How to Boost Machining, Milling Processes
Wednesday, January 25, 2017 @ 03:01 PM gHale
Fixing flaws introduced during the machining of large components used in the aircraft and heavy equipment industries can be time-consuming for manufacturers – and costly if they end up scraping the parts after fabrication.
That may soon change. That is because a new approach developed by researchers at Missouri University of Science and Technology is helping manufacturers eliminate those flaws before the parts end up created.
This new approach can greatly improve the accuracy of five-axis machine tools used to fabricate large parts.
Five-axis machine tools are computer-numerically controlled (CNC) machines that can move, cut or mill a part on five different axes at the same time. This allows manufacturers to create complex contours or curves when creating a large part, such as an aircraft wing.
“Five-axis machine tools are known to have 41 basic geometric errors,” said Jennifer Creamer, a Ph.D. student in mechanical engineering at Missouri S&T and the lead author of a paper on the subject.
As Dr. Robert G. Landers, professor of mechanical and aerospace engineering and a co-author of the paper, said, “The way you want the machine to move (when making a large part) is different than the way it actually moves due to inherent geometric errors.”
Because of these errors, manufacturers must make adjustments in calibrating their CNC machines.
Several different approaches exist to help compensate for those errors, but none of them provides a complete picture, Creamer said. Manufacturers must combine various methods to get the best sense of a milling problem. The result, she said, is “a piecemeal approach that makes calibration a time-consuming and expensive process.”
Along those lines, Creamer set out to find a way to eliminate that piecemeal approach and develop a new model for capturing complicated geometric errors while also automatically generating compensation tables for those errors. A compensation table is a kind of map of errors that can end up programmed into a CNC machine to reduce errors.
Flaws in the fabrication of large parts may seem insignificant given the large size of the parts, but they can be problematic. Parts for airplanes, for example, can be 120 feet long, and their size can make holding tight tolerances problematic, Landers said.
In Creamer’s research on five-axis machine tools, “She’s trying to hold errors to five thousandths of an inch over 120 feet,” he said.
In collaboration with colleagues at Boeing Research and Technology in St. Louis, where she works as an engineer, Creamer used a laser tracker to quickly measure the motion of all axes over the entire workspace of an industrial five-axis machine. Based on these measurements, she generated a set of compensating tables that could end up used to improve the accuracy on a variety of machine tools and related platforms.
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