Study the Physical Properties of Medium Density Fiberboard Utilized by  Hybrid Mixture of Efb Fiber and Kenaf Fiber

Redwan, Amamer; Badri, Khairiah Haji; Bahrum, Azizah

doi:10.22401/anjs.22.2.04

Cited by 4 publications

(1 citation statement)

References 11 publications

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“…During DFPR, DFVR, and DFER composites manufacturing, the ferrous fillers did not penetrate the dried leaves to prevent water absorption in the sample. This result is comparable to the outcomes collected from Redwan et al 73 that support incrementing the filler concentration and increasing the water absorption capacity of hybrid laminates. The results show that a minimal quantity of water absorption from nickel and cobalt fillers would be correlated to the formulation of water‐resistant fillers, which prevents the water molecules on plastic packaging applications.…”

Section: Resultssupporting

confidence: 89%

Machine learning‐based prediction of mechanical and thermal properties of nickel/cobalt/ferrous and dried leaves fiber‐reinforced polymer hybrid composites

Mohit,

Sanjay,

Siengchin

et al. 2023

Polymer Composites

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Dried leaves are the outstanding origin of cellulosic plant matter, and it is securing reputation as a renewable resource. Dried leaves fiber is suggested to possess the capability to substitute synthetic fibers in polymer laminates as a reinforcing component. The novelty of the present study reveals the effect of dried leaves fiber, cobalt, nickel, and ferrous reinforcement on the physical, mechanical, and thermal characteristics of epoxy, vinyl‐ester, and polyester polymers using artificial neural network (ANN) technique. These composites were fabricated using ultrasonication bath‐assisted wet layup method under ambient condition. The outcomes of this research exhibit that the dried leaves‐cobalt fillers reinforced in all three polymers possess higher mechanical and thermal stability characteristics when compared with other samples. The reason may be assigned to producing novel hydroxyl functional groups and strong interfacial bonding of fillers within the matrix as observed from Fourier‐transform infrared (FTIR) spectra and scanning electron microscope (SEM) micrographs, respectively. Moreover, as observed from the thermogravimetric analysis, the dried leaves‐ferrous filler‐reinforced polymer hybrid composites provided higher thermal stability. Statistical analysis was performed using the one‐way ANOVA technique and found that outcomes were significant statistically under the confidence level of 95%. Hence, this investigation not only emphasize the significance of investigating new polymer composites but also highlight the benefits of engaging advanced modeling to forecast the material characteristics precisely.Highlights Dried leaves and cobalt/nickel/ferrous are applied reinforcement to polymers. Composites fabricated using ultrasonication bath‐assisted wet layup technique. LM Algorithm‐based ANN selected for predicting the best composite. Higher mechanical and thermal stability with dried leaves‐cobalt filler. One‐way ANOVA proved statistically significant within the material properties.

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Section: Resultssupporting

confidence: 89%

Machine learning‐based prediction of mechanical and thermal properties of nickel/cobalt/ferrous and dried leaves fiber‐reinforced polymer hybrid composites

Mohit,

Sanjay,

Siengchin

et al. 2023

Polymer Composites

View full text Add to dashboard Cite

show abstract

Developing polylactic acid (PLA)-based medium-density fiberboard: investigating three key manufacturing factors and their impact on physical and mechanical properties

Bencsik,

Denes,

Kollar

et al. 2024

Eur. J. Wood Prod.

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Mechanical and thermal behavior of hybrid composite medium density fiberboard reinforced with phenol formaldehyde

Pugazhenthi

Anand

2021

Heliyon

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The world was in demand of wood products mainly for interior design, furniture making and household utilizes and at the same time agricultural residue usage was increased for making Engineering woods. Coconut is an abundant crop in Asia and coir fiber was extracted from coconut husk, as by-products. MDF was one of the by-products produced from coir reinforced with resin. In this work, the coconut coir was used to produce hybrid MDF with basalt fiber and phenol-formaldehyde resin hybridization. The panel was prepared with different coir and basalt fiber combinations by keeping a fixed resin percentage. The coir and basalt fiber percentage ranges from 40 to 75 % and 5–40 % respectively. SEM studied the morphological characteristic of the panel whereas thermal stability of the panel was evaluated through Thermo-gravimetric Analysis. The fire resistance was observed through a flammability test. The physical properties and mechanical properties were evaluated by ASTM Standards. From the investigations, the MoR and MoE have a higher value for Panel 3 with 29.14 N/mm 2 and 3143 N/mm 2 respectively and the internal bonding strength shows of 2.1 N/mm 2 maximum values of mechanical properties. The result shows for panel 3 has 15 % and 18 % more strength for MoE and MoR respectively and IB also shows 35 % of increased value.

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Study the Physical Properties of Medium Density Fiberboard Utilized by Hybrid Mixture of Efb Fiber and Kenaf Fiber

Cited by 4 publications

References 11 publications

Machine learning‐based prediction of mechanical and thermal properties of nickel/cobalt/ferrous and dried leaves fiber‐reinforced polymer hybrid composites

Machine learning‐based prediction of mechanical and thermal properties of nickel/cobalt/ferrous and dried leaves fiber‐reinforced polymer hybrid composites

Developing polylactic acid (PLA)-based medium-density fiberboard: investigating three key manufacturing factors and their impact on physical and mechanical properties

Mechanical and thermal behavior of hybrid composite medium density fiberboard reinforced with phenol formaldehyde

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