Nano Kirişlerin Değiştirilmiş Sonlu Elemanlar Taşima Matrisi Yöntemi ile Stabilite Analizi
Year 2021,
Volume: 8 Issue: 2, 931 - 941, 31.05.2021
Kanat Burak Bozdoğan
,
Farshid Khosravı Malekı
Abstract
Bu çalşmada değiştirilmiş Sonlu elemanlar–taşıma matrisi yöntemi nano kirişlerin stabilite analizi için uyarlanmıştır. Çalımada önce nano kirişin stabilite denklemi yerel olmayan Euler kiriş teorisi yardımıyla oluşturulmuştur. Diferansiyel denklemin çözümü ile önce elemanın sonlu elamanlar matrisi yazılmış daha sonra yapılan dönüşümle Ricatti taşıma matrisi elde edilmiştir. Çalışmanın sonunda sunulan yöntemin uygunluğunu literatürden alınan bir örnek üzerinde gösterilmiştir. Sunulan yöntemde matris boyutları klasik sonlu elemanlar yöntemine göre kayda değer bir şekilde azalmakta ve dolayısıyla çözüm süreside kısalmaktadır. Sunulan yöntem özellikle çok açıklıklı ve değişken kesitli nano kirişlerin çözümünde kullanılabilir.
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Stability Analysis of Nanobeams by Modified Finıie Element Transfer Matrix Method
Year 2021,
Volume: 8 Issue: 2, 931 - 941, 31.05.2021
Kanat Burak Bozdoğan
,
Farshid Khosravı Malekı
Abstract
In this study, the modified finite element-transfer matrix method has been adapted for the stability analysis of nanobeams. In the study, the stability equation of the nanobeam was first established with the help of the nonlocal Euler beam theory. With the solution of the differential equation, first, the finite element matrix of the element was written and then the Ricatti transfer matrix was obtained by the transformation. The suitability of the presented method is shown on an example taken from the literature. In the presented method, matrix dimensions are significantly reduced compared to the classical finite element method and therefore the solution time is shortened. The presented method can be used especially for the solution of multi-span and variable cross-section nanobeams.
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- [3]. Kumar, D., Heinrich, Ch., Waas, A.M., Buckling analysis of carbon nanotubes modeled using nonlocal continuum theories. Journal of Applied Physics, 2008, 103, 073521.
- [4]. Zhang, Y.Y., Wang, C.M., Challamel, N., Bending, buckling and vibration of micro/nanobeams by hybrid nonlocal beam model, Journal of Engineering Mechanics, 2010, 136(5), 562–574 .
- [5]. Mohammadi, H., Mahzoon, M., Mohammadi, M., Mohammadi, M., Postbuckling instability of nonlinear nanobeam with geometric imperfection embedded in elastic foundation, Nonlinear Dynamics, 2014, 76, 2005–2016.
- [6]. Wang, C.M., Zhang, H., Challamel, N., Duan, W.H.: On boundary conditions for buckling and vibration of nonlocal beams. European Journal of Mechanics-A/Solids, 2017, 61, 73–81.
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- [11]. Ebrahimi, F., Shaghaghi, G.R., Salari, E., Vibration analysis of sizedependent nano beams based on nonlocal timoshenko beam theory, Journal of Mechanical Engineering and Technology, 2014, 6(2).
- [12]. Ebrahimi, F., Nasirzadeh, P., A nonlocal Timoshenko beam theory for vibration analysis of thick nanobeams using differential transform method, Journal of Theoretical and Applied Mechanics, 2015, 53(4):1041–1052.
- [13]. Uzun, B., Numanoglu, H. M., Civalek, O., Free vibration analysis of BNNT with different cross-Sections via nonlocal FEM, Journal of Computational Applied Mechanics, 2018, 49(2):252–260
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- [18]. Murmu, T., Pradhan, S. C., Vibration analysis of nanoplates under uniaxial prestressed conditions via nonlocal elasticity. Journal of Applied Physics, 2009, 106(10):104301
- [19]. Farajpour, A., Danesh, M., Mohammadi, M., Buckling analysis of variable thickness nanoplates using nonlocal continuum mechanics, Physica E: Low-dimensional Systems and Nanostructures, 2011, 44(3): 719–727
- [20]. Karličić, D., Cajić, M., Adhikari, S., Dynamic stability of a nonlinear multiple-nanobeam system, Nonlinear Dynamics, 2018, 93(3), 1495-1517.
- [21]. Behdad, S., Fakher, M., Hosseini-Hashemi, S., Dynamic stability and vibration of two-phase local/nonlocal VFGP nanobeams incorporating surface effects and different boundary conditions, Mechanics of Materials, 2021, 153, 103633.
- [22]. Sourani, P., Hashemian, M., Pirmoradian, M., Toghraie, D., A comparison of the Bolotin and incremental harmonic balance methods in the dynamic stability analysis of an Euler–Bernoulli nanobeam based on the nonlocal strain gradient theory and surface effects, Mechanics of Materials, 2020, 145, 103403.
- [23]. Hamed, M. A., Mohamed, N. A., Eltaher, M. A., Stability buckling and bending of nanobeams including cutouts, Engineering with Computers, 2020, 1-22.
- [24]. Arda, M., Aydogdu, M., Dynamic stability of harmonically excited nanobeams including axial inertia, Journal of Vibration and Control, 2019, 25(4), 820-833.
- [25]. Eltaher, M. A., Khater, M. E., Park, S., Abdel-Rahman, E., Yavuz, M., On the static stability of nonlocal nanobeams using higher-order beam theories, Advances in nano research, 2016, 4(1), 51.
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- [27]. Dokainish, M. A., A new approach for plate vibrations: combination of transfer matrix and finite-element technique, 1972, 526-530.
- [28]. Rong, B., Rui, X., Wang, G., Modified finite element transfer matrix method for eigenvalue problem of flexible structures, Journal of applied mechanics, 2011, 78(2).
- [29]. Rong, B., Rui, X., Tao, L., Perturbation finite element transfer matrix method for random eigenvalue problems of uncertain structures, Journal of applied mechanics, 2012, 79(2).
- [30]. Ozturk, D., Bozdogan, K. A. N. A. T., Nuhoglu, A., Modified finite element-transfer matrix method for the static analysis of structures, Structural Engineering and Mechanics, 2012, 43(6), 761-769.
- [31]. Bozdoğan, K. B., Maleki, F. K., An Application of the Modified Finite Element Transfer Matrix Method for a Heat Transfer Problem. Kırklareli Üniversitesi Mühendislik ve Fen Bilimleri Dergisi, 2019, 5(1), 15-28.
- [32]. Wang, C.M., Zhang, Y.Y., Rames,S.S, ,Kitipornchai,S.,: Buckling analysis of micro- and nano-rods/tubes based on nonlocal Timoshenko beam theory, Jornal of Phyisics D: Applied Physics,2006,39,3904-3909