Abstract
Multiobjective optimization approaches have allowed the improvement of technical features in industrial processes, focusing on more accurate approaches for solving complex engineering problems and support decision-making. This paper proposes a hybrid approach to optimize the 3D printing technology parameters, integrating the design of experiments and multiobjective optimization methods, as an alternative to classical parametrization design used in machining processes. Alongside the approach, a multiobjective differential evolution with uniform spherical pruning (usp-MODE) algorithm is proposed to serve as an optimization tool. The parametrization design problem considered in this research has the following three objectives: to minimize both surface roughness and dimensional accuracy while maximizing the mechanical resistance of the prototype. A benchmark with non-dominated sorting genetic algorithm II (NSGA-II) and with the classical sp-MODE is used to evaluate the performance of the proposed algorithm. With the increasing complexity of engineering problems and advances in 3D printing technology, this study demonstrates the applicability of the proposed hybrid approach, finding optimal combinations for the machining process among conflicting objectives regardless of the number of decision variables and goals involved. To measure the performance and to compare the results of metaheuristics used in this study, three Pareto comparison metrics have been utilized to evaluate both the convergence and diversity of the obtained Pareto approximations for each algorithm: hyper-volume (H), g-Indicator (G), and inverted generational distance. To all of them, ups-MODE outperformed, with significant figures, the results reached by NSGA-II and sp-MODE algorithms.
Highlights
The product development conception during the manufacturing systems needs optimal experiment design techniques which can help to systematically develop experiments by incorporating important information to estimate parameters with higher accuracy
This section describes the statistical analysis of the experiments presented in the previous section
A statistical ANOVA analysis was conducted in a way to establish the problem over the 3D printing technology process
Summary
The product development conception during the manufacturing systems needs optimal experiment design techniques which can help to systematically develop experiments by incorporating important information to estimate parameters with higher accuracy. To optimize parameters related to additive manufacturing, the design of experiments methods has been used. When problems become complex and several objectives are taken, the optimization method allows obtaining faster and trustworthy solutions. The solution to a multiobjective optimization problem is normally not unique since the best solution for all objectives does not exist. It is important to combine analytical and heuristic techniques for solving complex problems such as technical parameters in the manufacturing processes (Tervo et al, 2003). For decision-making, it is necessary to obtain the current reality, relevant metrics, and optimized measures for the best decision (Canciglieri et al, 2015; Chen and Zhao, 2016)
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