Title :
Highly Stable Upwind FEM for Solving Ionized Field of HVDC Transmission Line
Author :
Huang, Guodong ; Ruan, Jiangjun ; Du, Zhiye ; Zhao, Changwei
Author_Institution :
Sch. of Electr. Eng., Wuhan Univ., Wuhan, China
Abstract :
The ionized field produced by corona discharge from a high-voltage direct current (HVDC) transmission line has a great influence on the electromagnetic environment. In this paper, a highly stable iterative algorithm based on an upwind finite-element method is introduced to analyze the ionized field of HVDC transmission line in the presence of the wind. The Kaptzov´s assumption is introduced on the conductor surface as a boundary condition. In the iterative procedure presented by Takuma, the controlling method is added to guarantee the convergence of the iteration, which has been tested to be effective. The impact of the wind on the ground-level electric-field intensity and ion current density of a bipolar HVDC transmission line is analyzed, and we find the wind has a significant influence on the ionized field which has to be considered in the engineering design.
Keywords :
HVDC power transmission; corona; finite element analysis; iterative methods; power transmission lines; Kaptzov assumption; bipolar HVDC transmission line; conductor surface; corona discharge; electromagnetic environment; engineering design; ground-level electric-field intensity; high-voltage direct current transmission line; highly stable iterative algorithm; highly stable upwind FEM; highly stable upwind finite-element method; ion current density; ionized field; Conductors; Corona; Current density; Finite element methods; HVDC transmission; Power transmission lines; Space charge; Electric-field intensity; Kaptzov´s assumption; highly stable iterative algorithm; wind;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2011.2174203
