Evaluating the performance of gamma irradiated okra fiber reinforced polypropylene (PP) composites: comparative study with jute/PP

Rahman, A. N. M. Masudur; Alimuzzaman, Shah; Khan, Ruhul A.; Hossen, Jamal

doi:10.1186/s40691-018-0148-y

Cited by 21 publications

(17 citation statements)

References 47 publications

(37 reference statements)

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“…The improvement in TS is due to modification or rearrangement of the polymeric structure of the composites at lower gamma radiation doses. In detail, gamma radiation is known as strong ionizing radiation, which can penetrate the polymeric structure of composites and create different types of reactive sites such as free radicals, ions and peroxides [ 33 , 34 , 35 ]. Therefore, these reactive species can cross-link each other and create a longer polymeric chain with larger molecules.…”

Section: Resultsmentioning

confidence: 99%

“…Gamma radiation is a powerful radiation which can reorganize the polymer structure and create a more crystallized structure of the material. Gamma radiation has been successfully applied in several studies to increase the mechanical properties of NFPCs [ 32 , 33 , 34 , 35 ]. In the current study, five different doses of gamma radiation, e.g., 100–500 krd were applied to the composites.…”

Section: Introductionmentioning

confidence: 99%

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Development and Characterization of Bio-Composites from the Plant Wastes of Water Hyacinth and Sugarcane Bagasse: Effect of Water Repellent and Gamma Radiation

2023

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Plant waste is a huge source of natural fibers and has great potential in the field of reinforced polymer composites to replace the environmentally harmful synthetic composites. In this study, fibers were extracted from water hyacinth (WH) petiole and sugarcane bagasse (SB) to make nonwovens by wet-laid web formation, and reinforced on the polyester (P) and epoxy (E) resins to make four types of composites namely, water hyacinth nonwoven reinforced epoxy (WH + E), water hyacinth nonwoven reinforced polyester (WH + P), sugarcane bagasse nonwoven reinforced epoxy (SB + E) and sugarcane bagasse nonwoven reinforced polyester (SB + P) composites. Water repellent (WR) on the nonwovens and gamma radiation (GR) on the composites were applied to improve the hydrophobicity and mechanical properties, such as tensile strength (TS), elongation at break and tensile modulus (TM) of the composites. The morphological structure of the fiber surfaces and tensile fractures were analyzed by SEM. FTIR spectra showed changes in functional groups before and after treatment. XRD analysis exhibited an increase in crystallinity for gamma-irradiated composites and a decrease in crystallinity for WR-treated composites compared to untreated composites. The SB composites (SB + E, SB + P) and polyester composites (WH + P, SB + P) showed higher water absorbency and lower mechanical properties than the WH composites (WH + E, WH + P) and epoxy composites (WH + E, SB + E), respectively. Hydrophobicity improved significantly by approximately 57% (average) at a concentration of 10% WR. However, TS and TM were reduced by approximately 24% at the same concentration. Thus, 5% WR is considered an optimum concentration due to the very low deterioration of TS and TM (<10%) but significant improvement in hydrophobicity (~39%) at this dose. On the other hand, GR treatment significantly improved TS, TM and hydrophobicity by 41, 32 and 25%, respectively, and decreased Eb% by 11% at a dose of 200 krd. However, mechanical properties and hydrophobicity deteriorated with further increase in dose at 300 krd. Thus, 200 krd is considered the optimum dose of GR.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development and Characterization of Bio-Composites from the Plant Wastes of Water Hyacinth and Sugarcane Bagasse: Effect of Water Repellent and Gamma Radiation

2023

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“…Composite materials' properties are determined by the reinforcing fiber properties making them find broad applications in various sectors due to their distinctive blending of mechanical and physical properties. [15][16][17] The composites strengthened with man-made fibers, carbon and glass fibers, for example, are presently dominating natural fiber-reinforced composites because of their moisture and corrosion resistance, stability, and improved strength. [18][19][20][21] However, some of these fibers interrupt the homogeneity of the resin matrix due to poor interaction with the resin, which negatively affects the mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

Effect of glass fiber loading and reprocessing cycles on the mechanical, thermal, and morphological properties of isotactic polypropylene composites

Achukwu

Owen

Danladi

et al. 2023

J of Applied Polymer Sci

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In this study, a preliminary finding is carried out to obtain the optimum E-glass fiber content in polypropylene (PP) plastic products using loadings of 5, 10, 20, 30, and 40 wt%. The formulation with the optimum loading of 10 wt % glass fiber was reprocessed 10 times via extrusion and compression molding techniques to simulate actual recycling and impacts on service life properties such as mechanical, toughness, chemical, thermal, composition, and morphology. In the result, mechanical properties were lost after each reprocessing without effect on the chemical properties and elemental compositions. The thermal studies showed a decrease in degradation temperatures with the onset degradation temperature (T Onset ) for the one-time reprocessed PP recorded at 336.93 C with a maximum rate of weight loss (T Max ) at 427.68 C which further reduced to 259.90 C (T Max of 388.47 C) after 10 extrusion run showing onestep decomposition patterns. This work provides that glass fiber-reinforced plastics should not be reprocessed beyond 3 times except when refreshed with the addition of virgin PP to make up for the lost property. This will be very useful for manufacturers who want to simultaneously save costs (retain profit margin) and maintain the environment.

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“…Due to bearing high cellulose content, high tensile strength, stiffness, and aspect ratio; okra bast fiber has been used to make a composite with a variety of polymers viz. polypropylene [13], epoxy [14], light density polythylene (LDPE) [15], etc. The composites of PVA and okra fiber may also have the prospective to produce materials with excellent mechanical properties and promising performance.…”

Section: Introductionmentioning

confidence: 99%

Biologically degummed and chemically treated okra bast fibers-reinforced Poly(vinyl alcohol) composites

Khan

Yılmaz

2022

Teksti̇l Ve Konfeksi̇yon

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This paper focuses on preparation of poly(vinyl alcohol) (PVA)-based composites reinforced with okra bast fibers at different percentages of 5, 10, 20% via solution casting method. Fibers obtained from different sections of okra plants were biologically degummed and scoured with Na2CO3. Selected fibers were bleached, treated with maleic anhydride or grafted with vinyl acetate. Mechanical, physical and biodegradational properties of the composites were investigated. The tensile strength of the produced composites ranges between 33.8 and 55.1 MPa, elasticity modulus from 1.8 to 2.6 GPa, elongation rate at break varies in 2.8-10%. Chemical treatments led to improved mechanical performance whereas increased fiber content reduces tensile strength, stiffness and elongation, as well as water absorption. Fiber addition significantly affected biodegradation in a complicated way: by decelerating mass loss but accelerating deterioration of mechanical properties.

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Evaluating the performance of gamma irradiated okra fiber reinforced polypropylene (PP) composites: comparative study with jute/PP

Cited by 21 publications

References 47 publications

Development and Characterization of Bio-Composites from the Plant Wastes of Water Hyacinth and Sugarcane Bagasse: Effect of Water Repellent and Gamma Radiation

Development and Characterization of Bio-Composites from the Plant Wastes of Water Hyacinth and Sugarcane Bagasse: Effect of Water Repellent and Gamma Radiation

Effect of glass fiber loading and reprocessing cycles on the mechanical, thermal, and morphological properties of isotactic polypropylene composites

Biologically degummed and chemically treated okra bast fibers-reinforced Poly(vinyl alcohol) composites

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