Piezoelectric sensor

About: Piezoelectric sensor is a research topic. Over the lifetime, 7127 publications have been published within this topic receiving 115903 citations.

Electro-mechanical impedance method for crack detection in metallic plates

Abstract: As a nondestructive evaluation technology, the EM impedance method allows us to identify the structural dynamics directly through in-situ active piezoelectric sensors. Previous work performed on 1-D steel beams structures shown through both theoretical analysis and experimental results that E/M impedance (or admittance) spectrum is a direct identifier of structural dynamics. The scope of presented work was to extend the positive results obtained for 1-D structure onto 2-D structures. Experiment analysis of 1-D and2-D structures has shown that E/M impedance (or admittance) spectrum accurately identifies the natural frequency spectrum of the specimens. Theoretical analysis was performed for particular boundary conditions to model the experimental set-up. Experiments were conducted on simple specimens in support of the theoretical investigation, and on thin-gauge aluminum plates to illustrate the method's potential. The number of specimens was sufficient to form a statistical data set. The aging aircraft panel was instrumented with piezoelectric active sensors and the spectrum of natural frequencies was measured at high frequency range. The changing of the spectrum due to presence of local small crack was noticed.

Industrial process device utilizing piezoelectric transducer

Abstract: A process device for coupling to an industrial process for use in monitoring or controlling the process includes a device housing configured to physically couple to the industrial process. A process variable sensor is configured to measure a process variable and measurement circuitry coupled to the process variable sensor provides an output related to the sensed process variable. A piezoelectric transducer provides an electrical output related to pressure pulsations in the industrial process. Electrical circuitry in the housing includes an input configured to receive the electrical output from the piezoelectric sensor.

Innovation Strategy Selection Facilitates High-Performance Flexible Piezoelectric Sensors

Abstract: Piezoelectric sensors with high performance and low-to-zero power consumption meet the growing demand in the flexible microelectronic system with small size and low power consumption, which are promising in robotics and prosthetics, wearable devices and electronic skin. In this review, the development process, application scenarios and typical cases are discussed. In addition, several strategies to improve the performance of piezoelectric sensors are summed up: (1) material innovation: from piezoelectric semiconductor materials, inorganic piezoceramic materials, organic piezoelectric polymer, nanocomposite materials, to emerging and promising molecular ferroelectric materials. (2) designing microstructures on the surface of the piezoelectric materials to enlarge the contact area of piezoelectric materials under the applied force. (3) addition of dopants such as chemical elements and graphene in conventional piezoelectric materials. (4) developing piezoelectric transistors based on piezotronic effect. In addition, the principle, advantages, disadvantages and challenges of every strategy are discussed. Apart from that, the prospects and directions of piezoelectric sensors are predicted. In the future, the electronic sensors need to be embedded in the microelectronic systems to play the full part. Therefore, a strategy based on peripheral circuits to improve the performance of piezoelectric sensors is proposed in the final part of this review.