An isogeometric approach for nonlocal bending and free oscillation of magneto-electro-elastic functionally graded nanobeam with elastic constraints

IF 2.9 3区 工程技术 Q2 ENGINEERING, CIVIL
Thu Huong Nguyen Thi, Van Ke Tran, Quoc Hoa Pham
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引用次数: 0

Abstract

This work uses isogeometric analysis (IGA), which is based on nonlocal hypothesis and higher-order shear beam hypothesis, to investigate the static bending and free oscillation of a magneto-electro-elastic functionally graded (MEE-FG) nanobeam subject to elastic boundary constraints (BCs). The magneto-electric boundary condition and the Maxwell equation are used to calculate the variation of electric and magnetic potentials along the thickness direction of the nanobeam. This study is innovative since it does not use the conventional boundary conditions. Rather, an elastic system of straight and torsion springs with controllable stiffness is used to support nanobeams’ beginning and end positions, creating customizable BCs. The governing equations of motion of nanobeams are established by applying Hamilton’s principle and IGA is used to determine deflections and natural frequency values. Verification studies were performed to evaluate the convergence and accuracy of the proposed method. Aside from this, the impact of the input parameters on the static bending and free oscillation of the MEE-FG nanobeam is examined in detail. These findings could be valuable for analyzing and designing innovative structures constructed of functionally graded MEE materials.

带弹性约束的磁电弹性功能分级纳米梁的非局部弯曲和自由振荡等几何方法
本研究利用基于非局部假说和高阶剪切梁假说的等几何分析(IGA),研究了磁电弹性功能分级(MEE-FG)纳米梁在弹性边界约束(BC)下的静态弯曲和自由振荡。磁电边界条件和麦克斯韦方程用于计算纳米梁沿厚度方向的电动势和磁势变化。这项研究具有创新性,因为它没有使用传统的边界条件。相反,它使用了刚度可控的直弹簧和扭转弹簧弹性系统来支撑纳米梁的开始和结束位置,从而创建了可定制的 BC。应用汉密尔顿原理建立了纳米梁的运动控制方程,并使用 IGA 确定挠度和固有频率值。为了评估所提出方法的收敛性和准确性,还进行了验证研究。此外,还详细研究了输入参数对 MEE-FG 纳米梁静态弯曲和自由振荡的影响。这些发现对于分析和设计由功能分级 MEE 材料构建的创新结构非常有价值。
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来源期刊
CiteScore
5.20
自引率
3.30%
发文量
734
期刊介绍: Frontiers of Structural and Civil Engineering is an international journal that publishes original research papers, review articles and case studies related to civil and structural engineering. Topics include but are not limited to the latest developments in building and bridge structures, geotechnical engineering, hydraulic engineering, coastal engineering, and transport engineering. Case studies that demonstrate the successful applications of cutting-edge research technologies are welcome. The journal also promotes and publishes interdisciplinary research and applications connecting civil engineering and other disciplines, such as bio-, info-, nano- and social sciences and technology. Manuscripts submitted for publication will be subject to a stringent peer review.
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