查看完整版本: [-- soil-structure interaction --]

-> 论文写作与文献 -> soil-structure interaction [打印本页] 登录 -> 注册 -> 回复主题 -> 发表主题

wangyanqiao 2008-07-08 12:59

soil-structure interaction

希望对大家有用

south860592 2008-07-08 13:52
小论文吗?

wangyanqiao 2008-07-09 10:44
是的。。。。。

pipilu1984 2008-07-16 08:46
Soil–structure interaction in yielding systems

The eects of soil–structure interaction in yielding systems are evaluated, including both kinematic and
inertial interaction. The concepts developed previously for interacting elastic systems are extended to
include the non-linear behavior of the structure. A simple soil–structure system representative of codedesigned
buildings is investigated. The replacement oscillator approach used in practice to account for
the elastic interaction eects is adjusted to consider the inelastic interaction eects. This is done by
means of a non-linear replacement oscillator dened by an eective ductility together with the known
eective period and damping of the system for the elastic condition. To demonstrate the eciency
of this simplied approach, extensive numerical evaluations are conducted for elastoplastic structures
with embedded foundation in a soil layer over elastic bedrock, excited by vertically propagating shear
waves. Both strength and displacement demands are computed with and without regard to the eect of
foundation exibility, taking as control motion the great 1985 Michoacan earthquake recorded at a site
representative of the soft zone in Mexico City. Results are properly interpreted to show the relative
eects of interaction for elastic and yielding systems. Finally, it is demonstrated how to implement this
information in the context of code design of buildings. Copyright ? 2003 John Wiley & Sons, Ltd.
KEY WORDS: eective damping; eective ductility; eective period; elastic system; yielding system;
soil–structure interaction

pipilu1984 2008-07-16 08:46
Soil-Structure Interaction and Imperfect Trench Installations
for Deeply Buried Concrete Pipes

Abstract: The imperfect trench installation method is used to reduce earth pressure on buried concrete pipes. Few quantitative refinements
to the imperfect trench installation method, however, have been added since the fundamental mechanics of the reverse arching
action were proposed by Marston and Spangler. There have been limited research results published regarding, primarily, qualitative
aspects of earth load reduction for imperfect trench conditions. This paper identifies variables that significantly affect earth loads, as well
as the effects of bedding and sidefill treatments. An optimum geometry for imperfect trench installations with regard to a soft material
zone is presented to maximize the earth load reduction effects. The optimization process was based on parametric studies of the geometry
and location of the soft zone, bedding, and sidefill treatments to reduce earth pressures. Predictor equations for earth load reduction rates
were formulated incorporating the optimum geometry for the soft zone and bedding and sidefill treatments.
DOI: 10.1061/ASCE1090-02412007133:3277
CE Database subject headings: Backfills; Buried pipes; Concrete pipes; Embankments; Finite element method; Installation; Poisson
ratio; Soil-structure interaction.

pipilu1984 2008-07-16 08:47
Numerical Simulation of Vertical Pullout of Plate Anchors in Clay
Abstract: The behavior of strip and circular plate anchors during vertical pullout in uniform and normally consolidated clays was studied
in this paper by means of small strain and large deformation finite-element analyses. Both fully bonded attached, and “vented” no
suction on rear face, anchors were considered. The current numerical results were compared with existing laboratory test data, finiteelement
results, and analytical solutions. This study showed that, in small strain analysis, the scatter of existing data was mainly due to
the effect of soil stiffness. In large deformation analysis, when soil and anchor base were attached with suction, the pullout capacity factor
formed a unique curve independent of the soil strength su, soil effective unit weight  and anchor size Bwidth of strip anchor and
Ddiameter of circular anchor. The transitional embedment depth ratio, HSD/B or HSD/D, where HSDtransition depth between shallow
and deep embedment was 1.4 for a strip anchor and 0.75 for a circular anchor. The ultimate pullout capacity factors Nc for deep
embedment were 11.6 and 11.7 for smooth and rough strip anchors and 13.1 and 13.7 for smooth and rough circular anchors, respectively.
However, when the anchor base was vented, the soil stayed attached to the anchor base for deep embedment, and the pullout capacity was
therefore the same as for the attached anchor. The separation depth ratio, Hs /B or Hs /D, where Hsembedment depth at which the soil
and anchor base separated was found to increase linearly with the normalized strength ratio, su /B or su/D.
DOI: 10.1061/ASCE1090-02412008134:6866
CE Database subject headings: Anchors; Pull out resistance; Soil strength; Deep water; Finite element method; Deformation.

jelod 2008-07-16 13:44
不错。谢谢

phdsxc 2008-07-20 20:10
好象是好东西,到时下载看看.

phdsxc 2008-07-20 20:11
谢谢 [s:65]  [s:65]  [s:65]  [s:65]

忍者家的猫 2009-06-09 13:32
新会员不给下啊~~~~   

fanjunwei 2019-05-04 18:00
岩土与结构相互作用应该是比较难的!


查看完整版本: [-- soil-structure interaction --] [-- top --]



Powered by phpwind v8.7 Code ©2003-2011 phpwind
Time 0.034094 second(s),query:5 Gzip enabled