Physics-based vibration feature for detecting eccentric workpiece/runout faults during continuous generating gear grinding processes

•Qualitative model to reveal vibration signature of eccentric workpiece/run-out faults during gear grinding.•Novel feature is defined based on the qualitative model.•Signal processing steps to extract the novel feature are proposed.•The developed feature is experimentally validated on a production m...

Full description

Saved in:
Bibliographic Details
Published in:Mechanical systems and signal processing 2021-05, Vol.153, p.107536, Article 107536
Main Authors: Ompusunggu, Agusmian Partogi, Vonderscher, Yann, Motl, Daniel
Format: Article
Language:English
Subjects:
Continuous generating gear grinding
Eccentricity
Fault detection
Feed rate
Gear grinding machines
Gear teeth
Grinding
Grinding machines
Hilbert transform
Instantaneous envelope
Instantaneous frequency
Malfunctions
Quality control
Robustness
Run-out error
Signal processing
Surface properties
Vibration monitoring
Workpiece eccentricity error
Workpieces
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Qualitative model to reveal vibration signature of eccentric workpiece/run-out faults during gear grinding.•Novel feature is defined based on the qualitative model.•Signal processing steps to extract the novel feature are proposed.•The developed feature is experimentally validated on a production machine at different test conditions.•The feature is robust and reliable for detecting eccentric workpiece/run-out faults of more than about 60 µm. Continuous generating gear grinding is a well-established and widely used process in the industry for large-scale production gears. It offers an economic/efficient process for finishing gears, which shapes the micro-geometry of the gear tooth flank and improves its surface quality. The resulting quality of ground gears depends on several factors, namely the tool performance, the machine stability as well as the correct clamping/positioning of the workpiece. The grinding step is very crucial since it has a direct impact on the operating quality of gears and in particular on the running noise behaviour of the end product. The potential of online vibration-based gear grinding monitoring has been explored and demonstrated in the previous work (Gryllias et al., 2017) as a means of quality control that could lead to the overall reduction of production losses and to the prevention of sending defective parts to customers. Several features which could be used to monitor the grinding processes and to identify a specific type of defects have been proposed & experimentally validated to some extent. The types of faults include (i) high feed rate, (ii) high infeed, (iii) non-flat workpiece, and (iv) eccentric workpiece. However, a further investigation on a new test campaign revealed that none of the features developed in (Gryllias et al., 2017) was robust enough to detect eccentric workpieces during the grinding process. It is worth mentioning here that an eccentric workpiece fault is unlikely to happen, but it is analogous to a runout on the incoming workpiece quality. In this paper, a qualitative model to predict the vibration signature due to eccentric workpieces/runouts is developed and discussed. Based on the qualitative understanding, a novel feature to detect eccentric workpieces/runouts during gear grinding processes based on vibration signals has been developed. The newly developed feature has been validated on real vibration signals captured during the emulation of process malfunctions on an industrial gear grinding mach
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2020.107536