APPLICATIONS OF ELECTROMAGNETIC PRINCIPLES IN THE DESIGN AND DEVELOPMENT OF PROXIMITY WIRELESS SENSORS
First, the analyses, design and development of a static electric field
type sensor are presented for application in embedded concrete moisture
content measurement. The analytical formulation and results based on
conformal mapping method for an interdigitated sensor clearly show the
dependency of the field penetration depth and the inter-electrode
capacitance on the electrode sizes and their spacings. It is observed
that larger electrode size and small separation are needed in order to
achieve substantially higher capacitance or large field penetration
depth. A meander and a circular sensor are fabricated and tested to
demonstrate concrete moisture content measurements that show that
moisture content is a linear function of sensor interelectrode
capacitance. Second, sub-wavelength dimension non-intrusive wave
launchers are designed and tested that can launch TDR or JTFDR type
broadband surface wave waveforms in the VHF-UHF bands in order to detect
cable faults. Greater than 3:1 transmission bandwidth (100-300 MHz) is
obtained with a cylindrical launcher on square orthogonal ground plane
while with a CSW launcher more than an octave (100-240 MHz) bandwidth is
achieved. Open circuit faults are detected using surface waves and TDR
on two XLPE cables. Third, a new mathematical method is developed that
can be used to determine the changes in the dielectric constant of a
cable insulating material. By comparing the experimental JTFDR waveform
signatures from a new and an aged cable, it is demonstrated that the
change in the average dielectric constant of the insulation material can
be estimated from the phase transfer functions obtained from the FFT of
measured magnitude and phase responses. The experimental data obtained
for two types of cables, XLPE and EPR show that the dielectric constant
decreases with accelerated aging. Finally, JTFDR surface wave sensing
method is developed and applied to determine the locations of aging
related insulation damage in power cables. The comparative power
spectral responses of conducted and non-intrusive surface wave JTFDR
waveforms clearly show the resulting bandwidth reduction in the latter
primarily because of the reflective nature of the coupling. It is
demonstrated that with the help of a non-intrusive wave launcher and a
120 MHz Gaussian chirp waveform the location of aging related insulation
damages can be detected. Experiments conducted show the
cross-correlation peaks at subsequent aging intervals as the cable is
aged inside a heat chamber.