Pipeline Structural Health Monitoring Using Macro-fiber Composite Active Sensors

Thien, Andrew B.

doi:10.2172/883462

Cited by 21 publications

(17 citation statements)

References 33 publications

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“…This allow us to achieve the required accuracy in the time domain, without the need for further processing of the samples by the DSP. As for the data processing, the computational characteristics and the configurability of the DSP enables the node to run most of the analysis algorithms typically needed [32]. However, for test purposes we have successfully implemented a fast fourier transform (FFT) which is an essential component of SHM algorithms.…”

Section: Requirementsmentioning

confidence: 99%

“…Thus there is no clear SHM algorithm that outperforms any other. However, we have chosen a representative SHM algorithm used at LANL in our evaluation [32] [4]. Figure 10 summarizes its operation.…”

Section: Dspmentioning

confidence: 99%

“…Given our energy self-sufficiency corresponding to 15 minutes of computation time, we can process multiple actuate-and-sense paths without any difficulty. An accurate damage localization can be achieved by sensing less than 10 paths [32].…”

Section: Dspmentioning

confidence: 99%

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Active sensing platform for wireless structural health monitoring

Musiani

Lin

Rosing

2007

Proceedings of the 6th International Conference on Information Processing in Sensor Networks - IPSN '07

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This paper presents SHiMmer, a wireless platform for active sensing that combines localized processing with energy harvesting to provide long-lived structural health monitoring. The life-cycle of the node is extended to 20 years by the use of super-capacitors for energy storage. During this period the node is expected to work completely maintenance-free. The node is capable of harvesting up to 780J per day. This makes it completely self-sufficient while employed in real structural health monitoring applications. Unlike other sensor networks that periodically monitor a structure and route information to a base station, our device acquires the data and processes it locally after being radio-triggered by an external agent. The localized processing allows us to avoid issues due to network congestion. Our experiments show that its 32-bits computational core can run at 100MIPS for 15 minutes daily.

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Section: Requirementsmentioning

confidence: 99%

Section: Dspmentioning

confidence: 99%

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Active sensing platform for wireless structural health monitoring

Musiani

Lin

Rosing

2007

Proceedings of the 6th International Conference on Information Processing in Sensor Networks - IPSN '07

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“…Additionally, the MFC uses interdigitated electrodes that capitalize on d33 effect piezoelectric coupling coefficient, allowing it to produce higher forces and strain than typical monolithic piezo-ceramic materials [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Feasibility of MFC (Macro-Fiber Composite) Transducers for Guided Wave Technique

Ren¹,

Yun²,

Seo³

et al. 2013

Journal of the Korean Society for Nondestructive Testing

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Since MFC(macro-fiber composite) transducer has been developed, many researchers have tried to apply this transducer on SHM(structural health monitoring), because it is so flexible and durable that it can be easily embedded to various kinds of structures. The objective of this paper is to figure out the benefits and feasibility of applying MFC transducers to guided wave technique. For this, we have experimentally tested the performance of MFC patches as transmitter and sensors for excitation and reception of guided waves on the thin aluminum alloy plate. In order to enhance the signal accuracy, we applied the FIR filter for noise reduction as well as used STFT(short-time Fourier transform) algorithm to image the guided wave characteristics clearly. From the results, the guided wave generated based on MFC showed good agreement with its theoretical dispersion curves. Moreover, the ultrasonic Lamb wave techniques based on MFC patches in pitch-catch manner was tested for detection of surface notch defects of which depths are 10%, 20%, 30% and 40% of the aluminum plate thickness. Results showed that the notch was detectable well when the notch depth was 10% of the thickness or greater.

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“…objective, the architecture of the node has been structured in such a As for the data processing, the computational characteristics and the way that the power consumption be near zero during the phase of configurability of the DSP enables the node to run most of the inactivity, corresponding to most of the day. This has been achieved analysis algorithms typically needed [32]. However, for test both by an accurate choice of components and by the purposes we have successfully implemented a fast fourier transform implementation of power-aware solutions in the node architecture.…”

Section: Introductionmentioning

confidence: 99%

Active Sensing Platform for Wireless Structural Health Monitoring

Musiani¹,

Lin²,

Rosing³

2007

2007 6th International Symposium on Information Processing in Sensor Networks

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In order to monitor structures with a high degree of accuracy, it is This paper presents SHiMmer, a wireless platform for sensing and often required to instrument the structure with a high density of actuation that combines localized processing with energy harvesting sensors. The installation of a wired sensor network can be to provide long-lived structural health monitoring. The life-cycle of prohibitively expensive, since it may require changes to the the node is significantly extended by the use of super-capacitors for structure itself (e.g. drilling holes in walls) and take several months energy storage instead of batteries. During this period the node is in big buildings and infrastructures. By contrast, wireless sensor expected to work completely maintenance-free. The node is capable networks provide structural engineers with a cheap and effective of harvesting up to 780J per day. This makes it completely selfway to instrument a structure and collect data regarding it, by sufficient while employed in real structural health monitoring eliminating the need to cable the structure under test. applications. Unlike other sensor networks that periodically monitor Wireless sensor networks, however, also create complexities of their a structure and route information to a base station, our device own. In particular, sensor nodes have severe energy constraints. acquires the data and processes it locally after being radio-triggered Battery-powered sensor nodes need periodical human intervention, by an external agent. The localized processing allows us to avoid in order to recharge or replace batteries. The life-cycle of batteries is issues due to network congestion. Our experiments show that its 32-only a few years. Some solutions allow the life-cycle to be extended bits computational core can run at IOOMIPS for 15 minutes daily.[7] [30], but after 10 years their capacity is reduced by 50% [28]. This would result in considerably high maintenance costs. A typical Categories and Subject Descriptors solution to this is to equip sensors with an energy harvesting circuit B.0 [Hardware]: general. which collects energy from the environment, such as with solar cells. Aside from energy harvesting nodes, a few wireless sensor General Terms nodes have been built for SHM applications [34] [24] [22]. Since they focus only on passive sensing, these solutions have limited Algorithms, Measurement, Performance, Design.computational power and acquisition fidelity. In addition to that, they do not implement any energy harvesting techniques. KeywordsIn this paper, we present SHiMmer, a system that shows it is indeed Actuation, sensing, wireless, low power, energy harvesting. feasible to build an active SUM sensor network comprised of energy self-sufficient nodes which perform all the damage detection

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Pipeline Structural Health Monitoring Using Macro-fiber Composite Active Sensors

Cited by 21 publications

References 33 publications

Active sensing platform for wireless structural health monitoring

Active sensing platform for wireless structural health monitoring

Feasibility of MFC (Macro-Fiber Composite) Transducers for Guided Wave Technique

Active Sensing Platform for Wireless Structural Health Monitoring

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