Open Access

In the presented paper data collected from the field related to damage statistics of electrical and electronic apparatus in household are reported and investigated. These damages (total number approx. 74000 cases), registered by five German insurance companies in 2005 and 2006, were adviced by customers as caused by lightning overvoltages. With the use of stochastical methods it is possible, to reasses the collected data and to distinguish between cases, which are with high probability caused by lightning overvoltages, and those, which are not. If there was an indication for a direct strike, this case was excluded, so the focus was only on indirect lightning flashes, i.e. only flashes to ground near the structure and flashes to or nearby an incoming service line were investigated. The data from the field contain the location of damaged apparatus (residence of the policy holder) and the distances of the nearest cloud-to-ground stroke to the location of the damage registered by the German lightning location network BLIDS at the date of damage. The statistical data along with some complementary numerical simulations allow to verify the correspondence of the Standards rules used for IEC 62305-2 with the field data and to define some correction needs. The results could lead to a better understanding whether a damage reported to an insurance company is really caused by indirect lightning, or not.

[Paper of the X International Symposium on Lightning Protection 9th - 13th November, 2009 - Curitiba, Brazil. 6 pages] The international standard IEC 62305-3, published in 2006, requires as an integral part of the lightning protection system (LPS) the consideration of a separation distance between the conductors of the LPS and metal and electrical installations inside the structure to be protected. IEC 62305-3 gives two different methods for this calculation: a standard, simplified approach and a more detailed approach, which differ especially regarding the treatment of the current sharing effect on the LPS conductors. Hence, different results for the separation distance are possible, leading to some discrepancies in the use of the standard. The standard approach defined in the main part (Clause 6.3) and in Annex C of the standard in some cases may lead to a severe oversizing of the required separation distance. The detailed approach described in Annex E naturally gives more correct results. However, a calculation of the current sharing amongst all parts of the air-termination and downconductor network is necessary, in many cases requiring the use of network analysis programs. In this paper simplified methods for the assessment of the current sharing are presented, which are easy to use as well as sufficiently adequate.

Zur 4. VDE/ABB-Blitzschutztagung 2001 wurde ein Messverfahren zur Bestimmung der magnetischen Schirmdämpfung an realen Bauwerksstrukturen im Frequenzbereich der natürlichen Blitzentladung vorgestellt, welches aus einer aktiven und einer passiven Komponente besteht. Mit diesem Messverfahren wurden seither an Bauwerken in industriellen Anlagen in einer Vielzahl von Einzelmessungen Werte der Schirmdämpfung aufgenommen. Eine Auswertung dieser Messungen wird in diesem Beitrag vorgestellt. In einigen Fällen wurden Gebäude vermessen, deren Schirmdämpfung ansatzweise mit den Formeln nach VDE V 0185-4 bestimmt werden kann. Hierbei treten zwischen den Messergebnissen und den berechneten Werten sowohl gute Übereinstimmungen als auch Differenzen von teilweise mehr als 10 dB auf. Eine erste Interpretation dieser Differenzen wird im vorliegenden Beitrag vorgenommen.