A Practical Evaluation Approach to Form Deviation for Surface of Revolution Based on Discrete Point Coordinate Data

Hua Qiu; Akio Kubo

doi:10.4028/www.scientific.net/AMM.217-219.2440

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A Practical Evaluation Approach to Form Deviation for Surface of Revolution Based on Discrete Point Coordinate Data
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 217-219A Practical Evaluation Approach to Form Deviation...

A Practical Evaluation Approach to Form Deviation for Surface of Revolution Based on Discrete Point Coordinate Data

Abstract:

This paper proposes a practical evaluation approach to form deviation for surface of revolution based on discrete point coordinate data. An approximate curve composed of circular arc segments decided from an optimal interpolation process is accepted for computing the form deviation at measured points instead of the generating line of the surface to be inspected. This operation significantly simplifies the algorithm and improves the efficiency in the evaluation calculation. At the same time, it is also guaranteed that the difference of both form deviation values relative to the approximate surface or to the original surface is restricted within the specified accuracy in the circular arc interpolation operation. The effectiveness and efficiency of the approach are verified through a practical example of the surface of revolution with a generating line in the form of cubic Bézier curve.