在3d打印产品中快速,精益和敏捷,多参数多趋势健壮的质量筛选

IF 3.9 Q2 ENGINEERING, INDUSTRIAL
George Besseris
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引用次数: 1

摘要

增材制造(AM)已经彻底改变了高度可定制物品的本地生产实现。然而,AM操作固有的高工艺复杂性使得最终产品的质量性能不确定。因此,通常需要评估增材制造的独特制造能力,以应对过程不稳定和最终产品不一致的反复出现的问题。改进机会可以通过经验探索调节最终产品质量性能的复杂现象来确定。因此,重点质量筛选和工艺优化研究还应考虑到对快速、实用和经济实验的特殊需要。鲁棒多因子解算器应该通过依赖小样本来预测效应强度,同时可能处理非线性和非正态趋势。我们提出了对经典田口方法的非参数修改,以便能够为任意3d打印过程生成快速且稳健的筛选/优化预测。新方法在最近发表的数据集中得到阐明,该数据集涉及熔融沉积工艺的困难田口筛选/优化应用。我们比较了两种方法在预测效应强度量级上的差异。我们评论了新技术可能比传统的基于田口的改进分析提供的实际优势。重点放在“无假设”方面,这体现在新的求解器中。结果表明,该工具是敏捷的。它还可以通过提供强大和更快的质量改进预测,可靠地支持定制的3d打印过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fast, lean-and-agile, multi-parameter multi-trending robust quality screening in a 3D-printed product

Additive manufacturing (AM) has revolutionized the local production realization of highly customizable items. However, the high process complexity - inherent to AM operations - renders uncertain the quality performance of the final products. Consequently, there is often a need to assess the unique fabrication capabilities of AM against the reoccurring issues of process instability and end-product inconsistency. Improvement opportunities may be identified by empirically exploring the complex phenomena that regulate the quality performance of the final products. Thus, focused quality-screening and process optimization studies should additionally take into account the special need for speedy, practical and economical experimentation. Robust multi-factorial solvers should predict effect strength by relying on small samples while possibly dealing with non-linear and non-normal trends. We propose a nonparametric modification to the classical Taguchi method in order to enable the generation of rapid and robust screening/optimization predictions for an arbitrary 3D-printing process. The new methodology is elucidated in a recently published dataset that involves the difficult Taguchi screening/optimization application of a fused deposition process. We compare differences in the predicted effect-strength magnitudes between the two approaches. We comment on the practical advantages that the new technique might offer over the traditional Taguchi-based improvement analysis. The emphasis is placed on the ‘assumption-free’ aspect, which is embodied in the new solver. It is shown that the proposed tool is agile. It could also reliably support a customized 3D-printing process by offering robust and faster quality improvement predictions.

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来源期刊
Advances in Industrial and Manufacturing Engineering
Advances in Industrial and Manufacturing Engineering Engineering-Engineering (miscellaneous)
CiteScore
6.60
自引率
0.00%
发文量
31
审稿时长
18 days
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