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单板层积材(LVL)强度和刚度特性的试验研究

Experimental Investigation on Strength and Stiffness Properties of Laminated Veneer Lumber (LVL).

作者信息

Romero Alfredo, Odenbreit Christoph

机构信息

Faculty of Science Technology and Medicine (FSTM), University of Luxembourg, L-4365 Esch-sur-Alzette, Luxembourg.

出版信息

Materials (Basel). 2023 Nov 16;16(22):7194. doi: 10.3390/ma16227194.

DOI:10.3390/ma16227194
PMID:38005123
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10672811/
Abstract

This study presents a testing campaign aimed at evaluating the strength and stiffness properties of laminated veneer lumber (LVL) specimens. LVL is an engineered wood product composed of thin glued wood veneers whose use in construction for structural applications has increased due to its sustainability and enhanced mechanical performance. Despite LVL's growing popularity, there is a lack of comprehensive information regarding stress-strain responses, failure modes, and the full set of strength and stiffness properties. These are particularly essential when LVL is employed in pure timber structures or composite systems such as steel-timber or timber-concrete load-bearing elements. This research aims to bridge this knowledge gap, focusing on crossbanded LVL panels, known as LVL-C, crafted from Scandinavian spruce wood, which is an LVL product with 20% of crossbanded veneers. The study explores LVL-C mechanical behavior in three primary orthogonal directions: longitudinal, tangential, and radial. A series of mechanical tests, including compression, tension, shear, and bending, was conducted to provide a thorough assessment of the material's performance. In compression tests, different behaviors were observed in the three directions, with the longitudinal direction exhibiting the highest stiffness and strength. Tensile tests revealed unique stress-strain responses in each direction, with gradual tension failures. Shear tests showcased varying shear stress-strain patterns and failure modes, while bending tests exhibited significant strength and stiffness values in flatwise bending parallel to the grain and flatwise bending perpendicular to the grain. This paper summarizes the comprehensive testing results and discusses the obtained strength and stiffness properties of LVL-C panels, providing valuable insights into their mechanical behavior for engineering applications.

摘要

本研究开展了一项测试活动,旨在评估单板层积材(LVL)试件的强度和刚度特性。LVL是一种人造木制品,由薄胶合木单板组成,由于其可持续性和增强的机械性能,其在建筑结构应用中的使用有所增加。尽管LVL越来越受欢迎,但关于应力-应变响应、破坏模式以及完整的强度和刚度特性的全面信息却很缺乏。当LVL用于纯木结构或复合系统(如钢-木或木-混凝土承重构件)时,这些信息尤为重要。本研究旨在填补这一知识空白,重点关注由斯堪的纳维亚云杉木制成的交叉单板层积材板(称为LVL-C),它是一种含有20%交叉单板的LVL产品。该研究探索了LVL-C在三个主要正交方向(纵向、切向和径向)的力学行为。进行了一系列力学测试,包括压缩、拉伸、剪切和弯曲测试,以全面评估该材料的性能。在压缩测试中,在三个方向上观察到了不同的行为,纵向方向表现出最高的刚度和强度。拉伸测试揭示了每个方向独特的应力-应变响应以及逐渐的拉伸破坏。剪切测试展示了不同的剪应力-应变模式和破坏模式,而弯曲测试在平行于木纹的平面弯曲和垂直于木纹的平面弯曲中表现出显著的强度和刚度值。本文总结了全面的测试结果,并讨论了获得的LVL-C板的强度和刚度特性,为其在工程应用中的力学行为提供了有价值的见解。

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