Insulator flashover caused by atmospheric icing is a serious accident with
high frequency. The flashover risk on insulators during ice-melting process
is higher than that during icing accretion process. Therefore, it is of
great theoretical significances and engineering value to carry out research
on risk prediction methods of ice-melting flashover on insulators. Firstly,
this paper presents a thermal balance equation of the iced insulator surface
for icing natural melting process and calculates the main influencing
parameters of the ice-melting process by thermodynamic analysis. Secondly,
this paper extracts the meteorological data from great numbers of on-site
ice-melting flashover cases to calculate the meteorological condition with
the highest flashover risk. On the basis of this, to judge the state of
freezing or melting, a thermodynamic criterion of freezing and melting state
is proposed, and the finite element analysis is applied to model iced and
non-iced insulators, and the temperature distribution, the wall heat
transfer coefficient distribution of the airflow field are analyzed. The
results suggest that the local micrometeorological temperature and the heat
transfer coefficient have the greatest impact on the ice-melting process of
insulators. The structure of insulator will be changed by the covered ice,
ended up to a cone-like structure which will weaken the influence of the
vortex on the central leeward side. And the heat dissipation and melt
characteristics of iced insulator will be quite different from that of
non-iced insulator.
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