| Abstract: |
Sustainable anicut structures represent critical hydraulic infrastructure components designed to manage water flow, facilitate irrigation, and support environmental conservation in arid and semi-arid regions. This empirical study focuses on the comprehensive design and structural analysis of anicut structures utilizing advanced finite element modeling through STAAD.Pro software. The research investigates the performance characteristics of sustainable anicut configurations under varying hydrological and geological conditions. Through detailed computational analysis, the study evaluates structural behavior under different load scenarios, material properties, and environmental stressors. The findings demonstrate that optimized anicut designs incorporating sustainable materials and principles can achieve a 34% reduction in material consumption while maintaining structural integrity. Data-driven analysis reveals significant correlations between foundation soil bearing capacity and structural stability coefficients. The implementation of green construction methodologies further reduces environmental impact by 28% compared to conventional approaches. This research contributes to the advancement of sustainable water management infrastructure by providing quantitative evidence supporting the adoption of STAAD.Pro modeling for anicut design optimization, cost reduction, and environmental sustainability. The outcomes facilitate improved decision-making processes for engineers and water resource managers implementing modern sustainable infrastructure solutions across developing regions. |