Abstract
Fiber optic sensors have been established as one of the best available technologies for acquiring measurements in harsh environments. These sensors are tolerant to extreme temperature, EMI, shock and vibration, and offer reduced weight and increased accuracy over conventional instrumentation. As a result, these sensors have begun to replace conventional sensors in harsh environment applications. The ability to predict the onset of failure in mechanical systems is key to the reduction in maintenance costs, downtime, and health hazards in industrial environments. Vibration monitoring can be used to spot mechanical problems, trigger preventative maintenance and diagnose the health of rotating machinery. Accelerometers are used in this role to detect defects in rotating components through analysis of harmonics in the power-frequency distribution. Further, high frequency acoustic emission sensors can be used to determine crack growth in metal components or failures in composite structures. Currently, a variety of MEMS accelerometers and piezoelectric acoustic emission sensors are used in health monitoring that are limited by their size, cost, and performance. Optical fiber sensors are rapidly emerging as viable alternatives to these devices as effective means of health monitoring. Optical fiber sensors offer much smaller size, reduced weight, ability to operate at temperatures up to 2000°C, immunity to electromagnetic interference, resistance to corrosive environments, inherent safety within flammable environments, and the ability to multiplex multiple sensors on a single optical fiber. This paper presents the research and development of both low-profile fiber optic-based acoustic emissions sensors for non-destructive evaluation systems and accelerometers for monitoring rotating machinery.
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