C. Lapre , D. Brouczek , M. Schwentenwein , K. Neumann , N. Benson , C.R. Petersen , O. Bang , N.M. Israelsen
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引用次数: 0
摘要
在过去十年中,添加制造(AM)工艺的使用迅速增长,如熔融沉积建模和立体光刻技术。3D 打印技术因其灵活性而在陶瓷部件生产方面具有优势。为了提高陶瓷工业的质量并减少资源消耗,需要快速、集成、高分辨率的次表面和无损检测(NDI)。本研究利用基于 4 μm 中心波长中红外超连续激光的中红外光相干断层扫描(MIR OCT),在 400 × 2048 像素的图像中对深度为 ∼ 0.7 mm 的三维打印氧化铝部件进行次表面监测,横向分辨率为 30 μm,轴向分辨率为 7 μm。我们检测了单个印刷陶瓷层,跟踪了所有四个加工步骤中的预定义缺陷,并展示了绿色阶段的缺陷如何影响最终产品。这项研究为将 NDI 集成到 AM 中奠定了基础。
Rapid non-destructive inspection of sub-surface defects in 3D printed alumina through 30 layers with 7 μm depth resolution
The use of additive manufacturing (AM) processes has grown rapidly over the last ten years like fused deposition modelling and stereolithography techniques. 3D printing offers advantages in ceramic component production due to its flexibility. To enhance quality and reduce resource consumption in ceramics industry, fast, integrated, sub-surface and non-destructive inspection (NDI) with high resolution is needed. This study demonstrates sub-surface monitoring of 3D printed alumina parts to a depth of ∼0.7 mm in images of 400 × 2048 pixels with a lateral resolution of 30 μm and axial resolution of 7 μm, using mid-infrared optical coherence tomography (MIR OCT) based on a 4 μm center wavelength MIR supercontinuum laser. We detected individual printed ceramic layers and tracked predefined defects through all four processing steps and demonstrated how a defect in the green phase could affect the final product. This research sets the stage for NDI integration in AM.
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