Research on shear mechanical properties of Eucalyptus scrimber and Ginkgo scrimber under different temperature conditions

IF 8 1区工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY

Construction and Building Materials Pub Date : 2025-10-01 DOI:10.1016/j.conbuildmat.2025.143791

Hangyu Li , Haitao Li , Shuai Liu , Mengzheng Cui , Haitao Ke , Pin Zhou

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引用次数: 0

Abstract

In response to the intensification of global warming, the utilization of wood as a renewable resource in the construction sector has garnered widespread interest. Nevertheless, the efficient application of fast-growing timber is hindered due to its inherent drawbacks, including lower strength and susceptibility to decay. As an engineered wood composite, scrimber has emerged as a solution to significantly augment mechanical properties through structural reconstitution. This study investigated Eucalyptus scrimber (ES) and Ginkgo scrimber (GS) as the research subjects, comprehensively analyzing their failure modes, mass loss rate, load-displacement curves and shear strength under different temperatures. Shear tests and Scanning Electron Microscopy (SEM) were employed to elucidate the variation patterns of mechanical properties and microstructural responses across nine temperature gradients from −20 °C to 260 °C. The results demonstrate that the failure modes of scrimber can be divided into fiber shearing failure and fiber tearing failure; under relatively high temperatures, scrimber exhibits the adhesive failure. The mass loss of scrimber increases with rising temperature, and the variation of mass loss rate with temperature for ES and GS parallel to the grain under different temperature conditions can be predicted using a fitted model. Generally, shear strength shows a tendency to decrease with rising temperature across the entire gradient. Observations via SEM have revealed the microstructural characteristics associated with each failure mode, and have further clarified the influence of temperature on the shear strength of scrimber from a microscopic perspective. By improving the model used to predict that the shear strength of softwood under high temperatures follows a bilinear variation, the model is made to adapt with the material characteristics of scrimber. The Hyperbolic Tangent Model is applied to more accurately predict the changes in the shear properties of scrimber under different temperature conditions. This study establishes a correlation between microstructural damage evolution and macroscale mechanical degradation, providing essential empirical data and predictive models to guide the engineering design of scrimber in different temperature environments.

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不同温度条件下桉木和银杏木剪切力学性能的研究

为了应对全球变暖的加剧，在建筑部门利用木材作为一种可再生资源已经引起了广泛的兴趣。然而，由于其固有的缺点，包括较低的强度和易腐烂，快速生长的木材的有效应用受到阻碍。作为一种工程木材复合材料，通过结构重组显著提高机械性能已经成为一种解决方案。以桉木（ES）和银杏木（GS）为研究对象，综合分析了不同温度下桉木的破坏模式、质量损失率、荷载-位移曲线和抗剪强度。通过剪切试验和扫描电镜（SEM）分析了- 20°C至260°C 9个温度梯度下的力学性能和微观结构响应的变化规律。结果表明：纤维纤维的破坏模式可分为纤维剪切破坏和纤维撕裂破坏；在相对较高的温度下，涂胶层出现粘接失效。随着温度的升高，纺纱纱的质量损失增大，并可以用拟合模型预测不同温度条件下与晶粒平行的ES和GS的质量损失率随温度的变化。总的来说，随着温度的升高，抗剪强度在整个梯度上呈下降趋势。通过扫描电镜观察，揭示了各破坏模式的微观结构特征，并从微观角度进一步阐明了温度对纱层抗剪强度的影响。通过对预测软木高温下抗剪强度服从双线性变化的模型进行改进，使该模型更能适应纤维材料的特性。采用双曲切线模型更准确地预测了不同温度条件下纤维剪切性能的变化。本研究建立了细观结构损伤演化与宏观尺度力学退化之间的相关性，为指导不同温度环境下纤维层的工程设计提供了必要的经验数据和预测模型。

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来源期刊

Construction and Building Materials 工程技术-材料科学：综合

CiteScore

13.80

自引率

21.60%

发文量

3632

审稿时长

82 days

期刊介绍： Construction and Building Materials offers an international platform for sharing innovative and original research and development in the realm of construction and building materials, along with their practical applications in new projects and repair practices. The journal publishes a diverse array of pioneering research and application papers, detailing laboratory investigations and, to a limited extent, numerical analyses or reports on full-scale projects. Multi-part papers are discouraged. Additionally, Construction and Building Materials features comprehensive case studies and insightful review articles that contribute to new insights in the field. Our focus is on papers related to construction materials, excluding those on structural engineering, geotechnics, and unbound highway layers. Covered materials and technologies encompass cement, concrete reinforcement, bricks and mortars, additives, corrosion technology, ceramics, timber, steel, polymers, glass fibers, recycled materials, bamboo, rammed earth, non-conventional building materials, bituminous materials, and applications in railway materials.