Abstract
An experimental study was conducted to evaluate durability (compressive strength and mass loss%) in the modified sulfur concrete within aggressive environments. The modified sulfur concrete was prepared by adding recycled polymeric and filler materials that showed a noticeable enhancement for modified sulfur concrete characteristics. A durability comparison between modified sulfur concrete and traditional concrete was investigated at normal and aggressive environments (10% HCl and 3% NaCl). A cuboid shape with size (50 × 50 × 50mm) was used in this research to investigate the durability of both modified sulfur and traditional concrete. The modified sulfur concrete characteristics revealed high stable structure than traditional due to preventing a process of crystallization of sulfur that modified with polymer and fillers. The compressive strength was 10.87 – 22.5% increased for modified sulfur concrete compared to the traditional concrete at the normal environment. In the aggressive environments, the modified sulfur concrete illustrated high resistance strength compared to the traditional concrete. The comparison revealed a significant impact for 10% HCl and 3% NaCl on the traditional concrete. The compressive strength decreased between (88.78 – 96.17) % for traditional concrete compared to modified sulfur concrete in 10% HCl solution and (84.25 – 95.06) % in 3% NaCl solution. Furthermore, mass loss % of the modified sulfur concrete indicated high resistance compared to the traditional concrete in both 10% HCl and 3% NaCl solutions.
Highlights
Traditional cement concrete has been extensively used concrete in industrial and civil construction
It was found that the compressive strength value for sulfur concrete much higher than traditional concrete
The results revealed minimum increase percentage of compressive strength for sulfur concrete compared to traditional concrete was 10.87% on day 21
Summary
Traditional cement concrete has been extensively used concrete in industrial and civil construction. Increasing the demand for traditional cement production was due to changes in lifestyle and urbanization. Population growth creates new infrastructure needs that can supply people's requirements, escalating the order to consume more cement amounts. Traditional cement concrete has a short life cycle against aggressive environments such as acidic and alkaline environments. The cement production plants are classified as one of the most impact plants on the environment, which the cement plants help emit 7% of the carbon dioxide to the atmosphere. Reducing the amount of cement consumption and improving the durability and stability of concrete have attracted more attention to enhancing the cement by using new technology
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