Mechanical performance of glulam beam-to-column joints with geometrical modulus: Experimental investigation and analytical approach

Mechanical performance of glulam beam-to-column joints with geometrical modulus: Experimental investigation and analytical approach

Due to the low embodied carbon and renewable features, wood is becoming increasingly popular in structural engineering. Connections have always been a critical design part, among which the beam-to-column joints with geometrical modulus could boost the prefabrication and the industrialization of timb...

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Bibliographic Details
Published in:Journal of Building Engineering Vol. 84; p. 108437
Main Authors: Li, Zheng, Wang, Yijing, Liu, Xuezheng, Ou, Jiajia, Gan, Zhaozhuo, He, Minjuan
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-05-2024
Subjects:
Beam-to-column joints
Finite element model
Glulam
Load bearing capacity
Semi-empirical formula
Glulam
Load bearing capacity
Finite element model
Semi-empirical formula
Beam-to-column joints
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Summary:Due to the low embodied carbon and renewable features, wood is becoming increasingly popular in structural engineering. Connections have always been a critical design part, among which the beam-to-column joints with geometrical modulus could boost the prefabrication and the industrialization of timber structures. In this research, the shear and tension performance of the beam-to-column joints were tested. Two series of standardized joints were designed. Monotonic and cyclic loading tests were carried out to obtain the mechanical performance of the joints. Finite element models for the two types of joints were established to investigate the load resisting mechanism. The results were verified with the experiments and the simulation could serve as the reference for the calculation of the bearing capacity. The codified approaches were applied and compared for the yielding strength calculation. The accuracy was improved when the number reduction of the fasteners was not considered. Rope effect and the pull-out strength of the fasteners should also be considered. Theoretical methods based on LEFM are deduced for the ultimate strength calculation. A revised semi-empirical formula is proposed based on the existing approaches, with which the more accurate results of the ultimate bearing capacity could be obtained. •The standardized design of the joints could boost the prefabrication and the industrialization of timber structures.•Finite element models were established to investigate the load resisting mechanism.•The codified approaches were compared for the yielding strength calculation. The key points of calculation were discussed.•The proposed semi-empirical formula could obtain a more accurate result of the ultimate strength than the LEFM method.
ISSN:2352-7102
2352-7102
DOI:10.1016/j.jobe.2024.108437