Toward high-efficiency multi-material additive manufacturing: a two-step hybrid fabrication strategy

IF 8.8 1区工程技术 Q1 ENGINEERING, MANUFACTURING

Virtual and Physical Prototyping Pub Date : 2025-07-25 DOI:10.1080/17452759.2025.2534466

Zhengda Chen, Da‐Wei Fu, Xiang‐Jun Zha, Huan Qi, Jigang Huang

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引用次数: 0

Abstract

Multi-material objects enable the integration of diverse properties and functionalities through precise three-dimensional material arrangement. Recent research highlights additive manufacturing as a pioneering approach for fabricating these complex structures, offering unprecedented control over spatial material distribution. However, it faces significant limitations when producing multi-material objects in the traditional layer-by-layer manner, as the approach requires frequent material switching, making the process prohibitively time-consuming. In this work, we present a two-step multi-material additive manufacturing strategy which achieves the fabrication of multi-material objects by capillary-driving the materials into the pre-printed framework and curing them with external energy sources. This strategy fundamentally eliminates the frequent material switching that occurs in traditional multi-material printing, thereby significantly enhancing the manufacturing efficiency of multi-material objects. Moreover, this strategy accommodates materials previously incompatible with conventional 3D printing. Tailored mechanical properties of multi-material structures can be achieved by adjusting the porosity and position of the framework. By adding stimulus-responsive materials into the multi-material structure, the strategy also enables 4D printing. This strategy opens a new avenue for the development of multi-material additive manufacturing.

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迈向高效多材料增材制造：两步混合制造策略

多材料对象通过精确的三维材料排列，实现了多种特性和功能的集成。最近的研究突出了增材制造作为制造这些复杂结构的开创性方法，提供了前所未有的空间材料分布控制。然而，当以传统的逐层方式生产多材料物体时，它面临着显着的局限性，因为该方法需要频繁的材料切换，使得该过程非常耗时。在这项工作中，我们提出了一种两步多材料增材制造策略，该策略通过毛细管驱动材料进入预打印框架并使用外部能量固化材料来实现多材料物体的制造。该策略从根本上消除了传统多材料印刷中频繁的材料切换，从而显著提高了多材料对象的制造效率。此外，这种策略可以适应以前与传统3D打印不兼容的材料。通过调整骨架的孔隙率和位置，可以实现多材料结构的定制力学性能。通过将刺激响应材料添加到多材料结构中，该策略还可以实现4D打印。这一战略为多材料增材制造的发展开辟了新的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Virtual and Physical Prototyping Engineering-Industrial and Manufacturing Engineering

CiteScore

13.60

自引率

6.60%

发文量

期刊介绍： Virtual and Physical Prototyping (VPP) offers an international platform for professionals and academics to exchange innovative concepts and disseminate knowledge across the broad spectrum of virtual and rapid prototyping. The journal is exclusively online and encourages authors to submit supplementary materials such as data sets, color images, animations, and videos to enrich the content experience. Scope: The scope of VPP encompasses various facets of virtual and rapid prototyping. All research articles published in VPP undergo a rigorous peer review process, which includes initial editor screening and anonymous refereeing by independent expert referees. This ensures the high quality and credibility of published work.

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