Finite element modelling and development of SiC-filled ZA-27 alloy composites in erosive wear environment: a comparative analysis

Mamatha, T.G.; Patnaik, Amar; Biswas, Sandhyarani; Kumar, Pradeep

doi:10.1177/1350650111412706

Cited by 14 publications

(8 citation statements)

References 25 publications

(25 reference statements)

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“…It has not been clarified how such combinations of a matrix material and a filler material affect the erosion characteristics of MMCs and CMCs. There has been no solid particle erosion data on newly developed advanced composite materials such as carbon based nano-reinforcements, CNTs, graphenes, and so on. Simulations studies on solid particle erosion of composites have been not yet enough done. 87, 119, 186–188 Further studies will be needed to quantitative simulations.…”

Section: Discussionmentioning

confidence: 99%

“…Mamatha et al. 119 performed solid particle erosion experiments of Zn-Al alloy reinforced by SiC particles (SiC/Zn-Al), and finite element simulations of erosion characteristics of the composites to validate experimental results. It was observed that the SiC/Zn-Al composites exhibited the better erosion resistance than unreinforced Zn-Al alloy.…”

Section: Metal Matrix Compositesmentioning

confidence: 99%

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Solid particle erosion of composite materials: A critical review

Miyazaki

2016

Journal of Composite Materials

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This article presents a critical review of papers dealing with solid particle erosion characteristics of polymer matrix composites, metal matrix composites, and ceramic matrix composites. In addition, the solid particle erosion characteristics of coatings for composite materials are also reviewed. Attention was paid to type of a reinforcement material (fiber/filler), amount of fiber/filler, fiber orientation, and interfacial strength between fiber/filler and matrix, which affect the solid particle erosion in addition to the variables affecting the solid particle erosion of monolithic materials, that is, impact angle, particle velocity, temperature, particle flux, and erodent properties such as shape, size, hardness, and so on. General characteristics of solid particle erosion for composites are extracted from the review of the papers.

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Section: Discussionmentioning

confidence: 99%

Section: Metal Matrix Compositesmentioning

confidence: 99%

Solid particle erosion of composite materials: A critical review

Miyazaki

2016

Journal of Composite Materials

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“…Table 2 gives the characteristics of both powders utilized in this research work. SiC has been used as reinforcement by different researchers (Izciler and Muratoglu 2003;Mamatha et al 2011). Si3N4 presents a higher hardness than SiC, due to which a harder casting is obtained.…”

Section: Methodsmentioning

confidence: 99%

Fabrication of 6061 aluminum alloy reinforced with Si₃N₄/n-Gr and its wear performance optimization using integrated RSM-GA

Sharma

Khanna

Singh

et al. 2016

Particulate Science and Technology

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In this research work the dry sliding wear behavior of a hybrid aluminum metal matrix composite is evaluated. Al 6061 is used as a matrix material while Si3N4 and nano-graphite powder (3-15 wt.%) are used as reinforcements. These two reinforcements (50 wt.% of each) were blended in high energy ball mill for homogeneous mixing to get the sound aluminum matrix composite (AMC). The hybrid composite is made by stir casting route and its wear rate was investigated against an EN32 steel disc surface, using a pin-on-disc tribometer. Integrated Downloaded by [University of Cambridge] at 22:30 13 June 20162 response surface methodology (RSM) and genetic algorithm (GA) are used to optimize the pinon-disc process parameters. Analysis of variance (ANOVA) shows that sliding distance plays a major role on the dry sliding wear rate followed by load, sliding speed and reinforcements. Twofactor interactions and quadratic terms have also significant contributions. Genetic algorithm suggested a minimum wear rate value of 0.827 mg at optimized setting. Micro-structural analysis by scanning electron microscopy (SEM) reveals that very fine grooves are obtained at optimized settings while at other settings severe ploughing is observed. Transition of wear mechanism takes place with the increase of speed (i.e., temperature between the two rubbing surfaces) from abrasive to adhesive.

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“…Similar, observations was observed for 2024 aluminum alloy MMCs with Al 2 O 3 filler particles, the density of the composites increased with increasing weight percentage and size of particles, whereas, the porosity of the composites increased with decreasing size and increasing weight percentage of particles. [23][24][25][26][27][28] Effect of varying wt.% of SiC on hardness of A356 alloy composite…”

Section: Effect Of Varying Wt% Of Sic On Void Content Of A356 Alloy Compositesmentioning

confidence: 99%

Experimental and finite element analysis of mechanical and fracture behavior of SiC particulate filled A356 alloy composites: Part I

Kukshal

Gangwar

Patnaik

2013

Proceedings of the Institution of Mechanical Engineers, Part L:

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In the present study, silicon carbide (SiC) filled cast aluminum (A356) alloy composites were fabricated using stir casting technique by varying SiC weight percentages from 0 wt.% to 25 wt.% at a range of 5 wt.%, respectively. The spherical shaped SiC particles of 60 mm size were uniformly mixed with the semi-solid alloy by mechanical stirrer. The physical and mechanical properties along with the fracture toughness of SiC filled A356 alloy composite were evaluated experimentally and compared with finite element analysis results for the validation purpose. It was found that the void content of A356 alloy composites varied from 1.01% to 2.69% and hardness from 21.25 HRB to 33 HRB with the increased SiC wt.% from 0% to 25%. The maximum experimental value of Young's modulus and flexural strength at 25 wt.% SiC filled A356 alloy composite was found to be 150.55 MPa and 315.94 MPa, respectively. Impact energy of the SiC filled A356 alloy composite also increased from 3.92 J at 0 wt.% to 7.82 J at 25 wt.% SiC. It was established that the stress intensity factor for unfilled and SiC filled A356 alloy composites increases with the increased crack length for 0-25 wt.% SiC content. The tensile and flexural behavior of the composite is simulated by three-dimensional (3D) unit cell model using appropriate boundary condition in ANSYS. Finally, stress intensity factor for the crack propagation is determined using 2D simulation of single side edge cracked specimen in compact tension. The maximum percentage error for tensile strength and fracture toughness as calculated experimentally and by finite element method was found to be 5.74% and 7.69%, respectively, which is within the acceptable range.

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Finite element modelling and development of SiC-filled ZA-27 alloy composites in erosive wear environment: a comparative analysis

Cited by 14 publications

References 25 publications

Solid particle erosion of composite materials: A critical review

Solid particle erosion of composite materials: A critical review

Fabrication of 6061 aluminum alloy reinforced with Si₃N₄/n-Gr and its wear performance optimization using integrated RSM-GA

Experimental and finite element analysis of mechanical and fracture behavior of SiC particulate filled A356 alloy composites: Part I

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Finite element modelling and development of SiC-filled ZA-27 alloy composites in erosive wear environment: a comparative analysis

Cited by 14 publications

References 25 publications

Solid particle erosion of composite materials: A critical review

Solid particle erosion of composite materials: A critical review

Fabrication of 6061 aluminum alloy reinforced with Si3N4/n-Gr and its wear performance optimization using integrated RSM-GA

Experimental and finite element analysis of mechanical and fracture behavior of SiC particulate filled A356 alloy composites: Part I

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Fabrication of 6061 aluminum alloy reinforced with Si₃N₄/n-Gr and its wear performance optimization using integrated RSM-GA