L. Spitaels, Endika Nieto Fuentes, Valentin Dambly, E. Rivière-Lorphèvre, P. Arrazola, F. Ducobu
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引用次数: 0
摘要
了解制造过程的公差间隔能力(TIC)是最重要的,尤其是当制造商与客户之间存在规格关联时。这些 TIC 可以使用 ISO 22514 的机器性能概念来确定。然而,很少有人将其应用于快速成型制造打印机,而按照建议对大部分打印区域进行测试需要很长时间(通常需要近 1 个月)。本文提出了一种名为 COMPAQT(快速机器性能评估组件)的新型部件设计,旨在提供相同水平的打印区域覆盖率,同时将制造时间控制在 24 小时以内。它可以确定潜在和实际的机器公差间隔能力。与特征尺寸无关,以 X 轴对齐的 TIC 值低于以 Y 轴对齐的 TIC 值,而以 Z 轴对齐的 TIC 值表现最佳。针对一个工件的测量显示出以 0 毫米 ± 0.050 毫米为中心的系统误差,而涉及两个工件的测量显示出高达 0.314 毫米的偏差。COMPAQT 可用于两种应用:评估打印机的公差间隔能力,以及通过将其纳入其他零件批次来跟踪其长期性能。
Faster Evaluation of Dimensional Machine Performance in Additive Manufacturing by Using COMPAQT Parts
Knowing the tolerance interval capabilities (TICs) of a manufacturing process is of prime interest, especially if specifications link the manufacturer to a customer. These TICs can be determined using the machine performance concept of ISO 22514. However, few works have applied this to Additive Manufacturing printers, while testing most of the printing area as recommended takes a very long time (nearly 1 month is common). This paper, by proposing a novel part design called COMPAQT (Component for Machine Performances Assessment in Quick Time), aims at giving the same level of printing area coverage, while keeping the manufacturing time below 24 h. The method was successfully tested on a material extrusion printer. It allowed the determination of potential and real machine tolerance interval capabilities. Independently of the feature size, those aligned with the X axis achieved lower TICs than those aligned with the Y axis, while the Z axis exhibited the best performance. The measurements specific to one part exhibited a systematic error centered around 0 mm ± 0.050 mm, while those involving two parts reached up to 0.314 mm of deviation. COMPAQT can be used in two applications: evaluating printer tolerance interval capabilities and tracking its long-term performance by incorporating it into batches of other parts.