Tribological and mechanical performances of newly developed eco-epoxy composites incorporating flax fibres and graphene nanoplatelets

Awwad, KY Eayal; Yousif, B. F.; Mostafa, Ahmad; Alajarmeh, Omar; Zeng, Xuesen

doi:10.1177/07316844221143451

Cited by 6 publications

(7 citation statements)

References 49 publications

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“…The stress values increased significantly after 30 N, evidenced by the increase in the wear coefficient value, as reported in Table 3. Therefore, it was considered that the mild-to-severe wear transition took place when the applied load exceeded 30 N. Similar findings was observed by the authors in a previous studies [23,24]. However, it can be noticed that the average mechanical stresses (Von-mises and shear stresses) increased by only around 25% at 60 N as compared to that in the mild region, i.e., 30 N (100% increase in the applied load) (see Fig.…”

Section: Geometrical Effectsupporting

confidence: 83%

“…These materials were provided by ATL Composites Pty., Ltd., Australia. Epoxy resin was selected due to its widely usage as a base matrix for polymer composites under wear conditions [22][23][24]. It is also used in composite forms as a load-bearing material, such as composite brakes in automobiles [25].…”

Section: Materials Characteristicsmentioning

confidence: 99%

“…The pressure values were determined based on the calculated contact area by using FEM. The sliding speed was fixed at 2 m/s for all tests while the applied load ranged from 15 to 60 N. These values were selected to cover both mild and severe wear regions, where PV fluctuates between 0.33 and 3.9 MPa•m•s -1 [23,24]. The tests were carried out at room temperature ~20 °C.…”

Section: Materials Characteristicsmentioning

confidence: 99%

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Finite element analysis and experimental validation of polymer–metal contacts in block-on-ring configuration

Awwad,

Fallahnezhad,

Yousif

et al. 2023

Friction

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The wear profile analysis, obtained by different tribometers, is essential to characterise the wear mechanisms. However, most of the available methods did not take the stress distribution over the wear profile in consideration, which causes inaccurate analysis. In this study, the wear profile of polymer–metal contact, obtained by block-on-ring configuration under dry sliding conditions, was analysed using finite element modelling (FEM) and experimental investigation. Archard’s wear equation was integrated into a developed FORTRAN–UMESHMOTION code linked with Abaqus software. A varying wear coefficient (k) values covering both running-in and steady state regions, and a range of applied loads involving both mild and severe wear regions were measured and implemented in the FEM. The FEM was in good agreement with the experiments. The model reproduced the stress distribution profiles under variable testing conditions, while their values were affected by the sliding direction and maximum wear depth (hmax). The largest area of the wear profile, exposed to the average contact stresses, is defined as the normal zone. Whereas the critical zones were characterized by high stress concentrations reaching up to 10 times of that at the normal zone. The wear profile was mapped to identify the critical zone where the stress concentration is the key point in this definition. The surface features were examined in different regions using scanning electron microscope (SEM). Ultimately, SEM analysis showed severer damage features in the critical zone than that in the normal zone as proven by FEM. However, the literature data presented and considered the wear features the same at any point of the wear profile. In this study, the normal zone was determined at a stress value of about 0.5 MPa, whereas the critical zone was at about 5.5 MPa. The wear behaviour of these two zones showed totally different features from one another.

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Section: Geometrical Effectsupporting

confidence: 83%

Section: Materials Characteristicsmentioning

confidence: 99%

Section: Materials Characteristicsmentioning

confidence: 99%

See 1 more Smart Citation

Finite element analysis and experimental validation of polymer–metal contacts in block-on-ring configuration

Awwad,

Fallahnezhad,

Yousif

et al. 2023

Friction

Self Cite

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“…However, in wear processes, the thermal energy generated at the interface, where rubbing occurs, has a substantial influence on the wear characteristics of the polymers. The generated frictional heat expedites the wear rate when the interface temperature (IFT) exceeds the specific polymer's temperatures, such as heat distortion temperature (HDT) and glass transition temperature (Tg) [9][10][11]. Due to this factor, the performance of most solid lubricants is restricted to polymer-specific temperatures.…”

Section: Introductionmentioning

confidence: 99%

Effects of Adding Graphite to Epoxy Resin on its Mechanical Properties and Mild-to-Severe Wear Performance at its Heat Distortion Temperature

Eayal Awwad

2024

Tribol. Ind.

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In this study, epoxy/graphite composites were fabricated based on different weight fractions (0, 3, 6, and 9 wt.%) of graphite powder for bearing applications. The mechanical and tribological properties were assessed. Adhesive wear tests covered the severe regions, where the interface temperature (IFT) exceeded the heat distortion temperature (HDT) of the epoxy. Graphite additions improved elastic modulus and hardness but decreased fracture strain and toughness of the composites. The tribological behaviors in the mild wear region were improved as the graphite content increased. In the mild wear region, the increase in graphite additions showed a good improvement by reducing the specific wear rate (SWR) and coefficient of friction (COF). In the severe wear region, the neat epoxy and higher graphite concentrations exhibited a dramatic increase in SWR, whereas the lowest addition of 3 wt.% exhibited good wear performance. For epoxy, the reason was that IFT exceeded its HDT, while the aggregation of graphite particles was the main reason in the case of higher graphite concentrations. SEM examinations showed severe wear signs—high ploughing and fracture—when IFT exceeded the HDT. However, by reducing the IFT, graphite additions did not show such severe wear features due to the accelerated heat dissipation.

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“…Several advantages, such as excellent thermal and mechanical properties, easy processability, and low production costs, make epoxy resin thermosets suitable for a wide range of applications. Following their huge commercial production, for applications in, for example, the automotive and aerospace industries, in 2019 the global epoxy market reached 26 billion dollars with an expected increase at a compound annual growth rate of 6.2% from 2020 to 2028 [34][35][36][37]. A computational and experimental analysis is carried out to compare curauá fibers, jute and sisal fibers used in epoxy resin matrix composites for use in industry, determining the most appropriate hybridization effect by establishing the proportions and amounts of each fiber in a hybrid composite with better mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

Numerical and Experimental Analyses of Hybrid Composites Made from Amazonian Natural Fibers

Pino

Bezazi

Boumediri

et al. 2023

J. Res. Updates Polym. Sci.

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The application of lignocellulosic fibers as reinforcements in composite materials has found increasing use in recent years, due to the attractive characteristics of natural fibers such as their low cost, high specific modulus, biodegradability, abundance and with many technical qualities. Natural fiber hybrid composites are very frequently used in automotive aerospace and other industries. In this work, numerical and experimental analysis is carried out to compare curauá, jute and sisal fibers in epoxy composites for use in industry. The most appropriate hybridization effect by establishing the amounts of each fiber on the mechanical properties was considered. Finite Element Models were designed and validated through mechanical tests. The number of Finite Element models and specimens performed was determined through the design of experiments using the Taguchi Method and then the results were statistically validated. Higher strength was obtained in composites made with curauá fiber, followed by jute and sisal fibers. Such behavior was achieved by FEM and experimental tests, revealing an increase in tensile strength by increasing the amount of fibers up to 35% in total. Higher strength was achieved when the composite was made with curauá (20 wt.%), jute (10 wt.%) and sisal (5 wt.%) fibers. The results show a good agreement between the FEM and the experimental tests. Furthermore, the results of the present study were compared with those obtained previously mentioned in the open literature.

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Tribological and mechanical performances of newly developed eco-epoxy composites incorporating flax fibres and graphene nanoplatelets

Cited by 6 publications

References 49 publications

Finite element analysis and experimental validation of polymer–metal contacts in block-on-ring configuration

Finite element analysis and experimental validation of polymer–metal contacts in block-on-ring configuration

Effects of Adding Graphite to Epoxy Resin on its Mechanical Properties and Mild-to-Severe Wear Performance at its Heat Distortion Temperature

Numerical and Experimental Analyses of Hybrid Composites Made from Amazonian Natural Fibers

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