采用创新的坐标磨削技术进行高精度玻璃加工

Anett Jahn, O. Seidel, A. Helming
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摘要

技术系统不断缩小 而功能有待改进。 对 高技术部件的要求超出了生产技术的可行极限。集成的精密组件必须满足不断增长的需求 关于 光学和几何特性。 传统的玻璃加工技术往往无法承受这些要求。研磨、研磨和抛光工艺 在单独的机器上 实现。因此,在机器和机器运动学的约束之间手动改变组件导致精度的重大损失以及设计和功能的限制。  为了满足要求,ShapeFab开发了一种更高效的制造工艺 ,用于玻璃制成的高精度部件。 所有以前分离的制造步骤组合在一台机器上。通过高精度五轴数控 跳汰磨削 和 相应的 集成CAD-CAM链,可以将精加工和抛光工艺充分 结合起来。 这 导致光学有效表面的应用几乎任何几何元素。此外,由于高度自动化的过程,即使在小批量生产中,复杂几何形状的加工也可以加速。  通过 我们的 技术,新一代组件 结构从300 μm  是可用的。高精度零件可以设计得更小, 更轻, 多功能。 例如,固定几何图形可以直接 集成 在光学功能 和自由形状 区域。 这使得元件能够以 μm的精度集成到最终应用中,即使没有夹具或进一步的调整元件。 整个技术系统可以设计紧凑,并且可以节省额外机械部件的成本。  应用几乎可以在光子学的所有领域找到。特别是半导体行业, 光学,医疗技术和激光技术的要求可以 满足。
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High-precision glass processing with innovative coordinate grinding technology
Technical systems are constantly getting reduced in size while functions are to be improved. The requirements for hightech components exceed the feasible limits of production technologies. Integrated precision components must meet everincreasing demands with regard to optical and geometric properties. Conventional technologies of glass machining often cannot withstand these requirements. Grinding, lapping and polishing processes are realized on separate machines. Thus, the manual change of components between the machines and constraints in machine kinematics result in significant loss of accuracy as well as restrictions in design and functionality.   To meet the requirements, ShapeFab developed a more efficient manufacturing process for high-precision components made of glass. All previously separated manufacturing steps are combined on one machine. By means of high-precision 5- axis CNC jig grinding and corresponding integration of CAD-CAM chain, processes of finest machining and polishing can be fully combined. This leads to application of optically effective surfaces to almost any geometrical element. In addition, the machining of complex geometries can be accelerated due to highly automated processes, even in low volume production.   With our technology a new generation of components with structures from 300 μm is available. High-precision parts can be designed smaller, lighter and multifunctional. For example, fixing geometries can be directly integrated in optical functional and freeform areas. This allows the components to be integrated into the final application with μm-precision, even without fixtures or further adjustment elements. The whole technical system can be designed compactly and costs for additional mechanical components can be saved.   Applications can be found in almost all areas of photonics. Especially requirements from the semiconductor industry, optics, medical technology and laser technology can be fulfilled.
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