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findings from this study are limited to findings from a certain pavement structure and
test site and therefore cannot be generalized. It would be beneficial to compare the test
results from this study to results from other pavement structures and test sites. For the
laboratory-based investigations, it is believed that incorporating
soil suction into
predictive resilient modulus models appears to give a new insight into predicting
seasonal resilient modulus variation due to moisture content changes. However, further
validation across a wider range of materials may be required, for both the approach and
the recommended parameters.
8.2.
Recommendations for future work
From the research carried out in this thesis, there are still many questions that need to
be further investigated in future research studies. The field study carried out here was
limited to a single specific test site with specific properties. The response and the stress
dependency of the unbound layers and their correlation to the measured moisture
content were evaluated using backcalculation of the surface deflection data.
Direct
measurement of in situ stresses and strains using pressure and deformation gauges along
with moisture sensors (or even suction measurement sensors) under moving traffic
loads and their response to seasonal moisture variation
would be an interesting
question, which should be further investigated.
Considering the importance of permanent deformation in unbound pavement layers in
rut formation, particularly in thin flexible pavements, it is
evident that more studies
need to be carried out on the permanent deformation properties of unbound materials
and the influence of the moisture content. Even though only two subgrade soils were
tested, it was observed that in most of the current permanent deformation models (due
to multiplicity of the model parameters) usually several combinations of parameters
would provide acceptable fit to the test data. This can cause a major confusion for a
user to select the right set of parameters when trying
to predict the permanent
deformation of the material in question. This major drawback is probably due to lack of
sufficient permanent deformation studies There is an apparent need and is
recommended that more permanent deformation tests be conducted to set up widely
accepted range limits for the parameters of different models
and if possible develop
simpler models with a minimum number of parameters.
Moreover, more research needs to be carried out to calibrate and implement permanent
deformation models that are based on data from multistage RLT tests. Comparing the
laboratory-based model predictions against the in situ pavement data or controlled APT
tests would be recommended as part of the evaluation and validation of the models.
Finally, and as the field and laboratory measurements illustrated, the environmental
factors and their effect on pavement material behaviour
and performance are very
complex in nature and it is believed that more research studies are certainly required to
progressively obtain a more complete understanding of the phenomena involved
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through both laboratory and field measurements. This will assist in developing
mechanistic approaches that can quantitatively account for
climatic factor effects on
material behaviour and pavement performance.