Abstract
Problem: Leakage of the transmission fluid or oil in powertrain systems (i.e., transmissions, cylinder heads, engine blocks, etc.) can cause engine overheating and/or permanent damage. Therefore, it is crucial to run a leak test to inspect for any possible porosity in the casting parts. However, the inspection results for the amount of leakage at given testing times are sensitive to the tested part's temperature, which varies from part to part but was not previously incorporated in the leak testing systems. The objective of this paper is to develop a robust leak testing system that is insensitive to the part temperature variations in real production processes.
Approach: In the production line, a part is tested at a temperature that is generally not equal to the calibration temperature at which the inspection threshold for leakage was set. To achieve a robust leak test that is insensitive to temperature variation in the tested part, we propose a temperature compensation algorithm to adjust the measured leak flow, taking into account the tested part temperature and the calibration temperature. For this purpose, a nonlinear mixed-effect model is first developed for modeling the leak flow profile as a function of both the leak testing time and the part temperature. Then, the fitted mixed-effect model is used to adjust the leak flow based on the calibration temperature. If the amount of the adjusted leakage at the given inspection time exceeds the inspection threshold, the part is rejected; otherwise, the part is accepted.
Results: The proposed compensation algorithm is developed and validated using a set of training samples and another set of test samples, respectively. We use the percentage of error reduction in the leak flow measurements at different temperatures as the criterion to validate the developed compensation algorithm. The results show that the average percentage of error reduction for the test samples is about 92%. This indicates a significant improvement in the leak testing results.
Additional information
Notes on contributors
Kamran Paynabar
Dr. Paynabar is an Assistant Professor in the H. Milton Stewart School of Industrial and Systems Engineering at Georgia Tech. His email address is [email protected].
Jionghua (Judy) Jin
Dr. Jin is a Professor in the Department of Industrial and Operations Engineering. Her email address is [email protected].
John Agapiou
Dr. John Agapiou is a technical fellow at the General Motors Research & Development Center. His email address is [email protected].
Paula Deeds
Ms. Deeds is an engineering manager at the General Motors Casting, Engine and Transmission Center. Her email address is [email protected].