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Electromechanical properties of barium titanate-polyvinylidene fluoride cement-based composites
Highlights Using PVDF in the composite results in improved electromechanical transferability. PVDF is beneficial (gives lower Qm and higher k) for receiving transducer in SHM. Highest kp and kt values can be observed at 60 vol% BT and 5–7 vol% PVDF.
Abstract In this study, 40–60 vol% barium titanate (BT) piezoelectric ceramic particles, Portland cement, and polyvinylidene fluoride (PVDF, 0–7 vol%) were used to fabricate 0–3 BT cement-based composites. The electromechanical coupling factor (k) and the mechanical quality factor (Qm) of the composites were investigated. Increasing BT and PVDF contents led to a decreased impedance of the composite. Moreover, the impedance peak detected was found to shift to a lower frequency. Broaden impedance peak can be observed when PVDF content increased. The electromechanical coupling factor of thickness mode (kt) and planar mode (kp) increased with increasing BT and PVDF contents. The highest values for kt (16.74%) and kp (16.94%) were found in the composite with 60 vol% BT and 5–7 vol% PVDF. The composite with no PVDF has a higher Qm value than composites with PVDF. The lowest Qm value can be observed at 3 vol% PVDF with all BT content.
Electromechanical properties of barium titanate-polyvinylidene fluoride cement-based composites
Highlights Using PVDF in the composite results in improved electromechanical transferability. PVDF is beneficial (gives lower Qm and higher k) for receiving transducer in SHM. Highest kp and kt values can be observed at 60 vol% BT and 5–7 vol% PVDF.
Abstract In this study, 40–60 vol% barium titanate (BT) piezoelectric ceramic particles, Portland cement, and polyvinylidene fluoride (PVDF, 0–7 vol%) were used to fabricate 0–3 BT cement-based composites. The electromechanical coupling factor (k) and the mechanical quality factor (Qm) of the composites were investigated. Increasing BT and PVDF contents led to a decreased impedance of the composite. Moreover, the impedance peak detected was found to shift to a lower frequency. Broaden impedance peak can be observed when PVDF content increased. The electromechanical coupling factor of thickness mode (kt) and planar mode (kp) increased with increasing BT and PVDF contents. The highest values for kt (16.74%) and kp (16.94%) were found in the composite with 60 vol% BT and 5–7 vol% PVDF. The composite with no PVDF has a higher Qm value than composites with PVDF. The lowest Qm value can be observed at 3 vol% PVDF with all BT content.
Electromechanical properties of barium titanate-polyvinylidene fluoride cement-based composites
Wittinanon, Thanyapon (author) / Rianyoi, Rattiyakorn (author) / Chaipanich, Arnon (author)
2021-06-05
Article (Journal)
Electronic Resource
English
Preparation of Electrospun Barium Titanate - Polyvinylidene Fluoride Piezoelectric Membranes
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