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长安大学学报（自然科学版）[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2024年2期

Page:

46-56

Research Field:

桥梁与隧道工程

Publishing date:

Info

Title:

Research on proportion of constrained torsion in mixed torsion of thin-walled bar

Author(s):

LIU Yong-jian¹; 2;  CHAI Liang¹;  XING Zi-han¹;  LI Jiang-jiang¹;  FENG Bo-wen¹

(1. School of Highway, Chang'an University, Xi'an 710064, Shaanxi, China; 2. Research Center of Highway Large Structure Engineering on Safety of Ministry of Education,Chang'an University, Xi'an 710064, Shaanxi, China)

Keywords:

bridge engineering;  thin-walled bar;  FEM;  pure torsion;  constrained torsion;  boundary condition

PACS:

U441

DOI:

10.19721/j.cnki.1671-8879.2024.02.005

Abstract:

In order to determine the proportional relationship between pure torsion and constrained torsion of thin-walled bar under mixed torsion with different boundary conditions, firstly, the mixed torsion differential equation was established based on Vlasov thin-walled structure theory. The proportion formula for constrained torsion of thin-walled bar under concentrated torque and uniform torque was derived using the initial parameter method. Based on simply supported boundary, the influence of boundary conditions on the proportion of constrained torsion was analyzed by introducing the constraint stiffness coefficient β. Then, the formula was verified using the finite element software ABAQUS. Finally, the calculation formula for the constrained torsion characteristic coefficient κ of the common section of steel bridge was provided, and the distribution range of κ for the steel-concrete composite twin I-girder bridge and the steel box girder bridge were counted. The results show that the derived formula for constrained torsion ratio agrees well with the calculation results obtained from ABAQUS. The proportion of constrained torsion is affected by the section's κ and boundary conditions. A larger κ corresponds to a smaller proportion of constraint torsion, and the influence of boundary conditions on the proportion of constraint torsion changes with κ. The β can effectively characterize the influence of boundary conditions on the proportion of constraint torsion. In simplified analysis, when 0<κ≤0.6, the influence of pure torsion can be disregarded, and the analysis can focus solely on constrained torsion. When κ exceeds 40, the impact of constrained torsion can be neglected, and the analysis can be based solely on pure torsion. In the case where 0.6<κ<40, a mixed torsion analysis is required. The calculated κ range for the steel-concrete composite twin I-girder bridge is 0.71 to 1.58, and the κ for the steel box beam bridge is greater than 39.8 tabs, 10 figs, 26 refs.

References:

[1] 干小东.箱形薄壁结构在翘曲扭转下的截面非线性分析[J].建筑科学,2012,28(11):9-12.
GAN Xiao-dong.Cross-section nonlinear analysis of reinforced concrete box girder thin-walled composite under warping torsion[J].Building Science,2012,28(11):9-12.
[2]闫新凯,刘永健,邢子寒,等.曲线双工字钢组合梁桥横梁受力分析研究[J].建筑科学与工程学报,2022,39(5):63-73.
YAN Xin-kai,LIU Yong-jian,XING Zi-han,et al.Research on internal force of crossbeam in curved steel-concrete composite twin I-girder bridge[J].Journal of Architecture and Civil Engineering,2022,39(5):63-73.
[3]郭靖宇,管 松,年玉泽,等.单箱单室薄壁箱梁约束扭转分析[J].常州工学院学报,2018,31(3):10-14,27.
GUO Jing-yu,GUAN Song,NIAN Yu-ze,et al.An analysis of the torsion single-box single-cell thin-walled box girder[J].Journal of Changzhou Institute of Technology,2018,31(3):10-14,27.
[4]王 彤,谢 旭,王 渊,等.桁腹式组合桁梁结构计算理论[J].浙江大学学报(工学版),2014,48(4):711-720,741.
WANG Tong,XIE Xu,WANG Yuan,et al.Analysis of prestressed composite truss girders with steel truss webs[J].Journal of Zhejiang University(Engineering Science),2014,48(4):711-720,741.
[5]徐秀丽,王曙光,刘伟庆,等.薄壁箱梁截面抗扭参数的简化计算方法[J].中国公路学报,2007,20(2):72-76,96.
XU Xiu-li,WANG Shu-guang,LIU Wei-qing,et al.Simplified calculation method for torsion parameters of thin-walled box girder section[J].China Journal of Highway and Transport,2007,20(2):72-76,96.
[6]NAKAI H,YOO C H.Analysis and design of curved steel bridges[M].New York:McGraw-Hill,1988.
[7]ANSI/ANSC360-10,Specification for structural steel buildings[S].
[8]EN 1993-1-3,Design of steel structures-Part 1-3:General rules-supplementary rules for cold-formed members and sheeting[S].
[9]Japan Road Association,Specifications for highway bridges with commentaries(Part Ⅱ steel bridge)[S].
[10]Korea Road & Transportation Association,Korean highway bridge design code[S].
[11]GB 50017—2017,钢结构设计标准[S].
GB 50017—2017,Standard for design of steel structures[S].
[12]LEBET J P,HIRT M A.钢桥:钢与钢-混组合桥梁概念和结构设计[M].葛耀君,苏庆田,译.北京:人民交通出版社,2014.
LEBET J P,HIRT M A.Steel Bridge:Conceptual and structural design of steel and steel-concrete composite bridges[M].Translated by GE YAO-jun,SU Qing-tian.Beijing:China Communications Press,2014.
[13]KOLLBRUNNER C F,BASLER K.Torsion in structures[M].Berlin:Springer,1969.
[14]NAKAI H,TANI T.An approximate method for the evaluation of torsional and warping stresses in box girder bridges[J].Proceedings of the Japan Society of Civil Engineers,1978,1978(277):41-55.
[15]KOMATSU S,NAKAI H,TAIDO Y.A proposition for designing the horizontally curved girder bridges in connection with ratio between torsional and flexural rigidities[J].Proceedings of the Japan Society of Civil Engineers,1974,1974(224):55-66.
[16]OKEIL A M,EL-TAWIL S.Warping stresses in curved box girder bridges:Case study[J].Journal of Bridge Engineering,2004,9(5):487-496.
[17]周东波,邓文琴,刘 朵,等.偏载作用下单箱三室波形钢腹板悬臂梁的力学特性[J].公路工程,2020,45(2):21-27,49.
ZHOU Dong-bo,DENG Wen-qin,LIU Duo,et al.Mechanical properties of single box three-cell cantilever girder with corrugated steel webs under eccentric loading[J].Highway Engineering,2020,45(2):21-27,49.
[18]邓文琴,毛泽亮,刘 朵,等.单箱三室波形钢腹板悬臂梁扭转与畸变分析及试验研究[J].建筑结构学报,2020,41(2):173-181.
DENG Wen-qin,MAO Ze-liang,LIU Duo,et al.Analysis and experimental study on torsion and distortion of single box three-cell cantilever girder with corrugated steel webs[J].Journal of Building Structures,2020,41(2):173-181.
[19]王 妍,张元海,王晨光.边界约束条件对箱形梁畸变效应的影响[J].中南大学学报(自然科学版),2021,52(12):4475-4483.
WANG Yan,ZHANG Yuan-hai,WANG Chen-guang.Influence of boundary restraint condition on distortion effect of box girders[J].Journal of Central South University(Science and Technology),2021,52(12):4475-4483.
[20]包世华,周 坚.薄壁杆件结构力学[M].北京:中国建筑工业出版社,1991.
BAO Shi-hua,ZHOU Jian.Structural mechanics of thin-walled bar[M].Beijing:China Architecture & Building Press,1991.
[21]陈 骥.钢结构稳定理论与设计[M].6版.北京:科学出版社,2014.
CHEN Ji.Stability of steel structures theory and design[M].6th ed.Beijing:Science Press,2014.
[22]邢子寒.曲线双工字钢板组合梁横梁受力机理研究[D].西安:长安大学,2021.
XING Zi-han.Study on the stress mechanism of the cross beam of the curved twin I-girder composite bridge[D].Xi'an:Chang'an University,2012.
[23]李 琳,白 昕,张元海.薄壁箱形截面扭转中心及主扇性坐标研究[J].兰州交通大学学报,2013,32(4):96-100.
LI Lin,BAI Xin,ZHANG Yuan-hai.Research on twist centre and principal sectorial coordinate of thin-walled box section[J].Journal of Lanzhou Jiaotong University,2013,32(4):96-100.
[24]刘永健,高诣民,周绪红,等.中小跨径钢-混凝土组合梁桥技术经济性分析[J].中国公路学报,2017,30(3):1-13.
LIU Yong-jian,GAO Yi-min,ZHOU Xu-hong,et al.Technical and economic analysis in steel-concrete composite girder bridges with small and medium span[J].China Journal of Highway and Transport,2017,30(3):1-13.
[25]刘永健,范泉锋,封博文,等.双工字钢-混凝土组合梁桥桥面板横向弯矩[J].长安大学学报(自然科学版),2022,42(6):1-11.
LIU Yong-jian,FAN Quan-feng,FENG Bo-wen,et al.Transverse moment of steel-concrete composite twin I-girder bridge deck[J].Journal of Chang'an University(Natural Science Edition),2022,42(6):1-11.
[26]陈 霄,侯 波,胡 雷,等.钢板组合梁桥预算定额幅度差系数研究[J].建筑科学与工程学报,2022,39(2):128-134.
CHEN Xiao,HOU Bo,HU Lei,et al.Calculating method for amplitude difference coefficient of budget quota for steel plate composite beam bridges[J].Journal of Architecture and Civil Engineering,2022,39(2):128-134.

Memo

Memo:

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Common functions

Last Update: 2024-03-01