Multifunctional composite structures with embedded conductive yarns for shock load monitoring and failure detection

Chaudhary, Birendra; Matos, Helio; Das, Sumanta; Owens, Jim

doi:10.1088/1361-665x/ad1e8c

Smart Mater. Struct.

2024

DOI: 10.1088/1361-665x/ad1e8c

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Multifunctional composite structures with embedded conductive yarns for shock load monitoring and failure detection

Birendra Chaudhary,

Helio Matos,

Sumanta Das

et al.

Abstract: This study evaluates the performance of composite structures with embedded conductive yarns during shock loads to create a multifunctional system for immediate failure detection. The scalable sensing yarns were made by braiding Kevlar fibers with Nitinol fibers and then integrating them into a carbon/epoxy prepreg. The multifunctional structure was subjected to a Mach 2 air blast load using a shock tube apparatus. The embedded sensor yarns were used to record their electrical performance, while Digital Image C… Show more

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Cited by 4 publications

References 24 publications

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Stretchable electronic strips for electronic textiles enabled by 3D helical structure

Stanley,

Kunovski,

Hunt

et al. 2024

Sci Rep

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The development of stretchable electronic devices is a critical area of research for wearable electronics, particularly electronic textiles (e-textiles), where electronic devices embedded in clothing need to stretch and bend with the body. While stretchable electronics technologies exist, none have been widely adopted. This work presents a novel and potentially transformative approach to stretchable electronics using a ubiquitous structure: the helix. A strip of flexible circuitry (‘e-strip’) is twisted to form a helical ribbon, transforming it from flexible to stretchable. A stretchable core—in this case rubber cord—supports the structure, preventing damage from buckling. Existing helical electronics have only extended to stretchable interconnects between circuit modules, and individual components such as printed helical transistors. Fully stretchable circuits have, until now, only been produced in planar form: flat circuits, either using curved geometry to enable them to stretch, or using inherently stretchable elastomer substrates. Helical e-strips can bend along multiple axes, and repeatedly stretch between 30 and 50%, depending on core material and diameter. LED and temperature sensing helical e-strips are demonstrated, along with design rules for helical e-strip fabrication. Widely available materials and standard fabrication processes were prioritized to maximize scalability and accessibility.

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Stretchable electronic strips for electronic textiles enabled by 3D helical structure

Stanley,

Kunovski,

Hunt

et al. 2024

Sci Rep

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An investigation into the electromechanical performance of textile fabrics with conductive yarn elements for data transfer capabilities

Chaudhary,

Lyngdoh,

Owens

et al. 2024

Textile Research Journal

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This paper investigates the electromechanical performance of textile fabric with conductive yarn elements for data transmission capabilities. Electromechanical experiments were conducted to evaluate the electrical response of copper yarn elements stitched axially to the textile fabric, while assessing the mechanical response of the system during tensile tests under axial loading. The results indicated that the yarn element exhibited low electricomechanical coupling below 1.5% strain, making it suitable for consistent electrical performance during low mechanical strain conditions. Computational models were also developed and correlated with the experimental results of the conductive yarn. The computational model was then expanded to investigate the effect of the braiding angle in the braiding system, providing insights into how these parameters influence the system’s performance. Overall, this research contributes valuable insights into the electromechanical behavior of textile fabric with conductive yarn elements, and presents a framework for optimizing data transfer capabilities in e-textiles and smart textile applications. The findings open opportunities for further advancements in the design and engineering of functional textiles for a wide range of applications.

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Review of Implosion Design Considerations for Underwater Composite Pressure Vessels

Matos,

Ngwa,

Chaudhary

et al. 2024

JMSE

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The implosion of underwater composite structures is a critical and complex engineering problem, necessitating high-strength, lightweight, and corrosion-resistant materials for deep-sea applications. This manuscript reviews the intricate failure mechanisms of composite structures, focusing on cylindrical structures under extreme underwater conditions. The recent Titan submersible implosion serves as a case study, highlighting the significance of rigorous design considerations. Key topics include material degradation, buckling instability, and material failure, with a detailed analysis of composite layup optimization and manufacturing processes such as filament winding and roll wrapping. The manuscript underscores the need for comprehensive testing, advanced simulation techniques, and monitoring system integration to ensure the safety and effectiveness of composite pressure hulls. Future research should focus on developing more accurate failure models, optimizing manufacturing processes, and enhancing material properties through innovations in composite science to realize the full potential of composite materials in deep-sea applications.

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Multifunctional composite structures with embedded conductive yarns for shock load monitoring and failure detection

Cited by 4 publications

References 24 publications

Stretchable electronic strips for electronic textiles enabled by 3D helical structure

Stretchable electronic strips for electronic textiles enabled by 3D helical structure

An investigation into the electromechanical performance of textile fabrics with conductive yarn elements for data transfer capabilities

Review of Implosion Design Considerations for Underwater Composite Pressure Vessels

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