Abstract
The resilience of rotating components, specifically traction sheaves and diverter pulleys in lift installations, is of paramount importance. However, these components frequently undergo fatigue failure due to their exposure to intense cyclic and dynamic loading conditions. Traditional methods for estimating bearing life, which show insufficiency in adapting to the dynamic operating conditions of lifts (such as variable load, speed, and direction), often fail to anticipate these breakdowns. An experimental laboratory rig comprising a rotating disk-shaft assembly with intentionally damaged components emulating real-world scenarios has been designed to address this challenge. Vibration data, representative of actual operational conditions, were systematically captured using accelerometers. This data was then leveraged to extract salient vibration features, which served as inputs to train artificial neural network (ANN) models within a supervised machine learning framework. The trained models have shown the capacity to identify and categorise damage patterns, thereby enabling a comprehensive understanding of fatigue failure mechanisms in these systems. The findings from this research demonstrate the potential for developing robust and efficient condition monitoring methodologies, which could significantly enhance both the longevity and safety of lift installations.
Original language | English |
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Article number | 6 |
Pages (from-to) | 65-72 |
Number of pages | 8 |
Journal | Symposium on Lift & Escalator Technologies |
Volume | 14 |
Publication status | Published - 20 Sept 2023 |
Event | 14th Symposium on Lift & Escalator Technologies - Hilton Northampton, Northampton, United Kingdom Duration: 20 Sept 2023 → 21 Sept 2023 Conference number: 14 https://www.liftsymposium.org/ |
Keywords
- Machine Learning
- Fault
- Pattern Recognition
- Maintenance
- Damage
- Roller Bearings