基于伽辽金分解和微分变换方法的纳米生物材料微梁非线性振动和转动分析

IF 2.8 Q2 MECHANICS

Journal of Applied and Computational Mechanics Pub Date : 2021-01-01 DOI:10.32973/jcam.2021.001

O. Adeleye, A. Atitebi, A. Yinusa

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引用次数: 1

摘要

本文利用伽辽金分解(GDM)和微分变换方法(DTM)对纳米生物材料中的微梁进行了非线性振动和旋转分析。在组织再生中，细胞迁移和生长对纳米支架孔隙率和孔径结构的依赖关系由纳米生物材料微梁的非线性振动和旋转动力学模型控制，并由一组非线性偏微分方程表示。应用GDM和DTM对控制模型进行了求解，并采用数值龙格-库塔法(RK4)对控制模型进行了较好的求解。从结果可以看出，Duffing项的增加导致微光束频率的增加。基础周期的增加也导致系统在自由和强制动力响应下的频率相应增加。本研究将促进组织工程技术在人体损伤组织再生中的应用。

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Nonlinear vibrational and rotational analysis of microbeams in nanobiomaterials using Galerkin decomposition and differential transform methods

In this paper, a nonlinear vibrational and rotational analysis of microbeams in nanobiomaterials using Galerkin Decomposition (GDM) and Differential Transform Methods (DTM) is presented. The dependency of cell migration and growth on nanoscaffold porosity and pore size architecture in tissue regeneration is governed by a dynamic model for the nonlinear vibration and rotation of the microbeams of nanobiomaterials and represented by a set of nonlinear partial differential equations. The solutions of the governing model are obtained by applying GDM and DTM and good agreement is achieved with numerical Runge-Kutta method (RK4). From the results, it is observed that an increase in Duffing term resulted in the increase of the frequency of the micro-beam. An increase in the foundation term also resulted in a corresponding increase in the frequency of the system for both free and forced dynamic responses. This study will enhance the application of tissue engineering in the regeneration of damaged human body tissues.

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来源期刊

Journal of Applied and Computational Mechanics MECHANICS-

CiteScore

6.90

自引率

3.20%

发文量

审稿时长

8 weeks

期刊介绍： The Journal of Applied and Computational Mechanics aims to provide a medium for dissemination of innovative and consequential papers on mathematical and computational methods in theoretical as well as applied mechanics. Manuscripts submitted to the journal undergo a blind peer reviewing procedure conducted by the editorial board. The Journal of Applied and Computational Mechanics devoted to the all fields of solid and fluid mechanics. The journal also welcomes papers that are related to the recent technological advances such as biomechanics, electro-mechanics, advanced materials and micor/nano-mechanics. The scope of the journal includes, but is not limited to, the following topic areas: -Theoretical and experimental mechanics- Dynamic systems & control- Nonlinear dynamics and chaos- Boundary layer theory- Turbulence and hydrodynamic stability- Multiphase flows- Heat and mass transfer- Micro/Nano-mechanics- Structural optimization- Smart materials and applications- Composite materials- Hydro- and aerodynamics- Fluid-structure interaction- Gas dynamics