Project Abstract

Abstract
Seismic retrofitting of existing structures is a critical aspect of civil engineering to enhance the resilience of buildings and infrastructures against earthquakes. This research project focuses on exploring the application of innovative materials and technologies in seismic retrofitting to improve the structural performance of existing buildings. The study aims to investigate the effectiveness of various retrofitting methods and materials in enhancing the seismic resistance of structures while considering factors such as cost-effectiveness, sustainability, and practicality. The research begins with a comprehensive review of the background of seismic retrofitting, highlighting the importance of retrofitting existing structures to mitigate the potential risks associated with seismic events. Various retrofitting techniques and materials currently used in the industry will be examined to identify their advantages, limitations, and potential for innovation. The literature review will also explore recent advancements in seismic retrofitting technology, including the use of fiber-reinforced polymers, base isolators, and damping systems. The methodology chapter outlines the research approach and methodology adopted for this study, including data collection methods, experimental procedures, and analysis techniques. The research methodology will involve a combination of laboratory testing, numerical simulations, and field investigations to evaluate the performance of innovative retrofitting materials and technologies under seismic loading conditions. The selection criteria for the test specimens, simulation parameters, and performance evaluation metrics will be clearly defined to ensure the reliability and validity of the research findings. The findings chapter presents a detailed analysis of the experimental and numerical results obtained from the seismic retrofitting tests conducted in this study. The performance of different retrofitting materials and technologies will be compared based on criteria such as structural integrity, energy dissipation, and deformation capacity. The discussion will also address the practical implications of the research findings, highlighting the potential benefits and challenges associated with implementing innovative retrofitting solutions in real-world applications. In conclusion, this research project contributes to the advancement of seismic retrofitting practices by exploring the use of innovative materials and technologies to enhance the seismic resilience of existing structures. The study findings provide valuable insights into the effectiveness of various retrofitting methods and materials, offering guidance for engineers, designers, and policymakers involved in improving the seismic performance of buildings and infrastructures. Overall, this research underscores the importance of proactive measures in enhancing the resilience of structures against seismic hazards and emphasizes the role of innovation in achieving sustainable and resilient built environments.

Project Overview