RETRACTED ARTICLE: Effects of roller burnishing process parameters on surface roughness of A356/5%SiC composite using response surface methodology

Dwivedi, Shashi Prakash; Sharma, Sandeep; Mishra, Raghvendra Kumar

doi:10.1007/s40436-014-0083-0

Cited by 33 publications

(13 citation statements)

References 28 publications

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“…Additionally, SiC is simply available and has good wettability with aluminum alloys. 18,19 Development of AA2014/eggshells' particulate MMC Figure 2 shows the schematic diagram of the electromagnetic stir casting setup to develop AA2014/eggshells' particulate/SiC hybrid green MMC. The matrix material was heated above its liquidus temperature in muffle furnace.…”

Section: Secondary Reinforcement Materialsmentioning

confidence: 99%

RETRACTED: Mechanical and metallurgical characterizations of AA2014/eggshells/SiC hybrid green metal matrix composite produced at optimum reinforcement parameters

Dwivedi

Sharma

Mishra

2016

Proceedings of the Institution of Mechanical Engineers, Part B:

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AA2014/carbonized eggshells/SiC hybrid green metal matrix composites are fabricated by electromagnetic stir casting process at optimum parameters (squeeze pressure of 60 MPa, stirring current of 12 A, stirring time of 180 s and matrix pouring temperature of 700°C, respectively). In the range of reinforcement parameters, the result shows that the tensile strength of hybrid metal matrix composite increases with the increase in carbonized eggshell and SiC preheat temperature. Whereas the tensile strength of AA2014/carbonized eggshell/SiC hybrid green metal matrix composite decreases with the addition of SiC beyond 2.5 wt%. The tensile strength of AA2014/carbonized eggshell/SiC hybrid green metal matrix composite increases with the increase in the eggshell weight percent until it reaches the center value (7.5 wt%); the tensile strength then starts to decrease with the increase in eggshell weight percent beyond the center limit (7.5 wt%). The optimum values of weight percent of carbonized eggshell, preheat temperature of carbonized eggshell, preheat temperature of SiC and SiC weight percent were found to be 7.5%, 300°C, 500°C and 2.5%, respectively, to get the maximum tensile strength (predicted: 259.12 MPa). The results reveal that sample of AA2014/7.5% eggshell/ 2.5% SiC shows best result among all the selected samples. The microstructure presents that the reinforcements (7.5 wt% carbonized eggshell and 2.5 wt% SiC particles) are uniformly distributed in the matrix AA2014 alloy. Transmission electron microscopy image shows proper wettability between AA2014 alloy and reinforcements (7.5 wt% carbonized eggshell and 2.5 wt% SiC particles). Density, X-ray diffraction, cost estimation, hardness, toughness, ductility and fatigue strength were also calculated to see the effect of carbonized eggshell and SiC addition in matrix alloy AA2014.

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Section: Secondary Reinforcement Materialsmentioning

confidence: 99%

RETRACTED: Mechanical and metallurgical characterizations of AA2014/eggshells/SiC hybrid green metal matrix composite produced at optimum reinforcement parameters

Dwivedi

Sharma

Mishra

2016

Proceedings of the Institution of Mechanical Engineers, Part B:

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“…It is a popular method commonly employed for modelling and analysis of machining process while a performance measure is affected by many factors and the aim is to optimise the measure. The approach is effectively used for development of predictive modelling for surface roughness in various machining process (Dwivedi et al, 2014;Tamang and Chandrasekaran, 2015). In this work, three process responses viz., R a , VB and CT are modelled in terms of v, f and d. The second order quadratic model is expressed as:…”

Section: Empirical Modellingmentioning

confidence: 99%

Machining performance optimisation of MQL-assisted turning of Inconel-825 superalloy using GA for industrial applications

Tamang

Chandrasekaran

Palanikumar³

et al. 2019

IJMMM

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This work investigates machining performance of Inconel 825 using chemical vapour deposition (CVD) TiN coated inserts in minimum quantity lubrication (MQL) approach. Three important measures in relation to machining of hard-to-cut materials viz., surface roughness (R a), tool wear (VB), and cutting temperature (CT) have been considered for investigation. The response surface methodology (RSM) modelling and relationship between input and output factors is studied. The machining parameters are optimised individually as well as simultaneously using genetic algorithm (GA). The minimum R a of 0.39 µm, VB of 15.37 µm and CT of 56.47°C was obtained. The significant contribution of this research is that the values of R a , VB and CT obtained are quite low when compared to those reported in literatures. For the application in manufacturing industries, a technology table is generated for selection of optimum process parameters having minimum VB or minimum CT satisfying the desired value of surface finish of components produced.

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“…The plastic deformation created by the roller is a displacement of the material that flows from the peaks into the valleys under pressure, and results in a surface finish with a strain-hardened surface [ 7 , 8 ]. The purpose of RB is plastic deformation of the surface layer in the area of the peaks of the surface asperities in order to obtain a roughness of Ra = 0.08–0.15 µm [ 9 ].…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Analysis of the Depth of the Strengthened Layer on Shafts Resulting from Roller Burnishing with Roller Braking Moment

et al. 2021

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The article presents the results of investigations into the depth of the plastically deformed surface layer in the roller burnishing process. The investigation was carried out in order to obtain information on the dependence relationship between the depth of plastic deformation, the pressure on the roller and the braking torque. The research was carried out according to the original method developed by the authors, in which the depth of plastic deformation is increased by applying a braking torque to the burnishing roller. In this method, it is possible to significantly increase (up to 20%) the depth of plastic deformation of the surface layer. The tests were carried out on a specially designed device on which the braking torque can be set and the force of the rolling resistance of the roller during burnishing can be measured. The tests were carried out on specimens made of C45 heat-treatable carbon steel. The dependence of the depth of the plastically deformed surface layer was determined for a given pressure force and variable braking moments. The depth of the plastically deformed layer was measured on the deformed end face of the ring-shaped samples. The microhardness in the sample cross-section and the evolution of the microstructure were both analysed.

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RETRACTED ARTICLE: Effects of roller burnishing process parameters on surface roughness of A356/5%SiC composite using response surface methodology

Cited by 33 publications

References 28 publications

RETRACTED: Mechanical and metallurgical characterizations of AA2014/eggshells/SiC hybrid green metal matrix composite produced at optimum reinforcement parameters

RETRACTED: Mechanical and metallurgical characterizations of AA2014/eggshells/SiC hybrid green metal matrix composite produced at optimum reinforcement parameters

Machining performance optimisation of MQL-assisted turning of Inconel-825 superalloy using GA for industrial applications

Experimental and Numerical Analysis of the Depth of the Strengthened Layer on Shafts Resulting from Roller Burnishing with Roller Braking Moment

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