增材制造的设计修改系统:面向可行的几何发展

S. E. Ghiasian, Prakhar Jaiswal, R. Rai, K. Lewis
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引用次数: 5

摘要

在设计和制造领域,增材制造(AM)在制造独特几何形状方面的重要作用是不可否认的。然而,增材制造技术的成功实施需要组件的几何规格与增材制造能力和约束之间的一致性。否则,增材制造可能导致打印失败和资源浪费。本研究的目标是通过纠正潜在的不可行的几何形状,为增材制造过程提供几何上可行的设计。为此,提出了一种新的设计修改系统,该系统使用适当的重新设计解决方案来解决am不可行的组件的问题区域。该系统还包括一个几何评估算法,该算法通过综合评估来识别潜在的问题部件特征。基于获得的可制造性反馈,通过整体设计修改系统对检测到的问题特征进行修改。通过实例分析说明了系统的功能,并通过实验验证了所实现的修改方法的有效性。
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A Design Modification System for Additive Manufacturing: Towards Feasible Geometry Development
The substantial role of additive manufacturing (AM) in fabricating unique geometries is undeniable in the domain of design and manufacturing. However, the successful implementation of AM technologies requires a consistency between the geometric specifications of a component and AM manufacturability capabilities and constraints. Otherwise, AM could result in failed prints and a wasteful use of resources. The goal of this research is to provide geometrically feasible designs for AM processes by rectifying the potentially infeasible geometries. To this end, a novel design modification system is presented that addresses the problematic areas of an AM-infeasible component using appropriate redesign solutions. This system also includes a geometric assessment algorithm which identifies the potential problematic part features using a comprehensive evaluation. Based on the obtained manufacturability feedback, the detected problematic features are then modified through a holistic design modification system. The functionality of the presented system is illustrated using a case study, and the effectiveness of the implemented modification approaches is also demonstrated through an experiment.
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