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摘要:
为了使得钢结构的性能与用钢量比达到最优,前人对槽型钢的截面尺寸优化进行了较为充分的研究。但是,涉及卷边角度的优化特别是偏心受压工况下的优化分析却很缺乏。以YaoTeng偏心受压计算公式,结合遗传算法,以冷弯卷边槽钢柱偏心受压为例,将槽钢卷边角度与偏心距作为设计变量,寻找在不同偏心距受压情况下,达到最大畸变屈曲临界应力的卷边角度。基于有限条分析程序,对两端简支与两端固支情况下不同截面尺寸构件的畸变屈曲临界应力进行了计算分析,最终得出不同偏心距受压下统一的最优卷边角度。为了方便工程设计人员设计时参考,建议卷边角度统一取为100°。
关键词:
偏心受压;斜卷边槽钢;有限条;遗传算法;最优卷边角度
中图分类号:TU391
文献标志码:A文章编号:16744764(2016)06009106
Abstract:
The optimization of the sectional dimensions is studied to make the ratio between performance and steel amount of steel sections become optimal. However, the optimization analysis of lip angle involving the eccentric compression is lack. A technique with the genetic algorithm and formulae for predicting the distortional critical stresses of coldformed lipped channels subjected to eccentric compression is developed to optimize the angles of lips of channels. The coldformed lipped channel columns under eccentric compressing have been taken as examples. The genetic algorithm regards the angle of lip and eccentric distance as design parameters. This method not only can decrease workload and aimless calculation but also can obtain accurate optimal angles. The distortional critical stresses of coldformed lipped channels with different dimensions under simply and clamped supports are obtained, based on the finite strip analyses. The optimal angles of coldformed channel steel members with different eccentric distances are presented. For designer’s convenience of design and application, the degree of 100 is suggested.
Keywords:
inclined lipped coldformed channel;eccentric compression;finite strip;optimal angle of lip
隨着生产技术的不断更新发展,冷弯成型钢构件朝着高强度、薄壁、截面形式复杂的趋势发展,出现了几种常见的屈曲模式,分别为:局部屈曲、畸变屈曲和整体屈曲[1]。由于可以用加劲及加支撑的方式来提高构件的局部屈曲和整体屈曲的临界应力,畸变屈曲则很可能成为最终主导构件失效的屈曲模式。Lau 和 Hancock等[23]提出了简化模型,推导出了受压构件弹性畸变屈曲临界应力。学者Li等[4]考虑翼缘板件弯曲的影响,在 Lau 和 Hancock 的畸变屈曲模型基础上进行修正,并推导出了类似于 Lau 和 Hancock 公式的弹性畸变屈曲临界应力计算公式。其公式可计算卷边槽形、Z 形以及Σ形冷弯薄壁型钢构件的畸变屈曲应力。周绪红等[5]考虑腹板屈曲对弹簧刚度的影响并提出了折减系数,推导两端简支、固支卷边槽钢畸变屈曲临界应力计算公式。Song等[6]采用了半解析有限条法对槽钢截面受剪力荷载进行分析。杨娜等[7]通过有限元与试验相对比,研究了组合效应对冷弯C型钢构件滞回性能的改善作用。Teng等[8]采用如图1所示的近似模型,推导出双向偏心受压构件卷边槽钢弹性畸变屈曲荷载的稳定方程,并提出了单向偏压和纯弯载荷畸变屈曲计算公式并对其公式进行相应的简化。研究表明[910],改变卷边与翼缘的夹角(后简称卷边角度)θ(如图2)不仅会改变斜卷边槽钢的截面几何特性,还会改变卷边对翼缘的约束作用,从而导致斜卷边槽钢构件发生畸变屈曲时临界应力以及畸变屈曲承载力发生变化。在此基础上,通过改变卷边的角度,从而达到提高构件承载力的目的,这为工程优化与改变构件截面形式来提高构件的强度与刚度提供了新的思路。
遗传算法是一种常见的全局优化的概率算法,采用遗传算法对工程问题进行优化,搜索过程既不受优化函数连续性的约束,也没有优化函数必须可导的要求,同时可进行对目标优化设计[1112]。也避免了给定初始值要求,能够有效地进行全局搜索。本文将姚谏等[13](简称YaoTeng) 推导得到的卷边槽钢畸变屈曲临界应力简化计算公式编成相应的程序,再利用遗传算法对其卷边角度进行优化,得出使构件畸变屈曲临界应力最大的卷边角度。 3.2结果分析
由图4~7可见,随着卷边角度变化,槽钢局部与整体相关屈曲临界应力变化不大,而畸变屈曲临界应力出现了先增大后减小的变化过程。由此可见,卷边角度的改变可以显著改变构件的畸变屈曲临界应力。
通过对最优角度的寻找,及最优角度对应的畸变屈曲临界应力计算,观察表1~2可知,无论是两端简支还是两端固支,无论是不同偏心距还是不同尺寸试样,其最优角度的畸变屈曲临界应力与标准(卷边角度为90°)构件的畸变屈曲临界应力相比较均有提升,畸变屈曲承载力峰值主要集中在95°~105°。
观察表1~2可知,无论简支还是固支情况下,不同构件在不同偏心距受压下畸变屈曲临界应力随卷边角度变化的趋势是一致的。其峰值主要集中在95°~105°,较标准角度(90°)均有不同程度的提高,最大可提升构件畸变屈曲临界应力的3.5%,提高值为1 203 N·cm。
4结论
1)通过CUFSM计算斜卷边槽钢在不同偏心距受压情况下畸变屈曲临界应力,计算结果显示,随着卷边角度的变化,当卷边角度大于90°时,构件畸变屈曲临界应力都有着不同幅度的提升,而局部与整体相关屈曲临界应力则没有明显的变化。
2)本文提出的将YaoTeng推导的畸变屈曲临界应力计算公式(偏心受压)与遗传算法相结合的技术,可以快速准确地找到最优的卷边角度,可为工程人员设计提供参考。
3)据优化结果分析,构件处于两端简支或固支约束条件下,偏心距一定范围内,使受压构件的畸变屈曲临界应力最大的最优卷边角度范围均集中在95°~105°。此外,为了方便工程师设计,建议卷边角度可统一采用100°。
参考文献:
[1]
ZEINODDINI V M, SCHAFER B W.Simulation of geometric imperfections in coldformed steel members using spectral representation approach[J].ThinWalled Structures,2012, 60: 105117.
[2] LAU S C W, HANCOCK G J. Distortional buckling formulas for channel columns [J]. Journal of Structural Engineering, ASCE, 1987, 113(5): 10631078.
[3] HANCOCK G J. Design for distortional buckling of flexural members [J]. Thin Walled Structures, 1997, 27(1): 312.
[4] LI L Y,CHEN J K. An analytical model for analyzing distortional buckling of coldformed steel sections [J]. ThinWalled Structures, 2008, 64: 14301436.
[5] ZHOU X, LIU Z, HE Z. General distortional buckling formulae for both fixedended and pinnedended Csection columns[J]. ThinWalled Structures, 2015, 94:603611.
[6] SONG H P, CAO H P, HANCOCK G J. Direct strength method of design for shear including sections with longitudinal web stiffeners[J]. ThinWalled Structures, 2014, 81(81):1928. (in Chinese)
[7] 楊娜, 彭雄, 杨庆山. 冷弯薄壁型钢C型构件滞回性能[J]. 土木建筑与环境工程, 2012, 34(2):6976.
YANG N,PENG X, YANG Q S.Analysis of hysteretic performance of Csection specimens of cold formed steel [J]. Joutnal of Civil, Architectural & Evironmental Engineering, 2012, 34(2):6976.(in Chinese)
[8] TENG J G, YAO J, ZHAO Y. Distortional buckling of the channel beam columns [J]. ThinWalled Structures, 2003, 47(7): 595617.
[9] 黄栩浩, 孙国军, 吴梦景,等. 冷弯薄壁卷边槽钢卷边角度优化设计[J].工业建筑, 2015, 45(11):167171.
HUANG X H, SUN G J, WU M J, et al. Optimizing design for stiffened angle of coldformed thinwalled channel with edge stiffened flanges [J]. Industrial Construction, 2015, 45(11):167171. (in Chinese)
[10] 孙国军, 赵银海, 黄栩浩,等. 卷边角度对C型冷弯构件抗畸变屈曲性能的影响[J]. 宁波大学学报(理工版), 2015(3):6873. SUN G J, ZHAO Y H, HUANG X H,et al. Influence of angle of lip on performance against distortional buckling of Csection coldformed members [J]. Journal of Ningbo University(Natural Science and Engineering Edition), 2015(3):6873. (in Chinese)
[11] 马永杰, 云文霞. 遗传算法研究进展[J]. 计算机应用研究, 2012, 29(4):12011206.
MA Y J,YUN W X. Research progress of genetic algorithm [J]. Application Research of Computers, 2012, 29(4):12011206. (in Chinese)
[12] 梁昊庆, 董石麟, 苗峰. 索穹顶结构预应力多目标优化的小生境遗传算法[J]. 建筑结构学报, 2016(2):9299.
LIANG H Q,DONG S L, MIAO F. Multiobjective optimization analysis of cable dome structures prestress based on niche genetic algorithm [J]. Journal of Building Structures, 2016(2):9299 . (in Chinese)
[13] 姚谏, 滕锦光.冷弯薄壁卷边槽钢的畸变屈曲荷载简化计算 [J].浙江大学学报(工学版), 2008, 42(9): 14941501.
YAO J,TENG J G. Simple formulae for distortional buckling loads of coldformed lipped channel sections [J]. Journal of Zhejiang University (Engineering Science), 2008, 42(9): 14941501. (in Chinese)
[14] 王海明, 張耀春. 直卷边和斜卷边受弯构件畸变屈曲性能研究 [J]. 工业建筑, 2008, 38(6): 106109.
WANG H M, ZHANG Y C. Distortional buckling performance study on flexural memebers [J].Industrial Construction, 2008, 6(38): 106109. (in Chinese)
[15] SCHAFER B W.CUFSM4.05Elastic buckling analysis of thinwalled members by the finite strip method and constained finite strip method for general end boundary conditions [EB/OL].Department of Civil Engineering,http://www.ce.jhu.edu/bschafer/cufsm/,2012. Johns Hopkins University,2012.
(编辑胡玲)
为了使得钢结构的性能与用钢量比达到最优,前人对槽型钢的截面尺寸优化进行了较为充分的研究。但是,涉及卷边角度的优化特别是偏心受压工况下的优化分析却很缺乏。以YaoTeng偏心受压计算公式,结合遗传算法,以冷弯卷边槽钢柱偏心受压为例,将槽钢卷边角度与偏心距作为设计变量,寻找在不同偏心距受压情况下,达到最大畸变屈曲临界应力的卷边角度。基于有限条分析程序,对两端简支与两端固支情况下不同截面尺寸构件的畸变屈曲临界应力进行了计算分析,最终得出不同偏心距受压下统一的最优卷边角度。为了方便工程设计人员设计时参考,建议卷边角度统一取为100°。
关键词:
偏心受压;斜卷边槽钢;有限条;遗传算法;最优卷边角度
中图分类号:TU391
文献标志码:A文章编号:16744764(2016)06009106
Abstract:
The optimization of the sectional dimensions is studied to make the ratio between performance and steel amount of steel sections become optimal. However, the optimization analysis of lip angle involving the eccentric compression is lack. A technique with the genetic algorithm and formulae for predicting the distortional critical stresses of coldformed lipped channels subjected to eccentric compression is developed to optimize the angles of lips of channels. The coldformed lipped channel columns under eccentric compressing have been taken as examples. The genetic algorithm regards the angle of lip and eccentric distance as design parameters. This method not only can decrease workload and aimless calculation but also can obtain accurate optimal angles. The distortional critical stresses of coldformed lipped channels with different dimensions under simply and clamped supports are obtained, based on the finite strip analyses. The optimal angles of coldformed channel steel members with different eccentric distances are presented. For designer’s convenience of design and application, the degree of 100 is suggested.
Keywords:
inclined lipped coldformed channel;eccentric compression;finite strip;optimal angle of lip
隨着生产技术的不断更新发展,冷弯成型钢构件朝着高强度、薄壁、截面形式复杂的趋势发展,出现了几种常见的屈曲模式,分别为:局部屈曲、畸变屈曲和整体屈曲[1]。由于可以用加劲及加支撑的方式来提高构件的局部屈曲和整体屈曲的临界应力,畸变屈曲则很可能成为最终主导构件失效的屈曲模式。Lau 和 Hancock等[23]提出了简化模型,推导出了受压构件弹性畸变屈曲临界应力。学者Li等[4]考虑翼缘板件弯曲的影响,在 Lau 和 Hancock 的畸变屈曲模型基础上进行修正,并推导出了类似于 Lau 和 Hancock 公式的弹性畸变屈曲临界应力计算公式。其公式可计算卷边槽形、Z 形以及Σ形冷弯薄壁型钢构件的畸变屈曲应力。周绪红等[5]考虑腹板屈曲对弹簧刚度的影响并提出了折减系数,推导两端简支、固支卷边槽钢畸变屈曲临界应力计算公式。Song等[6]采用了半解析有限条法对槽钢截面受剪力荷载进行分析。杨娜等[7]通过有限元与试验相对比,研究了组合效应对冷弯C型钢构件滞回性能的改善作用。Teng等[8]采用如图1所示的近似模型,推导出双向偏心受压构件卷边槽钢弹性畸变屈曲荷载的稳定方程,并提出了单向偏压和纯弯载荷畸变屈曲计算公式并对其公式进行相应的简化。研究表明[910],改变卷边与翼缘的夹角(后简称卷边角度)θ(如图2)不仅会改变斜卷边槽钢的截面几何特性,还会改变卷边对翼缘的约束作用,从而导致斜卷边槽钢构件发生畸变屈曲时临界应力以及畸变屈曲承载力发生变化。在此基础上,通过改变卷边的角度,从而达到提高构件承载力的目的,这为工程优化与改变构件截面形式来提高构件的强度与刚度提供了新的思路。
遗传算法是一种常见的全局优化的概率算法,采用遗传算法对工程问题进行优化,搜索过程既不受优化函数连续性的约束,也没有优化函数必须可导的要求,同时可进行对目标优化设计[1112]。也避免了给定初始值要求,能够有效地进行全局搜索。本文将姚谏等[13](简称YaoTeng) 推导得到的卷边槽钢畸变屈曲临界应力简化计算公式编成相应的程序,再利用遗传算法对其卷边角度进行优化,得出使构件畸变屈曲临界应力最大的卷边角度。 3.2结果分析
由图4~7可见,随着卷边角度变化,槽钢局部与整体相关屈曲临界应力变化不大,而畸变屈曲临界应力出现了先增大后减小的变化过程。由此可见,卷边角度的改变可以显著改变构件的畸变屈曲临界应力。
通过对最优角度的寻找,及最优角度对应的畸变屈曲临界应力计算,观察表1~2可知,无论是两端简支还是两端固支,无论是不同偏心距还是不同尺寸试样,其最优角度的畸变屈曲临界应力与标准(卷边角度为90°)构件的畸变屈曲临界应力相比较均有提升,畸变屈曲承载力峰值主要集中在95°~105°。
观察表1~2可知,无论简支还是固支情况下,不同构件在不同偏心距受压下畸变屈曲临界应力随卷边角度变化的趋势是一致的。其峰值主要集中在95°~105°,较标准角度(90°)均有不同程度的提高,最大可提升构件畸变屈曲临界应力的3.5%,提高值为1 203 N·cm。
4结论
1)通过CUFSM计算斜卷边槽钢在不同偏心距受压情况下畸变屈曲临界应力,计算结果显示,随着卷边角度的变化,当卷边角度大于90°时,构件畸变屈曲临界应力都有着不同幅度的提升,而局部与整体相关屈曲临界应力则没有明显的变化。
2)本文提出的将YaoTeng推导的畸变屈曲临界应力计算公式(偏心受压)与遗传算法相结合的技术,可以快速准确地找到最优的卷边角度,可为工程人员设计提供参考。
3)据优化结果分析,构件处于两端简支或固支约束条件下,偏心距一定范围内,使受压构件的畸变屈曲临界应力最大的最优卷边角度范围均集中在95°~105°。此外,为了方便工程师设计,建议卷边角度可统一采用100°。
参考文献:
[1]
ZEINODDINI V M, SCHAFER B W.Simulation of geometric imperfections in coldformed steel members using spectral representation approach[J].ThinWalled Structures,2012, 60: 105117.
[2] LAU S C W, HANCOCK G J. Distortional buckling formulas for channel columns [J]. Journal of Structural Engineering, ASCE, 1987, 113(5): 10631078.
[3] HANCOCK G J. Design for distortional buckling of flexural members [J]. Thin Walled Structures, 1997, 27(1): 312.
[4] LI L Y,CHEN J K. An analytical model for analyzing distortional buckling of coldformed steel sections [J]. ThinWalled Structures, 2008, 64: 14301436.
[5] ZHOU X, LIU Z, HE Z. General distortional buckling formulae for both fixedended and pinnedended Csection columns[J]. ThinWalled Structures, 2015, 94:603611.
[6] SONG H P, CAO H P, HANCOCK G J. Direct strength method of design for shear including sections with longitudinal web stiffeners[J]. ThinWalled Structures, 2014, 81(81):1928. (in Chinese)
[7] 楊娜, 彭雄, 杨庆山. 冷弯薄壁型钢C型构件滞回性能[J]. 土木建筑与环境工程, 2012, 34(2):6976.
YANG N,PENG X, YANG Q S.Analysis of hysteretic performance of Csection specimens of cold formed steel [J]. Joutnal of Civil, Architectural & Evironmental Engineering, 2012, 34(2):6976.(in Chinese)
[8] TENG J G, YAO J, ZHAO Y. Distortional buckling of the channel beam columns [J]. ThinWalled Structures, 2003, 47(7): 595617.
[9] 黄栩浩, 孙国军, 吴梦景,等. 冷弯薄壁卷边槽钢卷边角度优化设计[J].工业建筑, 2015, 45(11):167171.
HUANG X H, SUN G J, WU M J, et al. Optimizing design for stiffened angle of coldformed thinwalled channel with edge stiffened flanges [J]. Industrial Construction, 2015, 45(11):167171. (in Chinese)
[10] 孙国军, 赵银海, 黄栩浩,等. 卷边角度对C型冷弯构件抗畸变屈曲性能的影响[J]. 宁波大学学报(理工版), 2015(3):6873. SUN G J, ZHAO Y H, HUANG X H,et al. Influence of angle of lip on performance against distortional buckling of Csection coldformed members [J]. Journal of Ningbo University(Natural Science and Engineering Edition), 2015(3):6873. (in Chinese)
[11] 马永杰, 云文霞. 遗传算法研究进展[J]. 计算机应用研究, 2012, 29(4):12011206.
MA Y J,YUN W X. Research progress of genetic algorithm [J]. Application Research of Computers, 2012, 29(4):12011206. (in Chinese)
[12] 梁昊庆, 董石麟, 苗峰. 索穹顶结构预应力多目标优化的小生境遗传算法[J]. 建筑结构学报, 2016(2):9299.
LIANG H Q,DONG S L, MIAO F. Multiobjective optimization analysis of cable dome structures prestress based on niche genetic algorithm [J]. Journal of Building Structures, 2016(2):9299 . (in Chinese)
[13] 姚谏, 滕锦光.冷弯薄壁卷边槽钢的畸变屈曲荷载简化计算 [J].浙江大学学报(工学版), 2008, 42(9): 14941501.
YAO J,TENG J G. Simple formulae for distortional buckling loads of coldformed lipped channel sections [J]. Journal of Zhejiang University (Engineering Science), 2008, 42(9): 14941501. (in Chinese)
[14] 王海明, 張耀春. 直卷边和斜卷边受弯构件畸变屈曲性能研究 [J]. 工业建筑, 2008, 38(6): 106109.
WANG H M, ZHANG Y C. Distortional buckling performance study on flexural memebers [J].Industrial Construction, 2008, 6(38): 106109. (in Chinese)
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(编辑胡玲)