Numerical and Analytical Assessment of Flexural Performance in Partially Encased Composite Steel Beams
Elbosaty, S., Sharaf, T., Elghandour, M. (2025). Numerical and Analytical Assessment of Flexural Performance in Partially Encased Composite Steel Beams. EKB Journal Management System, (), -. doi: 10.21608/pserj.2025.401592.1423
Salah Nagy Elbosaty; Tarek Sharaf; Mohamed Elghandour. "Numerical and Analytical Assessment of Flexural Performance in Partially Encased Composite Steel Beams". EKB Journal Management System, , , 2025, -. doi: 10.21608/pserj.2025.401592.1423
Elbosaty, S., Sharaf, T., Elghandour, M. (2025). 'Numerical and Analytical Assessment of Flexural Performance in Partially Encased Composite Steel Beams', EKB Journal Management System, (), pp. -. doi: 10.21608/pserj.2025.401592.1423
Elbosaty, S., Sharaf, T., Elghandour, M. Numerical and Analytical Assessment of Flexural Performance in Partially Encased Composite Steel Beams. EKB Journal Management System, 2025; (): -. doi: 10.21608/pserj.2025.401592.1423

Numerical and Analytical Assessment of Flexural Performance in Partially Encased Composite Steel Beams

Port-Said Engineering Research Journal
Articles in Press, Accepted Manuscript, Available Online from 21 September 2025
Document Type: Original Article
DOI: 10.21608/pserj.2025.401592.1423
Authors
Salah Nagy Elbosaty* 1; Tarek Sharaf2; Mohamed Elghandour2
1civil engineering department faculty of engineering port said university
2Professor, Department of Civil Engineering, Port Said University, Egypt
Abstract
This paper presents a comprehensive numerical and analytical investigation into the flexural performance of partially encased composite steel beams (PECSBs) subjected to bending loads. A total of 54 finite element (FE) models were developed to assess the influence of critical geometric and material variables on structural behavior. The numerical results were validated against available experimental data to ensure accuracy and reliability. The interaction between the steel and concrete components was simulated using a friction coefficient of 0.65, derived from prior experimental findings. As part of the study’s contributions, novel analytical equations were proposed to estimate both the ultimate flexural strength and the mid-span deflection of PECSBs. These equations are based on physical parameters and validated numerical outcomes, offering a practical tool for structural engineers. In addition, a new dimensionless indicator, termed the Composite Flexural Index (CFI), was introduced to quantify flexural efficiency under varying levels of composite interaction. The proposed models and the CFI metric offer a robust framework for performance-based design and optimization of composite beam systems. The findings enhance the understanding of key design sensitivities and contribute to improving stiffness, ductility, and overall structural reliability in PECSB applications.
Keywords
Finite Element Analysis; Mid-span Deflection; Parametric Study; Analytical Modeling; Composite Flexural Index
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