Preparation, structure, and properties of the coir fiber/polypropylene composites

Zaman, Haydar U.; Beg, Mohammad Dalour Hossen

doi:10.1177/0021998313508996

Cited by 58 publications

(25 citation statements)

References 37 publications

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“…The result of jute and coir fibers reinforced PLA biocomposites impact strength displayed in Figure 4. The jute and coir fibers reinforced PLA biocomposites revealed considerable improvements from the impact strength compared to pure PLA, which gradually increase with fiber loading according to previous investigations [39,40]. Alkali and silane treatment washes out impurities by activating the surface and leaves the roughness with several pits onto the fiber surface, which leads better interfacial adhesion within the reinforced matrix and fibers consequence improved impact strength of biocomposites [16,41].…”

Section: Impact Strengthsupporting

confidence: 56%

Preparation and evaluation mechanical, chemical and thermal properties of hybrid jute and coir fibers reinforced bio-composites using poly-lactic acid and poly-caprolactone blends

Hossen

Feng

Yin

et al. 2020

Mater. Res. Express

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Green composites using thermoplastics and thermosets got immense popularity long back when it newly introduced to the industry due to diminishing reliance on oil-based or gasoline materials, which causes numerous environmental problems. In this paper, bio-composites mechanical, chemical, thermal, and degradation properties of hybrid jute and coir fibers reinforced polylactic acid (PLA) investigated. Throughout the fabrication procedure of biocomposites, jute, and coir fibers characterized into three different categories raw, alkali-peroxide, and alkali-silane combined chemical treatments followed a design containing in a total of ten optimized samples. Jute and coir fibers were mixed with a solution of polycaprolactone (PCL) for better fiber-matrix adhesion prior to fabrication. The mechanical properties of alkali-silane treated reinforced fibers biocomposites improved compared to untreated fibers, which exhibited for fiber contents 40% an increase of respectively 32.8% by tensile strength 25.95% by tensile modulus, 24.58% by flexural strength, 23.64% by flexural modulus, and 26.08% by impact strength. Besides, moisture absorption, thickness swelling, thermal stability (TG), and surface chemistry analysis (FTIR) properties investigated, according to fiber-matrix contents ratio, hot-pressing time, temperature, and pressure to identify the effect of biocomposites due to chemical treatments. Moreover, the fiber surface effect of chemical treatments and interfacial adhesion morphologies observed using SEM. Eventually, alkali-silane combined optimized samples demonstrated the most desirable result in every aspect. In addition, a 90 days burial degradation performed to see the degradation flow of the biocomposites.

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Section: Impact Strengthsupporting

confidence: 56%

Preparation and evaluation mechanical, chemical and thermal properties of hybrid jute and coir fibers reinforced bio-composites using poly-lactic acid and poly-caprolactone blends

Hossen

Feng

Yin

et al. 2020

Mater. Res. Express

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“…Mechanical interlocking of the exposed crystalline cellulose in the NaOH-treated coir fibre to the epoxy resin led to better fibre-matrix interfacial adhesion in the NaOHtreated coir fibre composites. Moreover, the removal of the hydroxyl groups in the NaOH-treated coir fibres reduces its hydrophilic nature and provides better compatibility of fibre to the matrix (Akhtar et al 2016;Brígida et al 2010;Kabir et al 2012;Li et al 2007;Punyamurthy et al 2017;Zaman & Beg 2014). In order to confirm the removal of the amorphous non-cellulose constituents from the coir fibres, FTIR spectroscopy was used to investigate the structural changes in the coir fibres surface before and after alkaline treatment.…”

Section: Water Absorption Testmentioning

confidence: 99%

“…Natural fibres such as coir, palm, flax, hemp, kenaf, and jute has gain extensive research interest (Akhtar et al 2016;Amiri et al 2015;Oushabi et al 2017;Sair et al 2018;Zhang et al 2017). Among different types of natural fibres, coir fibre is widely used as it is abundantly available, cheap, and possesses good mechanical and thermal properties (Brígida et al 2010;Haque et al 2012;Zaman & Beg 2014). Thermoset and thermoplastic polymers are the most common matrices use in natural fibre composites as they are lightweight and can be processed at low temperature.…”

Section: Introductionmentioning

confidence: 99%

Effect of Alkaline Treatment on Structural Characterisation, Thermal Degradation and Water Absorption Ability of Coir Fibre Polymer Composites

Yew¹,

Muhamad²,

Mohamed³

et al. 2019

JSM

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The alkaline treatment with 5 wt. % sodium hydroxide (NaOH) solution at room temperature for 24 and 48 h was performed on coir fibre. The structural characterisation, thermal degradation and water absorption ability of the untreated and NaOH-treated coir fibre polymer composites have been studied. Scanning electron microscope (SEM) images showed that coir fibres treated with NaOH have rough surface texture and the roughness of the fibre surface becomes significant as the duration of the NaOH treatment increased. Fourier transform infrared (FTIR) spectra confirmed that NaOH treatment removed hemicelluloses as evidenced by the absence of absorption bands at 1724.36 cm-1 and changes the absorption intensity at bands 1244.09 cm-1 and 1249.87 cm-1 due to the loss of lignin. NaOH-treated coir fibre composites demonstrated better thermal stability at low temperature degradation. At high temperature, the thermal stability was reduced due to the decreased of residual lignin content. The water absorption of the NaOH-treated coir fibre composites was lower than untreated coir composite contributed by better interfacial adhesion between the NaOH-treated coir fibre to epoxy resin.

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“…Among the natural fibers, it is pertinent to note that coir is essentially utilized in view of its low cost, durability among other advantages [8]. Coir has been accounted for as having the highest extension at break among common natural fibers, which allows it absorb strain more than other fibers [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Dynamic Mechanical Behaviour of Coir and Coconut Husk Particulate Reinforced Polymer Composites: The Effect of Exposure to Acidic Environment

Obada¹,

Kuburi²,

Dodoo‐Arhin³

et al. 2019

Fillers - Synthesis, Characterization and Industrial Application

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This chapter describes an experimental investigation into the dynamic mechanical properties of coir and coconut husk particulate reinforced polymer composites which were prepared by the hot press method. The composite was immersed in a strongly acidic environment of pH 2.2 for a period of 14 and 28 days (14P and 28P). Values of storage modulus at different vibrational frequencies recorded for the polymers at low temperatures where the molecules are still tightly compressed and the region of first solid state transitions are:

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Preparation, structure, and properties of the coir fiber/polypropylene composites

Cited by 58 publications

References 37 publications

Preparation and evaluation mechanical, chemical and thermal properties of hybrid jute and coir fibers reinforced bio-composites using poly-lactic acid and poly-caprolactone blends

Preparation and evaluation mechanical, chemical and thermal properties of hybrid jute and coir fibers reinforced bio-composites using poly-lactic acid and poly-caprolactone blends

Effect of Alkaline Treatment on Structural Characterisation, Thermal Degradation and Water Absorption Ability of Coir Fibre Polymer Composites

Dynamic Mechanical Behaviour of Coir and Coconut Husk Particulate Reinforced Polymer Composites: The Effect of Exposure to Acidic Environment

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