Abstract
Free-form surfaces have been widely used in complex optical devices to improve the functional performance of imaging and illumination quality and reduce sizes. Ultra-precision grinding is a kind of ultra-precision machining technology for fabricating free-form surfaces with high form accuracy and good surface finish. However, the complexity and variation of curvature of the free-form surface impose a lot of challenges to make the process more predictable. Tool path as a critical factor directly determines the form error and surface quality in ultra-precision grinding of free-form surfaces. In conventional tool path planning, the constant angle method is widely used in machining free-form surfaces, which resulted in non-uniform scallop-height and degraded surface quality of the machined surfaces. In this paper, a theoretical scallop-height model is developed to relate the residual height and diverse curvature radius. Hence, a novel tool-path generation method is developed to achieve uniform scallop-height in ultra-precision grinding of free-form surfaces. Moreover, the iterative closest-point matching method, which is a well-known algorithm to register two surfaces, is exploited to make the two surfaces match closely through rotation and translation. The deviation of corresponding points between the theoretical and the measured surfaces is determined. Hence, an optimized tool-path generator is developed that is experimentally verified through a series of grinding experiments conducted on annular sinusoidal surface and single sinusoidal surface, which allows the realization of the achievement of uniform scallop-height in ultra-precision grinding of free-form surfaces.
Highlights
With increasing demand of optical and photonic manufacturing industries, many types of high-resolution and compact structure of optical components are widely used for digital cameras, solar concentrator, aspectual illumination system and collimators [1,2,3,4]
Among various ultra-precision machining processes such as single point diamond turning (SPDT), diamond milling, fly cutting, micro-chiseling and ultra-precision diamond grinding, it is interesting to note that the grinding operation is highly capable of machining optical components made of hard and brittle materials than other machining processes due to high efficiency and high accuracy [6]
The tool path generation is vital for determining the surface quality and machining efficiency, which attracts a lot of research attention
Summary
With increasing demand of optical and photonic manufacturing industries, many types of high-resolution and compact structure of optical components are widely used for digital cameras, solar concentrator, aspectual illumination system and collimators [1,2,3,4]. The constant angle is widely used tool path generation strategy in machining complex surfaces [11,12,13], which resulted in non-uniform surface scallop-height. Most of research about tool path control method is based on constant arc-length or operation parameters to study the scallop-height generation, the influence of curvature of the machined surface on the scallop-height generation received little attention. It is vital to develop a tool path generation strategy to achieve constant scallop-height so as to improve surface accuracy. Relationship between the curvature and scallop-height is analyzed theoretically and a new control strategy for the tool path with variable feed speed is proposed, which can be used to achieve uniform scallopheight in ultra-precision grinding of freeform surfaces
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
