Spall Fault Quantification Method for Flight Control Electromechanical Actuator

Mohamed A A Ismail,Jens Windelberg,Edward Balaban

doi:10.3390/act11020029

Mohamed A A Ismail, Jens Windelberg + Show 1 more

Open Access

https://doi.org/10.3390/act11020029

Copy DOI

Journal: Actuators	Publication Date: Jan 20, 2022
Citations: 6	License type: CC BY 4.0

Affiliation: German Aerospace Center, Ames Research Center

Abstract

Flight control electro-mechanical actuators (EMAs) are among the primary onboard systems that significantly influence the reliability and safety of unmanned aerial vehicles. Recent reliability studies have shown that the ball-screw element of a flight control EMA is subject to oscillating operating conditions that may initiate rapid degradation, such as fatigue spall defects. Accordingly, detecting and quantifying such faults are crucial for developing efficient fault prognostic and remaining useful life estimation capabilities. In this study, a vibration-based fault quantification method is developed to quantify the fatigue faults of a ball-screw mechanism of an EMA. The method is based on identifying the ball passing instants through a localized surface defect on the vibrational jerk rather than the vibrational acceleration measurement. The jerk is numerically determined from conventional accelerometers using a Savitzky–Golay differentiator. This method was successfully tested for ball bearings and it is adjusted in this paper for ball-screw faults. The experimental validation is investigated on a set of fault-seeded samples on NASA’s Ames Research Center Flyable Electro-Mechanical Actuator test stand.

Highlights

There are many growing civil and military applications for unmanned aerial vehicles (UAVs) due to their low acquisition and operating costs
The focus is on flight control electro-mechanical actuators (EMAs) because their failures have a significant impact on the total system failures of in-service UAVs, according to US Office of the Secretary of Defense [3]
A vibration method was developed for quantifying spall fatigue faults for ball-screw based flight control EMAs

Summary

Introduction

There are many growing civil and military applications for unmanned aerial vehicles (UAVs) due to their low acquisition and operating costs. The reliability of inservice UAVs does not match the superior levels of general aviation [1,2] signaling that the root causes should be identified and mitigated by health monitoring systems. The focus is on flight control electro-mechanical actuators (EMAs) because their failures have a significant impact on the total system failures of in-service UAVs, according to US Office of the Secretary of Defense [3]. Several reliability studies have been conducted to identify the potential components and failure modes for health monitoring systems. The study in [4] emphasized that ball-screw failures are responsible for 16% of the total mechanical failures during accelerated run-to-failure tests for flight control EMAs

Methods

Results

Conclusion