Mechanical Analysis on the Splicing Form of Cross-Section Multiple Angle Steel for Transmission Line

Yuan Gao; Jun Ke Han; Qing Hua Li

doi:10.4028/www.scientific.net/AMR.625.30

Paper Titles

A Simple Method for Calculating the Bending Modal Frequencies of an Underwater Simply Supported Beam with Hydrodynamic Study
p.7

Study on the Basic Problems of Dynamics by Induction and Generalization
p.12

Nonlinear Vibration of Functionally Graded Material Cylindrical Shell Based on Reddy’s Third-Order Plates and Shells Theory
p.18

Experimental and Finite Element Study on Mechanical Behavior of Bolted Joint with Bolt Clearance in Transmission Tower
p.25

Mechanical Analysis on the Splicing Form of Cross-Section Multiple Angle Steel for Transmission Line
p.30

Dynamic System of a Mechanical Press Driven by SRM for Flexible Process
p.37

Numerical Simulation of Water Removal Process in the Microstructure of Gas Diffusion Layer with Mechanics Properties and Material Properties
p.41

Study on Optimization of Dynamic Characteristics of Turbo Generator Foundation
p.45

Three-Dimensional Simulation of Water Droplet Movement in PEM Fuel Cell Flow Channels with Fluid-Mechanics Properties and Different Deformations of GDL
p.53

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 625Mechanical Analysis on the Splicing Form of...

Mechanical Analysis on the Splicing Form of Cross-Section Multiple Angle Steel for Transmission Line

Abstract:

The stress inside and outside the traditional cross-section angle steel in transmission lines are uneven, resulting in the deviation of the actual carrying capacity and the theoretical design value. This paper proposes the use of improved splicing form of the cross-section angle steel to improve the structure’s mechanical properties. Two spliced forms of cross-section multiple angle steel are analyzed by finite element simulation analysis, so as to compare two different forms’ coordination of component displacement, uniform of force, and stress status on the maximum stress control section. It is pointed out that double angle splicing forms’ displacement compatibility and bearing capacity are better than single angle splicing forms. Especially for towers with different height legs, the maximum stress of the main members of the two splicing forms in the control section is respectively 4.7% and 13.7%.

You might also be interested in these eBooks

Research on Mechanics, Dynamic Systems and Material Engineering

View Preview

Info:

Periodical:

Advanced Materials Research (Volume 625)

Pages:

30-36

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.625.30

Citation:

Cite this paper

Online since:

December 2012

Authors:

Yuan Gao, Jun Ke Han, Qing Hua Li

Keywords:

Control Section, Coordination, Cross-Section Multiple Angle Steel, Double Angle Splicing Form, Force Uniform, Single Angle Splicing Form

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] ZUO Yuan-long, ZHAO Zheng, FU Peng-cheng, et al: Engineering Journal of Wuhan University Vol. 40(2007), p.209.

Google Scholar

[2] {0>王依群, 沈祖炎, 潘士劼. 双角钢组合"＋"型截面极限屈服面及其数学表达式[C]/1994 第三届全国结构工程学习会议工程力学(增刊), 北京, 1994: <}0{>Wang Yiqun, Shen Zuyan, Pan Shijie: Engineering Mechanical (Supplementary 1994).

DOI: 10.1360/csb1956-1-11-76

Google Scholar

[3] Li Zhen-bao, SHI Lu-yan, Xing Hai-jun: Electric Power Construction Vol. 30 (2003), p.8.

Google Scholar

[4] {0>王新敏. ANSYS工程结构数值化分析[M]. 北京: <}0{>Wang Xinmin: Numerical analysis of ANSYS engineering structure({0>人民交通出版社, 2007: <}0{>People's Communications Publishing Press, Beijing 2007).

Google Scholar

[5] {0>龚曙光, 谢桂兰, 黄云清. ANSYS参数化编程与命令手册[M]. 北京：机械工业出版社，2009: <}0{>Gong Shuguang, Xie Guilan, Hunag Yunqing: ANSYS parameter programming and command manual(Mechanical Industry Press, Beijing, 2009).

Google Scholar

[6] {0>张殿生. 电力工程高压送电线路设计手册[S]. 2版. 北京：中国电力出版社，2002: 324-362. <}85{>Zhang Dian-sheng: Design manual of high voltage power transmission line in power engineering(China Power Press, Beijing 2002).

DOI: 10.37155/2717-5197-0406-64

Google Scholar

[7] {0>单辉祖. 材料力学[M]. 北京: <}0{>Shan Huizu: Material Chemical (China {0>高等教育出版社，2009: <}0{>High Education Press, Beijing 2009).

DOI: 10.3866/pku.dxhx201507007

Google Scholar

[8] {0>GB50017-2003 钢结构设计规范[S]. <}0{>GB50017-2003 Design code for steel structure. <0}.

Google Scholar