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建立如图 2 所示的单桩二维分析模型 , 分析中假定 :1 桩的存在不影响基坑的开挖及围护结构的水平位移 ( 与文献 [1] 相同 );2 桩土相互作用由非线性弹簧来模拟 , 桩土不发生脱离 ;3 桩径不变 , 桩身为线弹性 ;4 基坑外土体不可压缩 ;5 不考虑桩身轴力对水平变形的影响。 f (h) 坑底围护结构地表 h H X 小应变围护结构 h 地表 X f (h) H dh 对称地表 h 微单元体 dh X 2f (h) 面积等效 2a L P 地表 2r0 桩 H H 0 u t uc 开挖面 u b h dh f (h) 围护结构 H 0 / 2 H 0 / 2 X 虚拟节点 -2 -1 0... i-1 i i+1 n... 节点放大 ω p,i ω s,i p i p i =f (ω s,i -ω p,i ) Z Z (a) (b) (c) Z E p I p Z n+1 n+2 虚拟节点 ω s,i -ω p,i 图 1 坑外土体位移计算模型图 2 邻近单桩水平响应的预测模型由弹性地基梁桩体挠曲微分方程可得 : 4 4 EI p pd ωp( z)/dz −2 r0[ ωs( z) − ωp( z)]/ ⎡1/ kni ωs( z) ωp( z) / pu( z) ⎤ ⎣ + − ⎦ = 0. (8) 用差分代替微分得 : 4 EI( ω − 4ω + 6ω − 4 ω + ω )/ λ = 2 r( ω − ω )/[1/ k + ω − ω / p ], (9) p p p, i+2 p, i+1 p, i p, i−1 p, i−2 0 s, i p, i ni s, i p, i u, i 式中 ,i=0,1,…,n; ω p,i 为桩身 i 节点挠曲值 ; ω s,i 为第 i 节点处自由场土体水平位移 ; k ni 为土体的初始地基反力系数 ; p u,i 为第 i 节点处的土体极限抗力值。桩顶桩底的边界条件为 : 3 ⎪ ⎧ωp,2 − 2ωp,1 + 2 ωp, −1 − ωp, −2 = (2 HF / EpIp ) λ = 0 桩顶 ( 外荷载 H F 及 M 均取为 0): ⎨ . (10) 2 ⎪⎩ ωp, −1 − 2 ωp,0 + ωp,1 = ( M / EpIp ) λ = 0 桩底 : ⎧ ⎪ ωp, n+2 − 2ωp, n+1 + 2ωp, n−1 − ωp, n−2 = 0 ⎨ . (11) ⎪⎩ ωp, n−1 − 2ωp, n + ωp, n+1 = 0 在此采用增量法求解式 (9)。令 δ = ωs( z) − ωp( z) , 即 δi = ωs, i − ωp, i , 将式 (9) 写成增量形式 , 即 : [ K ] Δ ω = [ K ] Δ δ = [ K ] Δω −Δ ω (12) 其中 ,{ ω p,i } p { p, i} s { i} s { s, i p, i} Δ 为桩身水平位移增量列向量 ,{ ω s,i } Δ 为桩身处自由场水平位移增量列向量 ,[ K p ] 及 [ Ks ] 分别为桩体刚度矩阵及土弹簧刚度矩阵。假定进行第 m 个增量步的求解时 ,[ K ] m 由第 m-1 增量步求的 { } m − 1 δ i 所对应的切线刚度确定 , 则 [ K p ] 及 [ K s ] 可根据式 (1) 及前一增量步的计算结果确定。五、方法验证选取文献 [6] 中的 “Basic Problem” 来进行对比验证。基坑围护结构深 13m, 开挖深度 10m; 地层为饱和软黏土 , 容重为 20kN/m 3 , c u 为 40kPa, E s 为 16MPa; 桩长 L = 22 m, 桩径为 500mm, E p = 30 Gpa, 桩距离基坑 x = 1 m。计算中假定 E i 为 32MPa( 约为 1600 c u ) [11] , 泊松比 v s 取 0.5。图 3 显示了 Poulos 法与本文方法计算结果的对比情况 , 由图可知 , 在 “ 挖至 -3m” 和 “ 挖至 -6m” 两种工况下 , 二者结果几乎重合 , 在 “ 挖至 -8m” 工况下 , 上半部分也完全吻合 , 下半部分存在一定的差别。总体上看 , 两种方法计算得到的桩轴线上自由场水平位移、桩身的水平位移及桩身弯矩等均表现出较好的一致性 , 本文提出的算法是合理可行的。六、结语本文提出了基于基坑测斜曲线评估基坑外任意一点土体水平位移的计算表达式 , 并考虑桩土界面水平荷载传递的非线性特性 , 给出一种由围护结构监测信息动态预测既有邻近单桩水平附加变形 s -397-
及附加内力的简单方法 , 利用该方法可以及时反馈邻近桩基的预警状态及演变趋势。实例分析表明 , 本文所提出方法的计算结果是合理可行的 , 能够较为有效地分析基坑开挖对邻近单桩的影响规律。深度 (m) 0 -5 -10 -15 -20 -25 Poulos 法 : 挖至 -3m -3m 挖至 -6m -6m 挖至 -8m -8m 本文挖方至法 -3m : 挖至 -6m -3m 挖至 -8m -6m 挖至 -8m 0.00 0.01 0.02 0.03 0.04 0.05 桩身水平位移 (m) (a) 自由场水平位移深度 (m) 0 -5 -10 -15 -20 -25 本文方法 : 挖至 -3m 挖至 -6m 挖至 -8m Poulos 法 : 挖至 -3m 挖至 -6m 挖至 -8m -50 0 50 100 150 桩身弯矩 (kNm) (b) 桩身弯矩图 3 与 Poulos 法计算结果的对比参考文献 [1] 杜金龙 , 杨敏 . 基坑开挖与邻近桩基相互作用的弹塑性解 . 岩土工程学报 , 2008, 30(8): 1121-1125. [2] Finno, R. J., Lawence, S. A. and Allawh, N. F. Analysis of performance of pile groups adjacent to deep excavation. Journal of Geotechnical Engineering, ASCE, 1991, 117(6): 934-955. [3] Poulos, H. G., and Chen, L. T. Pile response due to excavation- induced lateral soil movement. Journal of Geotechnical and Geoenvironmental Engineering, ASCE, 1997, 23(2): 94-99. [4] 杨敏 , 周洪波 , 杨桦 . 基坑开挖与临近桩基相互作用分析 . 土木工程学报 , 2005, 38(4): 91-96. [5] Poulos, H. G. and Davis, E. H. Elastic Solution for Soil and Rock Mechanics. Sydney: John Wiley & Sons, Inc, 1973. [6] Poulos, H. G. and Chen, L. T. Pile response due to excavation induced lateral soil movement. Journal of Geotechnical and Geoenvironmental Engineering, ASCE, 1997, 123(2): 94-99. [7] Xu, K. J. and Poulos, H. G. 3-D elastic analysis of vertical piles subjected to “passive” loadings. Computers and Geotechnics, 2001, 28: 349-375. [8] 黄茂松 , 张陈蓉 . 开挖条件下非均质地基中被动群桩水平反应分析 . 岩土工程学报 , 2008, 30(7): 1017-1023. [9] Huang, M. S. and Zhang, C. R. A simplified analysis method for the influence of tunneling on grouped piles. Tunnelling and Underground Space Technology, 2009, 24(4): 410-422. [10] Kondner, R. L. Hyperbolic stress-strain response: cohesive soils. Journal of the Soil Mechanics and Foundation Engineering Division, ASCE, 1963, 89(SM1): 115-143. [11] Goh A. T. C., Teh, C. I. and Wong, K. S. Analysis of piles subjected to embankment induced lateral soil movements. Journal of Geotechnical and Geoenvironmental Engineering, ASCE, 1997, 123(9): 792-801. [12] Vesic, A. S. Bending of beams resting on isotropic elastic solid. Journal of the Engineering Mechanics Division, ASCE, 1961, 87: 35-53. [13] Broms, B. B. <strong>The</strong> lateral resistance of piles in cohesionless soils. Journal of Soil Mechanics and Foundation Engineering, ASCE, 1964, 90(3): 123-156. [14] Reese, L. C., Cox, W. R., and Koop, F. D. Analysis of laterally loaded piles in sand. Proceedings of the 6th Annual Offshore Technology Conference, Houston, 1974: 473-483. [15] Sagaseta, C. Analysis of undrained soil deformation due to ground loss. Geotechnique, 1987, 37(3): 301-320. [16] Xu, K. J. and Poulos, H. G. <strong>The</strong>oretical study of pile behaviour induced by a soil cut. Proceedings of GeoEng 2000, Melbourne, 2000. -398-
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Proceedings of the 5th Cross-strait
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SCIENTIFIC COMMITTEE Chairman Jan-M
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ORGANIZING COMMITTEE Co-chairmen Yi
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设计大师金问鲁教授
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TABLE OF CONTENTS Scientific Commit
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J.T. Shi & L. Su Impact of Spatial
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Temperature Effect on Variation of
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Trace Analysis of Mechanical Respon
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Keynote Lectures
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图 1 海峡大桥三个路
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非主通航孔的跨径应
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The 5th Cross-strait Conference on
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图 3 空间结构按单元
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图 7 多面体空间框架
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图 14 内蒙古响沙湾沙
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5.3. MRF3 索穹顶 — 网壳
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图 29 杭州黄龙体育中
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(a) 鸟瞰图 (b) 计算模型
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As it is conventional, the displace
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⎡ n n ⎤ ⎢q 1 0( z− Li) q0(
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frequencies of interest and the tra
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Another phenomenon observed from Fi
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刚塑性平面应变极限
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采用数值极限分析法
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为了推测浅埋隧洞破
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鹤梁岩壁面上至今已
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图 6 黄庭坚题铭 “ 元
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图 16 巫山神女图 17 长
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五、历年来研究过的
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在会议结束前给我半
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图 31 院士建议文件的
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科所、重庆交通学院
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图 37 白鹤梁题刻中段
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图 46 上下游水平交通
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图 59 参观廊道安装在
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9.6. 白鹤梁水下博物
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(5) “ 无压容器 ” 水下
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-62-
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-64-
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-66-
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-68-
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(a) 模型 I (b) 模型 II (c)
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(a) 水平接缝处螺钉松
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表 5 模型 I 在 9 度罕遇
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1.2. 大型钢结构设计
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5250 5000 i= 0.07 1 i= 0.07 5000 16
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A Pb Pa Pb A Pb Pa Pb Pa Pa ax Pb P
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(a) 预应力索布置 (b) 1/6
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图 23 150m×150m 周边简支
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图 27(a) 自重作用下结
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四、结语 150m×150m 空间
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通过上述技术创新平
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* θt r1cosθ r2cosθ2 = = (9) * 1
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圖 10 水平軌枕方向之
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圖 19 水平軌枕方向之
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向量 r r &r r 的變化率
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Experimental Program More than 60 l
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failure mode specimens, applying CF
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columns were reinforced with three
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e formed at the column base and the
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Acceleration (g) 1 0.5 0 -0.5 Simul
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Table 2 Mix Proportion of the PDCC
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observed between the formwork and c
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In the above example, the GFRP with
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构的加固修复 , 二是
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FRP 网格 FRP 筋和索 FRP 布
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(2) 钢筋 - 连续纤维复
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生退化。拉伸强度相
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图 16 两种纤维混杂增
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σ tf 混凝土构件粘结
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新型抗震结构的荷载
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的破坏过程也与柱 C-S
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拉索频率阶数也低于
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A m plitude (m m ) 6000 5000 4000 3
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产工艺进行探索性研
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Girders with Externally Prestressed
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concrete columns were documented by
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fatigue life of steel columns. Xiao
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Figure 11 Relationships between res
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20. Xiao, Y. and Wu, H. (2000). “
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phenomenon, however, cannot be cons
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ase rock; H j ( iω) , H k ( iω) a
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For the coherency loss function bet
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Numerical Results The earthquake-in
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REFERENCES Bi, K., Hao, H. and Ren,
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Figure 3 Idealised bonded joint mod
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A = 0 1 (6a) B1 = −δ f (6b) f si
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Table 1 Test and predicted flexural
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COMPARISON OF FLEXURAL DEBONDING MO
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Figure 2 Location of smart aggregat
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Figure 5 Experimental setup Figure
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Figure 15 Impact location on FRP wr
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REFERENCES Bhalla, S. and Soh, C.K.
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The RVE, occupying a geometrical do
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[ ut ] is the tangential vector if
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extended to the resolution of the n
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469.1m,f m =55%,f I =45% -50 Σ 3 -
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頭混凝土護蓋敲除 ,
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發生夾片咬合失敗 ,
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會因設計長度不足 ,
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面之反推分析可知 ,
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因此連擋土牆本身之
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⎛τ ⎞ av ⎛amax ⎞⎛σ ⎞ v
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地液化与否初步判别
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等 (2000) [15] 在试验中都
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五、结论剪切波速法
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钢混凝土相当于将型
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A g — 混凝土毛截面面
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5.1. 大连市体育馆钢
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土梁中设立直线预应
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混凝土板外侧 , 受力
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试验采用跨中两点对
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为了深入了解槽型钢
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笔者针对已有结合部
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面 , 浇注的混凝土和
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(c) 波形钢腹板工字型
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manner for statistical analysis, (i
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3.3.1 Software System for Instrumen
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spectrum is obtained in an approxim
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e carried out once per maintenance
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The monitoring work is composed of
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displacement influence lines and st
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efers to data processing and storag
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Hong Kong Institution of Engineers.
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Monitoring Category Bridge Features
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9 Combination of Above Divided Sect
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Back to Routine Monitoring Not Exce
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Tsing Yi Stonecutters Figure 5 Layo
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Continuous Data Acquisition GPS Tim
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Y(+ve) Y T Temperature Distribution
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Type of Input Data Type of Data Pro
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Tsing Yi Stonecutters Stonecutters
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青衣 Tsing Yi 昂船洲 Stonec
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Accelerometer Fixing of Portable Ac
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Tsing Yi Stonecutters Bridge Stonec
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Structural Health Data Management S
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a mean recurrence interval with ext
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The present study is concerned with
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which all the variables have the sa
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450 35 400 30 350 300 25 ( 1.0E- 6)
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Structural Engineering and Mechanic
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provided in DBELA, a base rotation
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ξ ( μ − ) 3 eq −ξ0 = C + D 1
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equivalent displacements exceed the
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Displacement (cm) 70 60 50 40 30 20
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it give rather reasonable results,
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RANDOM FIELD AND SPATIAL AVERAGING
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satisfactorily when SOF is large bu
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those of the average shear strength
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then rinsed three times with deioni
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The Freundlich model can be express
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Ministry of Education for their fin
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United States.) The available site
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ACKNOWLEDGMENTS Financial support f
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the author has quoted the outdated
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Figure 5 The geological map of 2000
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Figure 11 Rock cores of vent brecci
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Due to the misidentification of roc
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ACKNOWLEDGEMENT The author would of
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Recently, as the development of fin
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( x ) ( x ) L m ( x ) ( x ) ( x ) L
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Step1: initializing the nonlinear o
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Table 1 The results of limit load m
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Page 369 and 370: 阿坝州没有水库 , 凉
Page 371 and 372: 汶川地震中属于溃坝
Page 373 and 374: 缝宽约 2mm~5mm; 纵向断
Page 375 and 376: The 5th Cross-strait Conference on
Page 377 and 378: Problem with Seismic Hazard Analysi
Page 379 and 380: INADEQUACY OF TSUNAMI MITIGATION ST
Page 381 and 382: demonstrated that huge earthquake c
Page 385 and 386: 三、粮库室内地面沉
Page 387 and 388: 土层的物理力学参数
Page 389 and 390: 笔者对 4# 粮库的沉降
Page 391 and 392: 二国标中主动土压力
Page 393 and 394: 表 3 c =0kPa 时不同的 δ
Page 395 and 396: 的值比公式 (1) 的值小
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Page 399 and 400: (3) 根据对隧道典型断
Page 401 and 402: 水平收敛位移 (mm) 12.00
Page 405 and 406: THREE PROCEDURES FOR SCALING GROUND
Page 407 and 408: Peak displacement (m) 84, 50, 16 pe
Page 409 and 410: CONCLUSIONS Performance-based desig
Page 413 and 414: Figure 3 Physical diagrams of pile
Page 415 and 416: load-deflection curve at the pile h
Page 417: 在此选取 Kondner [10] 及 Go
Page 423 and 424: The dual is min * w, b, ξξ , s.t
Page 425 and 426: Table 1 The results of example 1 Re
Page 427 and 428: P P P P P P P P P P P P 4 5 4 A 2 4
Page 431 and 432: Figure 2 is a photograph of the int
Page 433 and 434: SHAKING TABLE TEST PROGRAM System i
Page 435 and 436: Force (N) 600 500 400 300 200 100 N
Page 437 and 438: Figure 9 Comparison of SAF-TMD and
Page 441 and 442: 鋼線 , 近期更發展為
Page 443 and 444: 三、吊橋基本資料表
Page 445 and 446: 底端固定型式 □ 夾具
Page 447 and 448: 4.2.3 吊橋扭轉行為之
Page 451 and 452: 由式 (11)~(13) 可求得闭
Page 453 and 454: 3.2 脉动风压时程结构
Page 455 and 456: 4.2 主动控制力分析图
Page 459 and 460: egarded as a serviceability limit s
Page 461 and 462: observed that the measured values c
Page 463 and 464: _ Cumulative Frequency of Samples (
Page 465 and 466: 三个项目基本概况对
Page 467 and 468: 风作用下基底总 X 向 7
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主要技术指标对比表
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六、上部结构材料用
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m 2 , 三个项目采用混
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STADIUM ROOF BRIEF Jaber Al-Ahmad I
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a) 1st modal shape Figure.7 Modal s
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1) 所需的机具设备少
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6.1. 挠度选取典型加
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七、结论通过上述研
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where c = cope length,D = beam dept
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A post-ultimate stiffness of 200 MP
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Table 3 Summary of the variables of
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Effects of Web Slenderness (d/t w )
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REFERENCES ABAQUS/Standard User’s
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规程 [7]。文献 [2]、[3]
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为探究球节点壁厚对
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[4] 王星 , 董石麟 , 完海
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一、前言鋼纜為斜張
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圖 1 愛蘭矮塔斜張橋
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態頻率後 , 由圖 6 可清
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素連接 , 假設兩構件
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图 3 半片梁的有限元
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加固前的钢筋混凝土
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and a corresponding shear strain of
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对温度变化效应进行
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典型节点 : 在钢结构
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钢结构第一阶振型为
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(a) 上支座节点 (b) 下支
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上部屋面钢结构下部
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验算 4、6 号线重力荷
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采用 SAP2000, 对各种截
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高屏溪引橋共包含五
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表 3 由高屏溪斜張橋
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圖 7 垂直撓曲第一振
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表 7 在 P2 橋墩不同沖
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