Abstract
Magnesium nanocomposites reinforced with ceramic reinforcements have emerged as a superior structural material for automotive applications due to their excellent specific properties. In this context, the current study aims to scrutinize the performance of Mg-WC nanocomposites in tribological applications. The effect of various input parameters (wt.% of reinforcement, load, and speed) on output responses (wear and coefficient of friction) is scrutinized using response surface methodology. Mg-WC nanocomposites having varying weight percentages of WC are synthesized using ultrasonic treatment associated the stir-casting technique. Typical characterizations of as-cast nanocomposites are done using scanning electron microscopy (SEM) and energy-dispersive spectroscopy (EDS). SEM micrographs confirm homogeneous dissemination of fortified particles in the base matrix while EDS confirms elemental composition. Analysis of variance (ANOVA) study is conducted to discover significant parameters affecting tribological performance. Surface plots and contour plots for tribological responses are also examined to observe interaction effects. ANOVA on wear confirms that wt.% of WC and speed are the most significant parameters while the interaction between wt.% of WC and speed has a significant influence. For the coefficient of friction, all the input parameters are significant, and interaction between wt.% of WC and load is of utmost significance. Regression equations for response parameters are also developed. Additionally, a desirability approach is considered to investigate both single- and multiple-objective-optimization criterions of output parameters. The desirability function for both single- and multi-optimization remains 0.9778, suggesting the presence of all input parameters within the working limit. Predicted and experimental values of the optimal setting possess a close fit for the current study. Minimum wear is achieved when wt.% of WC is 1.73%, load is 40 N, and speed is 100 rpm. Minimum friction is obtained when wt.% of WC is 1.78%, load is 40 N, and speed is 100 rpm. The multi-optimization result shows that the minimum value of wear and friction is achievable when wt.% of WC is 1.73%, load is 40 N, and speed is 100 rpm. Finally, the worn surface of samples is examined to observe possible wear mechanisms.
Highlights
The attenuation of natural resources and skyrocketing price of fuels has pushed the automotive and aerospace industries towards emission depletion, fuel efficiency, and weight reduction
Detailed discussion of available literature reveals that researchers are fascinated towards developing magnesium-based nanocomposites and trying to achieve optimality for tribological behavior
scanning electron microscopy (SEM) analysis confirms that WC nanoparticles are distributed in the magnesium matrix
Summary
The attenuation of natural resources and skyrocketing price of fuels has pushed the automotive and aerospace industries towards emission depletion, fuel efficiency, and weight reduction. Banerjee and Sutradhar (2018) have employed the response surface methodology (RSM) to investigate the wear characteristics of Mg–Gr–WC nanocomposites and achieved optimized result. John Iruthaya Raj et al (2019) have employed an RSM-based central composite design (CCD) to examine the role of different parameters (load, wt.% of mica, and sliding speed) on wear behavior of Mg mica. Detailed discussion of available literature reveals that researchers are fascinated towards developing magnesium-based nanocomposites and trying to achieve optimality for tribological behavior. An optimality-based study of tribological behavior of Mg–WC nanocomposites using the RSM methodology is not available. Design of experiment is a typical methodical proposition to accomplish maximum indisputable statistics from minimum process specifics This statistical methodology proposes features of the experimental technique to achieve suitable particulars, which can FIGURE 5 | EDAX spectrum of Mg-2WC nanocomposite. Worn surface is observed under SEM to investigate wear mechanisms
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