Experimental and finite element analysis of permanent formwork impacts on flexural failures of reinforced concrete beams

Experimental and finite element analysis of permanent formwork impacts on flexural failures of reinforced concrete beams

•Various design scenarios of precast permanent formworks were applied to RC beams.•Flexural tests and FEM analysis were conducted.•Critical points of the beam flexural failure mechanism were thoroughly analyzed.•Formwork delays the process of flexural cracking and reinforcement yielding.•Formwork di...

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Bibliographic Details
Published in:Engineering failure analysis Vol. 168; p. 109069
Main Authors: Hai, Nguyen Minh, Fujikura, Shuichi, Rin, Tran Van, Shinoda, Yoshio, Nam, Phan Hoang, Tuan, Nguyen Duc, Thu Thuy, Mai Thi, Huong, Nguyen Van, Phuong, Pham Ngoc
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2025
Subjects:
Cracking
Finite element analysis
Flexural failure
High-performance concrete
Parametric analysis
Permanent formworks
Stainless steel
Yielding
Flexural failure
Yielding
Parametric analysis
Stainless steel
Cracking
Finite element analysis
High-performance concrete
Permanent formworks
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Summary:•Various design scenarios of precast permanent formworks were applied to RC beams.•Flexural tests and FEM analysis were conducted.•Critical points of the beam flexural failure mechanism were thoroughly analyzed.•Formwork delays the process of flexural cracking and reinforcement yielding.•Formwork dimensions and material properties significantly affect critical points. The use of precast permanent formwork in construction is an advanced method gaining attention due to its numerous benefits, especially in projects where dismantling formwork after concrete pouring is challenging. While most previous studies focus primarily on the mechanisms of reinforced concrete (RC) components with permanent formwork under specific design scenarios, where the formwork design parameters remain largely unchanged, this study provides a more comprehensive understanding of how formwork affects the flexural failure mechanisms of RC beams. It aims to optimize formwork system design by considering a wider range of design scenarios. This study includes entirely original flexural tests and efforts to develop a finite element model with accurate component models, particularly applying a cohesive model for the interface between the formwork and the cast-in-place concrete. The key contribution of the study is its clarification of the flexural failure mechanisms of beams using precast permanent formwork systems through both experimental and simulation approaches. Additionally, it includes a comprehensive parametric analysis that identifies how permanent formwork can delay critical failure points, such as flexural cracking and reinforcement yielding, while enhancing the ultimate load-bearing capacity of beams. Notably, increasing concrete strength and formwork thickness is more effective in delaying the onset of flexural cracks, whereas augmenting the diameter or tensile strength of the reinforcement within the formwork is more effective in postponing the reinforcement yielding and enhancing the beam ultimate load. These insights offer new perspectives on optimizing formwork systems for improved structural performance.
ISSN:1350-6307
DOI:10.1016/j.engfailanal.2024.109069