U. Starossek

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Chris Goodier

Loughborough University

Januarti Jaya Ekaputri

Institut Teknologi Sepuluh Nopember

Iolanda Craifaleanu

Technical University Of Civil Engineering, Bucharest

HILTON AHMAD

Universiti Tun Hussein Onn Malaysia

Virginie Boucher

CSIC (Consejo Superior de Investigaciones Científicas-Spanish National Research Council)

Hari Hariyadi

Mataram University

Barzin Mobasher

Arizona State University

Metalurgi Fisik (Physical Metallurgy) Reza Fadhila

State University of Medan

Osama El Hariri

Banha University At Egypt

Jana Javornik

University of East London

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Papers by U. Starossek

Complex Notation in Flutter Analysis. Technical Note

Flutter analysis in aircraft or bridge engineering has to include motion-induced aerodynamic forc... more Flutter analysis in aircraft or bridge engineering has to include motion-induced aerodynamic forces. These forces are mathematically described in two equivalent ways, namely, by real number or complex number expressions. Accordingly, flutter analysis can be performed using either real or complex arithmetic. At first glance, the use of either kind of notation seems to be more a question of personal preference, as both lead to the same numerical results. Nevertheless, this paper attempts to advocate the use of complex notation both in aircraft and bridge flutter analysis. Real-number and complex-number descriptions of the same mechanical phenomena are compared. It is shown that, apart from computational advantages, complex notation leads to mathematically more compact and more elegant expressions, which is of significance particularly from an educational standpoint.

Active Vibration Control of a Three Degree of Freedom Oscillator Using Two Eccentrically Rotating Masses

An active mass damper utilizing rotating masses to damp the vibrations of an oscillator with two ... more An active mass damper utilizing rotating masses to damp the vibrations of an oscillator with two translational degrees of freedom in a horizontal plane and one rotational degree of freedom about a vertical axis is presented along with a corresponding closed-loop control algorithm. The damper consists of two masses rotating about a single vertical axis, powered by two actuators. In a preferred mode of operation, these masses rotate with a nearly constant and equal angular velocity in opposite directions, thus producing a harmonic control force in a single horizontal direction. By varying the relative angular position of the rotating masses, this control force can be directed in an arbitrary direction and used to damp the translational motion. In previous research, a control algorithm was derived for this purpose. The rotational degree of freedom can additionally be controlled by producing a moment by imposing angular accelerations on the rotating masses. In this paper, the previous c...

Eigenschaften von Stabbogenbruecken bei dynamischer Anregung und abgestimmte Ermuedungslastmodelle / Characteristics of steel bowstring bridges under dynamic excitation and tuned fatigue load models

Behandelt wird die Analyse und die Berechnung von Stabbogenbruecken mit freistehenden Stabboegen ... more Behandelt wird die Analyse und die Berechnung von Stabbogenbruecken mit freistehenden Stabboegen bei dynamischer Anregung durch Fahrzeugueberfahrten. Das lange Nachschwingen der Konstruktion bewirkt eine grosse Ermuedungsbeanspruchung in den Boegen und den angrenzenden Bauteilen. Beschrieben wird das Tragverhalten der Boegen. Fuer die Berechnung mit Differenzialgleichungen laesst sich der Bogen als Einzelbauteil mit entsprechenden Lagerungsbedingungen herausloesen. Die Lastimpulse in den Boegen entstehen durch Ueberfahren der Endquertraeger, welche die beiden Boegen der Bruecke verbinden. Durch die Verbindung der Boegen mit den Endquertraeger entstehen gekoppelte gleichlaeufige und gegenlaeufige Eigenformen der Bogenschwingungen. Wird die Bruecke dynamisch angeregt, stellt sich eine Energiewanderung im System ein. Es hat sich gezeigt, dass mit dem Ansatz des vierachsigen Fahrzeugs des Ermuedungslastmodells 3 (ELM3) der DIN EN 1991-2 die dynamischen Einwirkungen auf die Boegen nur an...

Structural robustness of a cable-stayed bridge

The failure of one structural element can lead to the failure of further structural elements and ... more The failure of one structural element can lead to the failure of further structural elements and thus to the collapse of large structural sections or the entire structure. Such disproportionate collapses have been discussed and investigated for some years, but mainly for buildings. Generally, structures can be made collapse resistant by ensuring a high level of safety against local failure or by increasing their robustness. Robustness has been defined as the insensitivity to local failure. Increasing the robustness of cable-stayed bridges means to design for the loss of cables. The sudden loss of cables is a dynamic event and must be investigated in nonlinear dynamic analyses. For the design, only the maximum responses are of interest. For this, quasi-static analyses using dynamic amplification factors to account for the dynamic effects are advised. The size of these amplification factors is strongly discussed. In the first part of this paper, dynamic amplification factors are deter...

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Brueckendynamik. Winderregte Schwingungen Von Seilbruecken

An Investigation into the Active Vibration Control of Three Coupled Oscillators Using the Twin Rotor Dampers

Progressive collapse of structures – review and outlook

Advances in Engineering Materials, Structures and Systems: Innovations, Mechanics and Applications, 2019

Eccentric-wing flutter stabilizer – Effectiveness and costs

Bridge Maintenance, Safety, Management, Life-Cycle Sustainability and Innovations, 2021

Eccentric-wing flutter stabilizer: Analysis and wind tunnel tests

Insights and Innovations in Structural Engineering, Mechanics and Computation, 2016

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Efficient Fatigue Assessment in the Time Domain in Comparison to Spectral Fatigue Analysis of an Offshore Jacket Structure

Offshore Technology Conference, 2016

Bridge flutter control using eccentric rotational actuators

Wind and Structures An International Journal, 2013

ABSTRACT An active mass damper system for flutter control of bridges is presented. Flutter stabil... more ABSTRACT An active mass damper system for flutter control of bridges is presented. Flutter stability of bridge structures is improved with the help of eccentric rotational actuators (ERA). By using a bridge girder model that moves in two degrees of freedom and is subjected to wind, the equations of motion of the controlled structure equipped with ERA are established. In order to take structural nonlinearities into consideration, flutter analysis is carried out by numerical simulation scheme based on a 4th-order Runge-Kutta algorithm. An example demonstrates the performance and efficiency of the proposed device. In comparison with known active mass dampers for flutter control, the movable eccentric mass damper and the rotational mass damper, the power demand is significantly reduced. This is of advantage for an implementation of the proposed device in real bridge girders. A preliminary design of a realization of ERA in a bridge girder is presented.

Eccentric-wing Flutter Stabilizer for Bridges

IABSE Conference, Guangzhou 2016: Bridges and Structures Sustainability - Seeking Intelligent Solutions, 2016

A device is presented that aims at preventing bridge flutter. It consists of wings positioned alo... more A device is presented that aims at preventing bridge flutter. It consists of wings positioned along the sides of, and fixed relative to, the bridge deck. Flutter suppression efficiency is high provided the lateral eccentricity of the wings is large. It is a passive aerodynamic device that is more economical than other passive measures or devices. Moreover, it does not contain moving parts. This is an advantage over devices with moving parts that meet resistance due to reliability concerns. Results of a numerical study are presented in which the critical wind speed for flutter onset of a bridge without wings and with wings mounted in various configurations were determined. Preliminary wind tunnel test results are reported and a cost estimate is given.

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Active mass dampers for flutter control of bridges

In this study, the rotational mass damper and the movable eccentric mass damper for active bridge... more In this study, the rotational mass damper and the movable eccentric mass damper for active bridge deck flutter control are investigated. A two-dimensional sectional model was used to describe the structural dynamics of a bridge deck subjected to wind. The flutter analysis of the uncontrolled and the controlled system was carried out using the flutter derivatives of a trapezoidal cross section, experimentally determined, and the Hurwitz criterion. A numerical simulation scheme in time domain was developed using suitable rational function approximations of unsteady aerodynamic forces. Several control scenarios were simulated. Furthermore, a coupled numerical-experimental simulation method was used for verification of the numerical results. The energy demand of the active control was considered as a main factor for the applicability of the proposed devices.

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A novel active mass damper for vibration control of bridges

Bridge Maintenance, Safety Management, Health Monitoring and Informatics - IABMAS '08, 2008

ABSTRACT

Collapse resistance and robustness of bridges

Bridge Maintenance, Safety Management, Health Monitoring and Informatics - IABMAS '08, 2008

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Robustness assessment of a cable-stayed bridge

Bridge Maintenance, Safety Management, Health Monitoring and Informatics - IABMAS '08, 2008

The failure of one structural element can lead to the failure of further structural elements and ... more The failure of one structural element can lead to the failure of further structural elements and thus to the collapse of large structural sections or the entire structure. Such dispro- portionate collapses have been discussed and investigated for some years, but mainly for build- ings. Generally, structures can be made collapse resistant by ensuring a high level of safety against local failure or by increasing their robustness. Robustness has been defined as the insen- sitivity to local failure. Increasing the robustness of cable-stayed bridges means to design for the loss of cables. The sudden loss of cables is a dynamic event and must be investigated in non- linear dynamic analyses. For the design, only the maximum responses are of interest. For this, quasi-static analyses using dynamic amplification factors to account for the dynamic effects are advised. This paper examines the structural response of a cable-stayed bridge to the loss of one cable by means of dynamic analyses including large displacements. The effects of cable sag, transverse cable vibrations and structural damping are determined and dynamic amplification factors are computed. Finally, conclusions are drawn as to the collapse behavior of cable-stayed bridges taking into account non-linear material behavior.

Conceptual Layouts and Angles of DiaGrid for Building Frames using Topological Optimization

Proceedings of the Tenth International Conference on Computational Structures Technology

Terminology for treating disproportionate collapse

Bridge Maintenance, Safety, Management and Life-Cycle Optimization, 2010

A multitude of terms is used to describe structural characteristics and concepts in the context o... more A multitude of terms is used to describe structural characteristics and concepts in the context of disproportionate collapse. Some of them, namely collapse resistance, structural robustness and vulnerability are discussed in this paper. This paper distinguishes these terms and the associated structural characteristics, and suggests working definitions. Additionally, a performance-based general framework for preventing disproportionate collapse is presented.

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Cable-loss analyses and collapse behavior of cable-stayed bridges

Bridge Maintenance, Safety, Management and Life-Cycle Optimization, 2010

The interaction of steel tube and concrete core in concrete-filled steel tube columns

Tubular Structures XII, 2008

... von Nabil Mohsen Ahmed Falah aus Sana'a, Jemen 2009 ... Furthermore, the interaction bet... more

Complex Notation in Flutter Analysis. Technical Note

Active Vibration Control of a Three Degree of Freedom Oscillator Using Two Eccentrically Rotating Masses

Eigenschaften von Stabbogenbruecken bei dynamischer Anregung und abgestimmte Ermuedungslastmodelle / Characteristics of steel bowstring bridges under dynamic excitation and tuned fatigue load models

Structural robustness of a cable-stayed bridge

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Brueckendynamik. Winderregte Schwingungen Von Seilbruecken

An Investigation into the Active Vibration Control of Three Coupled Oscillators Using the Twin Rotor Dampers

Progressive collapse of structures – review and outlook

Advances in Engineering Materials, Structures and Systems: Innovations, Mechanics and Applications, 2019

Eccentric-wing flutter stabilizer – Effectiveness and costs

Bridge Maintenance, Safety, Management, Life-Cycle Sustainability and Innovations, 2021

Eccentric-wing flutter stabilizer: Analysis and wind tunnel tests

Insights and Innovations in Structural Engineering, Mechanics and Computation, 2016

Download

Efficient Fatigue Assessment in the Time Domain in Comparison to Spectral Fatigue Analysis of an Offshore Jacket Structure

Offshore Technology Conference, 2016

Bridge flutter control using eccentric rotational actuators

Wind and Structures An International Journal, 2013

Eccentric-wing Flutter Stabilizer for Bridges

IABSE Conference, Guangzhou 2016: Bridges and Structures Sustainability - Seeking Intelligent Solutions, 2016

Download

Active mass dampers for flutter control of bridges

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A novel active mass damper for vibration control of bridges

Bridge Maintenance, Safety Management, Health Monitoring and Informatics - IABMAS '08, 2008

ABSTRACT

Collapse resistance and robustness of bridges

Bridge Maintenance, Safety Management, Health Monitoring and Informatics - IABMAS '08, 2008

Download

Robustness assessment of a cable-stayed bridge

Bridge Maintenance, Safety Management, Health Monitoring and Informatics - IABMAS '08, 2008

The failure of one structural element can lead to the failure of further structural elements and ... more The failure of one structural element can lead to the failure of further structural elements and thus to the collapse of large structural sections or the entire structure. Such dispro- portionate collapses have been discussed and investigated for some years, but mainly for build- ings. Generally, structures can be made collapse resistant by ensuring a high level of safety against local failure or by increasing their robustness. Robustness has been defined as the insen- sitivity to local failure. Increasing the robustness of cable-stayed bridges means to design for the loss of cables. The sudden loss of cables is a dynamic event and must be investigated in non- linear dynamic analyses. For the design, only the maximum responses are of interest. For this, quasi-static analyses using dynamic amplification factors to account for the dynamic effects are advised. This paper examines the structural response of a cable-stayed bridge to the loss of one cable by means of dynamic analyses including large displacements. The effects of cable sag, transverse cable vibrations and structural damping are determined and dynamic amplification factors are computed. Finally, conclusions are drawn as to the collapse behavior of cable-stayed bridges taking into account non-linear material behavior.

Conceptual Layouts and Angles of DiaGrid for Building Frames using Topological Optimization

Proceedings of the Tenth International Conference on Computational Structures Technology

Terminology for treating disproportionate collapse

Bridge Maintenance, Safety, Management and Life-Cycle Optimization, 2010

Download

Cable-loss analyses and collapse behavior of cable-stayed bridges

Bridge Maintenance, Safety, Management and Life-Cycle Optimization, 2010

The interaction of steel tube and concrete core in concrete-filled steel tube columns

Tubular Structures XII, 2008

... von Nabil Mohsen Ahmed Falah aus Sana'a, Jemen 2009 ... Furthermore, the interaction bet... more

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