Dynamic analysis of functionally graded carbon nanotube–reinforced shell structures with piezoelectric layers under dynamic loads

Mallek, H.; Jrad, Hanen; Wali, Mondher; Kessentini, Amina; Gamaoun, Fehmi; Dammak, Fakhreddine

doi:10.1177/1077546319892753

Cited by 34 publications

(9 citation statements)

References 49 publications

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“…In recent years, FG concept has become an issue of great interest and has prompted a significant amount of research activities worldwide in several areas and advanced sectors. [15][16][17][18][19][20] Furthermore, disparity of mechanical properties between engineered and inherent biomaterials represents a crucial concern facing dental implantation clinic, which makes osseointegration and bone remodeling critical. Additionally, the use of functionally graded biomaterials in implant prostheses have been proposed as a promising improvement to common implant materials due to their ability to simultaneously satisfy biocompatibility, strength, corrosion resistance.…”

Section: Introductionmentioning

confidence: 99%

“…Generally, properties of the FG material vary continuously throughout the long of the structure with different volumes fractions governed by several laws. In recent years, FG concept has become an issue of great interest and has prompted a significant amount of research activities worldwide in several areas and advanced sectors 15–20 . Furthermore, disparity of mechanical properties between engineered and inherent biomaterials represents a crucial concern facing dental implantation clinic, which makes osseointegration and bone remodeling critical.…”

Section: Introductionmentioning

confidence: 99%

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Mandibular bone remodeling around osseointegrated functionally graded biomaterial implant using three dimensional finite element model

Elleuch

Jrad

Wali

et al. 2023

Numer Methods Biomed Eng

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Dental implantation surgery has been progressed as one of the most efficient prosthetic technologies, however, it still fails very often and one of the main causes is the large difference between implant mechanical properties and those in welcoming bony tissues, making it problematical in osseointegration and bone remodeling. Biomaterial and tissue engineering research shows that there is a requirement in developing implants with Functionally Graded Materials (FGM). Indeed, the great potential of FGM lies not only in the field of bone tissue engineering but also in dentistry. To improve the acceptance of dental implants inside the living bone, FGM were proposed to step up the challenge of ensuring a better match of mechanical properties between biologically and mechanically compatible biomaterials. The aim of the present work is to investigate mandibular bone remodeling induced by FGM dental implant. Three‐dimensional (3D) mandibular bone structure around an osseointegrated dental implant has been created to analyze the biomechanical behavior of the bone–implant system depending on implant material composition. In order to implement the numerical algorithm into ABAQUS software, UMAT subroutines and user‐defined material were employed. Finite element analysis have been conducted to determine the stress distributions in implant and bony system, and to evaluate bone remodeling induced by the use of various FGM and pure titanium dental implants over the period of 48 months.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mandibular bone remodeling around osseointegrated functionally graded biomaterial implant using three dimensional finite element model

Elleuch

Jrad

Wali

et al. 2023

Numer Methods Biomed Eng

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“…Goulas et al [6] employed 3D printing process using fused filament fabrication technique to produce FG composites having variable relative permittivity to be applied in microwave devices. Mallek et al [7] employed the linear double director shell theory for dynamic analysis of FG composite shells with piezoelectric facesheet subjected to dynamic load. Li et al [8] fabricated FG ultra-high performance cementitious beam-type structures using slurry-infiltrated fibrous concrete together with ultra-high performance concrete.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear oscillations of elliptical and sector prefabricated nanoplate-type structures made of functionally graded building material

2021

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The primary goal of this work is to apply for the first time the efficient isogeometric type of numerical solving technique for the geometrically nonlinear large-amplitude oscillations of nanoplates with arbitrary shapes with variable thicknesses incorporating simultaneously strain gradient size and nonlocality dependencies. Microplate thickness variation follows convex, concave, and linear patterns. Accordingly, isogeometric analysis is carried out to obtain precise geometrical description and higher-order efficient smoothness related to thickness variation within an arbitrary shape with no difficulty in meshing. It is assumed that nanoplates are made of functionally graded composite materials with variable material properties at different thicknesses. It is found that changing thickness variation pattern from convex to linear, and finally to concave increases the significance of both nonlocality and strain gradient size effects. Moreover, it is demonstrated that by increasing plate deflection and material gradient index, the contributions of strain gradient and nonlocal stress to the nonlinear frequency of functionally graded composite nanoplates are weakened.

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“…Smart materials [1][2][3][4][5] are widely utilised in the fields of architecture, automobiles, aeronautics and astronautics, biomedical devices, active control [6][7][8] and intelligent sensors. Shape-memory material, a type of smart material that can be potentially used for active vibration control, is particularly suitable for functioning in sensors and actuators.…”

Section: Introductionmentioning

confidence: 99%

Frequency manipulation of a light-activated shape-memory polymer-laminated cylindrical shell

Zhu

Zhang

2021

Proceedings of the Institution of Mechanical Engineers, Part E:

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A light-activated shape-memory polymer is a novel smart material that exhibits a dynamic Young's modulus when exposed to light. The non-contact actuation feature facilitates the lamination of a light-activated shape-memory polymer on host structures for realising frequency control. In this study, we investigated the natural frequency of a simply supported cylindrical shell coupled with light-activated shape-memory polymer patches located arbitrarily on the shell. Initially, we compared the natural frequency of a completely laminated cylindrical shell using two different approaches. Further, we analysed the effect of changes in the length and location of the light-activated shape-memory polymer patch pair on the natural frequency of the cylindrical shell. Based on the experimental results, we propose an optimal scheme, wherein several light-activated shape-memory polymer patch pairs are distributed on the surface of the shell, and the frequency control capability of the proposed scheme is evaluated comprehensively. The results verify that the optimal scheme has an adequate control effect on the natural frequency of the cylindrical shell.

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Dynamic analysis of functionally graded carbon nanotube–reinforced shell structures with piezoelectric layers under dynamic loads

Cited by 34 publications

References 49 publications

Mandibular bone remodeling around osseointegrated functionally graded biomaterial implant using three dimensional finite element model

Mandibular bone remodeling around osseointegrated functionally graded biomaterial implant using three dimensional finite element model

Nonlinear oscillations of elliptical and sector prefabricated nanoplate-type structures made of functionally graded building material

Frequency manipulation of a light-activated shape-memory polymer-laminated cylindrical shell

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