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弹性基底上受非均匀荷载加劲板的局部屈曲特性

张宁 刘永健 李慧 Siegfried FSTIEMER

张宁, 刘永健, 李慧, Siegfried FSTIEMER. 弹性基底上受非均匀荷载加劲板的局部屈曲特性[J]. 交通运输工程学报, 2017, 17(1): 36-44.
引用本文: 张宁, 刘永健, 李慧, Siegfried FSTIEMER. 弹性基底上受非均匀荷载加劲板的局部屈曲特性[J]. 交通运输工程学报, 2017, 17(1): 36-44.
ZHANG Ning, LIU Yong-jian, LI Hui, Siegfried F STIEMER. Local buckling characteristics of stiffened rectangular plate on elastic foundation subjected to non-uniform loads[J]. Journal of Traffic and Transportation Engineering, 2017, 17(1): 36-44.
Citation: ZHANG Ning, LIU Yong-jian, LI Hui, Siegfried F STIEMER. Local buckling characteristics of stiffened rectangular plate on elastic foundation subjected to non-uniform loads[J]. Journal of Traffic and Transportation Engineering, 2017, 17(1): 36-44.

弹性基底上受非均匀荷载加劲板的局部屈曲特性

基金项目: 

国家自然科学基金项目 51378068

交通运输部建设科技项目 2013 318 812 410

中央高校基本科研业务费专项资金项目 310821151101

详细信息
    作者简介:

    张宁(1981-), 男, 辽宁大连人, 西北农林科技大学讲师, 工学博士, 从事桥梁工程研究

  • 中图分类号: U443.31

Local buckling characteristics of stiffened rectangular plate on elastic foundation subjected to non-uniform loads

More Information
    Author Bio:

    ZHANGNing(1981-), male, lecturer, PhD, +86-29-82334577, johning@live.cn

  • 摘要: 针对弹性基底上板的局部稳定问题, 应用能量法推导了非均匀荷载作用下矩形加劲板的局部屈曲非线性特征方程, 建立了考虑弹性基底接触和纵向加劲肋作用的屈曲板迦辽金表达式; 基于牛顿迭代法, 建立了局部屈曲的非线性特征方程的增量迭代格式与屈曲荷载特征值的附加迭代方程。分析结果表明: 屈曲系数计算结果与有限元分析结果误差小于2%, 并且避免了有限元模拟的接触分析过程, 计算效率较高; 当荷载梯度为1时, 设置加劲肋的偏心构件的局部稳定性明显增强, 临界屈曲系数增加到51.1, 是普通板件的2.5倍; 加劲板件的纵向鼓曲波的长宽比约为0.6, 鼓曲波纵向排列相对密集, 而普通板件每个鼓曲波的长宽比约为1.0;在不增加加劲肋材料用量的前提下, 设置纵向加劲肋的最优位置为距离板件受压侧边缘的2/5板宽处, 临界屈曲系数增加为78.9, 是普通板件的4倍; 加劲肋的设置可将矩形钢管混凝土壁板的宽厚比增加到172, 将界限值提高2倍以上。可见, 在矩形钢管混凝土管壁设置纵向加劲肋能够有效提高偏压作用下管壁的局部稳定性, 改善矩形钢管混凝土的截面尺寸。

     

  • 图  1  非均匀受压的矩形加劲板

    Figure  1.  Rectangular stiffened plate subjected to non-uniform compression

    图  2  加劲板在弹性基底上的屈曲

    Figure  2.  Buckling of stiffened plate on elastic foundation

    图  3  屈曲特征方程的迭代求解过程

    Figure  3.  Iterative solution process of buckling characteristic equation

    图  4  加劲板横截面的屈曲变形

    Figure  4.  Buckling deflections of cross section for stiffened plate

    图  5  屈曲系数计算值对比

    Figure  5.  Comparison of computational values for buckling coefficient

    图  6  屈曲系数与荷载梯度的关系曲线

    Figure  6.  Relationship curves between buckling coefficient and stress gradient

    图  7  钢管混凝土偏心受压模式

    Figure  7.  Eccentric compression mode of concrete filled steel tube

    图  8  板件屈曲系数分布曲线

    Figure  8.  Distribution curves of buckling coefficients of plates

    图  9  不设置加劲肋板件的典型屈曲模态

    Figure  9.  Typical buckling mode of plate without stiffening rib

    图  10  设置加劲肋板件的典型屈曲模态

    Figure  10.  Typical buckling mode of plate with stiffening rib

    图  11  屈曲模态1

    Figure  11.  Buckling mode 1

    图  12  屈曲模态2

    Figure  12.  Buckling mode 2

    图  13  屈曲模态3

    Figure  13.  Buckling mode 3

    表  1  屈曲系数对比

    Table  1.   Comparison of buckling coefficients

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  • 收稿日期:  2016-10-12
  • 刊出日期:  2017-02-25

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