CRIS

Permanent URI for this communityhttps://cris.ute.edu.ec/handle/123456789/1

Browse

Settings

Subject: search.filters.subject.folding degree

Search Results

Now showing 1 - 2 of 2
  • Loading...
    Thumbnail Image
    Some of the metrics are blocked by your 
    consent settings
    Item type:Publication,
    Static responses for Graphene nanoplatlet reinforced aerobic sport plate
    (2025-06-25)
    Zang Zhaowei
    ;
    Song Zhiqiang
    ;
    Li Aiyun
    ;
    HABIBI, MOSTAFA  
    ;
    Albaijan, Ibrahim
    This work applies a detailed shear deformable based kinematic modeling of a graphene origami reinforced nanocomposite aerobic sport plate subjected to thermal and mechanical loading. The proposed model is application for analysis of the reinforced aerobic sport plate. The analytical bending analysis was performed using the virtual work principle. The behavioral relations were extended using the overall material properties derived from the previously developed relations of the experimental and statistical studies. The nanocomposite aerobic sport was composed of a copper matrix reinforced with graphene origami as a novel reinforcement. The overall material properties were developed with changes of thermal loads, volume fraction and folding parameter of aerobic sport plate. The numerical results were derived using the analytical works in terms of the significant import parameters. An increase in the displacements is observed with an increase in the thermal loads and folding parameter as well as decrease in volume fraction.
  • Loading...
    Thumbnail Image
    Some of the metrics are blocked by your 
    consent settings
    Item type:Publication,
    Stretchable-thickness model for dynamic responses of graphene origami reinforced badminton sport plate
    (Informa UK Limited, 2024-07-08)
    Wenwen Wang
    ;
    Jianhua Zhang
    ;
    Mostafa Habibi
    ;
    Ibrahim Albaijan
    In this article, we organize a stretchable-thickness model to present a frequency analysis for a composite plate applicable in badminton court which is reinforced with origami graphene. A higher order kinematic model is extended in this work including three bending, shear, and stretching functions, where the stretching functions is responsible for satisfying the out of plane shear strains and stresses at top/bottom surfaces of the badminton equipment. The sport or composites plate is manufactured from a copper matrix reinforced with graphene origami where the effective material properties are calculated based on micromechanical models as a function of volume fraction and folding degree of graphene origami, material properties of matrix and reinforcement and temperature. The numerical results are presented with changes of volume fraction, folding degree of reinforcement, and thermal loading along the thickness direction. The main novelty of this work is accounting thickness stretching deformation for the analysis of a graphene origami reinforced plate and investigating the responses of graphene origami as a new reinforcement. A verification investigation is presented for approve of the methodology, and solution procedure. An investigation on the order of deformation is presented for various thickness ratio of the badminton sport plate.