利用改进的一阶剪切理论和等时几何方法,研究位于粘弹性地基上的双曲面生物启发复合材料壳体在爆炸荷载作用下的瞬态响应

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引用次数: 0

摘要

对科学家来说,研究自然启发的应用是一个长期吸引人的课题。目前,源自自然的结构生长速度加快,这可能与其优越的机械性能和环境适应能力有关。采用螺旋形方案和设计的生物复合结构具有吸收冲击能量和抵御破坏的卓越能力。然而,关于螺旋形结构基体内部纤维重新定向和重新取向对其机械性能和反应性的影响,目前还缺乏广泛的研究。本研究旨在利用同构法探索生物启发螺旋形层压复合材料(B-iHLC)壳体在爆炸载荷影响下的静态和瞬态响应。外壳的结构完整性由一个称为帕斯捷尔纳克基础的粘弹性基础来维持,该基础包括两个刚度系数和一个阻尼系数。利用汉密尔顿原理和修正的一阶剪切理论,可获得控制壳体动力学的平衡方程,因此无需采用剪切修正系数。通过与权威出版物进行数值比较,本文的模型和方法得到了验证。本研究的结果可用于军事和民用基础设施的建设,当结构受到可能导致灾难性坍塌的严重应力时。本文的研究成果还可作为其他几个问题的基础,包括几何优化和类似机械结构的动态响应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Transient response of doubly-curved bio-inspired composite shells resting on viscoelastic foundation subject to blast load using improved first-order shear theory and isogeometric approach

Investigating natural-inspired applications is a perennially appealing subject for scientists. The current increase in the speed of natural-origin structure growth may be linked to their superior mechanical properties and environmental resilience. Biological composite structures with helicoidal schemes and designs have remarkable capacities to absorb impact energy and withstand damage. However, there is a dearth of extensive study on the influence of fiber redirection and reorientation inside the matrix of a helicoid structure on its mechanical performance and reactivity. The present study aimed to explore the static and transient responses of a bio-inspired helicoid laminated composite (B-iHLC) shell under the influence of an explosive load using an isomorphic method. The structural integrity of the shell is maintained by a viscoelastic basis known as the Pasternak foundation, which encompasses two coefficients of stiffness and one coefficient of damping. The equilibrium equations governing shell dynamics are obtained by using Hamilton's principle and including the modified first-order shear theory, therefore obviating the need to employ a shear correction factor. The paper's model and approach are validated by doing numerical comparisons with respected publications. The findings of this study may be used in the construction of military and civilian infrastructure in situations when the structure is subjected to severe stresses that might potentially result in catastrophic collapse. The findings of this paper serve as the foundation for several other issues, including geometric optimization and the dynamic response of similar mechanical structures.

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来源期刊
Defence Technology(防务技术)
Defence Technology(防务技术) Mechanical Engineering, Control and Systems Engineering, Industrial and Manufacturing Engineering
CiteScore
8.70
自引率
0.00%
发文量
728
审稿时长
25 days
期刊介绍: Defence Technology, a peer reviewed journal, is published monthly and aims to become the best international academic exchange platform for the research related to defence technology. It publishes original research papers having direct bearing on defence, with a balanced coverage on analytical, experimental, numerical simulation and applied investigations. It covers various disciplines of science, technology and engineering.
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