Research on Sag and Phase-Phase Space Change by Installing Interphase Spacers for Transmission Lines

Qing Hai Lin; Yuan Xi Yao; Lian Bo Tian

doi:10.4028/www.scientific.net/AMM.268-270.1274

Paper Titles

Vibration Experiment of Shearer Walking Unit
p.1257

Hybrid Excavator Shafting Torsional Vibration Analysis
p.1262

Influences of Main Parameters on Performance of Seed-Filling Device in Plot Seeder
p.1266

Rocker Mechanism Study of Crank Angle between Extreme Positions
p.1270

Research on Sag and Phase-Phase Space Change by Installing Interphase Spacers for Transmission Lines
p.1274

Research on the Design Loads of a Surface Warship
p.1279

Research on Combination Anti-Galloping Method between Interphase Spacer and Rotary Clamp Spacer for Transmission Lines
p.1284

R&D of Equipment for Deicing by Thermal Water-Jet and Mechanical Deicing Method
p.1288

Aerodynamic and Structural Design of Composite Wind Turbine Blades
p.1294

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 268-270Research on Sag and Phase-Phase Space Change by...

Research on Sag and Phase-Phase Space Change by Installing Interphase Spacers for Transmission Lines

Abstract:

Installation of inter-phase spacer can effectively protects against line fault caused by conductor galloping, non-synchronous swing and sleet jump etc large amplitude vibration, but sag of the conductor is changed if inter-phase spacer is installed. And installation of initial inter-phase spacer will cause change of inter-phase distance, which cause difficulty of successive installation. The empirical equation can’t accurately analyze change of the inter-phase distance caused during installation of the inter-phase spacer. In this paper, accurate conductor installation inter-phase spacer analysis model is established with non-linear finite element method. Change of the conductor sag after installation of the inter-phase spacer is calculated, and influence on inter-phase distance caused by different installation sequence is analyzed. The research result provides effective analysis method for length control of actual line installed inter-phase spacers, and ensures manufacturing and successful installation of the inter-phase spacer.

You might also be interested in these eBooks

Materials, Mechanical Engineering and Manufacture

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 268-270)

Pages:

1274-1278

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.268-270.1274

Citation:

Cite this paper

Online since:

December 2012

Authors:

Qing Hai Lin, Yuan Xi Yao, Lian Bo Tian

Keywords:

Finite Element Method (FEM), Interphase Spacer, Nonlinear Large Displacement, Phase-Phase Distance, Sag

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Wang Liming. Research of interphase composition insulation spacer[D]. Beijing: Tsinghua University, 1993. (In Chinese)

Google Scholar

[2] Cheng Yingtang. Design installation test and application of power transmission line fitting [M]. Beijing: Water resources and electric power publishing house, 1989. (In Chinese)

Google Scholar

[3] Carreira A J. Interphase spacers in regions of contamination [J]. IEEE Electrical Insulation Magazine, 2008, 24:35-42.

DOI: 10.1109/mei.2008.4665349

Google Scholar

[4] Ceng Junchang. Conductor tension force calculation of compact type line installation interphase spacer[J]. Power Construction, 2001, 22(4):18-22. (In Chinese)

Google Scholar

[5] Li Shanjin, Niu Junyou, Yang Yan. Influence calculation of interphase spacer on conductor sag[J]. Henan Science, 2012, 30(4): 481-483. (In Chinese)

Google Scholar

[6] Zhang Diansheng. Design manual of high voltage power transmission line in power engineering [M]. Beijing: China Power Press, 2007. (In Chinese)

Google Scholar

[7] Wang Lixin, Yang Wenbin, Yang Xinhua, etc. Finite element analysis of galloping in power transmission line[J]. Huazhong University of Science and Technology Journals, 2004, 21(1): 76-80. (In Chinese)

Google Scholar

[8] Veletsos A S, Darbre G R. Dynamic stiffness of parabolic cables [J]. International Journal of Earthquake Engineering structural dynamic, 1983, 11:367-401.

DOI: 10.1002/eqe.4290110306

Google Scholar

[9] Desai Y M, Yu P, Popplewell, et al. Finite element modeling of transmission line galloping [J]. Computers & Structures, 1995, 57(3):407-420.

DOI: 10.1016/0045-7949(94)00630-l

Google Scholar