Mechanical, fracture, and environmental performance of greener polymer composites containing low to high micro fillers with recycled and byproduct origins

Khedri, Ehsan; Karimi, Hamid Reza; Mohamadi, Razie; Aliha, M.R.M.; Masoudi Nejad, Reza

doi:10.1002/pc.28369

Polymer Composites

2024

DOI: 10.1002/pc.28369

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Mechanical, fracture, and environmental performance of greener polymer composites containing low to high micro fillers with recycled and byproduct origins

Ehsan Khedri,

Hamid Reza Karimi,

Razie Mohamadi

et al.

Abstract: Polymer adhesives have considerable mechanical and environmental privileges; however, their high price makes them uncommercial for common uses. This study investigates the incorporation of recycled or byproduct fillers in epoxy resin‐based composites to assess their mechanical properties, environmental impacts, and cost efficiency. The fillers examined include fly ash, glass powder, slag, silica powder, and limestone powder. Tensile, compressive, and fracture tests were conducted on composites with various fil… Show more

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Cited by 11 publications

References 86 publications

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Experimental and statistical damage analysis in milling of S2‐glass fiber/epoxy and basalt fiber/epoxy composites

Sayin,

Danisman,

Ersoy

et al. 2024

Polymer Composites

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S2‐glass fiber reinforced plastics (S2‐GFRP) and basalt fiber reinforced plastics (BFRP) have emerged as crucial materials due to their exceptional mechanical properties, and milling of composite materials plays an important role in achieving desired properties. However, they have proven challenges due to relative inhomogeneity compared with metals, resulting unpredictability in quality of milling operations. The objective of this work is to investigate the effect of cutting parameters, tool geometry and tool surface materials on the surface quality of composites using burrs as a metric. S2‐GFRP and BFRP composites were produced by the vacuum infusion method. Helical and straight flute end mills were manufactured from high‐speed steel (HSS) and carbide rounds, and half of them were coated with titanium nitride using reactive magnetron sputtering technique. Taguchi L18 orthogonal array is used to determine the effect of tool material, tool angle, coating, cutting direction, spindle speed, and feed rate on the machining quality of S2‐GFRPs and BFRPs with respect to burr formations. Milling experiments were conducted under dry conditions and then the burrs were imaged to calculate the total area and length. Statistical analysis was also performed to optimize the machining parameters and tool type for ensuring the structural integrity and performance of the final composite parts. The results showed that the selection of tool material has the most significant impact on the burr area and length of the machined surface. The novel image analysis allows to analyze the extent of the burr size with a desirable operation speed for industrial applications.Highlights Aerospace grade S2‐Glass (S2‐GFRP) and basalt fiber reinforced plastics (BFRP) were manufactured. Carbide and HSS end mills were fabricated and coated with titanium nitride protective layer. FRPs were machined at various process parameters designed by Taguchi method. Distinctive image processing was firstly used to compute milling induced Burr area and length. Statistical analysis was performed to quantify the contribution of parameters and optimize milling.

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Experimental and statistical damage analysis in milling of S2‐glass fiber/epoxy and basalt fiber/epoxy composites

Sayin,

Danisman,

Ersoy

et al. 2024

Polymer Composites

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Effect of recycling and bio‐filler addition on the mechanical, thermal, and morphological behavior of the injection molded flax/PLA green composite

Debnath,

Chakraborty,

Surya Rao

2024

Polymer Composites

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This study explores the mechanical, thermal, and morphological behavior of polylactic acid (PLA) composites reinforced with flax fiber (FF) during recycling. The influence of the addition of bio‐filler (w/w) on the recycling of FF/PLA composites was also analyzed. The recycling influencing the performance of FF/PLA composite was compared with that of halloysite nanotube (HNT)/FF‐PLA composites. The FF/PLA and HNT/FF‐PLA composited were fabricated by injection molding subjected to multiple recycling. The tensile and flexural properties of both composites were assessed after each recycling. Fractured specimens of the recycled samples were analyzed using a scanning electron microscope to study their morphology. Thermal degradation was evaluated through thermogravimetric analysis of the recycled FF/PLA and HNT/FF‐PLA samples. After the fifth recycling process, the HNT/FF‐PLA composite experienced a decrease in tensile strength by 75.01% and flexural strength by 59.88%. The performance of FF/PLA and HNT/FF‐PLA composites was detrimentally affected due to the thermal deterioration of flax fiber and the subsequent decrease in fiber length resulting from repeated reprocessing. The highest degradation for non‐recycled FF/PLA and HNT/FF‐PLA samples occurred at temperatures of 354°C and 347°C, respectively. Whereas the maximum degradation for recycled cellulose (RC)‐5 (fifth recycled) FF/PLA and HNT/FF‐PLA composite occurred at 328 and 327°C.Highlights Adding 1% HNT increased the tensile and flexural strength by 12.5% and 1.79%. The behavior of the composites was affected by the thermal degradation of FF. The maximum degradation of RC‐5 FF/PLA composite occurred at 327°C. The maximum degradation for RC‐5 HNT/FF‐PLA composite was noticed at 328°C.

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Rehabilitation and reinforcement of cracked pavements using crack sealers and composite patches

Aliha,

Karimi,

Khedri

et al. 2024

Heliyon

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Mechanical, fracture, and environmental performance of greener polymer composites containing low to high micro fillers with recycled and byproduct origins

Cited by 11 publications

References 86 publications

Experimental and statistical damage analysis in milling of S2‐glass fiber/epoxy and basalt fiber/epoxy composites

Experimental and statistical damage analysis in milling of S2‐glass fiber/epoxy and basalt fiber/epoxy composites

Effect of recycling and bio‐filler addition on the mechanical, thermal, and morphological behavior of the injection molded flax/PLA green composite

Rehabilitation and reinforcement of cracked pavements using crack sealers and composite patches

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