Abstract
This research presents the use of advanced nanocomposites in bridge building as a way to improve the stability and efficiency of concrete structures. By using nanocomposites, problems with performance under different loading circumstances, durability, and structural integrity have to be addressed. This study examines the structural behavior of concrete structures reinforced with cutting-edge nanocomposites using shear deformation theory, a numerical solution process, and Hamilton’s principle. The research starts out by examining the makeup and features of nanocomposite materials, emphasizing how they may enhance the structural and mechanical qualities of concrete. The dynamic response and stability of concrete structures reinforced with nanocomposite under various loading scenarios are assessed using numerical simulations and analysis grounded on Hamilton’s principle. The complex relationship between mechanical performance, structural geometry, and material composition is captured by the shear deformation theory. The behavior of nanocomposite-reinforced concrete structures, including their stiffness, strength, and weight fraction of nanocomposites, may be fully understood thanks to this theoretical framework. The study’s conclusions provide insight into how well-suited sophisticated nanocomposites are for boosting the strength and stability of concrete constructions, especially when it comes to building bridges. Engineers and researchers may enhance concrete system performance and design for robust and sustainable infrastructure development by using shear deformation theory, Hamilton’s principle, and numerical solution methodologies.
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