Imaging quality 3D-printed inch scale lenses with 10[angstrom] surface quality for swift small or medium volume production (Conference Presentation)

Organic Photonic Materials and Devices XXI Pub Date : 2019-03-05 DOI:10.1117/12.2506010

Bisrat G. Assefa, Henri Partanen, Markku Pekkarinen, Joris Biskop, J. Turunen, J. Saarinen

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Abstract

The demand for disposable optics, especially in biomedical fields involving point of care testing systems has led to navigation for new low-cost and high quality optics fabrication processes. We demonstrate that 3D-printing of optics allows on-demand fabrication of polymer lenses at a low price, when no expensive initial tooling expenses are required. However, achieving high surface quality imaging optics has been challenging primarily when the lens diameter is greater than fivefold of a millimeter. In this work, we demonstrate an imaging quality 3D-printed polymer lens with high surface quality of RMS = 0.92 ± 0.33 nm (δ, N=25) and surface profile deviation of ± 500 nm within 0.5 inch aperture diameter. The 3D-printing method is based on Luxexcel’s Printoptical® Technology, using modified ink-jet printheads, by depositing micro-droplets of Opticlear, which is a UV-curable polymer with an inhomogeneity index of 1.1-1.3×10-5 for 0.5 mm plate. We demonstrate a spatial resolution limit below 5 μm using a USAF1951-1x imaging resolution target for the 3D-printed singlet lens that is comparable to an off-the shelf commercial LA1509 N-BK7 plano-convex lens with the same specification parameters. Another application area of the inch-scale printed lens is in low-cost DSLR cameras. Experimental photos taken with a 3D-printed singlet lens and a commercial glass lens are nearly identical. As a result, manufacturing of 3D-printed singlet lenses with repeatability of ±200 nm for small or medium volume production at once becomes feasible by placing the printheads in parallel. We expect further developments towards achromatic optics by development of new 3D-printable polymers.

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成像质量10[埃]表面质量的3d打印英寸级镜头，用于快速中小批量生产(会议演示)

对一次性光学器件的需求，特别是在涉及护理点测试系统的生物医学领域，导致了新的低成本和高质量光学制造工艺的发展。我们证明，光学的3d打印允许按需制造聚合物透镜以低价格，而不需要昂贵的初始工具费用。然而，当透镜直径大于五倍毫米时，实现高表面质量成像光学一直具有挑战性。在这项工作中，我们展示了具有成像质量的3d打印聚合物透镜，其表面质量RMS = 0.92±0.33 nm (δ， N=25)，在0.5英寸孔径内表面轮廓偏差为±500 nm。3d打印方法基于Luxexcel的Printoptical®技术，使用改进的喷墨打印头，通过沉积Opticlear微滴，这是一种紫外线固化的聚合物，0.5 mm板的不均匀性指数为1.1-1.3×10-5。我们演示了使用USAF1951-1x成像分辨率目标的3d打印单线透镜的空间分辨率限制低于5 μm，其可与具有相同规格参数的现成商用LA1509 N-BK7平凸透镜相媲美。英寸级印刷镜头的另一个应用领域是低成本的数码单反相机。用3d打印单线透镜和商用玻璃透镜拍摄的实验照片几乎完全相同。因此，通过将打印头平行放置，可以同时制造具有±200nm重复性的小批量或中等批量生产的3d打印单线透镜。我们期望通过开发新的3d打印聚合物进一步发展消色差光学。

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Organic Photonic Materials and Devices XXI

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