Wideband and Wide Beam Polyvinylidene Difluoride (PVDF) Acoustic Transducer for Broadband Underwater Communications

Martins, M. S.; Faria, C. L.; Matos, Tiago; Gonçalves, L. M.; Cabral, José María Segura; Silva, António; Jesus, S. M.

doi:10.3390/s19183991

Cited by 14 publications

(7 citation statements)

References 18 publications

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“…In this group's next work, increasing the numbers of the holes caused higher outputs, and they proved that using this nanogenerator avoids corrosion in stainless steel in the process [96].…”

Section: Increasing Specific Surface Area Methodsmentioning

confidence: 88%

An Introduction to PVDF Nanofibers Properties, and Ways to Improve Them, and Reviewing Output Enhancing Methods for PVDF Nanofibers Nanogenerators

Aghayari¹

2021

Preprint

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PVDF has special piezo/pyro/ferroelectric, flexibility, low weight, biocompatibility, economical, good chemical/thermal, and high mechanical properties such as excellent nontoxic fiber/film formation. It has polar and nonpolar phases of α, β, γ, ε, and δ that the nonpolar α phase is the most stable one, but the β phase is the best of all because it has good piezo/pyro/ferroelectric properties. Copolymers are attractive because of their low weight, nontoxic, chemical acid resistance, flexibility, and ease of processing. These aspects result in their applications in many fields. They are used for piezoelectric nanogenerators, cooling/heating sensors, electronic devices (fuel cells, lithium-ion batteries (as separators), dye sensitive solar cells), filtration, oil/water separation, and photoelectric nanodevices. This review highlights the main aspects of the last decade's articles, and the focus is on the synthesis methods of PVDF nanofibers and their properties which results in their application in different fields of industry and especially focuses on finding ways to increase the output of PVDF nanofibers nanogenerators (weight/acoustic pressure nanogenerators

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Section: Increasing Specific Surface Area Methodsmentioning

confidence: 88%

An Introduction to PVDF Nanofibers Properties, and Ways to Improve Them, and Reviewing Output Enhancing Methods for PVDF Nanofibers Nanogenerators

Aghayari¹

2021

Preprint

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“…These transducers must detect motion that is far away; therefore, high-power device specifications are needed [ 6 ]. To design a high-power transducer, this study attempted to modify the transducer structure, add materials, change the driving piezoelectric material, and implement a transducer array [ 7 , 8 , 9 , 10 , 11 , 12 , 13 ]. Flextensional transducers, which enhance their output by changing their shape, have been studied.…”

Section: Introductionmentioning

confidence: 99%

Design of Piezoelectric Acoustic Transducers for Underwater Applications

Pyun

Kim

Park

2023

Sensors

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Interest in underwater transducers has persisted since the mid-1900s. Underwater transducers are designed in various shapes using various materials depending on the purpose of use, such as to achieve high power, improve broadband, and enhance beam steering. Therefore, in this study, an analysis is conducted according to the structural shape of the transducer, exterior material, and active material. By classifying transducers by structure, the transducer design trends and possible design issues can be identified. Researchers have constantly attempted new methods to improve the performance of transducers. In addition, a methodology to overcome this problem is presented. Finally, this review covers old and new research, and will serve as a reference for designers of underwater transducer.

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“…Piezoelectric materials have been used for producing transducers since World War I [ 1 ], and despite their longevity, new ingenious designs always emerge. Novel applications of piezoelectricity can range from thrusters [ 2 ] and robotic fingers [ 3 ] to underwater acoustic transducers, using novel materials such as piezoelectric polymers [ 4 , 5 ] and novel designs with piezoelectric ceramics [ 6 ]. This is the case of the recently proposed spiral acoustic source [ 7 ], which is able to generate a spiral acoustic field rather than the typical circular field.…”

Section: Introductionmentioning

confidence: 99%

In-Lab Demonstration of an Underwater Acoustic Spiral Source

Viegas

Zabel

Silva

2023

Sensors

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Underwater acoustic spiral sources can generate spiral acoustic fields where the phase depends on the bearing angle. This allows estimating the bearing angle of a single hydrophone relative to a single source and implementing localization equipment, e.g., for target detection or unmanned underwater vehicle navigation, without requiring an array of hydrophones and/or projectors. A spiral acoustic source prototype made out of a single standard piezoceramic cylinder, which is able to generate both spiral and circular fields, is presented. This paper reports the prototyping process and the multi-frequency acoustic tests performed in a water tank where the spiral source was characterized in terms of the transmitting voltage response, phase, and horizontal and vertical directivity patterns. A receiving calibration method for the spiral source is proposed and showed a maximum angle error of 3° when the calibration and the operation were carried out in the same conditions and a mean angle error of up to 6° for frequencies above 25 kHz when the same conditions were not fulfilled.

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Wideband and Wide Beam Polyvinylidene Difluoride (PVDF) Acoustic Transducer for Broadband Underwater Communications

Cited by 14 publications

References 18 publications

An Introduction to PVDF Nanofibers Properties, and Ways to Improve Them, and Reviewing Output Enhancing Methods for PVDF Nanofibers Nanogenerators

An Introduction to PVDF Nanofibers Properties, and Ways to Improve Them, and Reviewing Output Enhancing Methods for PVDF Nanofibers Nanogenerators

Design of Piezoelectric Acoustic Transducers for Underwater Applications

In-Lab Demonstration of an Underwater Acoustic Spiral Source

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