Title :
Strong and Weak Electric Field Interfering: Capacitive Icing Detection and Capacitive Energy Harvesting on a 220-kV High-Voltage Overhead Power Line
Author :
Moser, Michael J ; Bretterklieber, T. ; Zangl, Hubert ; Brasseur, Georg
Author_Institution :
Inst. of Electr. Meas. & Meas. ment Signal Process., Graz Univ. of Technol., Graz, Austria
fDate :
7/1/2011 12:00:00 AM
Abstract :
This paper focuses on problems which arise when both a power-harvesting system based on a capacitive principle and a capacitive measurement device [i.e., a capacitance-to-digital converter (CDC)] are used in one electronic system to build up an autonomous measurement device for icing detection on a high-voltage overhead power line. The overall capacitance of the measurement circuitry between the conductor and the energy harvester shell must remain within a well-defined range to keep the energy-harvesting circuitry operational and to operate the CDC within its specifications. A decoupling solution for both the data path and the power supply unit has been implemented and verified experimentally in a high-voltage laboratory and a field test.
Keywords :
capacitance measurement; electric fields; energy harvesting; power overhead lines; autonomous measurement device; capacitance-to-digital converter; capacitive energy harvesting; capacitive icing detection; capacitive measurement device; data path; electronic system; high-voltage overhead power line; power supply unit; power-harvesting system; strong electric field interfering; voltage 220 kV; weak electric field interfering; Linear matrix inequalities; Lyapunov method; Matrix decomposition; Nickel; Polynomials; Stochastic systems; Symmetric matrices; Capacitance measurement; decoupling of systems; energy harvesting; galvanic isolator; high-voltage overhead power line; icing detection; online condition monitoring; optical coupler; power system reliability; wireless communication;
Journal_Title :
Industrial Electronics, IEEE Transactions on
DOI :
10.1109/TIE.2010.2098362
