Powder Bed Fusion via Machine Learning-Enabled Approaches

IF 1.7 4区工程技术 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS Complexity Pub Date : 2023-04-30 DOI:10.1155/2023/9481790

Utkarsh Chadha, Senthil Kumaran Selvaraj, Abel Saji Abraham, Mayank Khanna, Anirudh Mishra, Isha Sachdeva, Swati Kashyap, S. Jithin Dev, R. Srii Swatish, Ayushma Joshi, Simar Kaur Anand, Addisalem Adefris, R. Lokesh Kumar, Jayakumar Kaliappan, S. Dhanalakshmi

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Abstract

Powder bed fusion (PBF) applies to various metallic materials used in the metal printing process of building a wide range of complex parts compared to other AM technologies. PBF process has several variants such as DMLS (direct metal laser sintering), EBM (electron beam melting), SHS (selective heat sintering), SLM (selective laser melting), and SLS (selective laser sintering). For PBF to reach its maximum potential, machine learning (ML) algorithms are used with suitable materials to achieve goals cost-effectively. Various applications of neural networks, including ANNs, CNNs, RNNs, and other popular techniques such as KNN, SVM, and GP were reviewed, and future challenges were discussed. Some special-purpose algorithms were listed as follows: GAN, SeDANN, SCNN, K-means, PCA, etc. This review presents the evolution, current status, challenges, and prospects of these technologies in terms of material, features, process parameters, applications, advantages, disadvantages, etc., to explain their significance and provide an in-depth understanding of the same.

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通过机器学习实现粉末床融合

与其他增材制造技术相比，粉末床熔融（PBF）适用于制造各种复杂零件的金属打印过程中使用的各种金属材料。PBF工艺有DMLS（直接金属激光烧结）、EBM（电子束熔化）、SHS（选择性热烧结）、SLM（选择性激光熔化）和SLS（选择性激光烧结）等几种变体。为了使PBF发挥其最大潜力，机器学习（ML）算法与合适的材料一起使用，以经济有效地实现目标。回顾了神经网络的各种应用，包括ann、cnn、rnn和其他流行的技术，如KNN、SVM和GP，并讨论了未来的挑战。列举了一些专用算法：GAN、SeDANN、SCNN、K-means、PCA等。本文从材料、特征、工艺参数、应用、优缺点等方面介绍了这些技术的发展历程、现状、挑战和前景，阐述了它们的意义，并提供了对它们的深入理解。

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来源期刊

Complexity 综合性期刊-数学跨学科应用

CiteScore

5.80

自引率

4.30%

发文量

595

审稿时长

>12 weeks

期刊介绍： Complexity is a cross-disciplinary journal focusing on the rapidly expanding science of complex adaptive systems. The purpose of the journal is to advance the science of complexity. Articles may deal with such methodological themes as chaos, genetic algorithms, cellular automata, neural networks, and evolutionary game theory. Papers treating applications in any area of natural science or human endeavor are welcome, and especially encouraged are papers integrating conceptual themes and applications that cross traditional disciplinary boundaries. Complexity is not meant to serve as a forum for speculation and vague analogies between words like “chaos,” “self-organization,” and “emergence” that are often used in completely different ways in science and in daily life.