Sand C, Kawan S, Lechler T, Neher M, Schweigert D, Franke J (2017)
Publication Language: English
Publication Type: Conference contribution, Conference Contribution
Publication year: 2017
Edited Volumes: Applied Mechanics and Materials (Volume 871)
Pages Range: 52-59
Conference Proceedings Title: Applied Mechanics and Materials - Energy Efficiency in Strategy of Sustainable Production III
DOI: 10.4028/www.scientific.net/AMM.871.52
Conventional serial and workshop productions use specific parameter ranges to evaluate the quality of a process. Our research showed that parameters within tolerances do not ensure good quality of the final product due to malicious parameter combinations along the assembly line. Therefore, data sets from assembly processes like force-way or force-time curves and quality measurements are evaluated in this novel approach. Using Fourier Transform, k-means, decision trees and a dynamic envelope curve, classification and process monitoring are processed in time and frequency domain. This enables new possibilities to characterize quality and process data, for advanced error detection as well as a more simplified tracing of faults. Here, holistic optimization and monitoring follows two strategies. First, a simplified tracing approach of malicious impacts regards quality results from test benches. Therefore, assembly processes are monitored and characterized by quality data. Second, defective influences, like tool break or calibration errors, are linked to variations of the usual process behavior. Here, the error detection approach focuses on process data from single assembly stations. This approach uses three different methods. First, Fourier Transform extracts additional information from process, energy and quality data. Second, k-means algorithm is used to cluster quality data and extend the data base. Third, a decision tree classifies the quality of the final good and characterizes assembly processes. Last, results of k-means clustering and selected classification methods are compared. This combination allows to increase process quality, improve product quality and reduce failure costs.
APA:
Sand, C., Kawan, S., Lechler, T., Neher, M., Schweigert, D., & Franke, J. (2017). Potentials for Error Detection and Quality Improvement in Assembly Lines Using FFT, Clustering and Dynamic Envelope Curve. In Trans Tech Publications Ltd (Eds.), Applied Mechanics and Materials - Energy Efficiency in Strategy of Sustainable Production III (pp. 52-59).
MLA:
Sand, Christian, et al. "Potentials for Error Detection and Quality Improvement in Assembly Lines Using FFT, Clustering and Dynamic Envelope Curve." Proceedings of the Applied Mechanics and Materials - Energy Efficiency in Strategy of Sustainable Production III Ed. Trans Tech Publications Ltd, 2017. 52-59.
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