An efficient RVE formulation for the analysis of the elastic properties of spherical nanoparticle reinforced polymers

被引:39
|
作者
Pontefisso, Alessandro [1 ]
Zappalorto, Michele [1 ]
Quaresimin, Marino [1 ]
机构
[1] Univ Padua, Dept Management & Engn, I-36100 Vicenza, Italy
来源
COMPUTATIONAL MATERIALS SCIENCE | 2015年 / 96卷
关键词
RVE; Nanocomposites; Nanoparticles; Interphase; Filler distribution; Morphology; FRACTURE-TOUGHNESS; CLAY NANOCOMPOSITES; MECHANICAL-PROPERTIES; THERMAL-CONDUCTIVITY; MOLECULAR-DYNAMICS; MULTISCALE; INTERPHASE; MODEL; COMPOSITES; INTERFACE;
D O I
10.1016/j.commatsci.2014.09.030
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Based on the use of Ripley function, a new algorithm for the generation of three-dimensional Representative Volume Elements (RVEs), easy to be meshed and imported in a FE code, is developed. The presence of an interphase zone, surrounding the nanofiller, of different mechanical properties with respect to the polymer matrix is accounted for. The basic features and potentialities of the tool are discussed by referring to a Complete Spatial Random Distribution. Moreover the effects of the material morphology on the overall interphase amount and on the elastic properties of polymer/particle nanocomposites are analysed. Eventually, a computational analysis is carried out to study the effects of the interphase thickness and properties on the elastic properties of nanocomposites. (C) 2014 Elsevier B.V. All rights reserved.
引用
收藏
页码:319 / 326
页数:8
相关论文
共 50 条
  • [11] Elastic properties of oriented polymers, blends and reinforced composites using the microindentation technique
    Krumova, M
    Flores, A
    Calleja, FJB
    Fakirov, S
    COLLOID AND POLYMER SCIENCE, 2002, 280 (07) : 591 - 598
  • [12] Elastic properties of oriented polymers, blends and reinforced composites using the microindentation technique
    M. Krumova
    A. Flores
    F. Baltá Calleja
    S. Fakirov
    Colloid and Polymer Science, 2002, 280 : 591 - 598
  • [13] Surrogate modeling of the effective elastic properties of spherical particle-reinforced composite materials
    Carlos Garcia-Merino, Jose
    Calvo-Jurado, Carmen
    Garcia-Macias, Enrique
    JOURNAL OF MATHEMATICAL CHEMISTRY, 2022, 60 (08) : 1555 - 1570
  • [14] Surrogate modeling of the effective elastic properties of spherical particle-reinforced composite materials
    José Carlos García-Merino
    Carmen Calvo-Jurado
    Enrique García-Macías
    Journal of Mathematical Chemistry, 2022, 60 : 1555 - 1570
  • [15] Effect of interphase zone on the overall elastic properties of nanoparticle-reinforced polymer nanocomposites
    Amraei, Jafar
    Jam, Jafar E.
    Arab, Behrouz
    Firouz-Abadi, Roohollah D.
    JOURNAL OF COMPOSITE MATERIALS, 2019, 53 (09) : 1261 - 1274
  • [16] Nanoparticle-reinforced solder alloys: A comprehensive review of recent formulation properties, and mechanical performance
    Yahaya, Muhamad Zamri
    Azmi, Ezzatul Farhain
    Salleh, Nor Azmira
    Saad, Abdullah Aziz
    Wang, Dawei
    Kheawhom, Soorathep
    Alshoaibi, Adil
    Mohamad, Ahmad Azmin
    JOURNAL OF MATERIALS RESEARCH AND TECHNOLOGY-JMR&T, 2024, 32 : 3682 - 3707
  • [17] A mechanical model for the prediction of the elastic properties of polymeric resins reinforced with liquid crystal polymers
    Blanas, AM
    Kontou, E
    Spathis, G
    JOURNAL OF REINFORCED PLASTICS AND COMPOSITES, 1999, 18 (05) : 390 - 412
  • [18] A machine learning approach to determine the elastic properties of printed fiber-reinforced polymers
    Thomas, Akshay J.
    Barocio, Eduardo
    Pipes, R. Byron
    COMPOSITES SCIENCE AND TECHNOLOGY, 2022, 220
  • [19] Numerical evaluation of effective elastic properties of CNT-reinforced polymers for interphase effects
    Kumar, Puneet
    Srinivas, J.
    COMPUTATIONAL MATERIALS SCIENCE, 2014, 88 : 139 - 144
  • [20] Parametric numerical evaluation of the effective elastic properties of carbon nanotube-reinforced polymers
    Tserpes, K. I.
    Chanteli, A.
    COMPOSITE STRUCTURES, 2013, 99 : 366 - 374
12345