Anti-galloping Design of Interphase Spacers in Three-phase Conductor Lines with Triangle Arrangement

PDF(1810 KB)

Journal of Vibration and Shock ›› 2016, Vol. 35 ›› Issue (1) : 106-111.

Yan Bo1,2, Cui Wei1, He Xiaobao1, Yang Xiaohui2,3, Lv Zhongbin2

Author information +

History +

Abstract

Anti-galloping design of interphase spacers in three-phase conductor lines with triangle arrangement is numerically studied. Based on the galloping characteristics of transmission line with 300m-span under wind load, four installation schemes of interphase spacers are presented and their anti-galloping efficiencies are numerically investigated. It is suggested that both vertical and horizontal vibration modes during galloping have to be taken into account in the installation design of interphase spacers, based on which anti-galloping schemes of interphase spacers for the transmission lines with 400m-span and 500m-span are designed and their anti-galloping efficiencies are further numerically proved.

Key words

double bundle conductor / interphase spacer / anti-galloping / numerical simulation.

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

Yan Bo1,2, Cui Wei1, He Xiaobao1, Yang Xiaohui2,3, Lv Zhongbin2. Anti-galloping Design of Interphase Spacers in Three-phase Conductor Lines with Triangle Arrangement[J]. Journal of Vibration and Shock, 2016, 35(1): 106-111

References

[1] Lilien J L. et al. State of the art of conductor galloping, A complementary document to "Transmission line reference book- Wind-induced conductor motion Chapter 4: Conductor galloping" based on EPRI research project 792, 2005.
[2] 王黎明，孙保强，张楚岩等，750kV紧凑型线路相间间隔棒力学分析与计算，高电压技术，2009，35（10）：2551-2556.
Wang LM, Sun BQ, Zhang CY, Mechanical analysis and calculation of interphase spacers on 750kV compact line, The high -voltage technology, 2009, 35(10): 2551-2556.
[3] 王黎明，单飞，候镭等，1000kV紧凑型输电线路相间间隔棒力学特性仿真分析及配置[J].高电压技术，2012,38(2):266-272.
Wang LM, Shan F, Hou L, Mechanical simulation analysis and configuration of interphase spacers on 1000kV compact line, High-voltage Technology, 2012, 38(2): 266-272.
[4] Kollar L.E., Fazaneh M., Van Dyke P., Modeling ice shedding propagation on transmission lines with or without interphase spacers, IEEE Transactions on Power Delivery, 2013, 28(1):261-267.
[5] Fu GJ, Wang LM, Guan ZC, Meng XB, Study on the prevention of conductor ice-shedding by interphase spacer, Proceedings of the 9th International Conference on Properties and Applications of Dielectric Materials, July 19-23, 2009, Harbin, China
[6] Kim HS, Nguyen TL, Analysis of galloping amplitudes for conductors with interphase spacers, The 30th Annual Conference of the IEEE Industrial Electronics Society, November 2-6, 2004, Busan, Korea. Pp.1520-1525
[7] Hou L, Wang LM, Yan D, Lu M and Guan ZC, Mechanical parameter optimization of interphase composite spacer used for controlling conductor galloping, 2007 Annual Report on Electrical Insulation and Dielectric Phenomena, pp.304-307.
[8] Fan Z., Hao SY., Zhou KT, Zhang QC, Effect of interphase composite spacers on transmission line galloping control, 2011 Second International Conference on Digital Manufacturing & Automation, August 5-7, 2011, IEEE Computer Society, Zhangjiajie, Hunan, China, pp.485-488.
[9] Fu GJ, Wang LM, Guan ZC, Hou L, Meng XB, MacAlpine M, Simulations of the controlling effect of interphase spacers on conductor galloping. IEEE Transactions on Dielectrics and Electrical Insulation, 2012, 19(4):1325-1334.
[10] 崔伟，严波，杨晓辉，吕中宾，双分裂导线相间间隔棒防舞数值模拟研究，振动与冲击，2014，33（20）：47-51.
Cui W, Yan B, Yang XH, Lv ZB, Effect of interphase composite spacers on double conductor galloping control, Journal of Vibration and Shock, 2014, 33(20): 47-51.
[11] 国家电力公司东北电力设计院，电力工程高压送电线路设计手册. 第二版, 北京：中国电力出版社，2003.
Northeast Electric Power Design Institute of State Power Company, Electrical engineering high voltage transmission lines design manual, the second edition, Beijing: China Electric Power Press, 2003.
[12] Hu J, Yan B, Zhou S, Zhang HY，Numerical investigation on galloping of iced quad bundle conductors [J], IEEE Transactions on Power Delivery, 2012, 27(2): 784-792.