Optimization of end milling on Al–SiC-fly ash metal matrix composite using Topsis and fuzzy logic

Tamiloli, N.; Venkatesan, J.; Murali, G.; Kodali, Shyam Prasad; Kumar, Tarun; Arunkumar, M.

doi:10.1007/s42452-019-1191-z

Cited by 18 publications

(9 citation statements)

References 28 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Apart from the implementation of parametric optimization of machining parameters during metal cutting, fuzzy TOPSIS was effective in various areas such as multi-response optimization of blended polymer composites (Şimşek and Uygunoğlu, 2016), optimization of drilling parameters for Al2O3 particles and sisal fiber-reinforced epoxy composites (Kamaraj et al ., 2018), optimization of the input parameters such as pulse on time, duty cycle, discharge current, etc. in the electron discharge machining process (Roy and Dutta, 2019) and optimization of the machining parameters of metal matrix composites (Al–SiC-fly ash) (Tamiloli et al ., 2019).…”

Section: Literature Reviewmentioning

confidence: 99%

Investigation of the effect of vibration in the multi-objective optimization of dry turning of hardened steel

Ahmed

Juberi

Bari

et al. 2023

IJIEOM

View full text Add to dashboard Cite

PurposeThis study aims to investigate the effect of vibration on ceramic tools under dry cutting conditions and find the optimum cutting condition for the hardened steel machining process in a computer numerical control (CNC) lathe machine.Design/methodology/approachIn this research, an integrated fuzzy TOPSIS-based Taguchi L9 optimization model has been applied for the multi-objective optimization (MOO) of the hard-turning responses. Additionally, the effect of vibration on the ceramic tool wear was investigated using Analysis of Variance (ANOVA) and Fast Fourier Transform (FFT).FindingsThe optimum cutting conditions for the multi-objective responses were obtained at 98 m/min cutting speed, 0.1 mm/rev feed rate and 0.2 mm depth of cut. According to the ANOVA of the input cutting parameters with respect to response variables, feed rate has the most significant impact (53.79%) on the control of response variables. From the vibration analysis, the feed rate, with a contribution of 34.74%, was shown to be the most significant process parameter influencing excessive vibration and consequent tool wear.Research limitations/implicationsThe MOO of response parameters at the optimum cutting parameter settings can significantly improve productivity in the dry turning of hardened steel and control over the input process parameters during machining.Originality/valueMost studies on optimizing responses in dry hard-turning performed in CNC lathe machines are based on single-objective optimization. Additionally, the effect of vibration on the ceramic tool during MOO of hard-turning has not been studied yet.

show abstract

Section: Literature Reviewmentioning

confidence: 99%

Investigation of the effect of vibration in the multi-objective optimization of dry turning of hardened steel

Ahmed

Juberi

Bari

et al. 2023

IJIEOM

View full text Add to dashboard Cite

show abstract

“…In the cutting tool length to diameter is large and complex curved surface parts processing, the conventional method of milling cutter are prone to deformation, able to withstand the radial cutting force is small, in order to avoid the flutter, affect the machining accuracy and other negative effect to adopt conservative cutting parameters, such as reducing cutting speed, cutting depth and cutting width, this limits the processing efficiency. In the process of interpolation and milling, the tool is fed along the spindle direction, and the rigidity of the cutting system is large, which can better avoid chatter, make the machining quality of parts more stable, and improve the cutting parameters appropriately to improve the material removal rate [14][15].…”

Section: Interpolation and Milling Machining Mode And Modelingmentioning

confidence: 99%

Interpolation and Milling Optimization of Titanium Alloy Based on Machine Learning and Multi-objective Algorithm

2020

View full text Add to dashboard Cite

With the continuous progress of the society, the manufacturing industry is facing greater challenges and opportunities. Complex, diverse and customized requirements demand greater flexibility and faster response times in manufacturing process systems. As a machining method that can quickly remove metal materials, insert milling has attracted much attention in recent years, and has been widely used in aerospace and die manufacturing industries. In this paper, the interpolation and milling optimization of titanium alloy based on machine learning and multi-objective algorithm is studied. In this paper, taking milling TC4 titanium alloy as an example, a machining optimization model based on multi-objective optimization is proposed to improve the quality and improve the efficiency. DDQN is used to optimize and model the parameters (satisfying the minimum surface roughness, maximum material removal rate and optimal milling force stability). Finally, the effectiveness of the multi-objective algorithm is verified by comparing with the empirical parameters.

show abstract

“…Sidhu and Yazdani [11] employed desirability function and lexicographic goal programming to identify the optimal machining condition for having minimum residual stress, tool wear rate (TWR) and maximum material removal rate (MMR) during electrical discharge machining (EDM) of SiC/A359 MMC. Tamiloli et al [12] integrated fuzzy logic with technique for order of preference by similarity to ideal solution (TOPSIS) for optimization of the end milling parameters while machining Al-SiC-fly ash MMC. It was observed that feed rate, speed and depth of cut would significantly affect surface roughness and cutting force during the machining operation.…”

Section: Introductionmentioning

confidence: 99%

A novel MOALO-MODA ensemble approach for multi-objective optimization of machining parameters for metal matrix composites

Kalita

Kumar

Chakraborty

2023

Multiscale and Multidiscip. Model. Exp. and Des.

View full text Add to dashboard Cite

Machining of metal matrix composites (MMCs) has now become an essential task in shaping them to their final usable forms for various industrial applications. These machining operations may range from drilling of simple through holes to cutting and shaping the composites into complex shapes.Determination of the optimal process parameters during their machining presents a combinatorial optimization problem, which may turn out to be more complex due to involvement of various material dependent parameters of the MMCs, like particle size, reinforcement percentage etc. The importance of optimization increases manifold due to conflicting settings of different process parameters for attaining the desired quality characteristics. In this paper, two nature-inspired optimization algorithms, i.e. multi-objective antlion optimization (MOALO) and multi-objective dragonfly algorithm (MODA) are applied for multi-objective optimization of various process parameters during machining of MMCs. To mitigate uncertainties in global optimality of the predicted Pareto optimal fronts arising due to stochastic nature of the metaheuristics, an ensemble approach integrating MOALO and MODA techniques is proposed here. It is demonstrated with the help of two case studies that MOALO-MODA ensemble is far superior to its individual counterparts and thus, can be employed for development of robust and reliable Pareto optimal fronts.

show abstract

Optimization of end milling on Al–SiC-fly ash metal matrix composite using Topsis and fuzzy logic

Cited by 18 publications

References 28 publications

Investigation of the effect of vibration in the multi-objective optimization of dry turning of hardened steel

Investigation of the effect of vibration in the multi-objective optimization of dry turning of hardened steel

Interpolation and Milling Optimization of Titanium Alloy Based on Machine Learning and Multi-objective Algorithm

A novel MOALO-MODA ensemble approach for multi-objective optimization of machining parameters for metal matrix composites

Contact Info

Product

Resources

About