Wake-induced vibration of two-phase conductors connected by spacers

Considering finite element approach applied to modelling of wind-induced split-phase overhead power line conductor oscillations caused by aerodynamic wake. Model represents an aeroelastic system including twin bundled conductor with spacers. Modified Simpson’s theory is used for conductor wake coupl...

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Bibliographic Details
Published in:IOP conference series. Materials Science and Engineering 2021-04, Vol.1129 (1), p.12040
Main Authors: Shavnya, R A, Danilin, A N
Format: Article
Language:English
Subjects:
Aerodynamic forces
Aeroelasticity
Conductors
Finite element method
Flutter
Mathematical models
Power lines
Spacers
Static equilibrium
Tensile strain
Wind effects
Wind speed
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Summary:Considering finite element approach applied to modelling of wind-induced split-phase overhead power line conductor oscillations caused by aerodynamic wake. Model represents an aeroelastic system including twin bundled conductor with spacers. Modified Simpson’s theory is used for conductor wake coupling simulation. Assuming small oscillating conductor deflection from element ends connection line compared to element length, thus the element tension and element tensile strain can be considered as constant values. Strain, as function of transverse displacements, defines as quadratic approximation. Element absolute displacements and twisting angles, together with Ritz’s method coefficients is taken as generalized coordinates, in which conductor move equations are compiled with non-linear elastic, inertial and aerodynamic forces. Appropriate linearized small oscillation equations near the static equilibrium are derived – those can be used for defining system flutter critical wind velocity. An example with split-phase twin bundled conductor, three-sub-span system is presented.
ISSN:1757-8981
1757-899X
DOI:10.1088/1757-899X/1129/1/012040