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Inelastic Deformation Analysis of Aluminum Bending Members 被引量:2

Inelastic Deformation Analysis of Aluminum Bending Members
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摘要 Aluminum alloys are typical nonlinear materials, and consequently bending members made of this material exhibit a nonlinear behavior. Most design codes do not pay much attention to such deformations and adopt a simple linear analysis for the calculation of deflections. This paper presents an investigation of the nonlinear deformation of aluminum bending members using the finite-element analysis (FEA). The plastic adaptation coefficient, which can be used to limit the residual deflection, is introduced, and the influence of residual deflection is investigated. A method for evaluating the plastic adoption coefficient is proposed. This paper also shows the load-deflection curve of aluminum bending members and the influence of several parameters. A semi-empirical formula is derived, and some numerical examples are given by FEA. The coefficients of the semi-empirical formula are modified by the FEA results using the nonlinear fitting method. Based on these results, two improved design methods for strength and deformation of aluminum bending members are proposed. Through the comparison with test data, these methods are proved to be suitable for structural design. Aluminum alloys are typical nonlinear materials, and consequently bending members made of this material exhibit a nonlinear behavior. Most design codes do not pay much attention to such deformations and adopt a simple linear analysis for the calculation of deflections. This paper presents an investigation of the nonlinear deformation of aluminum bending members using the finite-element analysis (FEA). The plastic adaptation coefficient, which can be used to limit the residual deflection, is introduced, and the influence of residual deflection is investigated. A method for evaluating the plastic adoption coefficient is proposed. This paper also shows the load-deflection curve of aluminum bending members and the influence of several parameters. A semi-empirical formula is derived, and some numerical examples are given by FEA. The coefficients of the semi-empirical formula are modified by the FEA results using the nonlinear fitting method. Based on these results, two improved design methods for strength and deformation of aluminum bending members are proposed. Through the comparison with test data, these methods are proved to be suitable for structural design.
作者 程明 石永久 王元清
机构地区 Key Laboratory of Structural Engineering and Vibration of Ministry of Education
出处 《Tsinghua Science and Technology》 SCIE EI CAS 2006年第6期648-656,共9页 清华大学学报(自然科学版(英文版)
关键词 aluminum bending member residual deformation plastic adaptation coefficient load-deflection relationship nonlinear fitting aluminum bending member residual deformation plastic adaptation coefficient load-deflection relationship nonlinear fitting
分类号 TG115.5 [金属学及工艺—物理冶金]
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参考文献10

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同被引文献30

  • 1CHENG Ming SHI Yongjiu WANG Yuanqing.Analysis of lateral stability of I-section aluminum beams[J].Science China(Technological Sciences),2006,49(6):742-751. 被引量:4
  • 2陈建航.减缓架空地线悬垂线夹磨损的金具连接方式[J].福建电力与电工,2009,29(4):51-52. 被引量:7
  • 3石永久,程明,王元清.铝合金在建筑结构中的应用与研究[J].建筑科学,2005,21(6):7-11. 被引量:60
  • 4石永久,程明,王元清.铝合金受弯构件整体稳定性的试验研究[J].土木工程学报,2007,40(7):37-43. 被引量:12
  • 5ZHU JIA HUA, BENYOUNG. Design of aluminum alloy flexural members using direct strength method [J]. J. Struct. Engrg. 2009, 135(5): 558-566.
  • 6BUYUKM, LOIKKANENM, KANCD. Explicit finite element analysis of 2024-T3/T351 aluminum material under impact loading for airplane engine containment and fragment shielding [R]. Aviation Research and Development, 2008: 48.
  • 7PUCHI-CABRERAES, STAIAMH, LESAGEJ, et al. Fatigue behavior of AA7075-T6 aluminum alloy coated with ZrN by PVD[J].International Journal of Fatigue, 2008. 30(7): 1220-1230.
  • 8PARKDONG YEOB, NIEWCZASMAREK. Plastic deformation of AI and AA5754 between 4.2 K and 295 K[J]. Materials Science and Engineering A-structural Materials Properties Microstructure and Processing, 2008, 491(1/2): 88-102.
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二级引证文献5

Tsinghua Science and Technology
2006年 第6期

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