Structural health monitoring for woven fabric CFRP laminates

Al-Saadi, Ahmed; Meredith, James O.; Swait, T.J.; Curiel-Sosa, J.L.; Jia, Yu; Hayes, Shannon

doi:10.1016/j.compositesb.2019.107048

Cited by 34 publications

(13 citation statements)

References 54 publications

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“…The electrical properties of CFRP are sensitive to mechanical strain, temperature and damage. Methods to detect these changes in resistance are described in the literature which either use physical electrodes attached to the CFRP [41,85,86], or are contactless [87]. The contactless method presented relies on the change of the signature of the response to an external EM wave.…”

Section: ) Measurement and Sensingmentioning

confidence: 99%

A Route to Sustainable Aviation: A Roadmap for the Realization of Aircraft Components With Electrical and Structural Multifunctionality

Jones

Norman

Burt

et al. 2021

IEEE Trans. Transp. Electrific.

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Section: ) Measurement and Sensingmentioning

confidence: 99%

A Route to Sustainable Aviation: A Roadmap for the Realization of Aircraft Components With Electrical and Structural Multifunctionality

Jones

Norman

Burt

et al. 2021

IEEE Trans. Transp. Electrific.

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“…CFRP [22] is employed in the majority of applications requiring lightweight, high-strength materials. Monitoring failures [23] is critical in today's industrial environment. The piezoelectric sensor's direct and indirect impact principles enable monitoring of material breakdown.…”

Section: Introductionmentioning

confidence: 99%

Smart Piezo-bonded carbon fibre/epoxy composite structure: experiments and finite element simulation

J¹,

Vasanthanathan²

2022

Mater. Res. Express

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Smart sensors patched to composite structures assist in the prediction of the mechanical behaviour of the structures. The present paper used finite element modelling and experimental procedures to conduct a detailed study on the response of composite laminate bonded with smart piezoelectric material. Fibre reinforced epoxy composite laminate was fabricated using the vacuum assisted resin transfer method. Test coupons in accordance with ASTM standards were prepared using high-speed and high-pressure abrasive water jet cutting. The mechanical properties of the composites were obtained through material characterization and the material properties were incorporated into the Finite element model. The layer-wise strain rate was computed with the ANSYS® Composite Prep Post module. A finite element model of a composite with piezoelectric sensor patch was created in ANSYS® APDL and harmonic analysis was conducted to determine the optimal frequency range for the applied load. An attempt was made to measure the strain by affixing lead zirconate titanate to a carbon fibre reinforced polymer laminate for cantilever configuration, and the LabVIEW® VI software module was integrated with the NI myDAQ system to detect the corresponding voltage for the excited frequency. The values of the generated voltage through numerical simulations were verified and validated using experimental counterparts.

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Section: Introductionmentioning

confidence: 99%

“…[13] Accordingly, considerable research has been reported on the resistive heating behavior of CF and their applications in deicing units, temperature sensors, micro heaters, and thermoelectric devices. [14][15][16][17][18][19] Although CF composites exhibit many advantages as effective heating elements, there are still existing challenges in heating applications. CFs have a smooth surface due to the manufacturing process, and such a smooth surface is not conducive to generating positive interfacial interactions between the fiber-matrix interface.…”

Section: Introductionmentioning

confidence: 99%

Utility of whiskerized carbon fabric surfaces in resistive heating of composites

et al. 2021

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In the present study, the embedding ZnO nano‐whiskers (NWs) on carbon fiber (CF) surface was carried out to study the changes in Ohmic heating and mechanical stability of carbon fabric reinforced green epoxy composite laminates. The ZnO NWs were grown onto the CF surface by hydrothermal method and subsequently the laminate composites with different number of carbon woven layers were prepared. To study the resistive heating behavior of the laminate composites, the temperature versus time curves were analyzed in three sections, from which the temperature response rate, the maximum temperature, and the electrical power efficiency were estimated. Later, the effects of Ohmic heating action on the structural damage and mechanical stability of the composites were examined by dynamic mechanical analysis and X‐ray micro computerized tomography. Multilayer ZnO/carbon woven composites were found to be rapidly heating, less power consumption, and have improved mechanical and structural stability over bare carbon woven composites. This indicated that ZnO NWs enhanced the adhesion between the fibers and matrix, meanwhile acting as a heat barrier to avoid degradation of the epoxy at the interface of the fiber and matrix during Ohmic heating.

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Structural health monitoring for woven fabric CFRP laminates

Cited by 34 publications

References 54 publications

A Route to Sustainable Aviation: A Roadmap for the Realization of Aircraft Components With Electrical and Structural Multifunctionality

A Route to Sustainable Aviation: A Roadmap for the Realization of Aircraft Components With Electrical and Structural Multifunctionality

Smart Piezo-bonded carbon fibre/epoxy composite structure: experiments and finite element simulation

Utility of whiskerized carbon fabric surfaces in resistive heating of composites

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