Effectiveness of Lightning Protection Devices 被引量：2

Effectiveness of Lightning Protection Devices

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摘要 In addition to the conventional Franklin Rod,many non-conventional air terminals are being used as lightning protection devices.As cited in previous works,these non-conventional devices emit space charge in the vicinity of the terminals during the process of lightning stroke.A number of factors affect the performance of these lightning protection devices,among them are geometry and dimension of the devices,location of the device above the ground,height of the cloud above the ground,and polarity of the lightning stroke.The performance of these lightning protection devices has been a topic of discussion by researchers for many years.Some studies focused on the magnitude of emission current from these devices as a criterion to evaluate their performances.The critical flashover voltage(CFO)between the devices and a metal screen simulating cloud can also be used as another criterion to evaluate the performance of the devices.Laboratory measurements were conducted in controlled conditions on different types of lightning protection devices to compare their performance.Four different types of devices were used in the present study:Franklin Rod,TerraStat models TS 100,TS 400,and Spline Ball Ionizer.The study focused on the CFO voltage of the air gap between devices and the metal screen.The CFO voltage was evaluated using standard switching and lightning impulses.The measurements were recorded for positive as well as negative polarity.The air gap between the devices and metal screen was selected at 2 m and 3 m.The results obtained provide a better understanding of the electrical performance of lightning protection devices. In addition to the conventional Franklin Rod,many non-conventional air terminals are being used as lightning protection devices.As cited in previous works,these non-conventional devices emit space charge in the vicinity of the terminals during the process of lightning stroke.A number of factors affect the performance of these lightning protection devices,among them are geometry and dimension of the devices,location of the device above the ground,height of the cloud above the ground,and polarity of the lightning stroke.The performance of these lightning protection devices has been a topic of discussion by researchers for many years.Some studies focused on the magnitude of emission current from these devices as a criterion to evaluate their performances.The critical flashover voltage（CFO）between the devices and a metal screen simulating cloud can also be used as another criterion to evaluate the performance of the devices.Laboratory measurements were conducted in controlled conditions on different types of lightning protection devices to compare their performance.Four different types of devices were used in the present study：Franklin Rod,TerraStat models TS 100,TS 400,and Spline Ball Ionizer.The study focused on the CFO voltage of the air gap between devices and the metal screen.The CFO voltage was evaluated using standard switching and lightning impulses.The measurements were recorded for positive as well as negative polarity.The air gap between the devices and metal screen was selected at 2 m and 3 m.The results obtained provide a better understanding of the electrical performance of lightning protection devices.

作者 S. Grzybowski T. Disyadej S. Mallick

机构地区 High Voltage Laboratory

出处《高电压技术》 EI CAS CSCD 北大核心 2008年第12期2517-2522,共6页 High Voltage Engineering

关键词雷电保护装置有效性接线端电流 air terminals critical flashover voltage dissipator devices emission current Franklin Rod lightning lightning leader lightning protection space charge

分类号 TM86 [电气工程—高电压与绝缘技术]

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参考文献10

1Uman M A, Rakov V A. A critical review of nonconventional approaches to lightning protection[J]. Bulletin of American Me teorological Society, 2002:1809-1820.
2Zipse D W. Lightning protection systems: advantages and disadvantages[J]. IEEE Trans on Industry Applications, 1994, 30 (5) : 1351-1361.
3Moore C B, Rison W, Mathis J, et al. Lightning rod improvement studies[J1. Journal of Applied Meteorology, 2000, 39 : 593-609.
4Berger G. Determination of the inception electric field of the lightning upward leader[C]// Proc. of 8th International Symposium of High Voltage Engineering (ISH'93). Japan:[s. n. ], 1993: 225-228.
5Grzybowski S, Molen G M, Sathishram S, et al. Lightning performance tests on 115 kV transmission line models with spline ball ionizers[C]// IEEE Proceedings of Southeastcon '94. Mi ami, FL: IEEE, 1994: 288-291.
6Grzybowski S, Taylor C D, Rodriguez Medina B, et al. Emission current from static dissipator devices at switching impulses [C]// Proc. Ⅷ International Symposium on Lightning Protection. Brazil: [s.n.], 2005: 201-206.
7Grzyhowski S, Taylor C D, Bean C, et al. Experimental study of emission current from lightning protection devices under rain and wind conditions[C]// Proc. Ⅸ Symposium on Lightning Protection. Brazil: [s. n. ], 2007: 244-249.
8Grzybowski S, Libby A L, Jenkins E B, et aI. DC dissipation current from elements used for lightning protection on 115 kV transmission lines[C]// Proc. IEEE SoutheastCon' 91 Conference. VA, USA: IEEE, 1991:1250-1254.
9Lee J B, Myung S H, Cho Y G, et al. Experimental study on lightning protection performance of air terminals[C]//Proc. Power Con 2002. [S.l.]: [s.n.], 2002: 2222-2226.
10Grzybowski S, Disyadej T, Mallick S. Effectiveness of lightning protection devices[C]// Proc. of 2008 International Conference on High Voltage Engineering and Application (ICHVE 2008). Chongqing, China: [s.n.], 2008:49-52.

同被引文献40

1周泽存,等.高电压技术[M].中国电力出版社,2007,北京.
2武汉高压研究所.线路雷击跳闸率计算方法和500kV超高压线路防雷设计中的几个问题[R].武汉:武汉高压研究所,1982.
3William Rison,James Mathis.Lightning rod improvement studies[J].Journal of Applied Meteorology,2000,39:593-609.
4William Rison,Charles B Moore,Graydon D Aulich.Lightning air terminals-is shape important[C]∥2004International Symposium on Electromagnetic Compatibility.Los Angeles,USA:[s.n.],2004:300-305.
5Moore C B,Aulich Ulich G D,William Rison.The case for using blunt-tipped lightning rods as strike receptors[J].Journal of Applied Meteorology,2003,42:984-993.
6Grzybowski S,Taylor C D,Median B Rodriguez.Emission current from static dissipator devices at switching impulses[C]∥Proceedings of the VIII International Symposium on Lightning Protection.Sap Palo,Brazil:[s.n.],2005:201-206.
7Grzybowski S,Mallick S,Disyadej T.Review of lightning performance study on dissipation devices[C]∥North American Power Symposium(NAPS).Mississippi,USA:[s.n.],2009:1-5.
8Taylor C D,Grzybowski S.SPICE simulation and measurement of emission current from the static dissipator devices at switching impulse[C]∥IEEE Southeast Conference.Memphis,USA:IEEE,2006:48-61.
9Grzybowski S,Taylor C D,Bean C,et al.Experimental study of emission current from lightning protection devices under rain and wind conditions[C]∥IX SIPDA.Foz do Iguacu,Brazil:[s.n.],2007:244-249.
10Grzybowski S,Taylor C D,Medina B Rodriguez,et al.Dissipa-tion current from static dissipator devices at switching impulses[C]∥Proceedings of the VIII International Symposium on Lightning Protection.Sao Palo,Brazil:[s.n.],2005:201-206.

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Effectiveness of Lightning Protection Devices 被引量：2

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