通过频率变化评估薄膜重装单片玻璃元件的断裂后刚度和剩余容量

4区工程技术 Q1 Mathematics

Mathematical Problems in Engineering Pub Date : 2024-03-01 DOI:10.1155/2024/8922303

Chiara Bedon, Marco Fasan

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引用次数: 0

摘要

建筑玻璃安全膜的主要目的是改造现有的整体元件，并在断裂后阶段防止碎片掉落。贴膜的附加值在于，只要碎片保持粘合，裂开的贴膜玻璃元件就能确保最低限度的残余机械和承重能力，这与碎片的交错和脱落密切相关。为了防止出现关键问题，这种机械特性分析既重要又不确定，需要采用特定的方法。为此，我们对断裂的薄膜粘接玻璃样品进行了动态调查，以评估其断裂后的刚度趋势及其对反复振动的敏感性。所采用的实验室布局是为了评估随机振动（重复 220 次）对悬臂装置中总共 12 个破裂试样的影响（随机施加的加速度峰值范围为 0.5-5 m/s2）。通过监测裂纹振动频率，量化了裂纹玻璃样品的薄膜效率和相应的残余弯曲刚度与损坏严重程度的函数关系，重点是碎片互锁。在有限元（FE）数值模型和分析计算的支持下，对定量实验估计值进行了比较分析和验证。结果表明--至少在小范围内--在反复随机振动的情况下，断裂后的刚度会逐渐降低，这隐含地影响了玻璃构件的剩余承载能力。最重要的是，在测试的结构中，裂纹振动频率受裂纹几何形状的影响极小，并且随着施加的随机冲击次数的增加而呈线性下降（每个样本平均下降 ≈20），从而证实了通过碎片互锁提供一定机械承载能力的改造潜力和效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Post-Fracture Stiffness and Residual Capacity Assessment of Film-Retrofitted Monolithic Glass Elements by Frequency Change

The primary goal of safety films for glass in buildings is to retrofit existing monolithic elements and prevent, in the post-fracture stage, any fall-out of shards. Their added value is that—as far as the fragments are kept bonded—a cracked film-glass element can ensure a minimum residual mechanical and load-bearing capacity, which is strictly related to the shards interlocking and debond. To prevent critical issues, such a mechanical characterization is both important and uncertain, and requires specific methodologies. In this regard, a dynamic investigation is carried out on fractured film-bonded glass samples, to assess their post-fracture stiffness trends and its sensitivity to repeated vibrations. The adopted laboratory layout is chosen to assess the effects of random vibrations (220 repetitions) on a total of 12 cracked specimens in a cantilever setup (with 0.5–5 m/s² the range of randomly imposed acceleration peaks). By monitoring the cracked vibration frequency, the film efficiency and corresponding residual bending stiffness of cracked glass samples are quantified as a function of damage severity, with a focus on fragments interlock. Quantitative experimental estimates are comparatively analyzed and validated with the support of finite element (FE) numerical models and analytical calculations. As shown—at least at the small-scale level—a progressive post-fracture stiffness reduction takes place under repeated random vibrations, and this implicitly affects the residual load-bearing capacity of glass members. Most importantly, for the tested configurations, it is shown that the cracked vibration frequency is minimally affected by crack geometry, and follows a rather linear decrease with the number of imposed random impacts (up to an average of ≈20 for each sample), thus confirming the retrofit potential and efficiency in providing some mechanical capacity through fragments interlock.

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来源期刊

Mathematical Problems in Engineering 工程技术-工程：综合

CiteScore

4.00

自引率

0.00%

发文量

2853

审稿时长

4.2 months

期刊介绍： Mathematical Problems in Engineering is a broad-based journal which publishes articles of interest in all engineering disciplines. Mathematical Problems in Engineering publishes results of rigorous engineering research carried out using mathematical tools. Contributions containing formulations or results related to applications are also encouraged. The primary aim of Mathematical Problems in Engineering is rapid publication and dissemination of important mathematical work which has relevance to engineering. All areas of engineering are within the scope of the journal. In particular, aerospace engineering, bioengineering, chemical engineering, computer engineering, electrical engineering, industrial engineering and manufacturing systems, and mechanical engineering are of interest. Mathematical work of interest includes, but is not limited to, ordinary and partial differential equations, stochastic processes, calculus of variations, and nonlinear analysis.