Affiliation:
1. Department of Strength of Materials and Building Structures, Faculty of Civil Engineering and Architecture, Kielce University of Technology, al. Tysiąclecia Państwa Polskiego 7, 25-314 Kielce, Poland
2. Department of Quality Management and Intellectual Property, Faculty of Management and Computer Modeling, Kielce University of Technology, al. Tysiąclecia Państwa Polskiego 7, 25-314 Kielce, Poland
Abstract
The commercialization of modular timber products as cost-effective and lightweight components has resulted in innovative engineering products, e.g., glued laminated timber, laminated veneer lumber, I-beams, cross-laminated timber and solid timber joined with wedge joints. With the passage of time, timber structures can deteriorate, or new structural elements are required to increase the stiffness or load-bearing capacity in newly built structures, e.g., lintels over large-scale glazing or garages, or to reduce cross-sectional dimensions or save costly timber material while still achieving low weight. It is in such cases that repair or correct reinforcement is required. In this experimental and numerical study, the static performance of flexural timber beams reinforced with prestressed basalt BFRP, glass GFRP and hybrid glass–basalt fiber bars is shown. The experimental tests resulted in an increase in the load-carrying capacity of BFRP (44%), GFRP (33%) and hybrid bars (43%) and an increase in the stiffness of BFRP (28%), GFRP (24%) and hybrid bars (25%). In addition to this, glued laminated timber beams reinforced with prestressed basalt rods subjected to biological degradation, 7 years of weathering and prolonged exposure to various environmental conditions were examined, and an increase in the load-bearing capacity of 27% and an increase in stiffness of 28% were obtained. In addition, full-size laminated timber beams reinforced with prestressed basalt bars were investigated in the field as an exploratory test under fire conditions at elevated temperatures, and the effect of the physical–mechanical properties during the fire was examined via an analysis of these properties after the fire. In addition, a satisfactory correlation of the numerical simulations with the experimental studies was obtained. The differences were between 1.1% and 5.5%. The concordance was due to the fact that, in this study, the Young, Poisson and shear moduli were determined for all quality classes of sawn timber. Only a significant difference resulted in the numerical analysis for the beams exposed to fire under fire conditions. The experimental, theoretical and numerical analyses in this research were exploratory and will be expanded as directions for future research.
Subject
General Materials Science
Reference49 articles.
1. Khaled, S. (2024, January 23). Finite Element Modelling for Timber Beams Reinforced with Carbon Fibre Reinforced Polymers (CFRP). A PHD Dissertation Submitted to the Faculty of Civil Engineering in Candidacy for the Degree of Doctor of Philosophy. BUDAPEST. Available online: https://repozitorium.omikk.bme.hu/items/9a7c910f-257e-4643-8f63-2c6be3a6de74.
2. Hybrid fiber reinforced polymer composites—A review;Sathishkumar;J. Reinf. Plast. Compos.,2014
3. Synthetic fibers and thermoplastic short-fiber-reinforced polymers: Properties and characterization;Unterweger;Polym. Compos.,2014
4. Experimental investigation on morphological, physical and shear properties of hybrid composite laminates reinforced with flax and carbon fibers;Ramesh;J. Chin. Adv. Mater. Soc.,2018
5. Numerical and Experimental Evaluation of the Mechanical Behavior of FRP-Strengthened Solid and Glulam Timber Beams;Avcar;J. Eng. Manag. Syst. Eng.,2023