{"title":"带有辅助磁芯和磁弹性面层的智能夹层纳米板的温度相关热屈曲和自由振动行为","authors":"Kerim Gokhan Aktas, Fatih Pehlivan, Ismail Esen","doi":"10.1007/s11043-024-09698-0","DOIUrl":null,"url":null,"abstract":"<p>This article addresses the thermomechanical thermal buckling and free vibration response of a novel smart sandwich nanoplate based on a sinusoidal higher-order shear deformation theory (SHSDT) with a stretching effect. In the proposed sandwich nanoplate, an auxetic core layer with a negative Poisson’s ratio made of Ti-6Al-4V is sandwiched between Ti-6Al-4V rim layers and magneto-electro-elastic (MEE) face layers. The MEE face layers are homogenous volumetric mixtures of cobalt ferrite (CoFe<sub>2</sub>O<sub>4</sub>) and barium titanate (BaTiO<sub>3</sub>). The mechanical and thermal material properties of the auxetic core and MEE face layers are temperature-dependent. Using Hamilton’s principle, governing equations are constructed. To characterize the size-dependent behavior of the nanoplate, governing equations are adapted with the nonlocal strain gradient theory (NSGT). By applying the principles of Navier’s technique, closed-form solutions are obtained. Parametric simulations are carried out to examine the effects of auxetic core parameters, temperature-dependent material properties, nonlocal parameters, electric, magnetic, and thermal loads on the free vibration and thermal buckling behavior of the nanoplate. According to the simulation results, it is determined that the auxetic core parameters, temperature-dependent material properties, and nonlocal factors significantly affect the thermomechanical behavior of the nanoplate. The outcomes of this investigation are expected to contribute to the advancement of smart nano-electromechanical systems, transducers, and nanosensors characterized by lightweight, exceptional structural integrity and temperature sensitivity. Also, the auxetic core with a negative Poisson’s ratio provides a metamaterial feature, and thanks to this feature, the proposed model has the potential to be used as an invisibility technology in sonar and radar-hiding applications.</p>","PeriodicalId":698,"journal":{"name":"Mechanics of Time-Dependent Materials","volume":"7 1","pages":""},"PeriodicalIF":2.1000,"publicationDate":"2024-05-09","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Temperature-dependent thermal buckling and free vibration behavior of smart sandwich nanoplates with auxetic core and magneto-electro-elastic face layers\",\"authors\":\"Kerim Gokhan Aktas, Fatih Pehlivan, Ismail Esen\",\"doi\":\"10.1007/s11043-024-09698-0\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>This article addresses the thermomechanical thermal buckling and free vibration response of a novel smart sandwich nanoplate based on a sinusoidal higher-order shear deformation theory (SHSDT) with a stretching effect. 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引用次数: 0
摘要
本文基于具有拉伸效应的正弦高阶剪切变形理论(SHSDT),探讨了新型智能夹层纳米板的热机械热屈曲和自由振动响应。在拟议的夹层纳米板中,Ti-6Al-4V 边缘层和磁电弹性(MEE)面层之间夹着由 Ti-6Al-4V 制成的具有负泊松比的辅助核心层。MEE 面层是钴铁氧体(CoFe2O4)和钛酸钡(BaTiO3)的均匀体积混合物。辅助磁芯和 MEE 面层的机械和热材料特性与温度有关。利用汉密尔顿原理,构建了控制方程。为了描述纳米板的尺寸相关行为,利用非局部应变梯度理论(NSGT)对控制方程进行了调整。通过应用纳维技术原理,得到了闭式解。通过参数模拟,研究了辅助磁芯参数、随温度变化的材料特性、非局部参数、电载荷、磁载荷和热载荷对纳米板自由振动和热屈曲行为的影响。根据模拟结果,可以确定辅助磁芯参数、随温度变化的材料特性和非局部因素对纳米板的热机械行为有显著影响。这项研究的成果有望推动智能纳米机电系统、传感器和纳米传感器的发展,这些系统、传感器和传感器具有重量轻、结构完整和温度灵敏度高等特点。此外,具有负泊松比的辅助磁芯还提供了超材料特性,得益于这一特性,所提出的模型有望在声纳和雷达隐藏应用中用作隐形技术。
Temperature-dependent thermal buckling and free vibration behavior of smart sandwich nanoplates with auxetic core and magneto-electro-elastic face layers
This article addresses the thermomechanical thermal buckling and free vibration response of a novel smart sandwich nanoplate based on a sinusoidal higher-order shear deformation theory (SHSDT) with a stretching effect. In the proposed sandwich nanoplate, an auxetic core layer with a negative Poisson’s ratio made of Ti-6Al-4V is sandwiched between Ti-6Al-4V rim layers and magneto-electro-elastic (MEE) face layers. The MEE face layers are homogenous volumetric mixtures of cobalt ferrite (CoFe2O4) and barium titanate (BaTiO3). The mechanical and thermal material properties of the auxetic core and MEE face layers are temperature-dependent. Using Hamilton’s principle, governing equations are constructed. To characterize the size-dependent behavior of the nanoplate, governing equations are adapted with the nonlocal strain gradient theory (NSGT). By applying the principles of Navier’s technique, closed-form solutions are obtained. Parametric simulations are carried out to examine the effects of auxetic core parameters, temperature-dependent material properties, nonlocal parameters, electric, magnetic, and thermal loads on the free vibration and thermal buckling behavior of the nanoplate. According to the simulation results, it is determined that the auxetic core parameters, temperature-dependent material properties, and nonlocal factors significantly affect the thermomechanical behavior of the nanoplate. The outcomes of this investigation are expected to contribute to the advancement of smart nano-electromechanical systems, transducers, and nanosensors characterized by lightweight, exceptional structural integrity and temperature sensitivity. Also, the auxetic core with a negative Poisson’s ratio provides a metamaterial feature, and thanks to this feature, the proposed model has the potential to be used as an invisibility technology in sonar and radar-hiding applications.
期刊介绍:
Mechanics of Time-Dependent Materials accepts contributions dealing with the time-dependent mechanical properties of solid polymers, metals, ceramics, concrete, wood, or their composites. It is recognized that certain materials can be in the melt state as function of temperature and/or pressure. Contributions concerned with fundamental issues relating to processing and melt-to-solid transition behaviour are welcome, as are contributions addressing time-dependent failure and fracture phenomena. Manuscripts addressing environmental issues will be considered if they relate to time-dependent mechanical properties.
The journal promotes the transfer of knowledge between various disciplines that deal with the properties of time-dependent solid materials but approach these from different angles. Among these disciplines are: Mechanical Engineering, Aerospace Engineering, Chemical Engineering, Rheology, Materials Science, Polymer Physics, Design, and others.