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Underwater Electroacoustic Transducers: Design and Development of Piezoelectric Devices



Perchevska, L., Drozdenko, O., & Drozdenko, K. (2021). Shifting the operating frequency of the piezoceramic electroacoustic transducer langevin type using passive cooling methods. ScienceRise, (4), 3-10. doi: -8416.2021.002019


The object of research: the shift of resonant frequency of the piezoceramic electroacoustic transducer Langevin type depending on the shape of the back plate.Investigated problem: the relationship between changes in shape of back plate of the Langevin type transducer with the resonant frequency of the oscillating system. Search quantitative contribution to shift the resonant frequency of each of the modifications: shape, diameter, thickness, weight of back plate.The main scientific results: vibration modes of a transducer with a back plate with horizontal and vertical radiator ribs were obtained. The graphs of the shift resonant frequency depending on the change in the diameter and thickness of the back tail with vertical radiator ribs are presented. It is established, that the change in the thickness and diameter of the back plate of the transducer effects on resonance frequency much less than the change in mass.The area of practical use of the research results: designing piezoceramic electroacoustic transducer with passive cooling method.Innovative technological product: guidelines for choosing the shape changes back plates of the Langevin type transducer for decreasing heating temperature, with keeping resonant frequency.Scope of the innovative technological product: scope of application of the Langevin type transducer: underwater acoustics, ultrasonic technological equipment, ultrasonic engine, piezotransformer, medical equipment, rock drilling devices.




Underwater Electroacoustic Transducers.pdf



In addition to the above-mentioned applications, which fall under the category of nondestructive testing, EMATs have been used in research for ultrasonic communication, where they generate and receive an acoustic signal in a metallic structure.[15] Ultrasonic communication is particularly useful in areas where radio frequency can not be used. This includes underwater and underground environments as well as sealed environments, e.g., communication with a sensor inside a pressure tank. 2ff7e9595c


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