A PROGRAMMING MODEL FOR ANALYZING THE MECHANICAL AND THERMAL BUCKLING BEHAVIOR OF ECO-CONCRETE PANELS INCORPORATING RECYCLED WASTE MATERIALS (GLASS AND RED BRICKS)
DOI:
https://doi.org/10.18623/rvd.v22.n2.3117Keywords:
Glass Waste, Red Brick Waste, Eco-concrete, Thermo-mechanical Properties, Mori-Tanaka Model, Buckling BehaviorAbstract
In today's world, there is an accumulation of glass waste and red brick waste due to several factors. These materials have a significant impact on environmental protection. Among the proposed solutions, incorporating a certain percentage of these wastes into concrete offers an interesting alternative. In this paper, the study focuses on the mechanical and thermal buckling behavior of concrete incorporating declared waste for panel applications. The study aims to develop a program to obtain the thermo-mechanical properties of a biphasic concrete mixture incorporating waste. The adopted model is the Mori-Tanaka model. The same program will then be used to determine the critical buckling load and the variation in the critical buckling temperature based on the first-order shear deformation theory (FSDT) with a correction factor of 5/6. It is clearly demonstrated that the inclusion of waste improves mechanical properties, but negatively affects thermal properties. Similarly, the critical buckling efforts are influenced by this waste incorporation. It is observed that brick waste yields better results compared to glass waste in terms of thermal buckling.
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