An experimental effort on the impact of hot press forming process parameters on tensile, flexural &amp; impact properties of bamboo fiber composites with the help of Taguchi experimental design

Banik, Nabanita

doi:10.1016/j.matpr.2018.06.391

Cited by 10 publications

(4 citation statements)

References 9 publications

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“…It is important for selecting the control factors. Based on the literature review on the factors influencing the mechanical properties of nonwoven fiber and polymer [11,15,16], the selected process parameters at three levels were studied using an L27 orthogonal array (Table 3). A full factorial experimental design will require at least 27 × 5 = 135 combinations of runs, However, using Taguchi's factorial experiment approach reduces it to only 27 runs, significantly reducing the experimental cost and time.…”

Section: Hydraulic Hot-pressing Process: Experimental Designmentioning

confidence: 99%

Optimization of the Effect of Hydraulic Hot-Pressing-Process Parameters on Tensile Properties of Kapok Fiber Nonwoven Web Based on Taguchi Experimental Design

Muhammad Abdul Mun'aim Mohd Idrus,

Aniq Danish Azli,

Md Redzuan Zoolfakar

et al. 2024

ARFMTS

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This paper investigates the effect of temperature on the physical properties of Kapok fiber web formed via the hot-pressing method. The kapok web was prepared using the Ashford drum carder. Test samples were subjected to heat treatment in a hydraulic hot-press under three different temperatures (160, 170, and 180°C), heating durations (5, 7.5, and 10 min), and pressures (500, 750, and 1000 psi). This study was conducted to clarify the tensile properties of kapok fabrics under optimal hot-press-forming process parameters such as temperature, heating time, and pressure; here, the Taguchi L27 orthogonal array experimental design was adopted for the optimization. The surface morphologies and tensile properties of kapok fabrics were investigated. The optimum combination of process factors was obtained through signal-to-noise (S/N) ratio analysis. Furthermore, analysis of variance was employed to determine the importance of the process parameter levels. Moreover, regression analysis was adopted to mathematically model the metamorphism of tensile properties with process parameters. A set of confirmation tests was also conducted, and the results verified the presented models. This study results showed that all three processing factors had significant influences on the tensile strength of the carded nonwoven kapok. The combination of hot-pressing parameters to obtain the optimum tensile strength was obtained as follows: 170°C temperature, 1000 psi pressure, and 10 min heating time.

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Section: Hydraulic Hot-pressing Process: Experimental Designmentioning

confidence: 99%

Optimization of the Effect of Hydraulic Hot-Pressing-Process Parameters on Tensile Properties of Kapok Fiber Nonwoven Web Based on Taguchi Experimental Design

Muhammad Abdul Mun'aim Mohd Idrus,

Aniq Danish Azli,

Md Redzuan Zoolfakar

et al. 2024

ARFMTS

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“…The superior qualities such as renewability, light weight, good mechanical strength, comparable specific strengths, cost effectiveness, acoustics, CO 2 absorption and thermal insulation properties are projecting biodegradable composites at its peak; replacing synthetic ones [9]. While the problems of synthetic composites, such as environmental problems, excess strength in specific applications or over strength, require expensive costs, these problems are solved by green composites or natural composites [9,10].…”

Section: Introductionmentioning

confidence: 99%

Thermal and Chemical Performance Evaluation of Thevetia peruviana Oil-Based Composites Reinforced with Short Sisal Fibers

Owa,

Adesina,

Bodede

et al. 2023

UJEES

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Thermal properties and chemical performance of newly developed Thevetia peruviana oil-based (TPO) bio-composites with short sisal fibers reinforcement were studied in this research, with the aim of producing materials derived from renewable resources for engineering applications. Three sets of TPO composites (5C, 10C and 15C) reinforced with sisal fibers 5, 10 and 15 wt% respectively were produced by compression moulding method. Thermographic analyser (TGA) was used to determine the thermal behavior of the new composites and the results showed that the composites thermal stability behavior increase with fiber loading. 5% degradation temperature (T5) and 10% degradation temperature (T10) of the new composites increased from 300 to 312 0C and from 338 to 419 0C, respectively. The char value of 8.264 of the unreinforced resin reduced on the addition of 5 wt% of fiber while there were enhancements in the char values of composites reinforced with 10 wt% and 15 wt% fiber. The chemical resistance and water absorption tests showed that the percentage gain/loss of the composites in all the reagents are negligible, with composite 5C showing superior resistance in all the media. The results showed that the newly produced bio-composites is a potential material for storage vessels production.

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“…Different combinations of fibers are offered good flexural strength and shore hardness compared to the previous research results. Novelty implemented is reflected in the results such as pair of natural fibers that enhanced the composite strength [10].…”

Section: Introductionmentioning

confidence: 99%

A Novel Study of Synthesis and Experimental Investigation on Hybrid Biocomposites for Biomedical Orthopedic Application

Rao¹,

Sabitha

Murugan

et al. 2021

International Journal of Polymer Science

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In recent years the biocomposites are highly utilized in the biomedical applications, due to excellent strength as well as weight ratio. A lot of natural fibers, namely, flax, hemp, jute, kenaf, and sisal are cheaply available in colossal amount. Aim of this study, a novel approach, is executed for construction of biomedical orthopedic parts by using mixture of natural fibers. This work handled biocomposites such as flax fiber (FX), chicken feather fiber (CF), kenaf fiber (KF), and rice husk fiber (RH) effectively. From all these composites, four sets of mixed fibers with reinforcement of polylactic acid polymer used for creating orthopedic parts. The hand-lay-based methodology is undertaken for preparation of hybrid biocomposites. Parameters involved for this study are fiber types (KF + RH, RH + FX, FX + CF, and CF + KF), laminate count (2, 4, 6 and 8) infill density (30%, 60%, 90%, and 120%), and raster angle (0/60, 30/120, 50/140, and 70/160). Finding of this work is dimensional accuracy, flexural strength, and shore hardness that are analyzed by L16 orthogonal array. ANOVA statistical analysis is enhanced and enlightens the results of flexural strength and source hardness of the biocomposites. Amongst in four parameters, the fiber type parameter extremely contributes such as 40.50% in the flexural analysis. Similarly, laminate count parameter highly contributes such as 31.01% in the shore hardness analysis.

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An experimental effort on the impact of hot press forming process parameters on tensile, flexural & impact properties of bamboo fiber composites with the help of Taguchi experimental design

Cited by 10 publications

References 9 publications

Optimization of the Effect of Hydraulic Hot-Pressing-Process Parameters on Tensile Properties of Kapok Fiber Nonwoven Web Based on Taguchi Experimental Design

Optimization of the Effect of Hydraulic Hot-Pressing-Process Parameters on Tensile Properties of Kapok Fiber Nonwoven Web Based on Taguchi Experimental Design

Thermal and Chemical Performance Evaluation of Thevetia peruviana Oil-Based Composites Reinforced with Short Sisal Fibers

A Novel Study of Synthesis and Experimental Investigation on Hybrid Biocomposites for Biomedical Orthopedic Application

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