Ultrasonic waves from radial mode excitation of a piezoelectric disc on the surface of an elastic solid

Chillara, Vamshi Krishna; Greenhall, John; Pantea, Cristian

doi:10.1088/1361-665x/ab85a2

Cited by 7 publications

(4 citation statements)

References 23 publications

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“…This piezoelectric disc exhibited a fundamental radial mode at 215 kHz ± 5 kHz. The radial mode allowed for significantly smaller dimensions while maintaining good coupling and the focusing of the main lobe of the longitudinal wave propagation at a given operation frequency [ 28 , 29 ].…”

Section: System Designmentioning

confidence: 99%

Wireless Passive Sensor Technology through Electrically Conductive Media over an Acoustic Channel

Schaechtle

Aftab

Reindl

et al. 2023

Sensors

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Hydrogen-based technologies provide a potential route to more climate-friendly mobility in the automotive and aviation industries. High-pressure tanks consisting of carbon-fiber-reinforced polymers (CFRPs) are exploited for the storage of compressed hydrogen and have to be monitored for safe and long-term operation. Since neither wired sensors nor wireless radio technology can be used inside these tanks, acoustic communication through the hull of the tank has been the subject of research in recent years. In this paper, we present for the first time a passive wireless sensor technology exploiting an ultrasonic communication channel through an electrically conductive transmission medium with an analog resonant sensor featuring a high quality factor. The instrumentation system comprised a readout unit outside and a passive sensor node inside the tank, coupled with geometrically opposing electromechanical transducers. The readout unit wirelessly excited a resonant sensor, whose temperature-dependent resonance frequency was extracted from the backscattered signal. This paper provides a description of the underlying passive sensor technology and characterizes the electric impedances and acoustic transmission as an electrical 2-Port to design a functional measurement setup. We demonstrated a wireless temperature measurement through a 10 mm CFRP plate in its full operable temperature range from −40 to 110 °C with a resolution of less than 1 mK.

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Section: System Designmentioning

confidence: 99%

Wireless Passive Sensor Technology through Electrically Conductive Media over an Acoustic Channel

Schaechtle

Aftab

Reindl

et al. 2023

Sensors

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show abstract

“…The propagation of ultrasonic waves in an elastic body is investigated in [ 6 ]. The study discusses the characteristics of ultrasonic wave propagation in an isotropic elastic solid material due to the radial mode excitation of a piezoelectric disk actuator connected to its surface.…”

Section: Introductionmentioning

confidence: 99%

Development of a Low-Frequency Piezoelectric Ultrasonic Transducer for Biological Tissue Sonication

Ostaševičius

Jurenas

Mikuckyte

et al. 2023

Sensors

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The safety of ultrasound exposure is very important for a patient’s well-being. High-frequency (1–10 MHz) ultrasound waves are highly absorbed by biological tissue and have limited therapeutic effects on internal organs. This article presents the results of the development and application of a low-frequency (20–100 kHz) ultrasonic transducer for sonication of biological tissues. Using the methodology of digital twins, consisting of virtual and physical twins, an ultrasonic transducer has been developed that emits a focused ultrasound signal that penetrates into deeper biological tissues. For this purpose, the ring-shaped end surface of this transducer is excited not only by the main longitudinal vibrational mode, which is typical of the flat end surface transducers used to date, but also by higher mode radial vibrations. The virtual twin simulation shows that the acoustic signal emitted by the ring-shaped transducer, which is excited by a higher vibrational mode, is concentrated into a narrower and more precise acoustic wave that penetrates deeper into the biological tissue and affects only the part of the body to be treated, but not the whole body.

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“…Transient wave propagation in solids and structures is encountered in several applications such as non-destructive evaluation (NDE) [13,14], structural health monitoring (SHM) [15][16][17][18], impact response [19], seismology [20], acoustics [21][22][23], and biomechanics [24] to mention just a few. In this context, ultrasonic guided waves provide a robust tool for damage detection in thin-walled flat and curved structures, such as aircraft fuselages, ship hulls, pressure vessels, and pipelines [15,16,[25][26][27].…”

Section: Introductionmentioning

confidence: 99%

On the numerical properties of high‐order spectral (Euler‐Bernoulli) beam elements

et al. 2023

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In this paper, the numerical properties of a recently developed high-order Spectral Euler-Bernoulli Beam Element (SBE) featuring a C 1 -continuous approximation of the displacement field are assessed. The C 1 -continuous shape functions are based on two main ingredients, which are an Hermitian interpolation scheme and the use of Gauß-Lobatto-Legendre (GLL) points. Employing GLL-points does not only avoid Runge oscillations, but also yields a diagonal mass matrix when exploiting the nodal quadrature technique as a mass lumping scheme. Especially in high-frequency transient analyses, where often explicit time integration schemes are utilized, having a diagonal mass matrix is an attractive property of the proposed element formulation. This is, however, achieved at the cost of an under-integration of the mass matrix. Therefore, a special focus of this paper is placed on the evaluation of the numerical properties, such as the conditioning of the element matrices and the attainable rates of convergence (ROCs). To this end, the numerical behavior of the SBEs is comprehensively analyzed by means of selected benchmark examples. In a nutshell, the obtained results demonstrate that the element yields good accuracy in combination with an increased efficiency for structural dynamics exploiting the diagonal structure of the mass matrix.

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Ultrasonic waves from radial mode excitation of a piezoelectric disc on the surface of an elastic solid

Cited by 7 publications

References 23 publications

Wireless Passive Sensor Technology through Electrically Conductive Media over an Acoustic Channel

Wireless Passive Sensor Technology through Electrically Conductive Media over an Acoustic Channel

Development of a Low-Frequency Piezoelectric Ultrasonic Transducer for Biological Tissue Sonication

On the numerical properties of high‐order spectral (Euler‐Bernoulli) beam elements

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