Development of a wireless sensor for vibration measurement I
This report outlines the design, development, and implementation of a novel wireless sensor system dedicated to the measurement of vibrations in diverse environments. The primary objective of this project was to create a versatile and efficient tool capable of wirelessly monitoring vibrations in...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/176569 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This report outlines the design, development, and implementation of a novel wireless sensor system
dedicated to the measurement of vibrations in diverse environments. The primary objective of this
project was to create a versatile and efficient tool capable of wirelessly monitoring vibrations in real time, providing valuable data for various applications, including monitoring vibrations on railway tracks.
The passage of trains over railway tracks generates vibrations that can have significant effects on both
the infrastructure and nearby surroundings. One of the effects is track Degradation. Repeated train
passages contribute to wear and tear on the tracks, leading to track degradation over time. This may
result in increased maintenance requirements and associated costs.
The wireless sensors incorporate accelerometers and wireless communication technology to enable
seamless and remote data acquisition. Utilizing low-power consumption components, the sensor
ensures prolonged battery life while maintaining accurate and reliable measurements. The wireless
capability allows for flexible deployment in hard-to-reach or hazardous locations, facilitating
comprehensive monitoring without the need for extensive wiring. The development process involved
thorough testing procedures with shaker systems to validate the sensor's performance and accuracy
across a range of vibration frequencies and amplitudes. A series of tests such as sweep sine test, dwell
sine test, classical shock test and random shock test were conducted. Results from various vibration
test demonstrate the sensor's effectiveness in providing real-time vibration data, showcasing its
potential for applications in predictive maintenance, structural analysis, and environmental monitoring.
The wireless connectivity not only streamlines data collection but also enhances the scalability of the
sensor network for large-scale deployments.
In conclusion, the presented wireless vibration sensor system represents a significant advancement in
the field of sensor technology, offering a reliable and versatile solution for monitoring vibrations in
diverse settings. The findings of this research contribute to the ongoing efforts in improving the
efficiency and accessibility of sensor systems for a wide range of applications |
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