Optimization of PTFE/Cu/Al<sub>2</sub>O<sub>3</sub> filled PMMA based composites on tribological properties using Taguchi design method

Gu, Dapeng; Zhang, Longxiao; Chen, Suwen; Song, Kefeng; Liu, Shouyao

doi:10.1002/app.46705

Cited by 12 publications

(5 citation statements)

References 34 publications

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“…Being tightly pressed into the polymer matrix, in the absence of interfacial adhesion, the filler particles enabled increasing this material property by several times. Meanwhile, features of increasing wear resistance due to the load redistribution from the polymer to the harder inclusions were discussed by many authors [44,45]. Loading with the fibers improved mechanical properties but was rarely discussed as a way to increase wear resistance.…”

Section: Remarks and Discussionmentioning

confidence: 99%

Increasing Wear Resistance of UHMWPE by Loading Enforcing Carbon Fibers: Effect of Irreversible and Elastic Deformation, Friction Heating, and Filler Size

et al. 2020

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The aim of the study was to develop a design methodology for the UltraHigh Molecular Weight Polyethylene (UHMWPE)-based composites used in friction units. To achieve this, stress–strain analysis was done using computer simulation of the triboloading processes. In addition, the effects of carbon fiber size used as reinforcing fillers on formation of the subsurface layer structures at the tribological contacts as well as composite wear resistance were evaluated. A structural analysis of the friction surfaces and the subsurface layers of UHMWPE as well as the UHMWPE-based composites loaded with the carbon fibers of various (nano-, micro-, millimeter) sizes in a wide range of tribological loading conditions was performed. It was shown that, under the “moderate” tribological loading conditions (60 N, 0.3 m/s), the carbon nanofibers (with a loading degree up to 0.5 wt.%) were the most efficient filler. The latter acted as a solid lubricant. As a result, wear resistance increased by 2.7 times. Under the “heavy” test conditions (140 N, 0.5 m/s), the chopped carbon fibers with a length of 2 mm and the optimal loading degree of 10 wt.% were more efficient. The mechanism is underlined by perceiving the action of compressive and shear loads from the counterpart and protecting the tribological contact surface from intense wear. In doing so, wear resistance had doubled, and other mechanical properties had also improved. It was found that simultaneous loading of UHMWPE with Carbon Nano Fibers (CNF) as a solid lubricant and Long Carbon Fibers (LCF) as reinforcing carbon fibers, provided the prescribed mechanical and tribological properties in the entire investigated range of the “load–sliding speed” conditions of tribological loading.

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Section: Remarks and Discussionmentioning

confidence: 99%

Increasing Wear Resistance of UHMWPE by Loading Enforcing Carbon Fibers: Effect of Irreversible and Elastic Deformation, Friction Heating, and Filler Size

et al. 2020

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“…At present, the research on the low-density inert composite liner is focused on the mutual compensation of the mechanical properties between metal and non-metal, so as to maximize the use of the advantages of the two materials. Adding different fillers to the PTFE matrix can effectively improve the mechanical properties of the material and make it exhibit better physical properties than a single material [1][2][3]. At present, most of the research on metal/non-metal liners is about PTFE-based or PTFE/Al-based active energetic materials.…”

Section: Introductionmentioning

confidence: 99%

Study on the Effect of PTFE/Cu Composite Material Preparation Process on Penetration Performance

Yi,

Hao,

Tang

et al. 2023

Polymers

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The jet formed by the traditional metal liner has a slender shape. The diameter of the jet head is consistent with that of the tail, and the ductility is good. When it is used to penetrate the target, it has a good damage effect. The low-density jet formed by the PTFE/Cu liner, according to the different preparation processes and densities, has different degrees of radial expansion. This phenomenon may lead to the expansion of the jet head during the penetration process, resulting in a damage effect, which is different from the previous jet on the target. In this paper, the numerical simulation of PTFE/Cu liners with different preparation processes penetrating steel targets is carried out, and the effects of different preparation processes and liner density on the penetration characteristics of jets penetrating steel targets are compared and analyzed. The PTFE/Cu shaped charge liner was processed according to different preparation processes, and the jet penetration steel target experiment was carried out, so as to verify and analyze the numerical simulation results.

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“…Nowadays, several prediction approaches are also used to predict and validate the experimental outcomes. [39,40,41,42] Jebran et al [43] have optimized the wear and friction behaviors of glass, bronze, and graphite-filled PTFE composite. The experiment was conducted by varying the sliding conditions and working environment, and so forth.…”

Section: Introductionmentioning

confidence: 99%

Experimentation and optimization of wear behavior on polytetrafluoroethylene composites using response surface methodology and bald eagle search optimization

Gajjal¹,

Lathkar²

2022

Polymer Composites

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In Industries, polytetrafluoroethylene (PTFE) is used as a solid lubricant due to its excellent toughness, lack of reactivity, high-thermal stability, and so forth. However, the abrasive resistive behavior is minimal for the virgin PTFE polymer. In this study, the wear and coefficient of friction (COF) of PTFE composite prepared by the combination of 10% halloysite, 10% graphite, and 10% bronze are investigated. The investigations are performed on a pin-on-disc test rig and analysis is done by response surface methodology (RSM), especially in Box-Behnken Design (BBD). The experimentation is performed by varying the sliding distance (Ds), sliding velocity (Vs), and applied load (L). In the analysis of COF, the load is considered as a significant parameter, and sliding distance is an influencing parameter for wear rate. From the experimentation, the proposed PTFE composite promotes COF of 0.0052 and a wear rate of 0.62 Â 10 À5 mm 3 /Nm. Such observed wear rate and COF are 2.8 times and 1.5 times better than the pure PTFE. The experimented outcomes are validated using hybrid DBN-based bald eagle search optimization (DBN-BESO), and RSM. From the validated results, the proposed hybrid DBN-BESO prediction process using the Matlab platform promotes closer values to the experimented outcomes. Besides, the parametric optimization is conducted using RSM and BESO approaches with the objective of minimum wear rate and COF. The optimized BESO results are superior to the RSM. BESO-based optimized wear rate is 0.0317 Â 10 À5 mm 3 /Nm and COF is 0.0352.

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Optimization of PTFE/Cu/Al₂O₃ filled PMMA based composites on tribological properties using Taguchi design method

Cited by 12 publications

References 34 publications

Increasing Wear Resistance of UHMWPE by Loading Enforcing Carbon Fibers: Effect of Irreversible and Elastic Deformation, Friction Heating, and Filler Size

Increasing Wear Resistance of UHMWPE by Loading Enforcing Carbon Fibers: Effect of Irreversible and Elastic Deformation, Friction Heating, and Filler Size

Study on the Effect of PTFE/Cu Composite Material Preparation Process on Penetration Performance

Experimentation and optimization of wear behavior on polytetrafluoroethylene composites using response surface methodology and bald eagle search optimization

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Optimization of PTFE/Cu/Al2O3 filled PMMA based composites on tribological properties using Taguchi design method

Cited by 12 publications

References 34 publications

Increasing Wear Resistance of UHMWPE by Loading Enforcing Carbon Fibers: Effect of Irreversible and Elastic Deformation, Friction Heating, and Filler Size

Increasing Wear Resistance of UHMWPE by Loading Enforcing Carbon Fibers: Effect of Irreversible and Elastic Deformation, Friction Heating, and Filler Size

Study on the Effect of PTFE/Cu Composite Material Preparation Process on Penetration Performance

Experimentation and optimization of wear behavior on polytetrafluoroethylene composites using response surface methodology and bald eagle search optimization

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Product

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Optimization of PTFE/Cu/Al₂O₃ filled PMMA based composites on tribological properties using Taguchi design method