A New Computational Approach for the Rocking Response of Deformable Bodies Considering Material Nonlinearity

Avgenakis, Evangelos; Psycharis, Ioannis N.

doi:10.7712/120117.5618.17884

Cited by 3 publications

(1 citation statement)

References 15 publications

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“…This formulation is extended in this paper in order to take material nonlinearity into account, since rocking members are expected to yield during strong seismic events. The monotonic case has been addressed in [20], but cyclic loading, which is examined herewith, is much more complex and needs a different treatment.…”

Section: Introductionmentioning

confidence: 99%

A Macro-Element Formulation for the Response of Inelastic Rocking Bodies Under Cyclic Loading

Avgenakis¹,

Psycharis²

2019

Proceedings of the 7th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COM

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In this paper, a macroelement for the prediction of the response of inelastic rocking bodies is proposed, which can be used in cyclic loading simulations. The ideas presented for the elastic rocking element formulation in previous works by the authors are extended here to the inelastic material case. Thus, apart from the deformability along the height of the body, the proposed macroelement also takes into account the inelastic deformations near the rocking interface, which is considered crucial for the accurate determination of the rocking response of deformable rocking bodies. Due to the partial loading of the rocking interface, nonlinear stress distributions develop across the rocking interface, which produce additional displacements to those predicted by the technical theory of bending. Taking these and the additional plastic displacements due to material nonlinearity into account, the correct stress distribution is determined based on the target displacements. The pushover curves derived with the proposed macroelement for characteristic problems are presented, while comparison is made against experimental results from the literature, showing satisfactory accuracy. 4719 COMPDYN 2019 7 th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering M. Papadrakakis, M. Fragiadakis (eds.

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Section: Introductionmentioning

confidence: 99%

A Macro-Element Formulation for the Response of Inelastic Rocking Bodies Under Cyclic Loading

Avgenakis¹,

Psycharis²

2019

Proceedings of the 7th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COM

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Magnetic restoring forces on rocking blocks

Syrimi,

Tsiatas,

Tsopelas

2024

Earthq Engng Struct Dyn

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This study investigates the idea of adding an extra magnetic restoring force to a rocking block to improve its overall dynamic performance. The proposed concept ensues by introducing a pair of identical magnets to the rocking block. Both magnets are considered lumped on their respective volume centers and are embedded within the rocking block and the supporting base. When properly magnetized, this pair of magnets provides the rocking block with an extra magnetic restoring force which, although it takes on its maximum value when the two magnets are in contact, decreases as the distance between the two magnets increases. The proposed concept, subjected to pulse‐type base excitations, reveals the inherent problem of magnetic restoring forces. From the overturning spectra of the rocking block, it is found that there are cases where the block fails (overturning) in the presence of magnets, while the same free‐of‐magnets block rocks safely (no overturning) when its own weight acts as the only restoring force. This interesting finding appears to be counterintuitive. Is it possible that by providing additional restoring force the block is “driven” to overturn? This study shows that when the rocking block returns toward the vertical position, the angular velocity, in the presence of magnets, is higher than the angular velocity, in the absence of them. This increase in the angular velocity is a direct outcome of the nature of the magnetic restoring forces, and it is mainly the reason that causes the overturning of the rigid block during its free vibration regime. To mitigate the shortcomings of using magnetic restoring forces, the idea of a semi‐active control of the pair of magnets is introduced and explained in detail. This paper concludes with the advantages and potential disadvantages of the overall performance of rigid blocks in the presence of magnetic restoring forces.

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Modeling of Inelastic Rocking Bodies under Cyclic Loading

Avgenakis

Psycharis

2020

J. Eng. Mech.

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A New Computational Approach for the Rocking Response of Deformable Bodies Considering Material Nonlinearity

Cited by 3 publications

References 15 publications

A Macro-Element Formulation for the Response of Inelastic Rocking Bodies Under Cyclic Loading

A Macro-Element Formulation for the Response of Inelastic Rocking Bodies Under Cyclic Loading

Magnetic restoring forces on rocking blocks

Modeling of Inelastic Rocking Bodies under Cyclic Loading

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