Your search keyword '"Sivasubramanian Palanisamy"' showing total 15 results

1. Advances in Manufacturing of Carbon-based Molecular Nanomaterials Based on Rice Husk/hull Waste

Author

Padmanabhan Rengaiyah Govindarajan, Joseph Arockiam Antony, Sivasubramanian Palanisamy, Nadir Ayrilmis, Tabrej Khan, Harri Junaedi, and Tamer Ali Sebaey

Subjects

rice-husk, biomass, nanomaterial, nanostructures, carbon, application, Biotechnology, TP248.13-248.65

Abstract

This review highlights potential application areas for carbon-based molecular nanoparticles, such as carbon dots, carbon nanotubes, graphene quantum dots, and carbon quantum dots. The success of nano-manufacturing hinges on robust collaboration between academia and industry to advance applicable manufacturing techniques. Choosing the right approach is crucial, one that integrates the carbon base of nanomaterials with the required properties and impurities, as well as the scalability of the process. Molecular, in this context, refers to the nanoscale carbon structures that form the basis of these materials, including their arrangement, bonding, and properties at the molecular level. The article also explores the characterization of different types of molecular nanomaterials. Nanomaterials are increasingly used in almost every contemporary industry, including construction, textiles, manufacturing, and computing. This article reviews the most prominent sectors globally that employ nanomaterials. Biomasses containing lignin, cellulose, and hemicellulose have become some of the most extensively studied. Initially, rice waste was utilized for bulk materials, but lately, the production of multifunctional materials has surged in interest. Carbon nanostructures derived from rice waste offer a broad spectrum of applications and enhanced biocompatibility. Recent advancements, challenges, and trends in the development of multifunctional carbon-based nanomaterials from renewable rice waste resources are considered.

Published

2024

2. Mechanical and Wear Performance Evaluation of Natural Fiber/Epoxy Matrix Composites

Author

Sivasubramanian Palanisamy, Sumesh Keerthiveetil Ramakrishnan, Carlo Santulli, Tabrej Khan, and Omar Shabbir Ahmed

Subjects

areca husk, thermal degradation, mechanical properties, wear properties, fracture morphology, Biotechnology, TP248.13-248.65

Abstract

Fibers collected from the husk of areca nut trees were chopped to a length of 30 mm and were either used as such or subjected to alkaline treatment by immersion in a 5% sodium hydroxide (NaOH) solution. The untreated and treated fibers were investigated using thermogravimetric analysis (TGA) before the fabrication of composites using an epoxy matrix. Different amounts of fibers were introduced in the matrix, fabricating the composite by compression molding. The composites were subjected to tensile, flexural, and Charpy impact and Shore D hardness testing, which all demonstrated the considerable advantage obtained with the growing quantity of fibers, especially when employing treated fibers, except in the case of hardness, where limited advantages were encountered. Wear tests were carried out on treated fiber composites and the surface morphology of the worn-out samples was studied, which also demonstrated the improvement in fiber-matrix bonding obtained with the growing amount of fibers. The main limitation of the fibers was their low elongation even after treatment. The fibers hardly reached 4%, which might represent a quite normal value for this kind of fibers, possibly due to with tendency to fibrillation. This would somehow compare these composites with others with similar amounts and lengths of natural fibers.

Published

2024

3. Crashworthiness Analysis and Morphology of Hybrid Hollow Tubes Reinforced by Aluminum Mesh with Hybrid Woven Fibre Composites (Basalt, Jute, Hemp, Banana, Bamboo) Using Roll-Wrapping Technique

Author

Padmanabhan Rengaiyah Govindarajan, Rajesh Shanmugavel, Sivasubramanian Palanisamy, Tabrej Khan, Harri Junaedi, Ajay Kumar, and Tamer Ali Sebaey

Subjects

hollow structural tubes, polymer composites, basalt, woven fibre, aluminum mesh, roll-wrapping, energy absorption, crushing force, Biotechnology, TP248.13-248.65

Abstract

This study investigated the mechanical performance of hybrid tubes made via roll-wrapping and enhanced with an aluminum mesh and epoxy matrix (AL-DMEM). The specimens included Basalt + Jute (BJAJB), Basalt + Bamboo (BBmABmB), Basalt + Banana (BBaABaB), Basalt + Hemp (BHAHB), and Basalt (BAB). The BBmABmB specimen showed the best mechanical properties with the highest peak crushing force, specific energy absorption, mean crushing force, and total energy absorption. The AL-DMEM integration improved load-bearing capacity and energy absorption, reducing matrix cracking and fiber breakage. Scanning electron microscopy and energy-dispersive X-ray analysis highlighted BBmABmB's robust reinforcement. Its superior structural integrity and aluminum content make it suitable for applications requiring high structural integrity, such as micromobility vehicles, highlighting the potential of AL-DMEM-reinforced composites in advanced engineering applications.

Published

2024

4. Mechanical, Morphological and Wear Resistance of Natural Fiber / Glass Fiber-based Polymer Composites

Author

K. R. Sumesh, Sivasubramanian Palanisamy, Tabrej Khan, A. Ajithram, and Omar Shabbir Ahmed

Subjects

natural fiber, epoxy resin, mechanical testing, morphological properties, surface treatments, Biotechnology, TP248.13-248.65

Abstract

Natural fibers along with glass fibers were used as the reinforcement of an epoxy matrix for the betterment of mechanical and wear applications. The combination of overall wt% up to 20 resulted in 23.8 MPa of tensile strength compared to 15.5 MPa for untreated fibers. The wt% of areca fiber (AF) (20 wt%)/glass fibers (GF) (20 wt%) with 5% alkali treatment yielded a maximum tensile strength up to 62.6% in comparison to untreated fiber at lowest percentage of 10 wt%. The increase in flexural strength with alkali treatment was observed from 20 to 50 wt% hybrid fiber incorporation. The alkali treated fibers, untreated fiber combinations achieved 33.8% and 26.8% improvement with impact properties. A decrease in the wear loss was shown with the increase in wt% of hybrid fiber incorporation from 20 to 40 wt%. The interfacial adhesion of fiber with matrix created a pressure absorbing zone that was positively influenced with applying higher loads. The frictional rate was highly increasing with increase in hybrid fiber wt% and also with higher loads applied. The SEM results for treated 20 wt% AF+20 wt% GF with hybrid fiber incorporation observed better results due to improved adhesion of fiber with matrix phase.

Published

2024

5. Mechanical, Morphological and Wear Resistance of Natural Fiber / Glass Fiber-based Polymer Composites

Author

K. R. Sumesh, Sivasubramanian Palanisamy, Tabrej Khan, A. Ajithram, and Omar Shabbir Ahmed

Subjects

natural fiber, epoxy resin, mechanical testing, morphological properties, surface treatments, Biotechnology, TP248.13-248.65

Abstract

Natural fibers along with glass fibers were used as the reinforcement of an epoxy matrix for the betterment of mechanical and wear applications. The combination of overall wt% up to 20 resulted in 23.8 MPa of tensile strength compared to 15.5 MPa for untreated fibers. The wt% of areca fiber (AF) (20 wt%)/glass fibers (GF) (20 wt%) with 5% alkali treatment yielded a maximum tensile strength up to 62.6% in comparison to untreated fiber at lowest percentage of 10 wt%. The increase in flexural strength with alkali treatment was observed from 20 to 50 wt% hybrid fiber incorporation. The alkali treated fibers, untreated fiber combinations achieved 33.8% and 26.8% improvement with impact properties. A decrease in the wear loss was shown with the increase in wt% of hybrid fiber incorporation from 20 to 40 wt%. The interfacial adhesion of fiber with matrix created a pressure absorbing zone that was positively influenced with applying higher loads. The frictional rate was highly increasing with increase in hybrid fiber wt% and also with higher loads applied. The SEM results for treated 20 wt% AF+20 wt% GF with hybrid fiber incorporation observed better results due to improved adhesion of fiber with matrix phase.

Published

2024

6. Influence of Washing with Sodium Lauryl Sulphate (SLS) Surfactant on Different Properties of Ramie Fibres

Author

Murugesan Palaniappan, Sivasubramanian Palanisamy, Thulasi mani Murugesan, Srinivas Tadepalli, Rashid Khan, Sabbah Ataya, and Carlo Santulli

Subjects

lignocellulosic fibres, ramie fibre, physico-chemical characterization, morphological characteristics, thermal properties, Biotechnology, TP248.13-248.65

Abstract

Green composite materials are a means of reducing reliance on synthetic and especially single-use plastics (SUP) and raising public awareness of the need for urgent action to protect the planet. Natural (lignocellulosic) fibres are increasingly utilized as the reinforcement in polymer matrix composites, in search for increased renewability and sustainability. This work concerns the effect of washing ramie (Boehmeria nivea) fibres using sodium lauryl sulphate (SLS) surfactant. The SLS-treated ramie fibres were examined for their morphological, physical, thermal, structural, and mechanical properties by powder X-ray diffraction (XRD), Fourier transform infrared (FTIR) spectroscopy, thermogravimetric analysis (TGA), scanning electron microscopy (SEM), and tensile testing. SLS treated ramie fibres density and crystallinity index values were 1.23 g/cc and 84.5%, respectively, with a very high cellulose content of 81.3%, because hemicellulose and loose particles were dissolved. SEM images depicted the relevant changes, with no significant damage on treated fibre surfaces. With some assistance from the treatment, fibres initiated their degradation only above 250 °C, culminating at 327 °C, which appears suitable for the manufacturing of composites with the most common matrices.

Published

2024

7. Crash-worthiness Analysis of Hollow Hybrid Structural Tube by Aluminum with Basalt-Bamboo Hybrid Fiber Laminates by Roll Wrapping Method

Author

Padmanabhan Rengaiyah Govindarajan, Rajesh Shanmugavel, Sivasubramanian Palanisamy, Tabrej Khan, and Omar Shabbir Ahmed

Subjects

hollow hybrid structure, basalt, bamboo, polymer laminates, roll wrapping method, axial compression, radial compression, Biotechnology, TP248.13-248.65

Abstract

Hollow hybrid structural tubes were evaluated using commercial-grade Diamond Micro Expanded Mesh (DMEM) thin mesh of aluminum (Al) as structural reinforcement. Axial, transverse (flexural), and radial compression tests were performed on four different layered hybrid structures using bamboo (Bm) and basalt (B). With a maximum force of 34.7 kN, compressive ultimate strength of 238 MPa, and strain of 12.6%, AlBmB (with layers labeled from inside to outside) was the best performer in the axial compression test. AlBmB’s adaptability was demonstrated by the flexural test, showing a maximum bending force of 4.7 kN, a flexural strength of 97.7 MPa, and a decreased deflection of 13.2 mm. Radial compression test results underscored the superior energy absorption characteristics of AlBmB. The varying material interfaces in the hybrid tubes yielded distinctive performances. AlBmB, incorporating bamboo and basalt layers, stood out with superior energy absorption and crush force characteristics, indicating enhanced crashworthiness. The other hybrids AlBm, AlB, and BmB also exhibited commendable performances, emphasizing the adaptability of different material combinations. The meticulous selection of DMEM and innovative roll wrapping method for fabrication reliably influenced the tubes’ mechanical properties. The study contributes to advancing the design of lightweight, durable, and high-strength components.

Published

2024

8. Crash-worthiness Analysis of Hollow Hybrid Structural Tube by Aluminum with Basalt-Bamboo Hybrid Fiber Laminates by Roll Wrapping Method

Author

Padmanabhan Rengaiyah Govindarajan, Rajesh Shanmugavel, Sivasubramanian Palanisamy, Tabrej Khan, and Omar Shabbir Ahmed

Subjects

hollow hybrid structure, basalt, bamboo, polymer laminates, roll wrapping method, axial compression, radial compression, Biotechnology, TP248.13-248.65

Abstract

Hollow hybrid structural tubes were evaluated using commercial-grade Diamond Micro Expanded Mesh (DMEM) thin mesh of aluminum (Al) as structural reinforcement. Axial, transverse (flexural), and radial compression tests were performed on four different layered hybrid structures using bamboo (Bm) and basalt (B). With a maximum force of 34.7 kN, compressive ultimate strength of 238 MPa, and strain of 12.6%, AlBmB (with layers labeled from inside to outside) was the best performer in the axial compression test. AlBmB’s adaptability was demonstrated by the flexural test, showing a maximum bending force of 4.7 kN, a flexural strength of 97.7 MPa, and a decreased deflection of 13.2 mm. Radial compression test results underscored the superior energy absorption characteristics of AlBmB. The varying material interfaces in the hybrid tubes yielded distinctive performances. AlBmB, incorporating bamboo and basalt layers, stood out with superior energy absorption and crush force characteristics, indicating enhanced crashworthiness. The other hybrids AlBm, AlB, and BmB also exhibited commendable performances, emphasizing the adaptability of different material combinations. The meticulous selection of DMEM and innovative roll wrapping method for fabrication reliably influenced the tubes’ mechanical properties. The study contributes to advancing the design of lightweight, durable, and high-strength components.

Published

2024

9. Influence of Washing with Sodium Lauryl Sulphate (SLS) Surfactant on Different Properties of Ramie Fibres

Author

Murugesan Palaniappan, Sivasubramanian Palanisamy, Thulasi mani Murugesan, Srinivas Tadepalli, Rashid Khan, Sabbah Ataya, and Carlo Santulli

Subjects

lignocellulosic fibres, ramie fibre, physico-chemical characterization, morphological characteristics, thermal properties, Biotechnology, TP248.13-248.65

Abstract

Green composite materials are a means of reducing reliance on synthetic and especially single-use plastics (SUP) and raising public awareness of the need for urgent action to protect the planet. Natural (lignocellulosic) fibres are increasingly utilized as the reinforcement in polymer matrix composites, in search for increased renewability and sustainability. This work concerns the effect of washing ramie (Boehmeria nivea) fibres using sodium lauryl sulphate (SLS) surfactant. The SLS-treated ramie fibres were examined for their morphological, physical, thermal, structural, and mechanical properties by powder X-ray diffraction (XRD), Fourier transform infrared (FTIR) spectroscopy, thermogravimetric analysis (TGA), scanning electron microscopy (SEM), and tensile testing. SLS treated ramie fibres density and crystallinity index values were 1.23 g/cc and 84.5%, respectively, with a very high cellulose content of 81.3%, because hemicellulose and loose particles were dissolved. SEM images depicted the relevant changes, with no significant damage on treated fibre surfaces. With some assistance from the treatment, fibres initiated their degradation only above 250 °C, culminating at 327 °C, which appears suitable for the manufacturing of composites with the most common matrices.

Published

2024

10. Mechanical Properties of Epoxy Composites Reinforced with Areca catechu Fibers Containing Silicon Carbide

Author

Rajkumar Ramasubbu, Arumugam Kayambu, Sivasubramanian Palanisamy, and Nadir Ayrilmis

Subjects

areca catechu fiber, chemical analysis, epoxy, mechanical characterization, silicon carbide, sem, Biotechnology, TP248.13-248.65

Abstract

The physical and chemical attributes of Areca catechu fiber (ACF) were explored. ACF is attractive because of its high cellulose content at 63.2 wt%. The mechanical properties were evaluated for Areca catechu fiber-reinforced epoxy composites, in which silicon carbide (SiC) was used as filler. The studied properties included water absorption, flexural strength, impact strength, tensile strength, and hardness properties. The tensile and flexural properties improved when the filler content increased from 40 to 50 wt%, but further increment in the filler content reduced the strength values. The addition of SiC adversely affected the bending and flexural properties of the composites at 40 and 50 wt% filler content, but it positively affected the properties at 60 wt% filler content. The hardness of the composites increased with the addition of 10% silicon carbide. From the results of this study, it is recommended that the ratio of silicon carbide in the composite should not exceed 10 wt% due to agglomeration. The composites containing 10 wt% SiC can be used for outdoor applications such as decking, railing, garden fencing, cladding, and siding applications.

Published

2024

11. Selection and Processing of Natural Fibers and Nanocellulose for Biocomposite Applications: A Brief Review

Author

Sivasubramanian Palanisamy, Thulasi Mani Murugesan, Murugesan Palaniappan, Carlo Santulli, Nadir Ayrilmis, and Azeez Alavudeen

Subjects

natural fiber composites (nfcs), density, chemical properties, mechanical properties, applications, Biotechnology, TP248.13-248.65

Abstract

In this study the recent developments in raw materials, manufacturing processes, and applications of natural fiber composites (NFCs) were reviewed. Natural fibers can represent a substitute for man-made fibers (including glass, aramid, and carbon) in a variety of biocomposite applications. Physical and chemical properties of the natural fibers are given and compared with the synthetic fibers. Advantages and disadvantages of NFCs in comparison with synthetic fibers such as glass and carbon fibers have been proposed. Criteria are described for the selection and processing of natural fibers for polymer composites used in different sectors such as automotive and building industries. The nanocellulose production methods, unique properties, and its recent industrial application in various sectors are given. This short review on NFCs considers their chemical, physical, and mechanical characteristics, as well as their various applications.

Published

2024

12. Mechanical Properties of Epoxy Composites Reinforced with Areca catechu Fibers Containing Silicon Carbide

Author

Rajkumar Ramasubbu, Arumugam Kayambu, Sivasubramanian Palanisamy, and Nadir Ayrilmis

Subjects

areca catechu fiber, chemical analysis, epoxy, mechanical characterization, silicon carbide, sem, Biotechnology, TP248.13-248.65

Abstract

The physical and chemical attributes of Areca catechu fiber (ACF) were explored. ACF is attractive because of its high cellulose content at 63.2 wt%. The mechanical properties were evaluated for Areca catechu fiber-reinforced epoxy composites, in which silicon carbide (SiC) was used as filler. The studied properties included water absorption, flexural strength, impact strength, tensile strength, and hardness properties. The tensile and flexural properties improved when the filler content increased from 40 to 50 wt%, but further increment in the filler content reduced the strength values. The addition of SiC adversely affected the bending and flexural properties of the composites at 40 and 50 wt% filler content, but it positively affected the properties at 60 wt% filler content. The hardness of the composites increased with the addition of 10% silicon carbide. From the results of this study, it is recommended that the ratio of silicon carbide in the composite should not exceed 10 wt% due to agglomeration. The composites containing 10 wt% SiC can be used for outdoor applications such as decking, railing, garden fencing, cladding, and siding applications.

Published

2024

13. Selection and Processing of Natural Fibers and Nanocellulose for Biocomposite Applications: A Brief Review

Author

Sivasubramanian Palanisamy, Thulasi Mani Murugesan, Murugesan Palaniappan, Carlo Santulli, Nadir Ayrilmis, and Azeez Alavudeen

Subjects

natural fiber composites (nfcs), density, chemical properties, mechanical properties, applications, Biotechnology, TP248.13-248.65

Abstract

In this study the recent developments in raw materials, manufacturing processes, and applications of natural fiber composites (NFCs) were reviewed. Natural fibers can represent a substitute for man-made fibers (including glass, aramid, and carbon) in a variety of biocomposite applications. Physical and chemical properties of the natural fibers are given and compared with the synthetic fibers. Advantages and disadvantages of NFCs in comparison with synthetic fibers such as glass and carbon fibers have been proposed. Criteria are described for the selection and processing of natural fibers for polymer composites used in different sectors such as automotive and building industries. The nanocellulose production methods, unique properties, and its recent industrial application in various sectors are given. This short review on NFCs considers their chemical, physical, and mechanical characteristics, as well as their various applications.

Published

2024

14. Use of Hemp Waste for the Development of Mycelium-grown Matrix Biocomposites: A Concise Bibliographic Review

Author

Sivasubramanian Palanisamy, Thulasi Mani Murugesan, Murugesan Palaniappan, Carlo Santulli, and Nadir Ayrilmis

Subjects

bio-blocks, agricultural substrates, polystyrene foam replacement, natural fibers, straw, sawdust, Biotechnology, TP248.13-248.65

Abstract

Mycelium from fungi can serve as the matrix or as a self-grown binder in a biocomposite. The reinforcing component may consist of various combinations of agro-based waste in short fiber or powder form. The complexity of their development is linked not only to the selection of the substrate, but also to the growth conditions of the mycelial material and its consolidation in a final form by the temperature increase that takes place. These materials have initially been proposed as a replacement for polystyrene foams, and the characterization is concentrated on compression performance and acoustic and thermal insulation properties. The present review concentrates on substrates that originated from the large productive system based on hemp (shives or hurds, waste fibers, and mats). Attention is paid to the performance obtained and to the amount of waste that is possibly employed to serve as the substrate.

Published

2023

15. Use of Hemp Waste for the Development of Mycelium-grown Matrix Biocomposites: A Concise Bibliographic Review

Author

Sivasubramanian Palanisamy, Thulasi Mani Murugesan, Murugesan Palaniappan, Carlo Santulli, and Nadir Ayrilmis

Subjects

bio-blocks, agricultural substrates, polystyrene foam replacement, natural fibers, straw, sawdust, Biotechnology, TP248.13-248.65

Abstract

Mycelium from fungi can serve as the matrix or as a self-grown binder in a biocomposite. The reinforcing component may consist of various combinations of agro-based waste in short fiber or powder form. The complexity of their development is linked not only to the selection of the substrate, but also to the growth conditions of the mycelial material and its consolidation in a final form by the temperature increase that takes place. These materials have initially been proposed as a replacement for polystyrene foams, and the characterization is concentrated on compression performance and acoustic and thermal insulation properties. The present review concentrates on substrates that originated from the large productive system based on hemp (shives or hurds, waste fibers, and mats). Attention is paid to the performance obtained and to the amount of waste that is possibly employed to serve as the substrate.

Published

2023