Techniques for measuring and compensating for servo mismatch in machine tools using a laser tracker

Servo mismatch, which affects positioning accuracy in computer numerical control (CNC) machine tools, is an important source of error. Dynamic measurements of simultaneous movements in two axes are essential in determining servo mismatch. A circular test using a double ball-bar (DBB) is used commonl...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2017-09, Vol.92 (5-8), p.2919-2928
Main Authors: Lee, Hoon -Hee, Son, Jin-Gwan, Yang, Seung-Han
Format: Article
Language:English
Subjects:
CAE) and Design
Circularity
Compensation
Computer-Aided Engineering (CAD
Cylinders
Devices
Double ball bars
Engineering
Error analysis
Industrial and Production Engineering
Lasers
Machine tools
Machining
Measuring instruments
Mechanical Engineering
Media Management
Numerical controls
Original Article
Positioning devices (machinery)
Quasistatic errors
Roundness
Servocontrol
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Description
Summary:Servo mismatch, which affects positioning accuracy in computer numerical control (CNC) machine tools, is an important source of error. Dynamic measurements of simultaneous movements in two axes are essential in determining servo mismatch. A circular test using a double ball-bar (DBB) is used commonly to assess such errors. However, servo-mismatch measurements of some machine tools, such as miniaturized machine tools, remain difficult due to structural restrictions of the measuring devices. In this study, a technique for servo-mismatch measurement via a bi-directional circular test using a laser tracker is described. The laser tracker is easy to set up experimentally and has fewer measuring range restrictions than other measuring devices. In order to ignore the effects of quasi-static errors, a bi-directional circular test is conducted using the laser tracker. Additionally, a compensation procedure, with a proportional equation, is proposed. The validity of the technique described was confirmed by comparison with the DBB result. In a machining test after servo-mismatch compensation, by adjusting the position loop gain, the roundness of a cylinder part was improved by ∼47.9%.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-017-0382-2