Lateral swelling pressure in variably saturated expansive clay

Garrett, Steven Ray

12 May 2023

Lateral swelling pressure induced in expansive soils upon wetting can adversely impact the performance and integrity of earthen structures and foundations. The yearly cost associated with damage to structures from expansive clays in the United States is estimated to exceed the loss associated with natural disasters such as earthquakes, floods, and hurricanes. The main objective of this dissertation is to provide new insight into the evolution of lateral swelling pressure in variably saturated expensive soils under infiltration via physical testing. In the first part of this study, a new laboratory-scale testing apparatus was built to measure lateral and vertical swelling pressures under anisotropic conditions. The testing apparatus was used to investigate the effect of compaction level on lateral swelling pressure in an expansive clay collected from central Arkansas. Results show that the higher the compaction, the higher the lateral swelling pressure. In contrast, compaction was found to have an insignificant effect on the vertical swelling pressure at a compaction level of less than 90%. In the second part, the laboratory-scale testing apparatus was employed to test the effects of four additives (lime, lime kiln dust, cement, and cement kiln dust). The results showed that the addition of a high calcium additive could significantly reduce the swelling pressures of expansive clay. The third part of the dissertation involved full-scale testing of lateral pressures in an expansive clay upon infiltration. A heavily instrumented 3-m high masonry wall backfilled with an expansive clay was built and subjected to infiltration. The degree of saturation, pore-water pressure, temperature, suction, and lateral and vertical pressures were monitored at different locations during the test. Results showed that the development of lateral pressure is rapid during initial saturation and levels out as the clay approaches saturation levels. This finding highlights the importance of monitoring lateral pressure over time to accurately predict its behavior. The study also found that lateral pressure develops prior to vertical pressure, depending on the area and restraint.

Lateral Swell

Expansive Clay. Pore-water pressure

Geotechnical Engineering

An Experimental Study On The Treatment Of Expansive Soils By Granular Materials

Hergul, Timucin

01 September 2012

Expansive soils are a worldwide problem that possesses various challenges for civil engineers. With increasing water content, they exhibit excessive volume changes, resulting in large horizontal and vertical stresses to the structures located or buried in these regions. The most common method to minimize this effect is to replace these types of clays around the proposed structure with nonexpansive soils. For the cases needing larger volume of replacement, either sidewalls or the foundations must be designed to cater for the anticipated pressures or a suitable improvement technique shall be applied in place. In this experimental study, it is intended to investigate the possible positive effects of trenches backfilled with granular material such as crushed stone or rock on the improvement of swell parameters of expansive soils. Thin-wall oedometer tests, conventional oedometer tests and larger size tests with moulds were performed on artificially compacted untreated and granular fill treated samples for this purpose. The trenches were modeled by opening a hole with a diameter that satisfies the predicted percent trench content at the center of the soil samples, which was then backfilled with granular material. Modified thin-wall oedometer tests were performed to measure the lateral swell pressures of both untreated and treated samples, whereas the conventional oedometer tests and tests on samples placed in moulds were performed to measure the vertical swell parameters of soils. It was observed that both the vertical swell percentages as well as the lateral swell pressures reduced considerably as the volume of granular material filled trench was increased. The treatment was observed to be more remarkable under the surcharge effect of a light weight structure or a fill placed on top.

TA Foundations, Earthwork 715-787