Investigation of the Effectiveness and Robustness of an MEMS-Based Structural Health Monitoring System for Composite Laminates

Caimmi, Francesco; Mariani, Stefano; Fazio, Marco

doi:10.1109/jsen.2014.2315831

Cited by 15 publications

(8 citation statements)

References 28 publications

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“…To avoid system failures and improve operational safety, there is a need for long-term and high accuracy monitoring of the systems [3]- [5]. Micro Electro Mechanical Systems (MEMS) have been emerging as a promising approach to provide real time, low cost, and reliable solutions for structural health monitoring [6], [7]. Nevertheless, the use of silicon-based MEMS sensors in harsh environment is questionable due to its low energy band gap, inferior wear-resistance, and high oxidation rate.…”

Section: Introductionmentioning

confidence: 99%

Wireless Battery-Free SiC Sensors Operating in Harsh Environments Using Resonant Inductive Coupling

Phan

Nguyen

Dinh

et al. 2019

IEEE Electron Device Lett.

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Silicon carbide (SiC) has been extensively investigated in the last decade, specifically for applications in harsh environments. However, most SiC sensors require an external power supply which cannot operate at high temperatures. This work develops a new sensing technology in a SiC platform based on near field communication to eliminate the requirement for wired power sources. 3C-SiC temperature sensors were fabricated from a SiC-on-insulator substrate formed by anodic bonding. The sensors functioned based on the thermoresistance of the SiC films with the high TCR of-13,000 ppm/K at 300 K and-3,000 ppm/K at 600 K. The change in the resistance of the SiC sensors was wirelessly measured using a reading coil placed outside of the heating chamber, showing a significant shift in the resonant frequency (-400 ppm/K at 600 K) of the couplingimpedance under the variation of temperatures. The proposed technique is promising for the development of wireless wideband-gap sensors used in extreme conditions.

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Section: Introductionmentioning

confidence: 99%

Wireless Battery-Free SiC Sensors Operating in Harsh Environments Using Resonant Inductive Coupling

Phan

Nguyen

Dinh

et al. 2019

IEEE Electron Device Lett.

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“…The local distortion of the microstructure they cause has been shown to result in a shorter lifetime, due to the inception of small defects that can eventually coalesce to provide a failure mode on their own. To avoid the SHM system being the source of a damage and so something that the system is supposed to feel and prevent as much as possible, in [ 17 , 18 , 19 ], we proposed to surface-mount inertial micro-sensors (MEMS) on composite plates; see also [ 20 ]. In fact, as composite structures are typically very thin and light in weight, the use of micro-sensors looks to be beneficial to attain the goal of minimal invasiveness of the SHM system.…”

Section: Introductionmentioning

confidence: 99%

A Multiscale Approach to the Smart Deployment of Micro-Sensors over Lightweight Structures

Capellari

Caimmi

Bruggi

et al. 2017

Sensors

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A topology optimization approach has been recently proposed to maximize the sensitivity to damage of measurements, collected through a network of sensors to be deployed over thin plates for structural health monitoring purposes. Within such a frame, damage is meant as a change in the structural health characterized by a reduction of relevant stiffness and load-carrying properties. The sensitivity to a damage of unknown amplitude and location is computed by comparing the response to the external actions of the healthy structure and of a set of auxiliary damaged structures, each one featuring reduced mechanical properties in a small region only. The topology optimization scheme has been devised to properly account for the information coming from all of the sensors to be placed on the structure and for damage depending on its location. In this work, we extend the approach within a multiscale frame to account for three different length scales: a macroscopic one, linked to the dimensions of the whole structure to be monitored; a mesoscopic one, linked to the characteristic size of the damaged region; a microscopic one, linked to the size of inertial microelectromechanical systems (MEMS) to be used within a marginally-invasive health monitoring system. Results are provided for a square plate and for a section of fuselage with stiffeners, to show how the micro-sensors have to be deployed to maximize the capability to detect a damage, to assess the sensitivity of the results to the measurement noise and to also discuss the speedup in designing the network topology against a standard single-scale approach.

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“…With regard to monitoring purposes, they were used in structural engineering and in seismology. In particular, [3] investigated the effectiveness and robustness of a MEMS-based structural health monitoring system which represents a new strategy for failure detection of composite laminates. Through laboratory tests, the MEMS accelerometer responses were properly validated with simultaneous measurements.…”

Section: Introductionmentioning

confidence: 99%

Exploiting Performance of Different Low-Cost Sensors for Small Amplitude Oscillatory Motion Monitoring: Preliminary Comparisons in View of Possible Integration

et al. 2016

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We address the problem of low amplitude oscillatory motion detection through different low-cost sensors: a LIS3LV02DQ MEMS accelerometer, a Microsoft Kinect v2 range camera, and a uBlox 6 GPS receiver. Several tests were performed using a one-direction vibrating table with different oscillation frequencies (in the range 1.5-3 Hz) and small challenging amplitudes (0.02 m and 0.03 m). A Mikrotron EoSens high-resolution camera was used to give reference data. A dedicated software tool was developed to retrieve Kinect v2 results. The capabilities of the VADASE algorithm were employed to process uBlox 6 GPS receiver observations. In the investigated time interval (in the order of tens of seconds) the results obtained indicate that displacements were detected with the resolution of fractions of millimeters with MEMS accelerometer and Kinect v2 and few millimeters with uBlox 6. MEMS accelerometer displays the lowest noise but a significant bias, whereas Kinect v2 and uBlox 6 appear more stable. The results suggest the possibility of sensor integration both for indoor (MEMS accelerometer + Kinect v2) and for outdoor (MEMS accelerometer + uBlox 6) applications and seem promising for structural monitoring applications.

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Investigation of the Effectiveness and Robustness of an MEMS-Based Structural Health Monitoring System for Composite Laminates

Cited by 15 publications

References 28 publications

Wireless Battery-Free SiC Sensors Operating in Harsh Environments Using Resonant Inductive Coupling

Wireless Battery-Free SiC Sensors Operating in Harsh Environments Using Resonant Inductive Coupling

A Multiscale Approach to the Smart Deployment of Micro-Sensors over Lightweight Structures

Exploiting Performance of Different Low-Cost Sensors for Small Amplitude Oscillatory Motion Monitoring: Preliminary Comparisons in View of Possible Integration

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