Advanced Micro Structuring and Joining Technologies for Direct Integration of Piezo Fibers into Metallic Materials

Schubert, Andreas; Koriath, Hans-Joachim; Wittstock, Volker; Müller, Bettina; Pierer, Alexander; Schmidt, Marek

doi:10.1002/adem.201800472

Cited by 3 publications

(1 citation statement)

References 18 publications

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“…The sensor principle used in this work is based on the structural integration of piezoceramic elements with a rectangular cross-section into a workpiece by forming [24,25]. First, a cavity in the workpiece, in this case a sonotrode, is formed by milling.…”

Section: Structurally Integrated Piezoceramicmentioning

confidence: 99%

Feasibility Study for Monitoring an Ultrasonic System Using Structurally Integrated Piezoceramics

Werner,

Krüger,

Drossel

2024

Sensors

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This paper presents a new approach to monitoring ultrasonic systems using structurally integrated piezoceramics. These are integrated into the sonotrode at different points and with different orientations. The procedure for integrating the piezoceramics into the sonotrode and their performance is experimentally investigated. We examine whether the measured signal can be used to determine the optimal operating frequency of the ultrasonic system, if integrating several piezoceramics enables discernment of the current vibration shape, and if the piezoceramics can withstand the high strains caused by the vibrations in a frequency range of approximately 20–25 kHz. The signals from the piezoceramic sensors are compared to the real-time displacement at different points of the sonotrode using a 3D laser scanning vibrometer. To evaluate the performance of the sensors, different kinds of excitation of the ultrasonic system are chosen.

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Section: Structurally Integrated Piezoceramicmentioning

confidence: 99%

Feasibility Study for Monitoring an Ultrasonic System Using Structurally Integrated Piezoceramics

Werner,

Krüger,

Drossel

2024

Sensors

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High‐Volume Production‐Compatible Technologies for Light Metal and Fiber Composite‐Based Components with Integrated Piezoceramic Sensors and Actuators

et al. 2018

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Globalization, the scarcity of resources and climate change constantly raise new questions in the field of production engineering. One promising approach to the challenges involved is to reduce component weight with the aid of lightweight design. The integration of sensors and actuators made of “smart materials” into lightweight composites facilitates enhanced characteristics and functions such as ultra‐lightweight design, superior dynamic properties, and structural health monitoring. This essay presents the strategy adopted by Collaborative Research Center/Transregio 39 “High‐volume compatible production technologies for light metal and fiber composite‐based components with integrated sensors and actuators” (PT‐PIESA) in connection with research and development targeting the acquisition of the requisite scientific fundamentals. It also presents a concept for the holistic analysis of complex process chains for function‐integrated lightweight components with embedded piezoceramic elements.

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Comparison of Structural Integrated Piezoceramics, Piezoelectric Patches and Strain Gauges for Condition Monitoring

Werner

Engelmann

Schmidt

et al. 2022

Sensors

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This paper presents a new approach to the structural integration of piezoceramics into thin-walled steel components for condition-monitoring applications. The procedure for integrating the sensors into metal components is described, and their functionality is experimentally examined with a 2 mm-thick steel sheet. The signal quality of the produced sensors is investigated in a frequency range from 100 Hz to 50,000 Hz and is compared with the results of piezo patches and strain gauges under the same conditions. The results show that due to a higher signal-to-noise ratio and a better coherence, the structurally integrated piezoceramics and the piezo patches are more qualified sensors for vibration measurement in the examined frequency range than the strain gauges. The measurements also indicate that the patches provide higher amplitudes for the frequency range up to 20 kHz. Beyond that, up to 40 kHz, the integrated sensors supplied higher amplitudes. The better signal quality in different frequency ranges as well as the different manufacturing and application methods can be interpreted as an advantage or disadvantage depending on the boundary conditions of the condition-monitoring system. In summary, structural integrated piezoceramics extend the options of monitoring technology.

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Advanced Micro Structuring and Joining Technologies for Direct Integration of Piezo Fibers into Metallic Materials

Cited by 3 publications

References 18 publications

Feasibility Study for Monitoring an Ultrasonic System Using Structurally Integrated Piezoceramics

Feasibility Study for Monitoring an Ultrasonic System Using Structurally Integrated Piezoceramics

High‐Volume Production‐Compatible Technologies for Light Metal and Fiber Composite‐Based Components with Integrated Piezoceramic Sensors and Actuators

Comparison of Structural Integrated Piezoceramics, Piezoelectric Patches and Strain Gauges for Condition Monitoring

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