A newly developed layered model to analytically predict the piezoelectric property of polymeric foams: Cellular geometry consideration

Piezoelectric property refers to the ability of materials to convert mechanical energy into electrical energy and vice versa. The development of science and technology and their orientation towards digital life will increase the need to use this property more and more. Polymeric foams are one of the...

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Veröffentlicht in:Journal of applied polymer science 2022-05, Vol.139 (17), p.n/a
Hauptverfasser: Daryadel, Mahsa, Azdast, Taher
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Azdast, Taher
description Piezoelectric property refers to the ability of materials to convert mechanical energy into electrical energy and vice versa. The development of science and technology and their orientation towards digital life will increase the need to use this property more and more. Polymeric foams are one of the materials that show high piezoelectric property. So far, only layered model has been proposed to predict the piezoelectric property of these materials. But to the best knowledge of the authors, there is no comprehensive research to investigate the accuracy of this model. Therefore, in this study, the obtained theoretical results from the layered model are compared to the experimental results and the accuracy of this model is investigated. Also, the presented solution by other authors to improve the accuracy of this model is studied. Finally, a new approach is developed to predict piezoelectric property of polymeric foams. The results show that the presented approach in this study increases the accuracy of the layered model compared to previous approaches. Considering the cellular structure of the polymeric foam as hexagonal geometry, the error is obtained 0.2%. Furthermore, the effect of different structural parameters on the maximum remnant charge density is investigated.
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subjects Accuracy
Cellular structure
Charge density
foams
Materials science
Model accuracy
Piezoelectricity
Plastic foam
Plastic foams
Polymers
porous materials
structure‐property relationships
theory and modeling
thermoplastics
title A newly developed layered model to analytically predict the piezoelectric property of polymeric foams: Cellular geometry consideration
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