Processing, Characterization of Furcraea foetida (FF) Fiber and Investigation of Physical/Mechanical Properties of FF/Epoxy Composite

Madival, Abhishek Sadananda; Deepak, Dharmpal; Srinivasulu, M.; Shettar, Manjunath; Shetty, Raviraj

doi:10.3390/polym14071476

Cited by 14 publications

(10 citation statements)

References 100 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…from 55.6 to 129.3 MPa) while the present SFD composite was much less sensitive to changes in material composition. Madival et al 58 developed an epoxy matrix composite reinforced by up to 30% Furcraea foetida (a similar plant to sisal) fibers: tensile strength reached again its maximum value for 30% volume fiber content but it was almost 35% lower than that of its counterpart SFD composite: only 32.1 versus 49.1 MPa. Sumesh and Kanthavel 28 analyzed hybrid sisal-banana fiber-reinforced epoxy composites: tensile strength was obtained for a 35% fiber content and is below that of the SFD composite (i.e.…”

Section: Discussionmentioning

confidence: 99%

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al₂O₃ powder hybrid‐reinforced epoxy composites

Herlina Sari,

Suteja,

Pruncu

et al. 2024

Polymer International

View full text Add to dashboard Cite

Hybridization of natural fibers with ceramic materials for reinforcing composites allows to optimize properties of these materials. For this reason, the present study aims to investigate physical, mechanical, water absorption, swelling and thermal properties as well as morphological characteristics of the hybrid Paederia foetida fibers–alumina powder (PFs/Al2O3) reinforced epoxy composite. Epoxy resin served as the matrix, while Paederia foetida fibers (PFs) and alumina powder (Al2O3) were employed as reinforcement. Five types of composites were fabricated using the hot‐pressing technique. The corresponding ratios of PFs:Al2O3 volume fractions considered here were 0%:40% (SFA), 10%:30% (SFB), 20%:20% (SFC), 30%:10% (SFD), and 40:0% (SFE), respectively. The results reveal that the density of the hybrid PFs/Al2O3 composites decreased for increasing volume fractions of PFs: from 2.173 g/cm3 of SFA composite to 1.042 g/cm3 of SFE composite. The highest values of tensile strength (i.e. 49.085 MPa), tensile elastic modulus (i.e. 1.431GPa) and impact strength (24 kJ/m2) were obtained for the SFD composite material with 30% volume fraction of PFs and 10% volume fraction of Al2O3: this happened because interface bonds between PFs, Al2O3and Epoxy phases achieved their optimal configuration. Overall, mechanical properties of hybrid PFs‐Al2O3 reinforced epoxy composites were superior over those of the composites reinforced only by PF fibers or only by Al2O3 powder. Water absorption and swellability reached their maximum values at the steady state occurring after tested samples remained immersed in the water for 820 h. The SFE composite reinforced only by PFs presented the highest water absorption and swelling (i.e. 6.034% and 5.81%, respectively) while for all other hybrid composites (e.g. SFD, SFC and SFB) these two quantities remained below 5%. Density and volume fraction of voids of hybrid PFs‐Al2O3 reinforced composites were consistent with the corresponding properties of the composites reinforced only by Al2O3 or PFs. The SFD composite was also the most thermally stable material. SEM observations of fractured surfaces indicated that the microstructure of PFs‐Al2O3 reinforced epoxy composites presents several voids, fiber pullouts and transverse fibers, which concur to optimize the mechanical response of the composite material. Remarkably, the SFD composite material was highly competitive with the most recently developed hybrid composites employing natural reinforcements.This article is protected by copyright. All rights reserved.

show abstract

Section: Discussionmentioning

confidence: 99%

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al₂O₃ powder hybrid‐reinforced epoxy composites

Herlina Sari,

Suteja,

Pruncu

et al. 2024

Polymer International

View full text Add to dashboard Cite

show abstract

“…The density of the Bamboo fibre was determined using a specific equation 25 . By employing these methods, researchers were able to accurately measure the diameter and density of bamboo fibres 26 , 28 . These parameters are essential for understanding the fibre's physical characteristics and its potential applications in various fields, including textiles, composites, and other engineering materials.…”

Section: Methodsmentioning

confidence: 99%

Mechanical superiority of Pseudoxytenanthera bamboo for sustainable engineering solutions

Jiyas,

Sasidharan,

Bindu Kumar

et al. 2023

Sci Rep

View full text Add to dashboard Cite

The advancement in natural fibre composites has replaced synthetic fibres in various commercial sectors. Bamboo species possess high mechanical properties due to their lignocellulosic fibre content, which makes them suitable for engineering applications and potential alternatives to solid wood. However, despite Bamboo being composed of 130 genera and 1700 different species, out of which many still remains underexplored. In this study, we investigated the, Lignocellulosic profiling, fibre strength, and mechanical characterization of two species of Pseudoxytenanthera Bamboo: Pseudoxytenanthera ritchiei, Pseudopxytenanthera stocksii, and the results obtained were compared with Bambusa balcooa, one of the priority species of bamboo identified by The International Plant Genetic Resources Institute (IPGRI). BET (Brunauer–Emmett–Teller) was used to quantify the samples’ density, while SEM–EDX and FTIR spectroscopy were used for elemental analysis. The samples were then subjected to tensile test in addition, thermogravimetric analysis and water absorption test were carried out for the three species. The results showed that Pseudoxytenanthera species possessed superior chemical and mechanical characteristics compared to the priority species of bamboo used for composites. Out of the two Pseudoxytenanthera species studied, Pseudoxytenanthera stocksii exhibited the highest values of cellulose, hemicellulose, lignin, pectin, ash, carbon, and silicon, indicating its chemical superiority. Moreover, Pseudoxytenanthera stocksii also showed higher mechanical values for tensile strength, making it suitable for a variety of engineering applications. The TGA values also indicated that Pseudoxytenanthera stocksii is stable at high temperatures when compared with other natural fibres.

show abstract

“…Similarly, certain researchers made an effort to create a composite material by using a novel type of plant fibre that underwent surface modifications. Madival et al [52] conducted research on Furcraea foetida, a plant commonly found in the Caribbean and South America, to determine its potential as a source of fibre for composite materials. The researchers measured the density of the raw fibre and compared it with the density of chemically treated fibres.…”

Section: Chemical Compositionsmentioning

confidence: 99%

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Gurupranes¹,

Rajendran²,

Gokulkumar

et al. 2023

International Journal of Polymer Science

View full text Add to dashboard Cite

Various environmental concerns motivate scientists and researchers to look out for unique new materials in science and technology. In order to address the demand for polymeric materials with partial biodegradability, the usage of lignocellulosic fibre in the polymer matrix has risen. Lignocellulosic fibres are a cheap, easily renewable resource that is readily available in all regions. Cellulosic plant fibres also have a plethora of possibilities for use in polymer reinforcement because of their properties. Many researchers put their effort into developing a natural polymer with better mechanical properties and thermal stability using nanotechnology and the use of natural polymers to make its composites with lignocellulosic fibres. This study provides a review of the biodegradable composite market, processing methods, matrix-reinforcement phases, morphology, and characteristic improvements. In addition, it provides a concise summary of the findings of significant research on natural fibre polymer composites (NFRCs) that have been published. Indeed, a noticeably brief discussion is provided on the significant issues faced during composite extraction as well as the challenges encountered during the machining. Recent developments in the study of lignocellulosic fibre composites or NFRCs have demonstrated their enormous potential as structural elements in vehicles, aerospace structures, buildings, ballistics, soundproofing, and other structures.

show abstract

Processing, Characterization of Furcraea foetida (FF) Fiber and Investigation of Physical/Mechanical Properties of FF/Epoxy Composite

Cited by 14 publications

References 100 publications

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al₂O₃ powder hybrid‐reinforced epoxy composites

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al₂O₃ powder hybrid‐reinforced epoxy composites

Mechanical superiority of Pseudoxytenanthera bamboo for sustainable engineering solutions

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Contact Info

Product

Resources

About

Processing, Characterization of Furcraea foetida (FF) Fiber and Investigation of Physical/Mechanical Properties of FF/Epoxy Composite

Cited by 14 publications

References 100 publications

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al2O3 powder hybrid‐reinforced epoxy composites

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al2O3 powder hybrid‐reinforced epoxy composites

Mechanical superiority of Pseudoxytenanthera bamboo for sustainable engineering solutions

Preparation, Characteristics, and Application of Biopolymer Materials Reinforced with Lignocellulosic Fibres

Contact Info

Product

Resources

About

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al₂O₃ powder hybrid‐reinforced epoxy composites

Physicomechanical, water absorption and thermal properties and morphology of Paederia foetida fiber–Al₂O₃ powder hybrid‐reinforced epoxy composites