Bio-Polyamide 11 Hybrid Composites Reinforced with Basalt/Flax Interwoven Fibers: A Tough Green Composite for Semi-Structural Applications

Russo, Pietro; Simeoli, Giorgio; Vitiello, Libera; Filippone, Giovanni

doi:10.3390/fib7050041

Cited by 29 publications

(22 citation statements)

References 20 publications

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“…It is worth noting that flax fibre is a very stiff material which has further contributed to this significant flexural properties' improvement. The attainment of such property enhancement with carbon fibre hybridisation provides a significant potential of natural fibre hybrid composites to be used for structural light weight applications [14]. The average flexural properties of three different types of composites are presented in Table 2, and load vs. deformation traces of these composites are shown in Figure 2.…”

Section: Flexural Propertiesmentioning

confidence: 99%

Effects of Hybridisation on the Low Velocity Falling Weight Impact and Flexural Properties of Flax-Carbon/Epoxy Hybrid Composites

Chapman

Dhakal

2019

Fibers

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The trend of research and adoption of natural plant-based fibre reinforced composites is increasing, with traditional synthetic fibres such as carbon and glass experiencing restrictions placed on their manufacture and use by legislative bodies due to their environmental impact through the entire product life cycle. Finding suitable alternatives to lightweight and high-performance synthetic composites will be of benefit to the automotive, marine and aerospace industries. This paper investigates the low-velocity impact (LVI) and flexural properties and damage characteristics of flax-carbon/epoxy hybrid composites to be used in structural lightweight applications. LVI, for example, is analogous to several real-life situations, such as damage during manufacture, feasibly due to human error such as the dropping of tools and mishandling of the finished product, debris strikes of aircraft flight, or even the collision of a vessel with another. Carbon fibre has been hybridised with flax fibres to achieve enhanced impact and flexural performance. The failure mechanisms of woven flax and flax-carbon epoxy hybrid composites have been further analysed using Scanning Electron Microscopy (SEM). It was observed from the experimental results that carbon fibre hybridisation has a significant effect on the impact and flexural properties and their damage modes. The results obtained from this study exhibited that the flexural strength and modulus of plain flax/epoxy composite increase significantly from 95.66 MPa to 425.87 MPa and 4.78 GPa to 17.90 GPa, respectively, with carbon fibre hybridisation. This significant improvement in flexural properties would provide designers with important information to make informed decisions during material selection for lightweight structural applications.

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Section: Flexural Propertiesmentioning

confidence: 99%

Effects of Hybridisation on the Low Velocity Falling Weight Impact and Flexural Properties of Flax-Carbon/Epoxy Hybrid Composites

Chapman

Dhakal

2019

Fibers

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“…Therefore the composite materials can be designed to meet the specific requirements. [10,11] The durability of the basalt mat used as external layers flax reinforced epoxy composites were tested with long-term aging tests which revealed that hybridization of basalt with flax enhances the durability of natural fibers composites. [12] The flax fibers are cheaper and are having low density with better mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

A new study on flax‐basalt‐carbon fiber reinforced epoxy/bioepoxy hybrid composites

et al. 2021

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The present research investigation focuses on the development of flax-basaltcarbon fiber reinforced epoxy/bioepoxy hybrid composites under different stacking sequence technique. The composites were fabricated using manual hand lay-up method and compression molding technique. The specimens were prepared using standard ASTM methods and subjected to various mechanical experimentations such as tensile, flexural, interlaminar shear strength, and impact tests. Water absorption study under distilled water condition, contact angle measurement, thermogravimetric analysis, and surface morphology study using scanning electron microscopy analysis was also performed. From the results obtained, the composites manufactured in the present work can be prospectively utilized in various engineering medium load structural applications.

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“…Owing to their unique characteristics, namely eco-friendliness, light weight, low cost, and high relative strength, these biomass composites have gradually been applied to engineering materials in various industrial applications, such as structural materials and tribomaterials for mechanical sliding parts, such as bearing, cum, gear, and seal, in recent years [ 12 , 13 , 14 , 15 , 16 ]. In particular, to further enhance the eco-friendliness of these biomass polymer composites, fully bio-based polymers such as polylactic acid (PLA) [ 17 , 18 , 19 , 20 , 21 , 22 ] and plant-derived polyamide (PA1010, PA11) [ 12 , 23 , 24 , 25 ] should ideally be used as the matrix polymer. However, these biomass composites have such drawbacks as poor interfacial adhesion between natural fiber and matrix biopolymer [ 3 , 12 , 14 , 26 ] and may, therefore, show poor mechanical and tribological properties.…”

Section: Introductionmentioning

confidence: 99%

Influence of Epoxy Resin Treatment on the Mechanical and Tribological Properties of Hemp-Fiber-Reinforced Plant-Derived Polyamide 1010 Biomass Composites

2021

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In this study, we investigated the influence of epoxy resin treatment on the mechanical and tribological properties of hemp fiber (HF)-reinforced plant-derived polyamide 1010 (PA1010) biomass composites. HFs were surface-treated using four types of surface treatment methods: (a) alkaline treatment using sodium chlorite (NaClO2) solution, (b) surface treatment using epoxy resin (EP) solution after NaClO2 alkaline treatment, (c) surface treatment using an ureidosilane coupling agent after NaClO2 alkaline treatment (NaClO2 + A-1160), and (d) surface treatment using epoxy resin solution after the (c) surface treatment (NaClO2 + A-1160 + EP). The HF/PA1010 biomass composites were extruded using a twin-screw extruder and injection-molded. Their mechanical properties, such as tensile, bending, and dynamic mechanical properties, and tribological properties were evaluated by the ring-on-plate-type sliding wear test. The strength, modulus, specific wear rate, and limiting pv value of HF/PA1010 biomass composites improved with surface treatment using epoxy resin (NaClO2 + A-1160 + EP). In particular, the bending modulus of NaClO2 + A-1160 + EP improved by 48% more than that of NaClO2, and the specific wear rate of NaClO2 + A-1160 + EP was one-third that of NaClO2. This may be attributed to the change in the internal microstructure of the composites, such as the interfacial interaction between HF and PA1010 and fiber dispersion. As a result, the mode of friction and wear mechanism of these biomass composites also changed.

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Bio-Polyamide 11 Hybrid Composites Reinforced with Basalt/Flax Interwoven Fibers: A Tough Green Composite for Semi-Structural Applications

Cited by 29 publications

References 20 publications

Effects of Hybridisation on the Low Velocity Falling Weight Impact and Flexural Properties of Flax-Carbon/Epoxy Hybrid Composites

Effects of Hybridisation on the Low Velocity Falling Weight Impact and Flexural Properties of Flax-Carbon/Epoxy Hybrid Composites

A new study on flax‐basalt‐carbon fiber reinforced epoxy/bioepoxy hybrid composites

Influence of Epoxy Resin Treatment on the Mechanical and Tribological Properties of Hemp-Fiber-Reinforced Plant-Derived Polyamide 1010 Biomass Composites

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