Your search keyword '"Piotr A. Bońkowski"' showing total 3 results

1. Rotation, Strain, and Translation Sensors Performance Tests with Active Seismic Sources

Author

Felix Bernauer, Kathrin Behnen, Joachim Wassermann, Sven Egdorf, Heiner Igel, Stefanie Donner, Klaus Stammler, Mathias Hoffmann, Pascal Edme, David Sollberger, Cédric Schmelzbach, Johan Robertsson, Patrick Paitz, Jonas Igel, Krystyna Smolinski, Andreas Fichtner, Yara Rossi, Gizem Izgi, Daniel Vollmer, Eva P. S. Eibl, Stefan Buske, Christian Veress, Frederic Guattari, Theo Laudat, Laurent Mattio, Olivie Sèbe, Serge Olivier, Charlie Lallemand, Basil Brunner, Anna T. Kurzych, Michał Dudek, Leszek R. Jaroszewicz, Jerzy K. Kowalski, Piotr A. Bońkowski, Piotr Bobra, Zbigniew Zembaty, Jiří Vackář, Jiří Málek, and Johana Brokesova

Subjects

rotation sensors, strain sensors, seismology, instrumentation, Chemical technology, TP1-1185

Abstract

Interest in measuring displacement gradients, such as rotation and strain, is growing in many areas of geophysical research. This results in an urgent demand for reliable and field-deployable instruments measuring these quantities. In order to further establish a high-quality standard for rotation and strain measurements in seismology, we organized a comparative sensor test experiment that took place in November 2019 at the Geophysical Observatory of the Ludwig-Maximilians University Munich in Fürstenfeldbruck, Germany. More than 24 different sensors, including three-component and single-component broadband rotational seismometers, six-component strong-motion sensors and Rotaphone systems, as well as the large ring laser gyroscopes ROMY and a Distributed Acoustic Sensing system, were involved in addition to 14 classical broadband seismometers and a 160 channel, 4.5 Hz geophone chain. The experiment consisted of two parts: during the first part, the sensors were co-located in a huddle test recording self-noise and signals from small, nearby explosions. In a second part, the sensors were distributed into the field in various array configurations recording seismic signals that were generated by small amounts of explosive and a Vibroseis truck. This paper presents details on the experimental setup and a first sensor performance comparison focusing on sensor self-noise, signal-to-noise ratios, and waveform similarities for the rotation rate sensors. Most of the sensors show a high level of coherency and waveform similarity within a narrow frequency range between 10 Hz and 20 Hz for recordings from a nearby explosion signal. Sensor as well as experiment design are critically accessed revealing the great need for reliable reference sensors.

Published

2021

2. Seismic Vulnerability of a Slender Intact Stalagmite standing in a Karstic Cave

Author

Katalin Gribovszki, Piotr A. Bońkowski, Marcin A. Jaworski, and Zbigniew Zembaty

Abstract

Recently, it has been argued that natural, intact stalagmites in caves give important constraints on seismic hazard since they have survived all earthquakes over their (rather long) life span. For this reason, applying detailed modelling methodologies to study the seismic motion of speleothems has special significance. Here we present a stalagmite-based study from the Little Carpathians of Slovakia, Plavecka priepast cave.The seismic response of stalagmite is computed using a robust, a fully three-dimensional, Finite Element Method model calibrated from free vibration records by Hilbert-Huang modal extraction. It is demonstrated that the stalagmite vibrations consist of pairs of closely coupled flexural natural modes with a negligible role of vertical excitations.An underground record of a moderate earthquake was applied to excite low intensity seismic vibrations. Particular attention was paid to observing the role of the vertical component of seismic ground motion. It is concluded that the failure mode of the stalagmite is driven by flexural vibrations. The safety margins of this stalagmite were assessed by analysing the tensile stress map from the seismic response computations. The location of the breaking point of the stalagmite is a result of a balance between the overturning bending moment and variations of horizontal cross-sections with height. The ultimate peak velocity of excitations equalling 3.2 mm/s is estimated.The used input data and the animations are available on these web pages:https://z.zembaty.po.opole.pl/SupplementaryStalagmite3Dview.htmlhttps://z.zembaty.po.opole.pl/SupplementaryStalagmite.html

Published

2022

3. Application of Rotation Rate Sensors in Modal and Vibration Analyses of Reinforced Concrete Beams

Author

Piotr Adam Bońkowski, Piotr Bobra, Zbigniew Zembaty, and Bronisław Jędraszak

Subjects

modal analysis, rotational mode, gyroscope, rotation rate sensors, UHPC, reinforced concrete beams, Chemical technology, TP1-1185

Abstract

The recent rapid development of rotation rate sensor technology opens new opportunities for their application in more and more fields. In this paper, the potential of rotational sensors for the modal analysis of full-scale civil engineering structural elements is experimentally examined. For this purpose, vibrations of two 6-m long beams made of ultra-high performance concrete (UHPC) were measured using microelectromechanical system (MEMS) rotation rate sensors. The beams were excited to vibrations using an impact hammer and a dynamic vibration exciter. The results of the experiment show that by using rotation rate sensors, one can directly obtain derivatives of mode shapes and deflection shapes. These derivatives of mode shapes, often called “rotational modes”, bring more information regarding possible local stiffness variations than the traditional transversal and deflection mode shapes, so their extraction during structural health monitoring is particularly useful. Previously, the rotational modes could only be obtained indirectly (e.g., by central difference approximation). Here, with the application of rotation rate sensors, one can obtain rotational modes and deflection shapes with a higher precision. Furthermore, the average strain rate and dynamic strain were acquired using the rotation rate sensors. The laboratory experiments demonstrated that rotation rate sensors were matured enough to be used in the monitoring and modal analyses of full-scale civil engineering elements (e.g., reinforced concrete beams).

Published

2020