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Titel |
Time and frequency GPR waveforms analysis for clay content evaluation in soils |
VerfasserIn |
F. Tosti, C. Patriarca |
Konferenz |
EGU General Assembly 2012
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Medientyp |
Artikel
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Sprache |
Englisch
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Digitales Dokument |
PDF |
Erschienen |
In: GRA - Volume 14 (2012) |
Datensatznummer |
250065574
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Zusammenfassung |
The mechanical behaviour of soils is partly affected by their clay content, which exerts some
considerable effects in many applications in the fields of civil engineering, geology and
environmental engineering. This study focuses on pavement engineering, but the approach
can be extended to other purposes.
The presence of clay in the bearing structural layers of pavements frequently causes
damages and defects, such as transversal and longitudinal cracks, deformations and rutting.
Consequently, the road safety and operability decrease, while the expected number of
accidents increases.
In this work Ground Penetrating Radar (GPR) laboratory inspections are carried out in
order to predict the presence of clay in pavement structural layers. Data are post-processed in
the frequency domain, according to the Rayleigh scattering method based on the Fresnel
theory. This new technique can be supported by other survey methods, improving the quality
of the results.
Analysis are carried out using two different GPR systems.
A Radar is used with ground-coupled antennae in a bistatic configuration and common
offset; the transmitter and receiver are linked by optic fiber electronic modules and operate at
500 MHz central frequency. The received signal is sampled in the time domain at time steps
of 7.8125 x 10-2 ns.
A Vector Network Analyzer (VNA) acquires ultra-wide band data in a bandwidth from
500 MHz to 3000 MHz. The signal is sampled in the frequency domain with approximately
1.56 MHz frequency steps. A double-ridged broadband horn antenna is connected via a
high-quality coaxial cable to the VNA pulse generator and illuminates the analyzed target in a
monostatic off-ground configuration.
The experimental setting required the use of road material, typically employed for
sub-grade and sub-base layers. Three kind of soils, classified as A1, A2, A3 by AASHTO are
used and adequately compacted in electrically and hydraulically isolated boxes. Bentonite
clay is gradually added from 2% to 25% in weight, according to mixing and compaction
laboratory procedures. A metal plate supports the experimental boxes, so that the GPR signal
is totally reflected.
GPR surveys are carried out for each clay content. The signals are analyzed in both time
and frequency domains.
In the time domain the reliability of results is validated by the electromagnetic theory, in
terms of signal amplitude, electric permittivity and time delay . In the frequency domain the
results are highly consistent for all the investigated soils . Assuming a residual water content
of the dry clay that is due to its hygroscopic capability, frequency spectra shift not linearly, as
expected from the scattering theory. The modulation depends on the water content and,
indirectly, on the clay content. The correlation between the central frequency values of the
spectra and the clay content is negative: decreasing values of the central frequency
correspond to increasing values in the clay content, from 0% up to 25%. A comparative
analysis of the three soil spectra for different clay contents has shown a different
behaviour of the clay, both for the ground-coupled radar and the broadband analyzer. In
general, in fine grain size soils lower central frequency value intensities are registered. |
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