Studies on mechanical, thermal, and water immersion of plant and animal wastage nanofiller–based bio-fiber-reinforced composites

Radhakrishnan, Sidharth; Khan, Anas; Dwivedi, Shashi Prakash; Sharma, Bhasha; Gupta, Sumit; Gupta, Pallav; Chaudhary, Vijay

doi:10.1007/s13399-023-04788-4

Cited by 23 publications

(9 citation statements)

References 47 publications

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“…The vertical milling machine played a crucial role in executing Friction Stir Processing (FSP), a meticulously designed technique for fabricating composite materials with exceptional properties. Precision was paramount, with specific parameters meticulously selected: a 10 mm pin diameter, 0° tool tilt angle, and a threaded tool profile [36][37][38][39][40]. The tool traversed transversely at 30 mm/min while rotating at 1300 revolutions per minute, with a 3 mm pin length and 20 mm shoulder diameter defining the operation.…”

Section: Development Of Compositementioning

confidence: 99%

Enhancing Aluminum-Based Composite Manufacturing: Leveraging Si3N4 Reinforcement via Friction Stir Process

Singh,

Goel,

Nagpal

et al. 2024

E3S Web of Conf.

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In the realm of composite manufacturing, this study delves into the innovative approach of enhancing Aluminum-Based Composite Manufacturing through Si3N4 Reinforcement leveraged via Friction Stir Process (FSP). The FSP technique, executed with precision using a vertical milling machine, intricately fabricates composite materials with unparalleled properties. Meticulously chosen parameters including pin diameter, tool tilt angle, and tool profile, coupled with precise tool traversal and rotation, define the operation. The composite substrate, composed of AA 2024, undergoes stringent cleanliness protocols before Si3N4 powders are strategically placed into a designated groove on the titanium surface for processing. Microscopic examination reveals the uniform dispersion of Si3N4 particles within the aluminum matrix, profoundly enhancing mechanical properties. The tensile strength experiences a remarkable 21.45% improvement, while hardness witnesses a significant enhancement of 36.9%. Additionally, fatigue strength is notably improved by 24.12%, and wear resistance sees a substantial boost of 30.44% following Si3N4 nanoparticle integration via FSP.

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Section: Development Of Compositementioning

confidence: 99%

Enhancing Aluminum-Based Composite Manufacturing: Leveraging Si3N4 Reinforcement via Friction Stir Process

Singh,

Goel,

Nagpal

et al. 2024

E3S Web of Conf.

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“…In aerospace engineering, these composites can find utility in casting crucial components, such as engine parts and structural elements. The combination of lightweight properties and heightened strength makes them particularly attractive for aircraft applications, where material efficiency is paramount. , Moreover, the improved wear resistance positions these composites for applications in various industrial settings, such as manufacturing machinery components, where resistance to abrasion and fatigue is essential. The ability to tailor the composition of A356 composites with TiMoVWCr HEA reinforcement allows for customization, catering to specific requirements in sectors ranging from automotive manufacturing to marine engineering. , …”

Section: Introductionmentioning

confidence: 99%

Exploring Microstructural, Interfacial, Mechanical, and Wear Properties of AlSi7Mg0.3 Composites with TiMOVWCr High-Entropy Alloy Powder

Dwivedi,

Sharma,

et al. 2024

ACS Omega

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This study explored the impact of varying weight percentages of TiMoVWCr high-entropy alloy (HEA) powder addition on A356 composites produced using friction stir processing (FSP). Unlike previous research that often focused on singular aspects, such as mechanical properties, or microstructural analysis, this investigation systematically examined the multifaceted performance of A356 composites by comprehensively assessing the microstructure, interfacial bonding strength, mechanical properties, and wear behavior. The study identified a uniform distribution of TiMoVWCr HEA powder in the composition A356/2%Ti2%Mo2%V2%W2%Cr, highlighting the effectiveness of the FSP technique in achieving homogeneous dispersion. Strong bonding between the reinforcement and matrix material was observed in the same composition, indicating favorable interfacial characteristics. Mechanical properties, including tensile strength and hardness, were evaluated for various compositions, demonstrating significant improvements across the board. The addition of 2%Ti2%Mo2%V2%W2%Cr powder enhanced the tensile strength by 36.39%, while hardness improved by 62.71%. Similarly, wear resistance showed notable enhancements ranging from 35.56 to 48.89% for different compositions. Microstructural analysis revealed approximately 1640.59 grains per square inch for the A356/2%Ti2%Mo2%V2%W2%Cr processed composite at 500 magnifications. In reinforcing Al composites with Ti, Mo, V, W, and Cr high-entropy alloy (HEA) particles, each element imparted distinct benefits. Titanium (Ti) enhanced strength and wear resistance, molybdenum (Mo) contributed to improved hardness, vanadium (V) promoted hardenability, tungsten (W) enhanced wear resistance, and chromium (Cr) provided wear resistance and hardness. Anticipating the potential applications of the developed composite, the study suggests its suitability for the aerospace sector, particularly in casting lightweight yet high-strength parts such as aircraft components, engine components, and structural components, underlining the significance of the investigated TiMoVWCr HEA powder-modified A356 composites.

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“…The precise composition and processing techniques allow engineers to tailor their properties to specific applications, making them indispensable in aerospace, automotive, construction, and consumer goods sectors [3].One of the most notable features of aluminum alloys is their outstanding strength-to-weight ratio, making them ideal for applications where lightweight materials with high structural integrity are essential [4][5]. Additionally, aluminum alloys exhibit excellent corrosion resistance, especially when combined with certain alloying elements, ensuring longevity and durability in various environments [6].Furthermore, the malleability of aluminum alloys facilitates intricate shaping and forming processes, enabling the production of complex components with relative ease. This characteristic, coupled with their excellent thermal and electrical conductivity, further expands their utility in a wide range of applications, including heat exchangers, electrical conductors, and structural components [7][8].…”

Section: Introductionmentioning

confidence: 99%

Steel Chips Reinforcement in Aluminum-Based Composites: Revolutionizing Manufacturing via Stir Casting Technique

Gurulakshmi,

Rama Sundari,

Lakhanpal

et al. 2024

E3S Web of Conf.

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This study investigates the utilization of waste steel chips as reinforcement in aluminum-based composites through the stir casting technique. Steel chip particles were introduced gradually into the molten aluminum alloy while stirring at 400 rpm for 10 minutes to ensure uniform dispersion. Precise temperature control prevented premature solidification, facilitating effective incorporation of steel chips. The resulting composite exhibited a predominantly uniform distribution of reinforcement, indicating successful processing.The addition of 7.5% waste steel chips led to remarkable improvements in mechanical properties. Tensile strength increased by 15.67%, while hardness showed a substantial enhancement of 25.56% compared to the base composite. Moreover, wear resistance exhibited a notable improvement of 19.45%. These enhancements underscore the efficacy of waste steel chips as reinforcement, revolutionizing manufacturing practices in aluminum composites. The findings highlight the potential for sustainable and cost-effective approaches to enhance mechanical performance, contributing to advancements in materials engineering and promoting eco-friendly manufacturing practices.

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Studies on mechanical, thermal, and water immersion of plant and animal wastage nanofiller–based bio-fiber-reinforced composites

Cited by 23 publications

References 47 publications

Enhancing Aluminum-Based Composite Manufacturing: Leveraging Si3N4 Reinforcement via Friction Stir Process

Enhancing Aluminum-Based Composite Manufacturing: Leveraging Si3N4 Reinforcement via Friction Stir Process

Exploring Microstructural, Interfacial, Mechanical, and Wear Properties of AlSi7Mg0.3 Composites with TiMOVWCr High-Entropy Alloy Powder

Steel Chips Reinforcement in Aluminum-Based Composites: Revolutionizing Manufacturing via Stir Casting Technique

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