sudden change in inclination along its depth and a
planar failure surface has been considered behind the retaining wall. The effects of a wide range of parameters like soil
friction angle, wall inclination, wall friction angle, amplification of vibration, variation of shear modulus and horizontal
and vertical seismic accelerations on the passive earth pressure have been explored in the present study. For the sake of
illustration, the computations have been exclusively carried out for constant wall friction through out the depth. Unlike
the Mononobe-Okabe method, which incorporates pseudo-static analysis, the present analysis predicts a nonlinear variation
of passive earth pressure along the wall. 相似文献
16.
17.
R. Trizzino 《Engineering Geology》1987,23(3-4):263-276
A simple method for evaluating the seismic stability of embankments and slopes has been developed by modifying the generalized procedure of slices proposed by Janbu. A pseudostatic analysis is carried out. The seismic force is represented through its horizontal and vertical components, acting on the centre of gravity of the soil mass. Defining a nominal state of plastic equilibrium, the safety factor of the slope for a given value of the seismic force is obtained through an iterative procedure that converges very rapidly. Moreover, by assuming a seismic force of intensity varying from zero value (static condition) up to a limit value, depending on the seismicity of the area, one can obtain the “influence lines” of the horizontal and vertical acceleration. Finally, a directional parametric analysis has been carried out considering a seismic force of a given intensity, acting in a direction varying from 0° to 360° with respect to the vertical axis through the gravity centre of the slope. By means of this procedure it is possible to locate a “critical zone” for the slope, i.e., that one within which any seismic force can cause the failure of the slope. Moreover, it appears that it is incorrect to consider only the horizontal acceleration in the stability analyses of slopes under earthquake loading conditions, as the most dangerous direction is usually different from the horizontal one. 相似文献
18.
Seismic Passive Earth Pressure Behind Non-vertical Retaining Wall Using Pseudo-dynamic Analysis 总被引:3,自引:0,他引:3
Priyanka Ghosh 《Geotechnical and Geological Engineering》2007,25(6):693-703
This paper shows a detailed study on the seismic passive earth pressure behind a non-vertical cantilever retaining wall using
pseudo-dynamic analysis. A planar failure surface has been considered behind the retaining wall. The effects of soil friction
angle, wall inclination, wall friction angle, horizontal and vertical earthquake acceleration on the passive earth pressure
have been explored. Unlike the Mononobe–Okabe method, which incorporates pseudo-static analysis, the present analysis predicts
a nonlinear variation of passive earth pressure along the wall. The results have been thoroughly compared with the existing
values in the literature. 相似文献
19.
The Wenchuan earthquake triggered 15,000 rock avalanches, rockfalls and debris flows, causing a large number of causalities and widespread damage. Similar to many rock avalanches, field investigations showed that tensile failure often occurred at the back edge. Some soil and rock masses were moved so violently that material became airborne. The investigation indicates that this phenomenon was due to the effect of a large vertical seismic motion that occurred in the meizoseismal area during the earthquake. This paper analyses the effect of vertical earthquake force on the failure mechanism of a large rock avalanche using the Donghekou rock avalanche as an example. This deadly avalanche, which killed 780 people, initiated at an altitude of 1,300 m and had a total run-out distance of 2,400 m. The slide mass is mainly composed of Sinian limestone and dolomite limestone, together with Cambrian slate and phyllite. Static and dynamic stability analysis on the Donghekou rock avalanche has been performed using FLAC finite difference method software, under the actual seismic wave conditions as recorded on May 12, 2008. The results show that the combined horizontal and vertical peak acceleration caused a higher reduction in slope stability factor than horizontal peak acceleration alone. In addition, a larger area of tensile failure at the back edge of the avalanche was generated when horizontal and vertical peak acceleration were combined than when only horizontal acceleration was considered. The force of the large vertical component of acceleration was the main reason rock and soil masses became airborne during the earthquake. 相似文献
20.
土钉墙空间效应和平滑破坏模式的三维分析 总被引:5,自引:2,他引:5
在实际工程中,土钉墙稳定性评估一般采用转动破坏模式,且不考虑其空间效应对设计方案的影响,其结果是有时得到的结论与实际状况不相符合.本文采用三维极限分析方法,对土钉墙空间效应和平滑破坏两个方面的问题进行了讨论,并结合一实际工程,对它们进行了分析,得到一些初步结论,以期对实际工程有一定的参考价值. 相似文献