Interception Probability and Proximity Effects: Implications in Shielding Design Against Lightning

Mikropoulos, Pantelis N.; Tsovilis, Thomas E.

doi:10.1109/tpwrd.2010.2043692

Cited by 17 publications

(20 citation statements)

References 28 publications

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“…Also, from (3) and (6) it can be deduced that the expected substation outage rates depend on the lightning attachment model adopted for the estimation of SFR X , I MSF and N SX of the incoming overhead transmission lines. This is shown in Table II, where the mean time between failures, MTBF, of the substation is evaluated based on different lightning attachment models [16], [18]- [22] and by employing the lightning crest current distribution suggested in [15]. From Table II it is obvious that the MTBF of the evaluated substation varies significantly among lightning attachment models, attaining values approximately from 150 to 450 years.…”

Section: Lightning Risk Assessment Resultsmentioning

confidence: 99%

Lightning risk assessment of a 170 kV GIS substation connected to the Hellenic transmission system through underground cables

Mikropoulos¹,

Tsovilis²,

Manousaridis³

et al. 2010

7th Mediterranean Conference and Exhibition on Power Generation, Transmission, Distribution and Energy Conversion (MedPower 201

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Lightning risk assessment of a 170 kV GIS substation connected to the Hellenic transmission system through underground cables has been performed. Fast-front overvoltages impinging on the substation due to shielding failure and backflashover of the incoming overhead transmission lines have been computed with the aid of ATP-EMTP simulations and evaluated with respect to the insulation level of the substation equipment. The mean time between failures of the substation is greatly reduced for higher tower grounding resistance and varies significantly among lightning attachment models employed for the evaluation of the lightning performance of the incoming overhead transmission lines. Implementation of the IEEE Std 1243:1997 in lightning risk assessment of substations imposes high requirements on protection against incoming fast-front overvoltage surges.Index Terms--ATP-EMTP, GIS substation, lightning surges, risk assessment, substation outage rate.

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Section: Lightning Risk Assessment Resultsmentioning

confidence: 99%

Lightning risk assessment of a 170 kV GIS substation connected to the Hellenic transmission system through underground cables

Mikropoulos¹,

Tsovilis²,

Manousaridis³

et al. 2010

7th Mediterranean Conference and Exhibition on Power Generation, Transmission, Distribution and Energy Conversion (MedPower 201

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“…However, depending on transmission line geometry, the striking distance and interception radius of the shield wire may be affected by the presence of the neighboring phase conductor; this was raised by Peterson and Eriksson [39] in [18] and discussed in detail in [28] and [40]. In fact, the competing upward discharge from a neighboring phase conductor, modifying the extent of development of the connecting upward discharge from the shield wire, may result in a reduction of the striking distance and interception radius of the shield wire.…”

Section: Discussionmentioning

confidence: 99%

“…E. Tsovilis (e-mail: thtsovil@auth.gr) are with the Department of Electrical Energy, School of Electrical and Computer Engineering, Aristotle University of Thessaloniki, Thessaloniki, 54124 Greece. been introduced [27], [28] by implementing a statistical lightning attachment model derived from scale model experiments [29].…”

Section: Introductionmentioning

confidence: 99%

Lightning attachment models and maximum shielding failure current: Application to transmission lines

Mikropoulos

Tsovilis

2009

2009 IEEE Bucharest PowerTech

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General relationships for the estimation of the maximum shielding failure current of overhead transmission lines have been derived by performing shielding analysis on the basis of several lightning attachment models including a recently introduced statistical one. The interdependence of maximum shielding failure current, transmission line geometry and factors employed in lightning attachment models is discussed through an application to typical 150 kV and 400 kV lines of the Hellenic transmission system. The maximum shielding failure current depends on transmission line geometry and shows a great variability among the lightning attachment models that are used in shielding analysis; electrogeometric models, thus also the IEEE Standard 1243:1997, yield higher values. These results are of great importance when considering that the maximum shielding failure current of transmission lines, besides being employed in estimating their shielding failure flashover rate, is an important parameter for insulation coordination studies. since 2005, he has been the Director of the High Voltage Laboratory at AUTh.His research interests include the broad area of high-voltage engineering with an emphasis given on air and surface discharges, electric breakdown in general, and lightning protection. Thomas E. Tsovilis (S'09) was born in Piraeus, Greece in 1983. He received the M.Eng. degree in electrical and computer engineering from Aristotle University of Thessaloniki, Thessaloniki, Greece, in 2005, where he is currently pursuing the Ph.D. degree in the High Voltage Laboratory. His research is dedicated to lightning protection, including theoretical analysis and scale model experiments.

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“…2.3 Statistical model [29][30][31][32] Lightning interception probability is an additional parameter that should be incorporated in the design of an efficient LPS. Striking distance and interception radius are described in [29][30][31][32] as statistical quantities following a normal distribution with a mean value and a standard deviation. Both quantities (R and S in Fig.…”

Section: Research Articlementioning

confidence: 99%

“…The expressions (2)- (5) of the rolling sphere model and the elliptical model are formulated for the special case of 50% interception probability, referred to as critical interception. Critical interception radius (R c ) and critical striking distance (S c ) are expressed in (6) and (7) [29][30][31][32]. The corresponding factors of the statistical model are shown in Table 2 S…”

Section: Research Articlementioning

confidence: 99%

Experimental investigation of the external lightning protection of ships through impulse voltage tests on a scaled‐down ship model

Nicolopoulou

Gonos

Stathopulos

2016

IET Science, Measurement & Technology

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Interception Probability and Proximity Effects: Implications in Shielding Design Against Lightning

Cited by 17 publications

References 28 publications

Lightning risk assessment of a 170 kV GIS substation connected to the Hellenic transmission system through underground cables

Lightning risk assessment of a 170 kV GIS substation connected to the Hellenic transmission system through underground cables

Lightning attachment models and maximum shielding failure current: Application to transmission lines

Experimental investigation of the external lightning protection of ships through impulse voltage tests on a scaled‐down ship model

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