Valorization of eggshell waste in designing flexible polyurethane-based piezoelectric composite materials for ultrasonic transducers

In this study, we have prepared a new formulation from flexible polyurethane/calcined waste eggshell (FPU/CWES) composites as a novel piezoelectric foam material for transducer applications. The CWES was loaded into the FPU matrix with different ratios (1–5%) by weight. The FPU/CWES composites were...

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Bibliographic Details
Published in:Journal of polymer research 2023-07, Vol.30 (7), Article 286
Main Authors: Maamoun, Ahmed Abdelhamid, Barakat, Mirham Abdallah Youssef, El-Wakil, Abd El-Aziz Arafa, Zulfiqar, Sonia, Oghenekohwo, Victor James
Format: Article
Language:English
Subjects:
Biomedical materials
Bulk density
Ceramic materials
Ceramics
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Composite materials
Elongation
Industrial Chemistry/Chemical Engineering
Mechanical properties
Nondestructive testing
Original Paper
Piezoelectricity
Polymer Sciences
Polyurethane foam
Polyurethanes
Sensitivity enhancement
Stability analysis
Thermal stability
Transducers
Ultrasonic testing
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Summary:In this study, we have prepared a new formulation from flexible polyurethane/calcined waste eggshell (FPU/CWES) composites as a novel piezoelectric foam material for transducer applications. The CWES was loaded into the FPU matrix with different ratios (1–5%) by weight. The FPU/CWES composites were characterized using FESEM, EDX, and FTIR techniques. Furthermore, gel fraction and apparent density tests were estimated for the obtained composites. The results disclosed that FPU/CWES 3% composite achieved maximum values of 88.5% and 36.62 kg/m 3 for gel fraction and density, respectively, compared to control FPU foam. TGA analysis displayed that adding (1–3 wt%) CWES increased thermal stability compared to control FPU foam. The FPU/CWES composites’ mechanical characteristics showed that the compressive and tensile strengths of the FPU/CWES 3% were increased to 17.85% and 15.78%, respectively, compared to the control FPU foam. At the same time, the elongation at break decreased with an increase in the CWES content. The piezoelectric coefficient (d 33 ) for FPU/CWES 3% composites showed superior enhancement compared to other traditional piezoelectric materials and thus can be considered a promising piezoelectric element for medical ultrasonic transducer fabrication and ultrasonic non-destructive testing to detect defects in different solid materials. Furthermore, FPU/CWES composites displayed advantages over other piezoelectric materials, such as ceramics or polymers, including increased sensitivity, enhanced performance at low frequencies, and greater adaptability to irregular and curved surfaces. Additionally, their lightweight nature and low cost make them an attractive option for developing innovative and valuable piezoelectric devices. Therefore, utilizing FPU/CWES composites as a piezoelectric material holds tremendous potential for advancements in various fields, including wearable electronics and biomedical applications.
ISSN:1022-9760
1572-8935
DOI:10.1007/s10965-023-03648-z