Abstract: The steps followed in the design of a reference resistive-capacitive divider for on-site calibration on the medium voltage grid are described. The design constraints are defined on the basis of the expected on-site conditions, rated primary and secondary voltage, insulation requirements and accuracy performances. The final set up of the divider is defined by making use of a circuital model. Both the stray parameters of the divider components and the capacitive coupling with the shield, which are estimated through finite element modelling, are included in the model. The electric field distribution between divider and shield is also estimated, taking into account the presence of the insulating medium to identify the electric field hot spots and verify the dielectric strength of the device. The variation of the divider behaviour in a frequency range from power frequency to 100 kHz is found to be within 200 ppm and 2 mrad for the ratio and phase displacement, so making feasible the extension of its use over a quite wide frequency range both as a reference or a measuring transducer.
DESIGN OF A RC MEDIUM VOLTAGE DIVIDER FOR ON-SITE CALIBRATION / Crotti, Gabriella; Giordano, Domenico; Sardi, Angelo. - (2009), pp. 210-214. (Intervento presentato al convegno 16th International Symposium on High Voltage Engineering, ISH2009 tenutosi a Cape Town (SouthAfrica) nel August 2009).
DESIGN OF A RC MEDIUM VOLTAGE DIVIDER FOR ON-SITE CALIBRATION
CROTTI, GABRIELLA;GIORDANO, DOMENICO;SARDI, ANGELO
2009
Abstract
Abstract: The steps followed in the design of a reference resistive-capacitive divider for on-site calibration on the medium voltage grid are described. The design constraints are defined on the basis of the expected on-site conditions, rated primary and secondary voltage, insulation requirements and accuracy performances. The final set up of the divider is defined by making use of a circuital model. Both the stray parameters of the divider components and the capacitive coupling with the shield, which are estimated through finite element modelling, are included in the model. The electric field distribution between divider and shield is also estimated, taking into account the presence of the insulating medium to identify the electric field hot spots and verify the dielectric strength of the device. The variation of the divider behaviour in a frequency range from power frequency to 100 kHz is found to be within 200 ppm and 2 mrad for the ratio and phase displacement, so making feasible the extension of its use over a quite wide frequency range both as a reference or a measuring transducer.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.