Abstract:
The unplanned and rapid growth of developments has led to adverse impacts on the climate
and biodiversity. Among them, the building industry is one of the foremost sectors. Therefore,
the proper selection of building materials and techniques is of prime importance. Out of several
sustainable materials, the soil has gained more attraction due to its advantageous features.
Hence, this century has seen several notable milestones after passing thousands of years with
the usage of soil in construction. Earthen flooring is one aesthetically attractive building
element that has recently been restored and modernized. In fact, terrazzo, ceramic tiles woods,
etc. are the widely available flooring materials associated with certain undesirable features.
Hence, a necessity has arisen to seek alternative flooring materials. However, soil as a flooring
material has not been investigated properly. Therefore, this research focuses on developing
soil as a flooring material with sustainable features while pursuing possible means of
increasing the strength of soil as a flooring material and enhancing the top surface finish. Then,
the durability and service characteristics, cost benefits, thermal performance would be
evaluated with the behavior on a real scale. The optimum soil gradation was first investigated.
Next, investigation results showed that the increase in water content causes a decrease in the
compressive strength, linearly at a constant rate for all cement percentages. The selected soil
cement mix with water form a concrete and 150 mm standard cubes were used to determine
the compressive strength. The best size and shape of test specimens were predicted and the
relationship between compressive strength and specimen size and shape was identified in this
background. Consequently, soil concrete was tested with the addition of metal as a course
aggregate, but it did not influence the improvement of compressive strength in a significant
level. Soil concrete with chemical admixtures showed that the admixtures were useful to
enhance the workability and strength. The Mixed proportion consisted of fine particle contents
0-10%, a sand content 55%-60%, gravel content 30%-35% with a maximum gravel size of
25mm. The required cement was 18%-20% that depended on the usage of the admixture. The
required moisture range was 16%-19% for soil concrete without admixtures to achieve a
workable mix. To form the top surface to be architecturally attractive and for smoothness with
regard to user comfort, the surfaces were smoothened in this background. Among several
resins, one synthetic resin and floor sealer were selected and applied on the prepared soil floor
samples as a surface coating. The Phenol-formaldehyde (novolac) resin was selected and cured
with the Hexamethylenetetramine (HMTA) with heat treatment. The bonding capacity of
coating in the soil floor, the water absorption, the abrasion resistance, the slip resistance and
the stain resistance were analyzed according to the relevant standards to evaluate the soil floor
with the resin coating for durability and service characteristics. Though all the tested
parameters were within the standard requirements, the abrasion resistance of resin surface
failed in this context. However, the floors which were with floor sealers showed positive
results. At the end of the series of experiments, the mixing proportion, the top surface finishing
material and the method of construction were decided for the continuation of the research.
Thermal performance and cost benefits were then evaluated and compared with other selected
existing floorings. According to the temperature variation pattern, the soil floor showed a
significantly low top surface temperature compared to the other floorings and indoor air
temperature. In fact, the Life Cycle Cost (LCC) for soil floor is significantly less compared to
other existing floorings.
Finally, the study findings suggest that soil could be used as a flooring material and a floor
sealer could be used as a top surface finishing layer with a long-term sustainability. However,
further research is required to find the suitability for a building's upper floors and the use of
natural resin as a top surface finishing material.
Citation:
Galabada, G.H. (2021). Development of soil based flooring material for tropics [Doctoral dissertation, University of Moratuwa]. Institutional Repository University of Moratuwa. http://dl.lib.uom.lk/handle/123/21182