TY - GEN

T1 - Introduction to an Adaptive Remaining Useful Life Prediction for forming tools

AU - Kellermann, Christoph

AU - Munderloh, Marco

AU - Neumann, Eric

AU - Adhisantoso, Yeremia Gunawan

AU - Ostermann, Jörn

PY - 2021

Y1 - 2021

N2 - As key components in the field of industry 4.0, data of sensors is often used for checking and observing the quality of subsystems. In modern manufacturing environments this huge amount of data enables machine health monitoring tools to analyze the behavior of mechanical components over time e.g. to estimate the remaining useful life (RUL) before breakdown. In this paper a system based on an autoencoder alike structure to forecast the deterioration of components is introduced. It is capable to predict the RUL based on the historical stress and usage conditions and identify anomalies like occurring faults by predicting the future with the encoder part, projecting it backwards with the decoder part, and then comparing it with the original data. The degradation forecast is estimated with respect to direct measurable parameters and not using a virtual health index. Our approach estimates the RUL on limited and noisy data and does not require knowledge of the true RUL. With the proposed setup our model is scalable to other production line configurations and product derivatives with different given production or quality thresholds without the need of a new training. We use real process data as well as synthetic signals for the training of the neural networks to improve the performance. We evaluate and demonstrate the performance of our RUL estimation approach against established forecast methods in the field of glass forming processes. We show that our approach of time series prediction in comparison to established prediction methods like RANSAC or ARIMA which require background knowledge delivers comparable accuracy and can additionally predict abnormal behavior.

AB - As key components in the field of industry 4.0, data of sensors is often used for checking and observing the quality of subsystems. In modern manufacturing environments this huge amount of data enables machine health monitoring tools to analyze the behavior of mechanical components over time e.g. to estimate the remaining useful life (RUL) before breakdown. In this paper a system based on an autoencoder alike structure to forecast the deterioration of components is introduced. It is capable to predict the RUL based on the historical stress and usage conditions and identify anomalies like occurring faults by predicting the future with the encoder part, projecting it backwards with the decoder part, and then comparing it with the original data. The degradation forecast is estimated with respect to direct measurable parameters and not using a virtual health index. Our approach estimates the RUL on limited and noisy data and does not require knowledge of the true RUL. With the proposed setup our model is scalable to other production line configurations and product derivatives with different given production or quality thresholds without the need of a new training. We use real process data as well as synthetic signals for the training of the neural networks to improve the performance. We evaluate and demonstrate the performance of our RUL estimation approach against established forecast methods in the field of glass forming processes. We show that our approach of time series prediction in comparison to established prediction methods like RANSAC or ARIMA which require background knowledge delivers comparable accuracy and can additionally predict abnormal behavior.

UR - http://www.scopus.com/inward/record.url?scp=85114961508&partnerID=8YFLogxK

U2 - 10.1109/aim46487.2021.9517557

DO - 10.1109/aim46487.2021.9517557

M3 - Conference contribution

SN - 978-1-6654-4140-7

T3 - IEEE/ASME International Conference on Advanced Intelligent Mechatronics, AIM

SP - 1297

EP - 1302

BT - 2021 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM)

ER -