精密玻璃成型模具材料的评价

M. Friedrichs, T. Grunwald, T. Bergs
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引用次数: 5

摘要

在激光技术、生物医药、消费电子等领域广泛应用的推动下,对几何形状复杂、尺寸小的高质量透镜的需求正在迅速上升。由于这种镜片的研磨和抛光既不实际也不经济可行,精密玻璃模压(PGM)已成为一种流行的生产方法。PGM是一种用于中、大批量生产高精度光学镜片的复制技术。在单周期成型过程中,玻璃预制品被加热至粘性状态,然后使用两个高精度成型工具压制成所需的形状。该工艺允许直接和有效地制造高形状精度和表面质量的光学器件,而无需任何机械后处理步骤。PGM工艺的效率主要取决于高精度成型工具的使用寿命。因此,各种研究都集中在提高模具寿命上。这项工作的重点是评估合适的模具材料的PGM,其中不同的基材和保护涂层被考虑。在此基础上,研究了三种不同成型温度的玻璃:普通光学玻璃、红外透射硫系玻璃和熔融二氧化硅玻璃。普通光学玻璃的成型温度范围为400°C至700°C,而硫化物玻璃的成型温度约为250°C。熔融二氧化硅需要更具挑战性的成型温度约1400°C。由于不同的成型温度,不同的模具材料可以评估每一个研究的玻璃。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of mold materials for precision glass molding
Driven by the wide range of applications in the fields of laser technology, biomedicine and consumer electronics, etc., the demand for high-quality lenses with complex geometries and small dimensions is rapidly rising. Since grinding and polishing of such lenses is neither practically nor economically viable, Precision Glass Molding (PGM) has become a popular production method. PGM is a replicative technology for producing high-precision optical lenses in medium or high volumes. During the one-cycle molding process, a glass preform is heated until the viscous state and afterwards pressed into the desired shape using two high-precise molding tools. This process permits the direct and efficient manufacture of high shape accuracy and surface quality optics without any mechanic post-processing step. The efficiency of PGM processes depend primarily on the lifetime of the high-precision molding tools. Therefore, various investigations focus on enhancing the molding tool lifetime. This work focuses on the evaluation of suitable mold materials for PGM, whereby different substrate materials as well as protective coatings are considered. At this, three different kinds of glass with varying molding temperature were investigated: common optical glass, infrared transmissive chalcogenide glass, and fused silica. The molding temperature of common optical glass ranges from 400°C to 700°C, whereas chalcogenide glass is molded at around 250°C. Fused silica requires a more challenging molding temperature of about 1400°C. Due to the varying molding temperatures, different mold materials can be evaluated for each of the investigated glasses.
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