Abstract:
Surface voltage measurement of an insulated (silicone rubber) overhead conductor
assumes importance for understanding corona, radio interference voltages, and design
purposes. Surface voltage measurement of a bare overhead conductor is quite simple as a
voltage divider can be directly connected. However, there are challenges in the
measurement of surface voltage on an insulating surface of an insulated covered
conductor using voltage dividers. In case of ac measurements, the capacitance parameter
dominates in deciding the potential distribution. In this work, it is demonstrated that the
measuring system itself will alter the voltage division between the capacitance of the
cylindrical insulated conductor and that of surrounding air acting as a capacitive divider.
The voltage distribution is shown to be drastically influenced by the measuring system
capacitance. In view of these issues, a novel experimental method is proposed for the
measurement of surface voltage of an overhead insulated covered conductor using
cylindrical strips. In general, this method can be applied to any cylindrical insulated
conductor and for the calibration of sensor-based measurements. The proposed empirical
method is tested by a validated simulation of the entire system, and it is proven
analytically. The analytical, experimental, and simulation results are in close conformity.
However, in case of a general insulator surface, the use of a cylindrical strip may not be
possible due to the reason that the voltage at different points on the surface of insulators
can be different (e.g., string insulators of overhead line). Also, while measuring potential
points near the earthed surface, the use of a cylindrical strip might electrically short
different potentials, which is not desirable. Considering these facts, a unique method is
presented, using which the surface voltage of any insulating surface such as insulator
strings or transformer bushings can be measured. The work is based on analytical
derivations, a more generalized method of measurement, applicable to any point on an
insulating surface of arbitrary geometry is proposed using circular-disc strips. The
proposed experimental method is applied to insulator strings and transformer bushings
and validated by simulation of the entire system. The simulation and experimental results
are in excellent agreement.
Generally, for power equipment insulation, the process of damage accumulation that
starts due to the presence of the defects eventually leads to power equipment failure. In power cables, conductor protrusions or metallic defects in insulation are important among
these defects. The electric field at the tip of sharp protrusions increases multifold due to
the small radius of curvature at the tip. The high electric field at the tip initiates electrical
treeing under sinusoidal voltages and leads eventually to insulation breakdown. These
defects can be modeled by using needle-plane geometry. Therefore, the study of needleplane
geometry assumes importance for the evaluation of electric stresses at the tip of
these defects. Here, electric field and space charge accumulation have been investigated
for needle-plane system (defect) in silicone rubber insulation under dc voltage conditions.
Prolate spheroidal coordinate system, believed to be closer to needle-plane system, has
been used for solving the governing differential equations, numerically, for space charge
and electric field distributions. Unlike past works, in which, space charge at needle tip
was assumed, either qualitatively or quantitatively, in this work, space charge formation
is estimated using nonlinearity of material properties alone. A comparison with previous
methods based on concentric spherical electrode approximations reveals that the results
are different for prolate spheroidal system at different nonlinearities. Interesting results on
the role of nonlinear conductivity on the dc electric field and space charge accumulation
at needle-tip are presented. Also, needle tip-plane breakdown experiments are conducted.
Further, for DC systems with line-commutated converters (LCC), where to reverse the
power flow, it is necessary to change the voltage polarity. It is known that high stresses
may occur at the conductor immediately after reversing the polarity of an external voltage
source and if not properly designed, stresses the cable leading to insulation failure. In
view of this, a 2D axisymmetric numerical model is presented to compute the timedependent
field, space charge, and current density distribution in needle plane geometry
under polarity reversal DC. Interesting results on the effect of polarity transition time,
applied polarity time step on the above-mentioned distributions have been addressed and
presented. The pronounced effect of nonlinear conductivity on the time-dependent field
distribution is also demonstrated. In addition, breakdown experiments are conducted on
tip-plane electrode system for different tip radii and for different applied time step
polarity reversal, and the results put forward a rational and practical estimate of
breakdown field.